Zhone Technologies Network Card Network Device User Manual

IMACS Product Book  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TABLE OF CONTENTS  
Section:  
Title:  
Page  
:
I.  
IMACS Product Overview  
II.  
Chassis and Common Equipment  
14  
14  
21  
23  
27  
1.  
2.  
3.  
4.  
IMACS Chassis and Backplane  
CPU Cards  
Interface Cards  
WAN Cards  
III. Voice Modules and Applications  
31  
31  
32  
34  
36  
39  
1.  
2.  
3.  
4.  
5.  
FXS  
FXO  
E&M  
P-Phone  
Voice Channel Bank Application  
IV. Data Modules and Applications  
41  
44  
47  
50  
53  
56  
60  
61  
62  
1.  
2.  
3.  
4.  
5.  
6.  
7.  
8.  
HSU  
SRU  
FRAD  
OCU-DP  
BRI  
DSO-DP  
BnR IP Concentrator  
PM-IOR  
V.  
Alarm Cards  
64  
Download from Www.Somanuals.com. All Manuals Search And Download.  
TABLE OF CONTENTS CONTINUED  
Section:  
Title:  
Page  
:
VI. Server Cards  
65  
65  
69  
77  
79  
85  
90  
94  
1.  
2.  
3.  
4.  
5.  
6.  
7.  
ADPCM  
ISDN  
Management Channel Concentrator (MCC)  
ACS-FRS  
ATM  
Internet Protocol Router  
Low-Bit Rate Voice Server  
VII. IMACS System Testing and Diagnostics  
98  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
I. IMACS Product Overview  
IMACS  
Zhone Technologies’ Integrated Multiple Access Communications Server (IMACS) is a highly flexible and  
intelligent Integrated Access Device (IAD) that enables service providers worldwide to offer a wide variety of  
business communication services efficiently and cost-effectively. Services include Plain Old Telephone Services  
(POTS), analog private lines, Digital Data Networks (DDN), Frame Relay, Integrated Services Digital Network  
(ISDN), Asynchronous Transfer Mode (ATM) based services, high-speed Internet access and integrated routing.  
The IMACS supports V.35, V.11/X.21, HDSL, T1, E1, fractional T1, fractional E1 and DS3 network interfaces. For  
user connectivity, a variety of interfaces are available to support analog and digital devices.  
An integrated Digital Cross Connect is available to consolidate multiple voice, data and T1/E1 services. In addition,  
IMACS offers a powerful array of built-in network diagnostic and fault isolation capabilities. These include built-in  
Bit Error Rate Testers, test tone and signaling state generation, digital and analog loop-back support and remote  
configuration and control. The Server slots on the IMACS platform enable provisioning advanced services such as  
voice compression (ADPCM and ACELP), ISDN call handling, Frame Relay switching and concentration, MCC  
and ATM adaptation.  
Three types of IMACS chassis are available. The IMACS 600, IMACS 800 and IMACS 900 differ in their card  
capacity and front or rear card install options. All models support the same range of modular cards, power supplies  
and system redundancy options. All IMACS systems can be fully managed either with local craft interface with a  
VT100 or PC or through a network management system using SNMP.  
The IMACS is a component of a complete line of managed, integrated access solutions from Zhone Technologies.  
Figure 1 shows how the service provider can deliver a complete suite of fast, efficient and reliable business  
communication services to the customers by deploying the Sechtor 300, IMACS, the StreamLine and the Z-Plex 10.  
Internet  
Sonet  
Ring  
ISDN  
Z-Plex 10  
ATM  
POTS  
Add/Drop  
Multiplexer  
Private Data  
Private Voice  
(PBX)  
PSTN  
M13  
Frame Relay  
ATM  
StreamLine  
Secht  
Internet  
Extranet  
Intranet  
Video  
3/1/0 DACS  
GR303 NS.2  
VT/VC Grooming  
IMACS  
Figure 1 - IMACS Product Family  
March 2001  
Page 1  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
IMACS Features and Benefits  
Flexibility and Intelligence  
Global Standards Compliant—ensures product can be integrated in any international telecommunications network.  
Provisioning for extensive array of services and applications—flexibility which enables providers to generate  
revenues without replacing existing equipment.  
Concurrent support for Circuit, Packet, Frame, and Cell processing—single solution for service providers to use  
rather than purchasing and managing multiple boxes and networks.  
Cost-effective migration path to emerging access services and technologies - investment protection.  
SNMP Manageable—industry-wide accepted standard for network management a Remote software download  
capability—time and technical support resources savings.  
Modular Architecture  
Ease of service and capacity expansion—preserves existing investment and reduces any need to forklift upgrade  
from old equipment.  
Flexibility of provisioning technologies using multi-bus architecture- analog, digital, packet, frame, cell, etc.—  
enables carriers to offer various services and be a “one-stop” provider which generates more revenues.  
Interchangeable set of User, WAN, and Server cards determine application set.  
Well-designed chassis to fit into a variety of standard racks.  
Powerful User Interface and Remote Management Capabilities  
Fully configurable through software—locally and remotely—eliminates need to send out technical support  
personnel to multiple sites, saving time and money.  
Remote software upgrade capability on various cards—eliminates need to purchase new cards.  
System Integrity Features  
Low power consumption.  
Single chassis redundancy of power supply, CPU, network interfaces and converter.  
Choice of clock synchronization sources with automatic clock fallback to alternate choice.  
Ease of Maintenance and Enhancement  
Multiple maintenance ports for WAN, data and voice modules.  
Extensive system-wide built-in diagnostics and fault isolation tests.  
Continuous alarm monitoring.  
Local and remote alarm logging.  
Easy access to customer technical support.  
Hot swappable cards.  
March 2001  
Page 2  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
IMACS Architecture Overview  
The IMACS chassis architecture supports three types of buses and five card types. The buses are the:  
User  
WAN  
Server  
Communicating through the buses are the following five card types:  
CPU  
WAN  
User  
Server  
Interface  
Each system has at least one CPU, WAN and one Interface card. These three cards provide common functions for  
the shelf. The WAN, User, and Server cards provide the specific voice/data terminal and network interfaces and  
processing required by the customer to transfer voice and data traffic from the customer premise to the network.  
IMACS architecture has specific card slots, which are tailored to provide either a WAN, User or Server function.  
IMACS System Bus Architecture  
The IMACS is a multiprocessor-based platform that handles today’s network access needs and provides a migration  
path to the wide range of services of the future. A unique multi-bus architecture provides this flexibility by off-  
loading and isolating the Wide Area Network (WAN) link processing tasks from those of inter-processor  
communications and channel I/O (input/output) control and signaling. The CPU card employs multiple  
communication buses extended through the back plane to the User, Server, WAN and Interface Cards. The CPU  
uses these buses to configure hardware on User, Server, WAN, or Interface cards and solicit status. Depending on  
the intelligence on the card, the CPU may either read or write to the card’s hardware registers or send and receive  
messages using a messaging protocol.  
This design approach yields two significant advantages over other access multiplexers. First, the off-loading of  
processing tasks across the multi-bus reduces system overhead, thereby improving the effective throughput and  
performance. Second, the isolation of functions allows rapid design and development of new network access  
compatible WAN functions. As the new functions are introduced, they occupy the Server card slot and do not  
impact or disrupt an existing system. For instance, the design of the Frame Relay Server card was performed  
utilizing the Server processor bus and is independent of other existing or future IMACS functions. When a Frame  
Relay server card is installed, it can perform Frame Relay access concentration on WAN links and fractional  
channels assigned to the IMACS. Figure 2 shows a functional block diagram of the IMACS’s multi-bus architecture  
and the manner in which functions are isolated.  
March 2001  
Page 3  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
DSX  
G.703 CEPT  
CSU  
NETWORK  
MANAGEMENT  
SNMP AGENT  
HDSL  
HDSL  
SERVER FUNCTIONS  
T1  
E1  
NODE  
MANAGEMENT  
ISDN PRI  
FRAME RELAY  
VOICE COMP  
WAN CONNECTIVITY  
MODEM  
TELNET  
VT100  
I/O X CONNECT  
MANAGEMENT  
COMMUNICATION  
RITS  
EXTERNAL ALARMS  
C
ATM  
ISDN  
BRI  
LAN  
DIGITAL  
ACCESS  
VOICE  
DATA  
OCU-DP  
‘U’ INTERFACE  
FXO  
FXS  
SUB-RATE  
IP/IPX ROUTING  
n x 56/64  
FRAD  
DSO-DP  
G.703  
‘S/T’ INTERFACE  
BRIDGING  
E&M  
Figure 2 - IMACS Architecture  
User Buses  
The User buses are essentially a group of four Time Division Multiplexing (TDM) highways, each 2.048 Mbps in  
capacity, and named A, B, C, and D. They are utilized by the User cards to format their traffic for further processing  
either by Server or WAN cards. User cards are intended to provide physical interfaces to data or voice equipment  
that either resides on site or is remotely connected over low speed analog or digital facilities. Server cards may  
interface with these buses directly; whereas a cross-connect or bus connect CPU is required to interface the user  
buses to WAN cards.  
IMACS Voice cards are designed to use the A and B buses only. When there are voice cards installed, the CPU  
allocates bandwidth on the A or B buses to these modules first. It then may utilize the remaining A and B bus  
bandwidth for any other User cards inserted into the shelf. Most Data Cards can be configured to use all 4 user  
buses.  
WAN Buses  
The WAN buses are a group of eight Time Division Multiplexing (TDM) highways, each 2.048 Mbps in capacity,  
and named W1-1, W1-2, W2-1, W2-2, W3-1, W3-2, W4-1 and W4-2, respectively. They are utilized by the WAN  
cards to format their traffic for transmission to high-speed digital facilities via the physical connector on the  
Interface card. A WAN link is typically a T1, CEPT-E1, DSX-1 or HDSL facility connection. There are four WAN  
card slots in an IMACS chassis. Each WAN card slot has 8 leads connected to the Interface card, which can be used  
to support a T1/E1 facility. The fourth WAN slot has all the WAN connections from the other 3 slots in addition to  
its own. These connections all terminate on the fourth WAN slot to support the WAN redundancy feature. The  
WAN in the fourth slot can substitute for one of the other WAN cards by connecting the redundant WAN card to the  
facility leads of the failed WAN card.  
March 2001  
Page 4  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Server Buses  
The Server buses are all the buses that are accessible by the Server cards. Effectively this is the union of User buses  
and WAN bases. This enables the Server cards to provide a data processing function for WAN and User cards. The  
Server/Server card typically provides a centralized processing function on data initially entering the system from  
User or WAN connections.  
A Server/Server card has the same highway interfaces as a CPU card with cross-connect functionality. A Server  
card can therefore function as a general cross-connect, or can rely on the cross-connect on the CPU, as needed by  
the application. The directions of the highways may be reversed, depending on whether a Server card is interfacing  
with User/WAN cards or with another CPU/Server card. For example, when a Server card is interfacing with  
User/Wan cards, it will drive the same TDM highways a CPU card normally drives. When interfacing to a CPU  
card it will drive the same TDM leads of a highway as a User/WAN card drive. When interfacing to another Server  
card, both cards may have to be programmed as to which highway lead to drive on and which to receive on. It may  
have to be able to drive and receive on both of the transmit and receive highways on a per time slot basis.  
Card Type Summary  
The IMACS chassis architecture supports five basic types of cards. They are the Central Processing Unit (CPU)  
card, Interface card, Wide Area Network (WAN) card, User card and Server card. Each IMACS system has at least  
one CPU and WAN card and one Interface card. These three cards provide common functions for the shelf. The  
WAN, User, and Server cards provide the specific data terminal and network interfaces and processing required by  
the customer to transfer data from the premise to the network. IMACS architecture has specific card slots, which are  
tailored to provide either a WAN, User or Server function.  
CPU Card  
The CPU is the “brain” of the IMACS and performs most of the configuration, management, and MIB and common  
processing for the IMACS. In addition the CPU card provides the interconnection of WAN, User, and Server TDM  
buses through a bus connect or cross-connect function. The IMACS can have up to 2 CPU cards, which provide a  
redundant control and switching complex. If the primary CPU fails, the standby takes over. A Mini-DACS 1/0  
cross-connect for 256 DSOs is available.  
Interface Card  
The interface card has common hardware, which is managed by the active CPU card. Configuration information  
processed on the CPU card is stored in the NVRAM on the interface card. It has interfaces to support a modem,  
control terminal, management port, printer, alarm relay, and provides the physical connection to the eight T1/E1  
interfaces used by the WAN cards. The card also contains the clock hardware, which provides the entire back plane  
timing signals for the PCM buses. One Interface card is required per system.  
WAN Card  
The WAN cards provide electrical interfaces to high-speed digital facilities, which are connected via the Interface  
card. The WAN cards take the voice and data traffic off the TDM bus, which was put there by the User and Server  
cards, and transmit the information over a WAN link. A WAN link is typically a T1, CEPT-E1, DSX-1, or HDSL  
facility connection. The WAN cards support a 1:N redundancy feature with Cross Connect CPUs only.  
March 2001  
Page 5  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Voice Card  
The IMACS supports a wide-variety of cards to support voice channel bank applications. Typically they are a  
family of cards each of which provides 8 ports, which translate the analog signal to PCM and translate the signaling  
information from the analog interface for transmission over a digital facility. The interfaces supported include FXS,  
FXO, E&M, FXS Coin, FXO Coin and P-phone.  
Data Card  
The IMACS supports multiple types of data cards for transport of Digital Data in 2, 4, 8 or 10 port models. They  
include High-speed synchronous V.35, EIA530, RS449, RS422, V.1 data, low speed RS232, V.24 data, DDS traffic  
(Digital Data via an OCU-DP or DSO-DP) and ISDN-BRI traffic.  
Server Card  
The Server cards provide voice and data processing functions for WAN voice and User cards. The Server card  
typically provides a centralized processing function on traffic initially entering the system from User or WAN  
connections. The function is implemented, as a Server card when processing is needed on the data, following the  
termination of the physical interface layer. One example is protocol processing, where information needs to be  
extracted from a bit oriented protocol entering from one port, is processed, and sent out another port. The hardware  
function of the protocol processing is separated from the hardware required to support the physical interfaces.  
Traffic may arrive from time slots over a WAN link, or via an FXS card. An example is the ADPCM voice  
compression server card. The compressed voice data can be extracted from selected time slots of T1/E1 WAN links,  
and then expanded by ADPCM Server module. This can be accomplished without each WAN card having the  
hardware required to compress all its channels. Server cards can also be used to perform a high-speed trunking and  
aggregation function for the shelf. In these applications a Server card may have a high-speed cable or optical  
interface. An example of a high-speed aggregation function on a Server card is the ATM Server card, which has a  
high-speed DS3 interface. Other examples are the Frame Relay module for Frame Relay concentration, ISDN-PRI,  
Inverse-muxing, or Low Bit Rate Voice (LBRV).  
Redundancy and Load Sharing  
IMACS supports load sharing and redundancy of the following critical system modules:  
System Power Supply Unit  
CPU Card  
WAN Card  
ADPCM Voice Compression Card  
Power Supply Redundancy  
The IMACS Power Supply Units can support load sharing power redundancy and require the installation of two  
identical power supplies in the unit. The status of the power supplies is reported via LEDs that are visible through  
the front panel. Both IMACS power supplies load share in supplying all the power signals on a shelf. This includes  
120/240 VAC, 24 VDC and -48VDC (when equipped). The IMACS power supplies are fully equipped with “ORing  
Diodes” on all power rails. Therefore, insertion and removal of power supplies are non-intrusive to system  
operation. Depending on system configuration, a single power supply can fully support the system. The main  
IMACS CPUs are also equipped with power supply monitoring functions. This capability enables the CPU boards  
to monitor the instantaneous levels of all voltages in the system. This provides immediate alarming of failed power  
supplies by the active CPU card.  
March 2001  
Page 6  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
CPU Card Redundancy  
The IMACS CPU cards typically support redundant operation when paired with an identical CPU card. The CPUs  
communicate with each other once every second. If there is a problem with the standby CPU (i.e., communications  
transfer did not take place), an alarm is raised by the active CPU, indicating a problem with the standby CPU. The  
active CPU monitoring is achieved via hardwire watchdog timers on the Interface Card. The Interface Card’s  
hardware timers are sensing specific control points from the controlling CPU circuit pack. These timers require only  
8 seconds to detect and reset to the redundant blinking CPU card.  
WAN Card Redundancy  
The IMACS Dual WAN cards in conjunction with a Dual WAN card with Relays support a 1-to-N redundancy. For  
redundant operation, the redundant WAN card will be located in the last WAN slot which is marked W4 and can be  
used in systems with cross connect CPUs to act as a redundant card for up to three Dual WAN cards containing the  
same modules. Both ports of the redundant card must be populated with either the DSX/CEPT or CSU module and  
must be an exact match to any corresponding WAN Cards with which it is redundant.  
All IMACS WAN cards communicate with the active CPU card every half-second. If the WAN card fails to  
properly communicate with the active CPU card, the WAN card is declared failed and a switch occurs. These  
actions occur within an eight second time frame. The WAN card failures can also occur from craft defined rules.  
These rules are based on Carrier Group Alarm (CGA) declaration assignments. A CGA switch will occur 1.5  
seconds after a CGA declaration, or forced “OOS” command from the User Interface (UI). The WAN card will  
remain in the switched condition for 20 seconds, or until synchronization can be achieved. If synchronization is not  
achieved, the WAN switch will return to its original state. If the switch is successful, the active CPU issues an  
alarm and the WAN switch continues in a steady state operation.  
ADPCM Redundancy  
The IMACS Adaptive Differential Pulse Code Modulation (ADPCM) Server card provides 1-to-N redundancy when  
used with 2 other identical cards. The ADPCM card has on-board diagnostics that can detect a failure in one second,  
and switch in three seconds.  
System Synchronization and Clocking  
The Interface card includes a Stratum 4 clock circuit, which is capable of running off its own crystal oscillator or  
phase locking to a 8 KHz reference clock on the back plane. Any card plugged into the back plane that connects to a  
network-like facility can be programmed to supply the reference clock input to the Stratum 4 Clock. As an option, a  
separate external timing source may be used on a specific interface card.  
The IMACS supports a three-tiered hierarchy of system clocking sources that are provisioned under the interface  
card menu options. Should the Primary source fail, the system will fall back onto the Secondary source. Should  
both Primary and Secondary sources fail, the system will default to its internal Stratum 4 clock. In all cases,  
recovery is automatic should the failed clock(s) recover.  
Both the Primary and Secondary clocks can be user-programmed to be derived from the following:  
IMACS system’s internal oscillator.  
Any of the WAN interfaces in the system.  
A server card such as the ATM, which can provide timing through the DS3 link.  
A user card such as the BRI.  
An external synchronization device (framed T1 and unframed E1) through an 8922 I/F card.  
March 2001  
Page 7  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
The system will switch to the backup clock source upon detection of one of the following conditions in the currently  
active source:  
CGA Red Alarm.  
CGA Yellow Alarm.  
Out-Of-Service (OOS) condition.  
Clock source is placed in loop back mode.  
Clock source is placed in standby mode.  
IMACS System Management  
When the IMACS’ active CPU runs the IP protocol stack, it provides SNMP and Telnet support for management of  
local and remote IMACS units as well as provides for routing of IP datagrams to other IMACS systems. The Telnet  
protocol is a remote terminal protocol that allows any PC or workstation equipped with a TELNET client application  
to establish terminal sessions with an IMACS.  
The Simple Network Management Protocol (SNMP) is a widely adopted industry standard method of providing  
common network management control. A typical SNMP management architecture involves a Manager, such as  
Zhone Technologies’ Element Management System (EMS) product and an SNMP Agent, which is responsible for  
providing device management data to the manager. Agents come in two forms: Embedded and Proxy. Embedded  
agents run directly on the device being managed, while Proxy agents require an intermediate system to translate  
from a proprietary messaging format. The IMACS uses Embedded SNMP agents to report management information  
to the manager.  
SNMP is a protocol standard that specifies how management data should be transported between an Agent and a  
Manager. SNMP MIBs (Management Information Base) specifies what comprises the management data. There are  
multiple MIBs that address many types of computer and telecommunications equipment. Some of these are defined  
as standards and are referred to by their RFC (Request For Comment) number. Other MIBs are specific to the  
device being managed and are referred to as Enterprise MIBs. The IMACS supports the following standard and  
enterprise MIBs:  
MIB-II (RFC 1213)  
DS1 MIB (RFC 1406)  
Alarm MIB (Traps to RFC 1215)  
Cross Connect MIB  
Frame Relay MIB RFC1604  
Frame Relay DTE MIB - RFC 1315  
MCC MIB  
ATM Forum UNI3.0 MIB  
DS3 MIB (RFC 1495)  
AToM MIB (RFC 1595)  
Standard MIBs are written to provide management data on a wide number of devices, and in some cases not all of  
the parameters of a MIB are appropriate for the device being managed. Therefore extensions or omissions may be  
required in any standards based MIB.  
The IMACS offers several methods of transporting the SNMP and Telnet traffic from remote sites to the Network  
Management.  
These methods include transport via:  
PPP or SLIP.  
FDL for T1 ESF mode or E1 National Bit 4.  
B7R Encoded Time Slots 24 (T1) or 31 (E1).  
Nx64 HDLC or FR available on CPU5.  
Frame Relay Management PVC.  
ATM Management PVC.  
March 2001  
Page 8  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
IMACS Management Via PPP or SLIP  
IMACS alarms are reported either to a local device or via an internal 2400 bps modem in a proprietary ASCII  
format to a central site. Additionally, the IMACS can be optioned to use TCP/IP and encode alarms as standard  
SNMP traps. One method of transmitting TCP/IP management information and SNMP traps is to activate the Serial  
Line Internet Protocol (SLIP) on the DB-9 port set at 9.6 Kbps. requires that a routed network exists and has full  
connectivity back to the location where the SNMP-based NMS resides. Figure 4 illustrates how terminal servers are  
used to provide connectivity from the IMACS’ serial interface to the router-based network. A typical NMS scenario  
is described below:  
Remote Site 1  
Router  
Remote Site 2  
PBX  
CODEC  
PBX  
CODEC  
Router  
IMACS  
IMACS  
Frame Relay  
Network  
Terminal  
Server  
Terminal  
Server  
NMS  
Figure 3 - IMACS Connectivity to Terminal Servers  
1. An alarm occurs in the IMACS on the left side of the diagram and an SNMP trap is sent out the serial port on  
the interface card.  
2. A serial port of a Terminal Server that is configured for SLIP or PPP accepts the SNMP trap and forwards it  
over the Ethernet LAN.  
3. The IP destination is the NMS; where it is picked up by the router for delivery to the NMS.  
4. The router forwards the trap and other traffic destined for remote LANs, via its Frame Relay WAN connection.  
The router is connected through the IMACS to a Frame Relay network. The Frame Relay Network delivers the  
SNMP trap to the Operations Center on the right side of the diagram.  
5. At the Operations Center, the IMACS, acting as a DSU/CSU, delivers traffic to the router.  
6. The router places the SNMP trap onto the appropriate LAN where the NMS resides.  
7. The NMS acknowledges and processes the trap. At this point an operator, noticing this new alarm, could initiate  
a TELNET session back to the originating IMACS or could browse the MIBs from the NMS.  
March 2001  
Page 9  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
As shown in Figure 4 the IMACS supports multiple methods of communicating SNMP messages and Telnet  
terminal sessions between an end node and the network management station. The addition of PPP support allows  
the IMACS to connect to routers or terminal servers to establish a connectivity path to the network management  
station. The utilization of PPP is similar to that of SLIP.  
PSTN  
T1/E1  
Frame  
Relay  
PBX  
PPP  
Router  
Figure 4 - SNMP Messages and Telnet Sessions on IMACS  
IMACS Management Using FDL/SA4  
Another method of transporting IP datagrams is via the Facility Data Link (FDL) on a T1 link using the Extended  
Super Frame (ESF) format. The FDL channel is a 4 Kbps channel available on the DS1 frame in the ESF overhead.  
The SA4 bits in the frame alignment word of the E1 constitute the equivalent for E1. This method requires that a  
DACS II is used in the central office, and is provisioned to extract the FDL / SA4 stream from the T1 /E1 and map it  
into a DS0 channel. DS0 channels from each remote node are then transported to an IMACS equipped with a B7R  
or MCC card so that IP datagrams can be extracted.  
The use of the 4 Kbps FDL to carry management information across the network is illustrated in Figure 6. The  
remote IMACS at the top of the figure are terminated in a DACS II. The remote IMACS transport the TCP/IP  
management information across the FDL. The DACS II transforms the FDL channel into a DS0 channel using its  
proprietary B7R encoding scheme. These DS0s, carrying management information are combined with other DS0s  
carrying user information and arrive at the IMACS as shown in the bottom of the figure.  
March 2001  
Page 10  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
IMACS  
FDL over ESF  
IMACS  
IMACS  
DACS  
Each FDL is mapped  
to a separate DS0  
NMS  
T1  
38.4 kbps SLIP  
Terminal  
Server  
IMACS  
Concentrator Node  
Figure 5 - IMACS Management Using FDL  
The management DS0s are connected internally to the B7R card with a limit of eight management DS0s per card.  
The output of the B7R card is RS-232 at up to 38.4 Kbps using SLIP. This output is fed into a terminal server or a  
router and transported to a NMS. Alternatively, the SLIP Async stream can be connected directly into a locally  
attached NMS if a port is available. Furthermore, the MCC server card supports up to 128 remote connections.  
IMACS Management Using B7R encoded DS0 (TS 24 for T1 and TS 31 for E1)  
A third method is to carry IP traffic in a DS1’s time slot 24 or E1’s time slot 31. This method requires that each  
time slot 24/31 from multiple remote nodes are groomed in the network into a single T1, and are transported to an  
IMACS equipped with a B7R or MCC card so that IP data can be extracted.  
A B7R card or a MCC card is used in the IMACS at the central site to accept and decode SNMP network  
management information from up to eight remote IMACS (via separate DS0s) (128 for MCC). The IMACS at the  
remote sites can place SNMP traps and other IP traffic in a B7R encoded DS0 (time slot 24/31). A B7R card is not  
required at the remote sites. At the central site a B7R/MCC card is required only if the B7R / DS0 transport  
mechanism is utilized.  
The TCP/IP option must be available to support the B7R function. If the SNMP traps and associated TELNET  
sessions are carried in a B7R encoded DS-0 from the originating IMACS (instead of within the FDL), a DACS II is  
not required. In this case the NMS data from the originating IMACS is formatted by the remote IMACS’s CPU in  
the same B7R format as would have been generated by the DACS II if the FDL scheme was used. In either case, a  
B7R or MCC card is required at the NMS concentrator site. The B7R card is a User card, therefore up to eight B7R  
cards may reside in an IMACS node, supporting eight DS0s each, for a total of 64 remote sites per IMACS. The  
MCC card is a server card, supporting up to 128 remote IMACS nodes. A total of 3 MCC cards are supported per  
concentrator node.  
March 2001  
Page 11  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
To manage the IMACS containing the B7R card, a separate SLIP/PPP connection from the DB9 on the interface  
card is required. The local IMACS cannot route its own SNMP information to an internal B7R card. For example,  
if a network has eight remote nodes, two SLIP connections are required at the central site - one for the eight remote  
IMACS and one for the local IMACS.  
The Management Channel Concentrator (MCC) card allows management of the local system as well as 128 remote  
IMACS nodes. The remote systems may either be communicating using B7R on TS 24 (T1) or B4R on TS31 (E1)  
directly, via a cross-connect or be using FDL (T1) /SA4 (E1) with a DACS version 6.2 or equivalent. In addition,  
the MCC card has also four ports configurable with for a variable number of nx64 kbit DS0s. These can be used to  
forward already concentrated IP traffic down to a second MCC card.  
Any SNMP manager can receive the SNMP trap and respond by initiating a TELNET session with the originating  
IMACS for diagnostics and control. Note that the local and remote reporting feature of the IMACS is disabled if the  
TCP/IP network management feature is active. The IMACS supports sending traps up to three SNMP trap servers,  
allowing alarms to be sent to multiple network management stations.  
However, once the cards are installed and the chassis populated, these identifiers are no longer visible.  
March 2001  
Page 12  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
a) E & M card with 2713 Hz Loop back – Module# 811760:  
This feature will provide digital loop back (both audio and signaling) when activated by a 2713 Hz tone of specified  
level and duration. The requirements are provided by BellCore PUB 42004. When a validated tone is detected the  
channel should disconnect the user and provide loop back of signals (audio and signaling) received from the  
network. The loop back must be performed without inserting any gain or loss in the path. After tone activation, the  
channel shall remain in the loop back mode unless deactivated for a period of 20 minutes (+/- 1 minute) after which  
the channel shall automatically revert to the idle (non loop back) mode.  
b) (Optional) P-Phone Line card with 8 ports (PPS Module# 812160 and PPO Module#  
813160):  
The purpose of this feature is to provide an 8-port P-Phone Line card in the Streamline for Host 1.2. The P-Phone  
line card is used by Nortel to support transport of P-Phone service. There are two applications of the line card, one  
at the Office end (P-Phone Office – PPO), and one at the Station end (P-Phone Station – PPS). Hence, PPO and  
PPS are two user cards designed to support connectivity between a Nortel SL-100 PBX or DMS-100 based Centrex  
PBX and Nortel M5000 series Electronic Business Sets (P-Phones). The P-Phone is an electronic telephone set  
capable of supporting premium Meridian Digital Centrex (MDC) features offered by the local DMS switch. The  
data channel allows out-of-band signaling between the P-Phone and the DMS switch. This data channel allows the  
user to activate MDC features, such as conference calling by simply pushing keys on the P-Phone set, and for the  
DMS to deliver information, such as caller identification, to the P-Phone display. This P-Phone line card encodes the  
received out-of-band signaling tones, transports them across the carrier and decodes the digital representation back  
to out-of-band tones at the other end. Hence, this line card simply repeats the signaling end-to-end.  
The market for P-Phones is by definition limited to Nortel switches and PBXs: DMS100 (Class 5 switch), DMS500  
(Combination of Class 5 and a Tandem switch), DMS10 (Lower capacity switch for rural areas) and SL100 (Large  
Enterprise PBX).  
P-Phones supported include: M5000 series business sets, models M5009, M5112, M5209, M5212 and M5312.  
March 2001  
Page 13  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
II. IMACS Chassis and Common Equipment  
1. IMACS Chassis and Back Plane  
The IMACS is available in three chassis models to meet various space/capacity requirements. They are the IMACS  
600 Universal Enclosure, the IMACS 800 Universal Enclosure and the IMACS 900 Universal Enclosure.  
IMACS 800 Universal Enclosure  
The IMACS 800 Universal Enclosure provides card slots on both the front and back of the unit for both front and  
rear loading. These are sometimes referred to as the “Network” and “User” sides respectively. There are nine card  
slots that are accessible from the front and an additional nine that are accessible from the back. Card slots are  
intended to accommodate specific card types and are keyed so that only those card types may be inserted in those  
slots. A CPU card may be inserted in either Slot C1 or C2. Two CPUs can be installed in Slots C1 and C2  
simultaneously to provide CPU redundancy. All IMACS Universal Enclosure models are NEBS (TR63) approved.  
The nine front card slots are allocated and shown in Figure 7 as follows:  
Slot Number  
C1 and C2  
Card Types Supported  
CPU cards  
P1, P2 and P3  
W1, W2, W3 and W4  
Server cards  
WAN cards  
JP1  
1
2
3
F1  
F2  
C1 C2 P1 P2 P3 W1 W2 W3 W4  
Figure 6 - IMACS 800 Universal Enclosure—Front View  
March 2001  
Page 14  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
The nine back card slots are designated as IF and U1 through U8 respectively and are allocated and shown in Figure  
7 as follows:  
Slot Number  
IF  
Card Types Supported  
Interface card  
U1 through U8  
Voice, Data and External Alarm cards  
R1  
AC  
R2  
R3  
R4  
R5  
R
+
-
N
-
+
A
+
-
C
O
M
G
V
V
V
B
R
IF U1 U2 U3 U4 U5 U6 U7 U8  
Figure 7 - IMACS 800 Universal Enclosure—Rear View  
In addition to the card slots described above, the IMACS 800 chassis accommodates a power supply and ringing  
generator system. The power and ringing system can consist of up to two power supplies, two 120/240VAC-to-  
48VDC Converters, and up to three ringing generators. Five ringing generators can be supported in a system if there  
are no 120/240VAC-to-48VDC Converters installed. The maximum power consumption of an IMACS is 125  
Watts. Power supplies are inserted into either of the two power slot positions (F1 and F2) from the front of the  
chassis.  
The IMACS 800, 900 and 600 models support load sharing power redundancy. To achieve redundancy, the  
installation of two identical power supplies is required. The power supply status is reported via LEDs that are  
visible through the front panel. Alarm messages are generated when one of the two power supplies malfunctions or  
fails.  
IMACS 900 Universal Enclosure  
The IMACS 900 Universal Enclosure has the same capacity as and provides the same module slots in a front-  
loading only “repackaged” version of the IMACS 800 chassis.  
There are nine slots that are referred to as the “Network” cards and an additional nine (9) that are “User” cards  
respectively. CPU card installation and slot allocation is the same as the IMACS 800. The nine network card slots  
are allocated the same as the IMACS 800 and are shown in Figure 9. The nine user card slots are designated as IF  
and U1 through U8 respectively and are the same as the IMACS 800.  
March 2001  
Page 15  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
R1  
R2  
R3  
R4  
R5  
F1  
F2  
AC  
RGR  
+
-
VN  
VA  
VB  
-
+
+
-
COM  
JP1  
1
2
3
S
U
/
R
U
E
C1 C2  
P1 P2 P3 W 1 W 2 W3 W 4 IF U1 U2 U3 U4 U5 U6 U7 U8  
Figure 8 - IMACS 900 Universal Enclosure  
In addition to the card slots described above, the IMACS 900 chassis supports the same power supply and ringing  
generator system as the IMACS 800. Power supply loading is done the same way as the IMACS 800.  
IMACS 600 Front Load Enclosure  
The IMACS 600 Universal Enclosure provides card slots only on the front of the unit as shown in Figure 10.  
This chassis is ideally suited for wall mount installations. In contrast to the IMACS 800 and 900 Enclosures (where  
User, CPU, WAN, and Server Cards were installed in the dedicated card slots), the IMACS 600 chassis allows user  
cards to be installed in any unused Server card or WAN card slot.  
Slot Number  
C1 and C2  
P1-P4  
W1-W4  
IF  
Card Types Supported  
CPU card  
Any Server or User card  
Any WAN or User card  
Interface card  
March 2001  
Page 16  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
JP1  
1
2
3
S
U
/
R
U
E
S1  
S2  
R1  
R
G
R
+
V
-
-
V
+
+
V
-
C
O
M
N
A
B
C1 C2 P1 P2 P3 P4 W1 W2 W3 W4 IF  
Figure 9 - IMACS 600 Universal Enclosure  
In addition to the card slots described above, the IMACS 600 Universal Enclosure accommodates two power  
supplies or one AC Power Supply, one AC-DC converter, and one ringing generator.  
Physical and Environmental Characteristics  
The IMACS Universal Enclosure dimensions are shown in Table 1.  
Table 1--IMACS Dimensions  
Chassis  
Model  
600  
Height  
in.  
9.120  
9.120  
15.375  
Width  
Depth  
cm  
in  
cm  
in  
cm  
23.16  
23.16  
39.05  
17.042  
17.042  
16.918  
43.29  
43.29  
42.97  
9.131  
15.300  
9.105  
23.19  
38.86  
23.13  
800  
900  
The IMACS 600/800/900 can be mounted on:  
EIA 19” (482 mm) standard open rack  
Enclosed Cabinet or a WECO 23” (584 mm) standard open rack  
Enclosed Cabinet (by using adapter ears)  
Wall-mounted (with 4 screws)  
Desktop  
March 2001  
Page 17  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
All the IMACS units are convection-cooled and require some minimum clearances for optimum operation.  
Clearance requirements also account for distance required for removal and insertion of cards from/into the  
chassis. The minimum clearances are shown in Table 2.  
Table 2—IMACS Minimum Clearances  
600  
800  
900  
Front  
Back  
Top  
15” (38 cm) 15” (38 cm) 15” (38 cm)  
0” (0 cm)  
2” (5 cm)  
2” (5 cm)  
15” (38 cm)  
2” (5 cm)  
2” (5 cm)  
0” (0 cm)  
2” (5 cm)  
2” (5 cm)  
Bottom  
In all cases, the unit must be installed in an environment that meets the following specifications:  
AC power (120VAC):  
AC power (120/240 VAC):  
DC power (-48 VDC):  
DC power (24 VDC):  
Power consumption:  
90 VAC to 135 VAC  
175 VAC to 264 VAC  
-42 VDC to -60 VDC OR-39VDC TO -60VDC  
20 to 32 VDC OR -18VDC TO 36 VDC  
125 Watts  
o
o
o
o
Operating temperature:  
0 C to 50 C (41 F to 121 F)  
o
o
o
o
Storage temperature:  
Operating Rel. Humidity:  
-20 C to 80 C (-4 F to 176 F)  
5% to 85%  
The IMACS Universal Enclosures conform to the following regulatory standards shown in Table 3.  
Table 3—IMACS Compliance With Regulatory Standards  
ANSI 310-D  
UL 459  
Racks, Panels, and Associated Equipment  
Telephone Equipment  
Bellcore GR-63-CORE  
Network Equipment-Building System (NEBS), Level 3  
Requirements: Physical Protections  
Bellcore GR-1089-CORE, Issue 1  
Bellcore TR-NWT-000295 Issue 2  
CE EN 500 81-1  
Electrical compatibility and electrical safety generic criteria  
for network telecommunications equipment  
Isolated Ground Planes: Definition and Application to  
Telephone Central Offices  
Electromagnetic compatibility generic emission standard  
Part 1 Residential, commercial and light industry  
Electromagnetic compatibility generic immunity standard  
Part 1 Residential, commercial and light industry  
Safety of information technology equipment including  
electrical business equipment  
CE EN 500 82-1  
CE EN 60 950/A2  
UL 1459  
CSA C22.2, No. 950, DOC CS03  
UL Standard for Safety of Telephone Equipment  
Safety of information technology equipment including  
electrical business equipment  
FCC Part 68 – Subpart B  
Requirements for Connection of Terminal Equipment  
Systems and Protective Apparatus to the Telephone Network  
Racks, Panels, and Associated Equipment  
Subpart B  
IEC 297-1  
FCC Part 15  
Power Supplies  
The IMACS has six power supplies and two ring generators, which can be installed or configured depending on the  
application. Power supply models 8901, 8902 and 8907 provide +/-5VDC and +/-12VDC. As shown in table 4, the  
main difference between these models is the input voltage.  
March 2001  
Page 18  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Models 8903, 8905 and 8908 power supplies provide -48 VDC talk battery voltage from an AC input voltage. As  
shown in table 4, the difference between models 8903 and 8905 is the input voltage range. Model 8905 has a much  
wider input voltage range. Allowing it to operate from any AC line voltage, where as model 8903 has a limited  
range. Model 8908 can only be used with the 900 chassis. It also has the benefit of a wide input voltage range but  
with the addition of providing 300 watts of talk battery power.  
Table 4—Power Supply Specifications  
Model 8901 AC Power Supply 120/240 AC  
Input Voltage  
Self-detecting, 90VAC to 135 VAC at 60HZ  
175 VAC to 264 VAC at 50 Hz  
Input Frequency  
Inrush Surge Current  
Output Power  
47 to 63 Hz  
Max. 12 amp peak at 264 VAC cold start  
55W Continuous  
Maximum Number per system  
Redundancy  
2
Optional  
Ventilation  
Convection cooled  
Protection  
Unit is fused and protected from short circuits and over-  
voltage  
Approvals  
UL 1459, EN 60950, CSA-C22.2 No.950, CE Mark  
Model 8902 DC Power Supply 48 VDC  
Input Voltage  
Inrush Surge Current  
Output Power  
Maximum Number per system  
Redundancy  
-39 to -60 VDC  
Maximum 12 amp at 60VDC  
55 Watts Continuous  
2
Optional  
Ventilation  
Convection cooled  
Protection  
Unit is fused protected from short circuits and overage  
Unit is diode protected from reversed polarity  
UL 1459, EN60950, CSA-C22.2 No.950, CE Mark  
Approvals  
Model 8907 DC Power Supply 24 VDC,  
Input Voltage  
18 to 36 VDC  
Inrush Surge Current  
Output Power:  
Maximum Number per system  
Redundancy  
Maximum 12 amp at 36 VDC  
55 Watts Continuous  
2
Optional  
Ventilation  
Convection cooled  
Protection  
Unit is fuse protected from short circuits and over-voltage  
Unit is diode protected from reverse polarity  
Approvals  
UL 1459, EN60950, CSA-C22.2 No.950, CE Mark  
Model 8903 Power Supply 120 VAC  
Input Voltage  
90VAC to 132 VAC  
Input Frequency  
60 Hz  
Inrush Surge Current  
Output Voltage  
Max. 20amp peak at 132 VAC cold start  
-48.0 VDC  
Maximum Number per system  
Redundancy  
2
Optional  
Ventilation  
Convection cooled  
Protection  
Unit is fused and protected from short circuits and over-  
voltage  
Approvals  
UL 1459, UL 1950, CSA-C22.2 No.950  
March 2001  
Page 19  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Model 8905 Power Supply, 120/240 VAC  
Input Voltage  
90 Vrms to 260 Vrms  
Input Frequency  
50/60 Hz  
Output Power  
100W max  
Output Voltage  
-48.0 VDC  
Output Current  
2 amp  
Maximum Number per system  
Redundancy  
2
Optional  
Ventilation  
Convection cooled  
Approvals  
UL 1459, UL 1950, CSA-C22.2 No.950, CE Mark  
Model 8908 Power Supply, 105/240 VAC  
Input Voltage  
90 Vrms to 260 Vrms  
Input Frequency  
50/60 Hz  
Output Power  
300 W max  
Output Voltage  
-48.0 VDC  
Output Current  
6.25 amp  
Maximum Number per system  
Redundancy  
2
Optional  
Ventilation  
Approvals  
Forced Air, (120mm Fan)  
UL 1459, UL 1950, CSA-C22.2 No.950  
Ring Generator  
Ring generators are required to supply ringing current whenever there are Foreign Exchange Station (FXS) Cards  
operating in the unit or if there is one or more Foreign Exchange Office (FXO) ports that are used in Manual Ring  
Down (MRD) mode.  
The current ring generator model is: Model 890620  
Model 890620,the internal ring generators, will support up to 24 simultaneously ringing phones. Additional ringers  
can be added depending on the chassis and application, (see table 5). The exact number of simultaneously ringing  
subscriber lines supported is a function of the Bell Ringer Equivalency Number (REN) of the attached devices and  
the loop impedance. The user may attach an external ring generator to the IMACS terminal block location marked  
RGR.  
The model 890620 is an enhanced version of the current 8906 ring generator. This model has improved operating  
efficiency and inrush current limiting.  
Table —Ring Generator Specifications  
Model 890620 Ringing Generator  
Input Voltage  
Efficiency  
Protection  
Noise  
42 to 57 VDC, linear = 0.84 max.  
57% at 48 V and 1 kOhm load  
5 A slow blow fuse, primary current limiting  
Less than 32dBrnc  
Output Voltage  
Output Current  
Output Frequency  
Operational Modes  
Maximum Number per system  
100 VDC rms default – adjustable from 60 to 105 Vrms  
160 mA RMS continuous, 230 mA RMS cadence  
20 Hz +/- 1 Hz  
Strap selectable: Master or Slave  
1
1 Master, 3 slaves (DC operation)  
2 slaves (AC operation)  
1 Master, 1 slave  
IMACS 600  
IMACS 800  
IMACS 900  
Redundancy  
There is no provision for Master Ringer redundancy, however  
the slave units provide fail-over protection  
March 2001  
Page 20  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Ventilation  
Approval  
Convection cooled  
UL 1459, CSA-C22.2, No. 950  
March 2001  
Page 21  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
2. CPU Cards  
The CPU card has two micro-controllers, which performs most of the configuration, management, and common  
processing for the IMACS. The CPU card provides the interconnection of WAN/User/Server TDM buses through a  
bus connect or cross-connect function. The CPU can have flash memory which is used to store configuration  
information and facilitates new firmware uploads. The IMACS can have up to 2 CPU cards, which provide  
redundant control and switching capabilities. If the primary CPU fails, the standby takes over.  
There are two microprocessors on the CPU card. The primary micro-controller on the CPU card does the  
configuration and maintenance functions for the IMACS. It is connected through an internal bus to all the  
Server/WAN/User cards and the Interface card. It controls the modem, database, serial terminal interfaces, and  
Stratum 4 clock configuration contained on the Interface card. The CPU is responsible for configuring the hardware  
residing on the cross-connect module (CCM), and configuring hardware on WAN/User cards. It is responsible for  
downloading configurations onto intelligent cards through the appropriate configuration interface. Finally, it  
accesses each WAN card to process FDL messages. The CPU provides control functionality, however it is the  
Interface card that stores the system configuration information.  
The second micro-controller handles standard signaling processing for voice applications. It manages both the  
digital (bit-robbed) and the analog (48V) signaling capabilities of the IMACS. It has enough throughput and  
interfaces to handle the 62 voice channels routed through the A and B buses. The CPU receives signaling from each  
analog voice port and in turn processes the data and generates the appropriate signaling bits over the signaling  
highway to the WAN cards. The WAN cards then embed the signaling bits into the T1/E1 data stream. It also  
processes the signaling from the T1/E1 link to the User cards. The CPU can also customize the format of the  
signaling bits. This is an important feature when interfacing with a variety of central office switches and PBXs.  
Additionally, the CPU card has an interface to the IMACS’ time slot switching matrix. The switching matrix may  
either be a Bus connect (BCON) or Cross Connect (XCON). In the Bus connect configuration, the User bus ports  
can be connected to WAN bus ports but not the Server bus. When Cross-connect is used, all the TDM buses are  
brought up to the switching matrix, which is able to cross-connect time slots between the incoming and outgoing  
buses.  
CPU cards can only be installed in the CPU slots. The shelf can be equipped with two CPUs, which form an  
active/standby pair. Watchdog timer circuitry on the Interface card helps monitor the active CPU and will activate  
the standby CPU if the active CPU fails. The active and standby CPUs communicate directly and the active can  
switch to standby by sending a single message. Additionally, a user can manually switch from the active to standby  
CPU by initiating a command from the VT-100 console. It is the CPU card, which initializes the system upon  
power-up and runs a self-test on all cards plugged into the system. After the initialization procedure, the CPU card  
continuously polls all cards in the system to determine their operating status. Table 7 provides detailed  
specifications on the five CPU models.  
March 2001  
Page 22  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 7—Operational Modes  
Model  
880060  
880460  
Mode  
Cross Connect  
No  
No  
Drop and Insert  
Yes  
Yes  
Terminate  
Yes  
Yes  
Bus-connect  
Enhanced bus-  
connect  
880160, 880260,  
880360  
Cross-connect  
Yes  
Yes  
Yes  
Green for normal operation. Amber for card fault or test mode (amber  
on new cards).  
LED Indicators  
Code Storage  
Models 880060, 880160, 880460  
Model 880260  
256K EPROM  
512K EPROM  
Model 880360  
Configurable with maximum 8MB DRAM and 4MB Flash memory  
Maximum number of WAN links  
Model 880060  
Up to 2 WAN links  
Model 880160, 880260, 880360  
Model 880460  
Up to 8 WAN links  
Up to 4 WAN links. WANs in slot W1 supports voice only operate in  
either Terminate or Drop and Insert mode. WANs in slot W3 operate  
in Terminate mode only and only terminate certain data ports.  
Support for CPU redundancy  
Model 880060  
No  
Model 880160, 880260, 880360,  
880460  
Yes  
Support for WAN link redundancy  
Model 880060  
No  
Model 880460  
1:1—A WAN card in slot W2 provides backup for an identically  
configured WAN card in slot W1. A WAN card in slot W4 provides  
backup for an identically configured WAN card in slot W3.  
1:N—A single model 8014 WAN card in slot W4 provides backup for  
identically configured 8010 WANs in slots W1 through W3.  
Model 880160, 880260, 880360  
Support for Server Cards  
Model 880060, 880460  
Model 880160  
Model 880260, 880360  
Standards Conformance  
Bellcore GR-63-CORE  
No  
Only ADPCM Server card  
Support for all server cards  
Network Equipment-Building System (NEBS) Requirements: Physical  
Protections  
CE EN 500 81-1  
CE EN 500 82-1  
CE EN 60 950/A2  
Electromagnetic compatibility generic emission standard Part 1  
Residential, commercial and light industry  
Electromagnetic compatibility generic immunity standard Part 1  
Residential, commercial and light industry  
Safety of information technology equipment including electrical  
business equipment  
UL 1950  
CSA C22.2, No. 950  
UL Standard for Safety of Information Technology Equipment  
Safety of information technology equipment including electrical  
business equipment  
March 2001  
Page 23  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
3. Interface Cards  
The Interface card has common hardware, which is managed by the active CPU card. One Interface card is required  
per system residing in Slot IF on the IMACS chassis. It provides the physical interface to support a modem, control  
terminal, printer, alarm relay, and provides the connection up to 8 T1/E1 interfaces used by the WAN cards. The  
card also contains the clock hardware, which provides the entire back plane timing signals for the TDM buses. The  
Interface card also contains the configuration database of the IMACS, time of day clock function and watchdog  
timer.  
The database resides in non-volatile SRAM, which enables it to retain its information even when the card is  
unplugged or the IMACS is powered down. The IMACS has software configurable settings for both the primary  
and secondary system-timing clocks. If the primary clock fails, the system will automatically switch to the operator  
defined secondary clock source. The interface card contains the Stratum 4 clock hardware for providing internal  
timing. Other timing options include: timing off the WAN card; timing off an installed ATM server card and timing  
off an installed 826070 or 826171 BRI card. It also has an option for external timing from external synchronization  
clocks (892260 IF card).  
The Interface card may have a Modem port that is used to connect an ITU V.22 internal dial modem to a standard  
telephone line. This port may be used either to log into the unit from a remote VT100 terminal or to send system  
alarms to a remote device. The modem port presents an RJ11 female connector.  
The node port on the Interface card provides the form-C contact closure and the physical interface so that the Alarm  
Cut-Off (ACO) alarm may activate an external alarm system. The node port presents an RJ48 female connector  
with an RS485 electrical interface.  
The Control Terminal port is used to connect a VT100 or compatible terminal to the IMACS system for node  
management and control purposes. The Control Terminal port presents an RJ48 female connector with an RS232  
DCE electrical interface. The port is set to VT100 mode for asynchronous operation at 9600 bps with 8 data bits, 1  
stop bit, and no parity. Also, the port supports an automatic log out feature after 15 minutes of inactivity.  
The Computer Port connects a local device for printing alarms or can be configured to support SLIP for transport of  
SNMP management information or database configuration information. IMACS Release 5.x provides support of  
asynchronous PPP and SLIP. The computer port presents a DB9 male connector with an RS232 electrical interface.  
The Interface card also stores ISDN Call profiles and signaling translation tables. All configuration information is  
stored on the Interface card NVRAM for non-volatile storage of system configuration. A copy of the system  
configuration is stored on the Interface card can be downloaded to the Flash memory on the CPU card. There are  
eight Interface card Models:  
1. 892060 Eight port T1/E1 Interface Card, 2400bps modem  
2. 892160 Eight port T1/E1 Interface Card, no modem  
3. 892260 Eight port T1/E1 Interface Card, no modem, with external sync input  
4. 892360 Eight port T1/E1 Interface Card, 2400bps modem  
5. 892460 Eight port T1/E1 Interface Card, no modem (required for CPU 8803)  
6. 892560 Two port T1/E1 Interface Card, no modem or DB9 port  
7. 892660 Two port T1/E1 Interface Card, 2400bps modem  
8. 892760 Two port E1 Interface Card, no modem  
The 8920 Interface Card supports eight T1 or E1 WAN links, via a 50-pin Amphenol connector. The card has a DB-  
9 serial port for network management and two RJ48 jacks: one for an RS 485 node port and one for an RS-232 VT-  
100 control terminal port. There is a RJ-11 modem port as well. It supports eight T1 or E1 WAN links. The  
March 2001  
Page 24  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
892160 Interface Card is the same as the 892060 Interface card with the exception of the modem and can be used  
with the 880060, 880160 and 880460 CPU cards.  
The 892260 Interface Card is similar to the 892460 except there is an external synchronization option, no node port  
and the DB-9 serial port is a DTE-male type. The external synchronization option is for support of up to 8 T1  
Framed or E1 Unframed signals and this card can be used with the 880260 and 880360 CPU cards.  
The 892360 Interface Card supports eight T1 or E1 WAN links, via a 50-pin AMP connector. The card has 128KB  
of NVRAM, a DB9 serial port for network management and three RJ48 jacks that connect to the modem, nodal port  
and VT-100 control terminal port.  
The 892460 Interface Card supports the same functionality as the 892360 Interface card except that it has no internal  
modem port. It requires an 880360 CPU and 5.X.Y CPU firmware.  
The 892560 Interface card supports one or two T1 or E1 WAN links via 2 RJ-48 jacks and includes a single RJ-48  
jack for a VT100 control terminal. Additionally, two sets of Bantam jacks are available for monitoring each WAN.  
This interface card does not support WAN redundancy.  
The 892660 Interface card supports one or two T1 or E1 WAN links via 2 RJ-48 jacks. The 892660 includes a  
single RJ-48 jack for a VT100 control terminal, an RJ11 port for an internal 2400 bps, and a DB9 port.  
Additionally, two sets of Bantam jacks are available for monitoring each WAN. This interface card does not support  
WAN redundancy.  
The 892760 Interface card supports two E1 WAN links via 2 BNC connectors. The 892760 includes a single RJ-48  
jack for a VT100 control terminal, an RS 485 Node Port and a DB9 port. Table 8 provides a detailed list of the  
Interface Cards’ specifications.  
March 2001  
Page 25  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 8—Interface Card Specifications  
Model 892xxx Interface Cards  
Configuration Storage  
CPU Host Firmware compatible  
Models 892060, 892160, 892560, 32KB NVRAM  
892660 and 892760  
3.x.y  
Models 892260, 892261, 892360  
and 892460  
128KB NVRAM  
4.x.y, 5.x.y  
Interfaces  
Model  
T1/E1  
Links  
Computer Port Control  
Node Port  
Internal  
Modem  
External Sync  
Terminal  
Interface  
Port  
(DB-9)  
892060  
892160  
892260  
892261  
892360  
892460  
892560  
892660  
892760  
8 T1/E1  
YES  
YES  
YES  
YES  
YES  
YES  
YES  
YES  
YES  
YES  
YES  
YES  
YES  
YES  
YES  
YES  
YES  
NO  
YES  
NO  
NO  
8 T1/E1  
8 T1/E1  
8 T1/E1  
8 T1/E1  
8 T1/E1  
2 T1  
YES  
YES  
YES  
YES  
YES  
NO  
NO  
YES  
YES  
NO  
NO  
NO  
NO  
NO  
NO  
NO  
YES  
NO  
NO  
2 T1  
YES  
YES  
YES  
NO  
2 E1  
YES  
WAN Ports  
Electrical Interface  
G.703 or DSX-1  
Model  
Connector Type  
892060, 892160, 892260, 892261, 892360 and 892460  
892560 and 892660  
One Female 50-pin RJ-27X Telco connector  
Two Female RJ-48 connector  
892760  
Two Pair Female BNC connector  
DB9F DCE (requires 1201 cable)  
DB9M DTE (requires 1202 cable)  
All Models prior to Rev CO  
All Models from Rev CO  
Electrical Interface  
Function  
RS-232, ITU-T V.28  
Connects to local Element Management System  
8 bit characters plus one start and one stop bit with no parity  
19.2Kbps (PPP) or 9.6Kbps (SLIP)  
Code Set  
Max Speed  
March 2001  
Page 26  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 8—Interface Card Specifications (continued)  
Control Terminal Interface Port  
Connector  
RJ-48F, 8 pin, EIA 561  
DCE RS232, ITU-T V.28  
Electrical Interface  
Function  
Connect local VT100-compatible Control Terminal (local craft interface on the  
892260)  
Speed  
Maximum 9,600 bps asynchronous  
Code Set  
8 bit characters plus one start and one stop bit with no parity  
Node Port  
Connector  
RJ-48F, 8-pin  
Electrical Interface  
Alarm Output  
Function  
Dry contact  
Passive current loop, one normally open loop and one normally closed loop  
Alarm management between co-located IMACS nodes and external alarm  
management systems and panels  
Models 892060, 892360, 892660 only  
Female 6-pin RJ-11c socket  
Modem Port  
Connector  
Electrical Interface  
Protection  
600 ohm 2-wire balanced  
HV zener, 0.25A fuses on Tip and Ring  
Function  
Connect internal modem to PSTN for access to remote operator and remote EMS  
network management system  
Model 892060, 892360, 892660 only  
Modem Specifications  
Compatibility  
Modulation  
ITU-T V.22 bis  
16 point QAM  
Line interface  
Ringer Equivalence  
Approval  
2-wire balanced 600 ohm  
0.2 A  
FCC Part 68  
Equalization  
Transmit Level  
Receiver Sensitivity  
Dialing Mode  
Speed Supported  
Code Set  
Receive automatic adaptive, transmit fixed compromise  
-9.5 dBm  
On to OFF threshold -4.5dBm, OFF to ON threshold -48 dBm  
DTMF Tone  
2,400 bps asynchronous  
8 bit characters plus one start and one stop bit with no parity  
Adapters  
Model 1106 with 2 BNC  
connectors  
Supports 1 E1 circuit on 75 ohm coaxial cable (RG59)  
Model 1121 with 2 RJ48 sockets  
Model 1181 with 8 RJ48 sockets  
Supports 2 T1 or E1 circuits on twisted pair cable plus bantam jacks for test  
Supports 8 T1 or E1 circuits on twisted pair cable  
Model 1184 with 16 BNC sockets Supports 8 E1 circuits (suitable for IMACS 800)  
Standards Conformance  
ITU-T V.28  
Electrical characteristics for unbalanced double-current interchange circuits  
ITU-T G.703  
ITU-T V.22 bis  
Physical/Electrical Characteristics of Hierarchical Digital I/F  
2400 bits per second Duplex Modem Using the Frequency Division  
Technique  
EIA 56  
8-Position Non-Synchronous Interface between DTE and DCE Employing  
Serial Data Interchange  
March 2001  
Page 27  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 8—Interface Card Specifications (continued)  
EIA RS232-C  
Interface between DTE and DCE Employing Serial Binary Data  
Bellcore GR-63-CORE  
CE EN 500 81-1  
Network Equipment-Building System (NEBS) Requirements: Physical Protections  
Electromagnetic compatibility generic emission standard Part 1 Residential,  
commercial and light industry  
CE EN 500 82-1  
Electromagnetic compatibility generic immunity standard Part 1 Residential,  
commercial and light industry  
CEN EN 60 950/A2  
Safety of information technology equipment including electrical business  
equipment  
FCC Part 68  
DOC CS03  
UL 1459  
UL 1950  
CSA C22.2, No. 950  
Requirements for Connection of Terminal Equipment Systems and Protective  
Apparatus to the Telephone Network  
UL Standard for Safety of Telephone Equipment  
UL Standard for Safety of Information Technology Equipment  
Safety of information technology equipment including electrical business  
equipment  
4. WAN Cards  
The WAN cards manage the flow of data through the integrated access system network. It provides the logical and  
electrical interface to high-speed digital facilities, which are typically physically connected via the Interface card.  
WAN cards take the data off the bus, which was put there by the User and Server cards, and transmit the information  
over a WAN link. A WAN link is typically a T1, E1, DSX-1, or HDSL facility connection. This WAN link can be  
either user or network link. In combination with the CPU card, the WAN card provides E1 to T1 and T1 to E1  
conversion.  
The WAN Cards also provide performance statistics. They are stored in memory on the IMACS’ host CPU card and  
retrieved upon command. The performance statistics are gathered and displayed in 15-minute intervals and retained  
for 24 hours. In the T1 environment, an error is defined as any CRC-6, Controlled Slip, or Out of Frame (OOF)  
error for ESF framing, and any Bipolar Violation (BPV), Controlled Slip, or OOF error for the D4 format. In an E1  
environment, an error is defined as any CRC-4 error, Controlled Slip, or OOF error.  
In the AT&T mode, two sets of registers (user and network) accumulate performance data for T1 WAN links. It is  
possible to view both the user and network registers, but the end user can only clear the user registers. The network  
only has access to the network registers, and can only clear those registers. The ANSI and E1 WAN links have only  
one set of registers.  
For further information regarding performance, and integrated test capabilities such as loop backs, BERT Tests and  
Signal Quality please see Section 13, IMACS System Testing and Diagnostics.  
Each port on the WAN cards can be individually configured with DSX/CEPT or CSU plug-in modules. Both CSU  
and DSX modules are used to connect to T1 facilities operating at 1.544 Mbps. The CEPT module is used for  
connection to a 2.048 Mbps E1 facility. All WAN interfaces comply with the appropriate North American and  
international standards. Those cards equipped with CSU or DSX/CEPT modules also act as the “near end”  
termination points for the Subscriber Loop Carrier (SLC-96) facilities defined in BellCore publication  
TR-TSY-000008, Issue 2, August 1987. Each WAN card can operate in dual channel bank, drop and insert, or full  
digital cross-connect mode and can perform T1-E1 conversion, including PCM A-Law to µ-Law conversion. When  
fully populated with 4 dual WAN cards, the IMACS supports 8 T1 or E1 connections, in any combination of T1  
(DSX1 or DSX1 with CSU) , E1 (CEPT) and HDSL interfaces.  
The DSX/CEPT and CSU Modules are used to connect to T1 facilities, which operate at 1.544 Mbps. The CEPT  
function of the DSX/CEPT module is used internationally for connection to a 2.048 Mbps E1 network. The HDSL  
module provides a high-speed digital subscriber line (HDSL) interface.  
Each WAN card slot has eight leads connected to the Interface card slot, which can be used to support facility  
interfaces. The last WAN slot has all the WAN connections from the other three slots in addition to its own to  
support the WAN redundancy feature. The WAN card in the last slot can substitute for one of the other WAN cards.  
March 2001  
Page 28  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
There are four highways dedicated to the WAN slot, which are used to carry TDM data and signaling. Each WAN  
slot is connected to the Interface card through the back plane.  
The IMACS supports six models of WAN cards:  
1. 800060 Single T1/E1 WAN card  
2. 801060 Dual T1/E1 WAN Card  
3. 801460 Dual T1/E1 WAN Card with Relays  
4. 801160 Dual E1 HDSL WAN Card  
5. 801560 Dual T1 WAN card with ESF loop back  
6. 802060 PairGain HDSL T1 WAN Card  
The 800060 Single T1/E1 Link Card is the basic WAN Card. It has a single port for DSX/CEPT or CSU modules.  
The 801060 Dual T1/E1 WAN card has two ports for either DSX/CEPT or CSU operation or a combination of the  
two. Both ports of this card must be populated with either the DSX/CEPT or CSU module.  
The 801460 Dual T1/E1 Link Card with Relays can be used in systems with Cross Connect CPUs to act as a  
redundant card (1:N redundancy) for up to three standard WAN cards. Both ports of this card must be populated  
with either the DSX/CEPT or CSU module and must be an exact match to any WAN Cards with which it is  
redundant.  
The 801560 WAN card with ESF Loop back is able to detect ESF data link codewords for line and payload activate  
and deactivate commands and the universal loop back deactivate command. A minimum reception of 10 continuous  
command patterns by each channel is required to trigger the loop back detection process, and the performing of the  
command. Since all 8 channels (4 WAN cards) are processed by one processor on the CPU card, simultaneous  
detection on more than one channel requires more than 10 repetitions.  
The 802060 Pair Gain HDSL WAN is a dual WAN card designed to support the North American (T1) market using  
the PairGain HDSL OEM module (HOM). This also supports 4:1 redundancy as well as user configurable HRU  
functionality relative to HDSL timing. The IMACS can support up to four (4) 802060 WAN cards simultaneously  
and can be configured, monitored and tested through the IMACS craft interface and/or through the SNMP MIB  
interface. This design supports two PairGain HDSL modules per card for either IMACS to IMACS configurations  
as well as IMACS to PairGain NTU configurations. Each module may be configured as primary or subordinate.  
There must be one primary and one subordinate in the circuit. The unit designated as the primary can be accessed to  
change system parameters and view HDSL system performance history and current status. The subordinate  
provides HDSL system performance history and current status. The subordinate unit receives configuration  
parameters from the master unit at the other end of the loop. These configuration parameters include: Timeout for  
loop back, DS1 line code option (e.g. B8ZS/AMI), DS1 framing format (e.g. SF/ESF). The 802060 HDSL WAN  
module is supported by IMACS HOST 5.1 (or greater).  
For connection to T1/E1 facilities, a DSX/CEPT or CSU Plug-in module is required per WAN port. The available  
modules are:  
811 T1-DSX/E1-CEPT Plug-in Module (transmission range is 655 ft.)  
812 T1-CSU Plug-in Module (transmission range is 3000 to 6000 ft)  
82030 2*1168Kbps E1 HDSL Module (compliant with ETSI ETR-152)  
82100 Dual T1 HDSL Module  
These plug-in modules are mounted on the WAN cards for operation. The 811 T1-DSX/CEPT plug-in module  
supports either DSX or CEPT modes. Jumper / shorting pin settings on the module specify DSX or CEPT  
operation. The 812 CSU plug-in module is required for T1 Channel Service Unit (CSU) operation. It can be  
operated in D4, ESF, SLC96 or SLCD4 mode.  
The 801160 Dual E1-HDSL WAN Card has two ports that are equipped with E1-HDSL modules from ADTRAN.  
The HDSL modules provide 2.048 Mbps E1 transmission over 2 copper pairs. It provides transport of data at an E1  
rate over copper cable without mid-span repeaters or conditioning. For connection to copper loops, one HDSL  
module is required per WAN port.  
March 2001  
Page 29  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
The 802060 Dual T1 HDSL WAN Card has two ports that that are equipped with 82100 T1 HDSL modules. The  
HDSL modules provide 1.544 Mbps T1 transmission over 2 copper pairs. Both modules have to be installed for  
proper operation and do not support redundancy. Table 9 depicts the various T1/E1 WAN card specifications. In  
addition to the specifications listed in Table 9 (below) the 802060 card is in conformance with ITU-T Q.421 and  
ITU-T Q.422. The transmission range is software selectable for the following: 0, 133, 266, 399, 533 or 655 ft. (up  
to 200 meters), and CSU (allowing connections to the equipment side of a co-located external CSU over a short  
distance, four-wire cable). Software selectable line build out (LBO) settings are also available for all of the  
aforementioned transmission ranges.  
Table 9—WAN Card Hardware Specifications  
Model  
Number of Ports Number of  
Cards  
Physical Interface  
Electrical Interface  
800060  
1
2
2
2
2
1 to 4  
1 to 4  
1 to 4  
1 to 4  
1 to 4  
Through 892xxx I/F  
card  
Through 892xxx I/F  
card  
Through 892xxx I/F  
card  
Through 892xxx I/F  
card  
811 (T1-DSX/E1-CEPT)  
812 (T1-CSU) - 1 per port  
811 (T1-DSX/E1-CEPT)  
812 (T1-CSU) - 1 per port  
811 (T1-DSX/E1-CEPT)  
812 (T1-CSU) - 1 per port  
82100 is used to provide 1 T1  
HDSL interface  
801060,  
801460  
801560  
802060  
801160  
Through 892xxx I/F  
card  
82030 provides 2*1168Kbps E1  
HDSL module. Required for each  
port.  
T1 Signal Format  
Electrical Interface  
Frame Format  
Line Coding  
ANSI T1.102/T1.403, DSX-1, balanced 100 Ω  
D4, ESF, Subscriber Loop Carrier (SLC) 96, SLCD4  
AMI or B8ZS  
Signaling  
AT&T 43801, 62411, ITU-T, Q.421, Q.422 using Robbed-bit method  
CRC-6, Controlled Slip, Bipolar Violation, Out of Frame  
BellCore TR-TSY-000191  
Error Detection  
Alarm Indication  
SLIP Limit  
126 bits or 138 bits  
Bit Rate and Tolerance  
E1 Signal Format  
Electrical Interface  
Coding  
1.544Kbps +32PPM. Jitter complies with ANSI T1.403  
G.703 balanced 120 or unbalanced 75 Ω  
HDB3  
Framing  
ITU-T G.704 Timeslots consist of 8 bits. Frame consists of 32 time slots,  
Multi-frame consists of 16 frames  
Signaling  
CAS, CCS In Timeslot 16 if required.  
CAS Signaling protocols: AT&T 43801, 62411, ITU-T Q.421 (2)  
CRC-4, Controlled Slip, Out of Frame  
ITU-T G.732  
Error Detection  
Alarm Indication  
Performance and Test Options  
Loop backs  
T1  
E1  
Line, local, channel, loop back generation and detection  
FDL in accordance with AT&T 54016 or ANSI T1.403 (8015 only)  
National Bit Supporting (G.704)  
Standards Conformance  
AT&T TR43801  
AT&T TR54016  
Digital Channel Bank Requirements & Objectives  
Requirements for Interfacing Digital Terminal Equipment to Service  
Employing the Extended Superframe Format  
AT&T TR62411  
AT&T TR41449  
Accunet T1.5 Service, Description and Interface Specifications  
ISDN Primary Rate Interface Specification  
BellCore TR-TSY-000008  
BellCore TR-TSY-000191  
Digital Interface Between the SLC 96 Digital Loop  
Alarm Indication Signal, Requirements and Objectives  
March 2001  
Page 30  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 9—WAN Card Hardware Specifications (continued)  
ANSI T1.101  
ANSI T1.107  
ANSI T1.403  
ANSI T1.408  
FCC Part 68  
Synchronization Interface Standards for Digital Networks  
Digital Hierarchy - Formats Specifications  
ISDN, Network-to-Customer Installation -DS1 Metallic I/F  
ISDN Primary Rate  
Requirements for Connection of Terminal Equipment Systems and Protective  
Apparatus to the Telephone Network  
ITU-T G.703  
ITU-T G.704  
Physical/Electrical Characteristics of Hierarchical Digital I/F  
Synchronous Frame Structure Used at Primary and Secondary Hierarchical  
Levels  
ITU-T G.735  
ITU-T G.732  
Characteristics Of Primary PCM Multiplexed Equipment Operating at 2048  
Kbps and Offering Synchronous Digital Access At 384 Kbps and/or 64 Kbps  
Characteristics of Primary PCM Multiplexed Equipment Operating at 2048  
Kbps  
ITU-T G.736  
ITU-T G.823  
Characteristics of A Synchronous Digital Multiplex Equipment at 2048 Kbps  
The Control of Jitter and Wander Within Digital Networks Which Are Based  
on the 2048 Kbps Hierarchy  
ITU-T G.824  
The Control of Jitter and Wander Within Digital Networks Which Are Based  
on the 1544 Kbps Hierarchy  
Bellcore GR-63-CORE Issue 1  
Network Equipment-Building System (NEBS) Requirements: Physical  
Protections  
Bellcore GR-1089  
CE EN 500 81-1  
ESD Sec 2, EMC Sec 3,  
Electromagnetic compatibility generic emission standard Part 1 Residential,  
commercial and light industry  
CE EN 500 82-1  
Electromagnetic compatibility generic immunity standard Part 1 Residential,  
commercial and light industry  
CE EN 550-22  
EMI Level B  
CE EN 60 950/A2  
Safety of information technology equipment including electrical business  
equipment  
UL 1950  
ETSI ETR 152  
CSA C22.2, No. 950  
UL Standard for Safety of Information Technology Equipment  
High Bit Rate Digital Subscriber Line Transmission  
Safety of information technology equipment including electrical business  
equipment  
March 2001  
Page 31  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
III. IMACS Voice Modules and Applications  
1. Foreign Exchange Station (FXS) Card  
The IMACS supports one Foreign Exchange Station (FXS) card, the 812960 FXS Card, which provides eight 2-wire  
analog ports with a terminating impedance of 600 ohms.  
FXS cards can be installed in any IMACS chassis User Slot, and will (in most cases) require a ring generator. AC  
powered systems will also require a –48 VDC converter. FXS cards encode the incoming analog voice signals into  
64 Kbps PCM format before transmission onto the network. Each FXS card provides a single 50-pin female  
amphenol connector (RJ27X).  
All port parameters are software configurable on a port-by-port basis. The Mode setting specifies whether the port  
is to be used for standard Foreign Exchange Station, Foreign Exchange Software Defined Network (“wink”), Private  
Line Automatic Ringdown (PLAR), or Dial Pulse Origination applications. For example in the case of a PLAR  
circuit, the port can be programmed to provide Ringback Tone towards the caller. The Type setting specifies Loop  
Start, Loop Start with Forward Disconnect, Ground Start, Ground Start Immediate and Ground Start Automatic  
operation. If the PLAR mode is selected, then the two options supported under Type are “D3” and “D4” which meet  
the pre-1988 and post-1988 specifications for PLAR circuits. The PCM Coding options supported include µ-Law,  
A-Law and inverted A-Law, and the user may also select the Trunk Conditioning mode (busy or idle) that should be  
applied towards the attached equipment should the WAN facility that the port is connected to fails. In addition, both  
the Transmit (Tx) and Receive (Rx) TLP levels can be set in increments of 0.1 dB. The Tx TLP range is from -10.0  
dB to +5.0 dB. The Rx TLP range is from -10.0 dB to +2.0 dB.  
The user may also specify, on a port-by-port basis, whether to use North American ANSI standard ABCD signaling  
(which is the default) or ITU (CCITT) ABCD signaling by turning the signaling conversion setting “on” or “off”.  
The trans-hybrid balance may be specified as one of eight values as well as for a customized user-specified  
terminating impedance. At the present time, all eight values are identical and are set for a terminating impedance of  
600+2.15µF in the case of a Model 8129 FXS card.  
Software-initiated testing and diagnostics supported on FXS cards include the setting of both analog and digital loop  
back towards the network and the generation of a Digital MilliWatt (DMW) signal on a port-by-port basis. A robust  
set of Test functions allow the user to monitor and set the state of the analog Tip and Ring leads of any FXS port and  
to set and monitor the state of the ABCD signaling bits of the digitized voice signal. In cross-connect systems, the  
Test functionality also includes the ability to generate test tones (300Hz, 1 kHz, 3 kHz and “quiet”) and transmit  
those toward either the user side or the network side of the system. FXS cards can use the voice-compression  
features of the ADPCM and LBRV Server cards. Table 10 provides all the relevant FXS cards specifications.  
Table 10—FXS Specifications  
Model 8129 2-wire Analog FXS Voice Card  
Physical Characteristics  
Model 812960  
8 ports  
Physical Interface  
Dimensions of Card  
Weight of Card  
1 female 50-pin Telco connector  
8 x 0.94 x 7.48 inches (HWD)  
1 lb or .4 k  
Power Consumption of Card  
Signaling Modes  
3.12 W  
Software configurable on a per port basis: foreign exchange station  
(FXS), FXS defined network (Megacom), Private Line Automatic  
Ringdown (PLAR), Dial Pulse Originating (DPO)  
Loop Start, Ground Start, Loop Start with Forward Disconnect, Feature  
Group D (for high-speed modem services), Bill On Answer, D3, D4,  
DPO and Single Party, Universal Grade Voice  
Signaling Types  
Specification  
Short Loop  
Long Loop  
Loop Resistance  
Termination Impedance  
VF Transmission  
Min 300 Ω, Max 700 Ω  
600 + 2.16 uF  
Min 300 , Max 1800 Ω  
March 2001  
Page 32  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Characteristics  
Nominal Transmit TLP  
Nominal Receive TLP  
2-Wire Return Loss  
Software configurable, -10.0dB to +5.0dB, steps of 0.1dB  
Software configurable, -10.0dB to +2.0dB, steps of 0.1dB  
>28 dB Echo, >20 dB singing (against 600 ohm, in series with 2.16 uF  
with additional 25 ohm resistor between tip and ring)  
Software configurable, A-Law, A-Law inverted, u-Law  
Echo: 20dB, SRL-LO: 12dB, SRL-HI: 12 dB  
PCM Coding  
Transhybrid Loss  
Standards Conformance  
AT&T TR43801  
Bel1Core TR-NWT 000057  
Digital Channel Bank Requirements and Objectives - November 1982;  
Functional Criteria for Digital Loop Carrier System - January 1993  
BellCore GR-63-CORE  
Network Equipment-Building System (NEBS) Requirements: Physical  
Protection  
ITU-T G.712  
ITU-T Q.552  
(11/96) - Transmission Performance Characteristics of Pulse Code  
Modulation (replaces G.712, G.713, G.714 and G.715)  
Transmission Characteristics of 2 -wire analog interface of a Digital  
Exchange  
FCC Part 68  
Requirements for Connection of Terminal Equipment Systems and  
Protective Apparatus to the Telephone Network  
Subpart 15  
FCC Part 15  
UL 1459  
UL Standard for Safety, Telephone Equipment  
2. Foreign Exchange Office (FXO) Card  
The IMACS supports only one variant of Foreign Exchange Office (FXO) card:  
813960/813970 FXO Card provides eight 2-wire analog ports with terminating impedance of 600 ohms.  
FXO cards can be installed in any of the User Slots of the IMACS chassis. FXO cards encode the incoming analog  
voice signals into 64 Kbps PCM format before transmission onto the network. A Ringing Generator is required if  
one or more FXO ports in a system are programmed to operate in Manual Ringdown (MRD) mode. In addition, a  
physical jumper must be set on the FXO card for each port programmed for MRD operation. Each FXO card  
provides a single 50-pin female AMPHENOL connector (RJ27X).  
All port parameters are software configurable on a port-by-port basis. The Mode setting specifies whether the port  
is to be used for standard Foreign Exchange Office, Foreign Exchange Software Defined Network, Dial Pulse  
Terminate, or Manual Ring Down (MRD). As described above, the MRD mode also requires the setting of physical  
jumpers. The Signal setting specifies Loop Start, Loop Start with Forward Disconnect, Ground Start, R2, and  
Immediate R2 operation. In “fxodn” and “dpt” modes, the user may also specify the wink duration time and wink  
delay from 0.1 seconds to 9.9 seconds in 0.1-second increments. The PCM Coding options supported include “µ-  
Law”, “A-Law” and inverted A-Law. The user may select the Trunk Conditioning mode (“busy” or “idle”) that  
should be applied towards the attached equipment should the WAN facility that the port is connected to fail. In  
addition, both the Transmit (Tx) and Receive (Rx) TLP levels can be set in increments of 0.1 dB. The Tx TLP range  
is from -10.0 dB to +5.0 dB. The Rx TLP range is from -10.0 dB to +2.0 dB.  
The user may also specify, on a port-by-port basis, whether to use North American ANSI standard ABCD signaling  
(which is the default) or ITU (CCITT) ABCD signaling by turning the signaling conversion setting “on” or “off.”  
The trans-hybrid balance may be specified as one of eight values (known as “set1” through “set8”) as well as for a  
customized user-specified terminating impedance (“user”). All eight values are identical and are set for a  
terminating impedance of 600Ω ± 2.15µF in the case of the Model 813960 FXO cards.  
Software-initiated testing and diagnostics supported on FXO cards include the setting of both  
analog and digital loop backs towards the network and generating a Digital MilliWatt signal on a  
port-by-port basis. A robust set of Test functions allow the user to monitor and set the state of  
March 2001  
Page 33  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
the analog Tip and Ring leads of any FXO port. It also sets and monitors the state of the  
digitized voice signal’s ABCD signaling bits in cross-connect systems, the Test functionality also  
includes the ability to generate test tones (300Hz, 1 kHz, 3 kHz and “quiet”) and transmit those  
toward either the user side or the network side of the system. Table 11 reviews the FXO Card  
specifications.  
Table 11—FXO Specifications  
Model 813960 2-wire Analog FXO  
Voice Card  
Physical Characteristics  
Model 813960  
8 ports  
Physical Interface  
Dimensions of Card  
Weight of Card  
1 female 50-pin Telco connector  
8 x 0.94 x 7.48 inches (HWD)  
1 lb or .4 k  
Power Consumption of 813960  
3.03 W  
Card  
Models 813960 Signaling Mode  
Software configurable on a per port basis: Foreign Exchange  
Office (FXO), FXO Defined Network, Manual Ringdown and  
Dial Pulse Terminating (DPT)  
Models 813960 Signaling Type  
Loop Start, Ground Start, Loop Start Forward Disconnect, Loop  
Start R2, Ground Start Automatic, Loop Start E&M, MRD, DPT,  
R2, Immediate R2, Dial Pulse E&M, Caller ID  
600 ohms  
Termination Impedance  
VF Transmission Characteristics  
Nominal Transmit TLP  
Nominal Receive TLP  
Software configurable, -10.0dB to +5.0dB, steps of 0.1dB  
Software configurable, -10.0dB to +2.0dB, steps of 0.1dB  
>28 dB Echo, >20 dB singing (against 600 ohm, in series with  
2.16 uF with additional 25 ohm resistor between tip and ring  
Software configurable, A-Law, A-Law inverted, u-Law  
Echo: 22dB, SRL-LO: 14dB, SRL-HI: 20 dB  
2-Wire Return Loss  
PCM Coding  
Transhybrid Loss  
Standards Conformance  
AT&T TR43801  
Digital Channel Bank Requirements and Objectives – November  
Functional Criteria for Digital Loop Carrier System – January  
1993  
Bell CoreTR-NWT-000057  
BellCore Protections GR-63 CORE  
Network Equipment-Building System (NEBS) Requirements:  
Physical Protection  
(11/96) – Transmission Performance Characteristics of Pulse Code  
Modulation (replaces G.712, G.713, G.714 and G.715)  
Transmission Characteristics of 2 –wire analog interface of a Digital  
Exchange  
ITU-T G.712  
ITU-T Q552  
Transmission Characteristics of 4 –wire analog interface of a Digital  
Exchange  
Requirements for Connection of Terminal Equipment Systems and  
Protective Apparatus to the Telephone Network  
Subpart B  
ITU-T Q.553  
FCC Part 68  
FCC Part 15  
UL 1459  
Standard for Safety, Telephone Equipment  
March 2001  
Page 34  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
3. E&M Card  
The IMACS supports three variants of E&M cards:  
810860 E&M Card supports eight 2-wire E&M or Transmission Only (TO) ports  
811760 E&M Card support eight 4-wire E&M or Transmission Only (TO) ports and 2713 Hz loop back support  
811960 E&M Card supports eight 4-wire E&M or Transmission Only (TO) ports  
The 811960 E&M card offers an extended Transmit TLP range (-17.5 to +14.5dB) to better support dedicated 4-  
wire modem applications. This may be required in situations when specific types of modems being connected to the  
ports cannot, or will not, change their output power levels. Modems can only be connected with the E&M when  
placed in TO mode.  
E&M cards can be installed in any of the User Slots of the IMACS chassis. E&M cards encode the incoming analog  
voice signals into 64 Kbps PCM format before transmission onto the network. Each E&M card provides a single  
50-pin female AMPHENOL connector (RJ27X). All three cards support E&M signaling types I, II, IV and V.  
Most port parameters are software configurable on a port-by-port basis including the Mode of each port (“E&M”,  
“E&MR2” or “TO”). The PCM Coding to be used is either u-Law, A-Law or A-inv (for inverted A-Law). The  
Trunk Conditioning (busy or idle) is configured on the equipment in case the WAN facility that the port is connected  
to fails.  
The user may also specify, on a port-by-port basis, whether to use North American ANSI standard default, ABCD  
signaling, or ITU (CCITT) ABCD signaling by turning the signaling conversion setting “on” or “off”.  
Software-initiated testing and diagnostics supported on E&M cards include the setting of both analog and digital  
loop backs towards the network and the generation of a Digital MilliWatt signal on a port-by-port basis. A robust  
set of test functions allow the user to monitor and set the state of the analog E & M leads of any port and to set and  
monitor the state of the ABCD signaling bits of the digitized voice signal. In cross-connect systems, the Test  
functionality also includes the ability to generate test tones (300Hz, 1 kHz, 3 kHz and “quiet”) and transmit those  
toward either the user side or the network side of the system.  
The 811760 E&M with 2713 Hz Loop back will provide digital loop back (both PCM voice and signaling) when  
activated by a 2713 Hz tone of specified level and duration. This complies with requirements as per Bellcore PUB  
42004.  
When a validated tone is detected the channel disconnects the transmit path from the user and provides loop back of  
signals (PCM voice and signaling) received from the network. The loop back is performed at “equal level”, i.e.  
without inserting any gain or loss in the path. In addition, a “make busy” signal is being applied towards the user.  
Table 12 reviews the E&M card specifications.  
Table 12—E&M Analog Voice Card Specifications  
Models 810860 2-wire  
Models 811760 and 811960 4-wire  
E&M Analog Voice Card  
Physical Characteristics  
Model 810860 and 811960  
Physical Interface  
Dimensions of Card  
Weight of Card  
8 ports  
1 female 50-pin Telco connector  
8 x 0.94 x 7.48 inches (HWD)  
1 lb or .4 k (Model 811960)  
Power Consumption of Card  
Signaling Mode  
2-wire (810860)  
3.5 W (Model 811960)  
Software configurable on a per port basis: E&M, Transmit Only,  
Symmetrical R2 signaling, E&MR2, Modified R2 (r2mod)  
4-wire (811960)  
Signaling Types  
Types I, II, V are switch configurable by card. Supports Normal  
Page 35  
March 2001  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
(toward user) and Tandem (toward CO)  
E&M Sensor Characteristics  
Nominal Transmit TLP  
Nominal Receive TLP  
Termination Impedance  
2-wire (810860) and 4-wire (811960), Impedance > 15K ohms,  
Sensitivity > 2.5 mA  
Software configurable, -16.5dB to +7.3dB, steps of 0.1dB (2-wire); -  
17.5 dB +14.5dB, steps of 0.1 dB (4-wire)  
Software configurable, -16.3dB to +7.5dB, steps of 0.1dB (2-wire); -  
16.3dB +7.5dB steps of 0.1dB  
600 Ohms with 2.16 uF capacitor in series (2-wire); 600 Ohms (4-wire)  
Delay Specification  
Absolute Group Delay  
(dependent on codec)  
Peak to Average Ratio (PAR)  
Standards Conformance  
AT&T TR43801  
<600 us (2-wire and 4-wire)  
94 to 97 (2-wire and 4-wire)  
Digital Channel Bank Requirements and Objectives – November 1982  
Functional Criteria for Digital Loop Carrier System – January 1993  
Bell CoreTR-NWT-000057  
BellCore GR-63 CORE  
Network Equipment-Building System (NEBS) Requirements: Physical  
Protection  
ITU-T G.712  
(11/96) – Transmission Performance Characteristics of Pulse Code  
Modulation (replaces G.712, G.713, G.714 and G.715)  
Transmission Characteristics of 2 –wire analog interface of a Digital  
Exchange  
ITU-T Q.552  
ITU-T Q.553  
Transmission Characteristics of 4 –wire analog interface of a Digital  
Exchange  
FCC Part 68  
Requirements for Connection of Terminal Equipment Systems and  
Protective Apparatus to the Telephone Network  
Subpart B  
FCC Part 15  
UL 1459  
Standard for Safety, Telephone Equipment  
UL 1950  
CE EN 500 81-1  
UL Standard for Safety of Information Technology Equipment  
Electromagnetic compatibility generic emission standard Part 1  
Residential, commercial and light industry  
CE EN 500 82-1  
CE EN 60 950/A2  
Electromagnetic compatibility generic immunity standard Part 1  
Residential, commercial and light industry  
Safety of information technology equipment including electrical  
business equipment  
March 2001  
Page 36  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
P-Phone Station and Office Line Cards  
The P-Phone Line Cards support transport of Nortel Electronic Business Service (EBS) or P-Phone service. Nortel’s  
EBS is provided through the use of an Electronic Business Set (also EBS) capable of supporting premium Meridian  
Digital Centrex (MDC) features offered by the local DMS SuperNode switch. A data channel allows out-of-band  
signaling between the EBS and the DMS SuperNode switch. This data channel allows the user to activate MDC  
features, such as conference calling, by simply pushing special keys on the EBS, and for the DMS SuperNode to  
deliver information, such as calling number identification, to the EBS display.  
P-Phone is a very popular service among large corporations who have chosen Nortel Centrex vs. a PBX. This  
service is very popular in metropolitan areas; as more companies move away from purchasing their own PBXs, P-  
Phone will be even more popular among the corporate DMS customers. In addition, as more and more CLECs enter  
traditional RBOC bases, they will need to be able to provide P-Phone services.  
Figure 10A shows a general application drawing where an IMACS system is used at both the CO end and at the  
customer remote end. As shown, there are two applications of the Line Card, one at the office end, also known as P-  
Phone Office (PPO), and one at the station end referred to as P-Phone Station (PPS).  
Figure 10 - Universal IMACS P-Phone Application  
P-Phone #1  
:
:
:
:
:
Line 1  
T1  
E1  
Network  
T1  
E1  
:
:
:
IMACS with  
PPS Line Card  
IMACS with  
PPO Line Card  
P-Phone #N  
Nortel CO Switch  
Two types of P-Phone line cards are used in pair gain carrier systems such as DLCs and the IMACS system. One  
type, referred to as a passive line card, encodes the received out-of-band signaling tones, transports them across the  
carrier and decodes the digital representation back to out-of-band tones at the other end. In other words, the passive  
line card simply repeats the signaling end-to-end. The second type, referred to as an active line card, terminates the  
messages received at the 2-wire port and either responds as appropriate to the local terminal device or forwards the  
message over the digital carrier.  
The above figure shows just one working circuit. In reality, the Line Card will be able to support eight (8) working  
circuits. The most common application for P-Phone would have more than one circuit going to a customer location.  
Very rarely would there be just one circuit terminating at one customer. The P-Phone line cards support the  
following Nortel PBXs, switches and Meridian business phone sets:  
DMS100 (Class 5 switch)  
DMS500 (Combinations of Class 5 and a tandem switch)  
DMS10 (Lower capacity switch for rural areas)  
SL100 (Large enterprise PBX; same as DMS100)  
M5000 series business sets  
Table 12A reviews the PPO and PPS line card specifications.  
March 2001  
Page 37  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 12A—PPO and PPS Line Card Specifications  
Models 812160 and 813160 Eight Channel Line  
Card  
Physical Characteristics  
Model 812160 and 813160  
Software provisionable options  
Transport length  
8 channels  
Level control and A-Law/Mu law  
Over 3,000 feet of copper cable at 2W VF ports  
8 kHz tone, ASK, half duplex  
Out of band signaling  
7-bit voice encoding scheme. LSb used to carry signaling.  
Loop current, presence or absence at the local end; loss of  
sealing current, far end  
Voice Transmission  
Status Indicators  
Subscriber and Central Office  
Interface—Transmit Channel  
Levels received from 2W port  
Level adjustment  
Attenuation distortion (relative to 1 kHz)  
Idle channel noise  
-2 dBm to +1 dBm  
-3 to +2dB in 0.1 dB increments  
-0.5 to +1.0 db, 400 Hz to 2800 Hz  
23 dBrnC  
March 2001  
Page 38  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 12A—PPO and PPS Line Card Specifications (continued)  
Subscriber and Central Office  
Interface—Receive Channel  
Level generated to 2W port with 0dB loss  
Level adjustment  
Attenuation distortion (relative to 1 kHz)  
Idle channel noise  
0 dBm ± 0.5 Db  
-3 to +2 dB in 0.1 dB increments  
-0.5 to +1.0 db, 400 Hz to 2800 Hz  
23 dBrnC  
2W Port Characteristics  
Maximum connected copper loop  
Impedance  
3000 feet, 26 gauge, non-loaded pair  
900 ohms  
Return Loss, voiceband into 900+ 2.16 µF  
Return loss, single frequency into 900+ 2.16 µF  
Sealing Current Source  
> 18 dB ERL, > 0 dB SRL LO, HI  
> 25.6 dB @ 8 kHz  
Minimum voltage at NI (display set)  
Minimum voltage at NI (non-display set)  
Loop length  
15.8 V into a 38 ma sink through 3000 ft  
14.5 V into a 17 mA sink through 3000 ft  
0 to 3000 feet  
Polarity  
Sealing Current Sink  
Ring lead must be negative relative to tip lead  
<960 ohms DC resistance  
8 kHz Signaling Specifications  
Signaling method  
ASK half duplex, carrier only present during transmission of  
information or acknowledgment  
1 kb/s, half duplex  
Signaling rate  
Received 8kHz signal levels at 2W port  
Standards Conformance  
.200 to 1.5 V peak to peak  
BellCore GR 1089-CORE, Section 2  
BellCore GR 1089 section 3 and EN 500  
81-1, Level B  
ESD Protection  
Radiated Emissions  
BellCore GR 1089 CORE, Section 3  
BellCore GR 1089 CORE, Section 3  
FCC Part 68  
Conducted Emissions  
Immunity  
Requirements for Connection of Terminal Equipment Systems  
and Protective Apparatus to the Telephone Network  
Subpart B  
Standard for Safety, Telephone Equipment  
UL Standard for Safety of Information Technology Equipment  
Electromagnetic compatibility generic emission standard Part 1  
Residential, commercial and light industry  
Electromagnetic compatibility generic immunity standard Part 1  
Residential, commercial and light industry  
Safety of information technology equipment including electrical  
business equipment  
FCC Part 15  
UL 1459  
UL 1950  
CE EN 500 81-1  
CE EN 500 82-1  
CE EN 60 950/A2  
March 2001  
Page 39  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Voice Channel Bank Application  
This is the simplest IMACS application, which can be used by a service provider. The IMACS is used in this  
configuration when one or more digital T1/E1 trunks are needed to interface with analog PBXs or key systems at the  
customer premises. In the US, the break-even point for bringing in a T1 trunk as opposed to multiple analog lines is  
typically 6 analog lines. As a result, there is a huge market for cost-effective voice channel bank such as the IMACS.  
A single IMACS can be used to provision up to 62 analog POTS lines (FXS, FXO, E&M) on digital Central Office  
switches as shown in Figure 11.  
Figure 11—IMACS As A Voice Channel Bank  
Local Digital Switch  
D
S
X
IMACS  
Max 8 T1/E1  
POTS/  
CLASS  
P
A
N
E
L
• 62 POTS/CLASS Lines  
Customer Premise  
Central Office  
The IMACS can also be deployed in applications, which do just the reverse of voice channel banks. This is most  
likely to be found in wireless local loop applications in which the wireless service provider may use a state-of-the-  
art wireless local loop. The output of the wireless base station is normally a T1/E1. However, the existing PSTN  
may still have analog switches. The IMACS is used to convert from robbed-bit signaling/CAS to analog trunks  
(FXO).  
The voice channel bank platform can be upgraded to provide an array of additional services just by adding  
application modules to the chassis. It comes with a built-in suite of testing and diagnostics tools, which significantly  
enhance the service and support capabilities.  
TR-008 Application  
BellCore’s TR-008 standard describes the requirements necessary for a Local Digital Switch (LDS) to connect to a  
remote terminal (RT) across a T1 (1.544Mbps) digital interface. The standard allows supporting from one to four  
T1s per RT without facility Automatic Protection Switching (APS), and two to five T1s with facility APS.  
The LDS can interface the RT in Mode I (no concentration), Mode II (2:1 concentration), and Mode III (24 special-  
service circuits on 24 DS1 time-slots). TR-008 supports traditional POTS, CLASS, and Coin services but does not  
support ISDN BRI. If the service provider deploys a channel bank at the customer premise that does not provide  
TR-008 capability then it needs a 1/0 DCS with TR-008 capability at the central office to integrate with the LDS.  
The IMACS also supports TR-008 switch integration. The IMACS with TR-008 operation can connect directly to  
the LDS, eliminating the need for the 1/0 DCS as shown in Figure 12a.  
March 2001  
Page 40  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Local Digital Switch  
D
S
X
IMACS  
2 x T1/E1  
POTS/  
CLASS  
P
A
N
E
L
• 48 TR008 Lines  
• MODE 1 (Shelves A&B)  
Customer Premise  
Central Office  
Figure 12a - IMACS Using TR-008  
IMACS TR-008 feature can support 48 lines on 2 T1 links. IMACS is an ideal vehicle to provide integrated POTS  
services for line sizes of 48 and under. IMACS supports Mode I, Shelf A&B of TR-008 specification. The IMACS  
supports extensive testing and diagnostics capabilities, which minimizes troubleshooting and allows for high service  
levels.  
T1-E1 Conversion  
The Digital Access and Cross-connect System (DACS) capabilities and the signaling and companding conversion  
features of the IMACS can be used to provide gateway functionality between a DS1 transport network and an E1  
transport network. See Figure 12b for an illustration of this capability.  
W1-1  
W2-1  
W1-2  
W2-2  
IMACS  
E1  
DS1  
Transport  
Network  
Transport  
Network  
W3-2  
W4-2  
W3-1  
W4-1  
Figure 12b - IMACS Using T1/E1 Conversion  
Depending on the application, the signaling conversion can be set by the user to ITU-to-ANSI; ANSI-to-ITU or  
None. Similarly, the companding can be set by the user to A-Law-to-µ-Law, µ-Law-to-A-Law or none. As shown  
in the figure above, each WAN card must be configured with one port for DSX1 and one for CEPT. A cross-  
connection circuit must be made for each DS1 to E1 DSO re-assignment. Time Slots 0 and 16 cannot be used on the  
E1 link. Time slot 0 is used for timing and time slot 16 is used for Channel Associated Signaling (CAS). TS16 is  
available in data-only applications.  
March 2001  
Page 41  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
IMACS Data Modules and Applications  
The IMACS supports multiple user cards for transport of digital data. A list of all cards/model types that can be  
used in the chassis is provided in Table 13.  
Table 13—Data Card Types  
Type of Card  
Description  
820260 HSU Card  
Supports two RS530/V.35 or RS-449 data ports via DB25 female connectors. It can  
also support RS232 data through the use of the appropriate Personality module.  
Supports 56K, 64K and Nx56/64K data applications.  
820360 HSU Card  
Supports two V.11/X.21 data ports which connects to RS530 or X.21 CPE devices via  
DB25 female connectors. The ports may be configured as user ports, or can be used as  
externally clocked network interface ports. Supports 56K, 64K and Nx56/64K data  
applications.  
821260 HSU Card  
821360 HSU Card  
Supports two V.35 synchronous data ports via two DB25 female connectors. Supports  
56K, 64K and Nx56/64K data applications.  
Provides two miniature DB26 female connectors. Each port can be configured to  
support RS530 or V.35 devices. Interface selection is made on a port-by-port basis.  
The 8213 supports V.25bis dialing commands (an in-band dialing protocol) and RS-  
366 dialing through the use of separate DB15 pin RS-366 port connectors on the rear  
of the card. Supports 56K, 64K and Nx56/64K data applications.  
821460 HSU Card  
821560 HSU Card  
Supports two V.35 synchronous data ports via two DB25 female connectors. The  
ports can be configured as user ports, or be used as externally clocked network  
interface ports. Supports 56K, 64K and Nx56/64K data applications.  
Provides four miniature DB26 female connectors. Each port can be configured to  
support RS530 or V.35 devices. Interface selection is made on a port-by-port basis.  
Supports 56K, 64K and Nx56/64K data applications. Can also support RS232 data at  
56Kbps through the use of the 1253xx Personality Module and 1240 cable layer. The  
821570 HSU card has improved clock jitter performance.  
821660 HSU Card  
Provides four miniature DB26 female connectors. Each port can be configured to  
support RS530 or V.35 devices. Interface selection is made on a port-by-port basis.  
Supports 56K, 64K and Nx56/64K data applications. Can also support RS232 data at  
56Kbps through the use of the 1253xx Personality Module and 1240 cable layer.  
Supports tail circuits greater than 24 timeslots. V.35 interface compatible with  
international standards, and individually selectable transmit/receive clock inversion  
options.  
March 2001  
Page 42  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 13—Data Card Types (continued)  
822060 SRU Card  
Provides 10 port RS-232C/V.24 interfaces. Supports synchronous and/or  
asynchronous data ports from 300 bps to 38.4 Kbps.. Supports DS0-A, DS0-B,  
V.14 and X.50 Division 3 sub-rate multiplexing format. SRU card ports can also  
be multiplexed with voice traffic on an ADPCM engine (up to 19.2 Kbps data  
circuit in 24 Kbps ADPCM channel). The 822061 SRU card provides equivalent  
functionality as the 822060 except the Idle Pattern has been changed.  
822160 SRU Card  
822460 SRU Card  
Functionality equivalent to 822060 SRU card. When used with 822060, increases  
the SRU port density per IMACS system beyond the current limit of 60.  
The 822460 SRU has 4 DB-26 female connectors. Supports synchronous and/or  
asynchronous data ports from 300 bps to 38.4 Kbps. Supports DS0-A, DS0-B,  
V.14 and X.50 Division 3 sub-rate multiplexing formats. SRU card ports can also  
be multiplexed with voice traffic on an ADPCM engine (up to 19.2 Kbps data  
circuit in 24 Kbps ADPCM channel).  
822560 SRU Card  
Supports 10 RS-232E synchronous and/or asynchronous data ports from 300 bps to  
38.4 Kbps. Supports DS0-A, DS0-B, V.14 and X.50 Division 3 sub-rate  
multiplexing formats by hardware instead of software. The configuration is  
controlled via local terminal or remote NMS. The SRU offers lower delay and  
increasing throughput. SRU card ports can also be multiplexed with voice traffic on  
an ADPCM engine (up to 19.2 Kbps data circuit in 24 Kbps ADPCM channel).  
Supports CSU, DSU and OCU loop backs.  
822860 BnR  
Concentrator Card  
Provides concentration for time slots containing diagnostics from remote IMACS  
units. Multiplexes up to 8 ports of Bit-7-Redundant (B7R) or B4R formatted data  
channels from up to 8 different DS0s onto a single, asynchronous channel at up to  
38.4 Kbps. Data on the aggregate channel is in SLIP format and the interface is  
RS-232.  
823160 FRAD Card  
Frame Relay Assembler/Disassembler provides encapsulation for HDLC/SDLC or  
Async ports up to 38.4 Kbps. Transparent/Sync up to 38.4 Kbps. This card  
concentrate up to 8 non-frame inputs into 2 data streams at 56Kbps or 64Kbps.  
Total of 10 ports may be assigned to input (FRAD) or output (concentrator) ports  
based on configuration guidelines. Access to this card is via on-card RS-232 or  
through DS0-B over T1.  
824160 and 822460  
OCU-DP Cards  
The 824160 (5 port) and 822460 (10 port) allows provisioning of DDS services or  
consolidation of DSU traffic as DS0-A or DS0-B. Interfaces directly to DSU at  
speeds up to and including 64 Kbps. Does not support BCH error correction,  
performance monitoring or operation in CSU mode (used only for back-to-back  
OCU-DP ports). Emulates an 8247 for existing system compatibility. Each port  
may be connected to a DSU/CSU operating at 64, 56, Switched 56, 19.2, 9.6, 4.8 or  
2.4 Kbps. DSUs can be local to several thousand feet distant to IMACS based on  
speed and wire gauge.  
BRI Card  
OCU-DP Card 8249  
The 8249 is a 2 port OCU-DP card that provides interfaces for provisioning of  
DDS services or consolidation of DSU traffic. Supports DS0-A or DS0-B sub-rate,  
56K, 64K and Switched 56Kbps DDS. Supports BCH error correction,  
performance monitoring or operation in CSU mode. Secondary channel operation  
can be enabled if desired. Optional error correction for inter-IMACS circuits.  
March 2001  
Page 43  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
825460 DSO-DP Card Provides 4 ports of DS0-DP or G.703 64K. For G.703, clock can be selected to be  
co- directional or contra-directional.  
826070 BRI Card  
This BRI-U card provides 8 ports of 2-wire 2B1Q interface via a single RJ27X (F),  
50-pin amphenol connector. Adheres to 2B+D format. Supports external timing.  
Can be used to support NTUs for dedicated operation or for connections to BRI-U  
interface devices. Commonly used for BRI Terminal extension.  
826170 BRI Card  
This BRI-U card provides 8 ports of 2-wire 2B1Q interface via a single RJ27X (F),  
50-pin amphenol connector. Adheres to 2B+D format. Supports external timing.  
Can be used to support NTUs for dedicated operation or for connections to BRI-U  
interface devices. Commonly used for BRI Terminal extension. Provides sealing  
(or wetting) current, 7.5mA or 15mA.  
826171 BRI Card  
826270 BRI Card  
This BRI-U card provides 8 ports of 2-wire 2B1Q interface via a single RJ27X (F),  
50-pin amphenol connector. Adheres to 2B+D format. Supports external timing.  
Can be used to support NTUs for dedicated operation or for connections to BRI-U  
interface devices. Commonly used for BRI Terminal extension. Provides sealing  
(or wetting) current, 7.5mA or 15mA. No “DC signature” feature support.  
This BRI-S/T card provides 8 ports of 4-wire interfaces via a single RJ27X (F), 50-  
pin amphenol connector. Adheres to 2B+D format. Supports external timing.  
Provides TE, NT1 and NT2 emulation. Commonly used to provide remote  
extension of four wire BRI CPE devices from an ISDN PBX. Requires external  
power connection (-48V DC) if more than 3 cards installed in IMACS chassis  
unless 891330 and 8908 are used (special cable required).  
826361 BRI Card  
826461 BRI Card  
826462 BRI Card  
Supports 8 ports of 2-wire 2B1Q via a single RJ27X connector. Supports LULT  
and LUNT. Supports Bi-directional B1, B2 and D channel. Network clock for bit  
timing to LULT and EOC as per TR000397 using 3 DS0 TDM methods. Support  
Interim Performance Monitoring as per TR-000397 and TR-000829. Provides  
sealing current. No “DC Signature”.  
Supports 8 ports of 2-wire 2B1Q via a single RJ27X connector. Supports LULT  
and LUNT. Supports Bi-directional B1, B2 and D channel. Network clock for bit  
timing to LULT and EOC as per TR000397 using 3 DS0 TDM methods. Support  
Interim Performance Monitoring as per TR-000397 and TR-000829. Provides “DC  
Signature” but no sealing current.  
Supports 8 ports of 2-wire 2B1Q via a single RJ27X connector. Supports LU, LT,  
LULT and LUNT and network management of NTUs (2560 and 2561). Supports  
Bi-directional B1, B2 and D channel. Network clock for bit timing to LULT and  
EOC as per TR000397 using 3 DS0 TDM methods. Support Interim Performance  
Monitoring as per TR-000397 and TR-000829.  
828060 PM-IOR Card Inter Office Router card is based on Lucent Technologies PortMaster product line.  
Connects 10BaseT Ethernet LAN to T1/E1 WAN. Uses PPP or Frame Relay and  
IP (TCP/IP and IPX) to route up to 1.2 Mbps through WAN. Can assign Nx56/64  
Kbps DS0s. Configure router through RJ-45 console port. Supports SNMP  
network management.  
March 2001  
Page 44  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
HSU Card  
The HSU card allows the connection of high-speed data terminal equipment (DTE) and data communications  
equipment (DCE) to WAN links, server cards (FRS) or another HSU card. The HSU card also provides low or mid-  
density connectivity for local, synchronous peripherals such as, LAN Bridge/Routers and legacy SNA/SDLC  
devices. Additionally, these high-speed data cards provide broadcast functionality for point to multi-point  
operations suitable for applications such as video-conferencing. When used in conjunction with an 8840 PRI Server  
Card, the HSU card can be used to provide switched data application functionality. All HSU cards can be installed  
in any of the User Slots in an IMACS chassis.  
Each port on a HSU can be independently configured to operate at speeds of Nx56 or Nx64 Kbps, where N equals 1  
to 24 in T1 mode or 1 to 31 in E1 mode. In addition to the data rate, each synchronous port’s Transmit Clock can be  
programmed for Internal or External modes and both the Clock and Data Polarity may be inverted through software.  
The External Transmit Clock mode and the Inverted Clock Polarity mode may be useful in ensuring that both the  
Transmit Clock and the Transmit Data are in sync when they reach the HSU port. This should occur when the HSU  
port and the attached device are connected over a long cable. The Data Polarity may be inverted to ensure the  
density for Nx64 Kbps data circuits supporting HDLC-based protocols that are connected to non-B8ZS T1 facilities.  
The “Clear To Send” control lead may always be set to high, low or local mode. In local mode, the CTS signal  
reflects the state of the Request To Send (RTS) signal that is received from the attached DTE device. In that mode,  
the delay between RTS and CTS is software set-able, with options of 0, 30, 60 or 100 milliseconds. Additionally, if  
the HSU port is programmed to operate at Nx56 Kbps, then RTS will be transmitted end-to-end and presented as  
RLSD at the far end of the circuit.  
Software-initiated diagnostics support the setting of local loop backs towards either the network or the attached DTE  
equipment. Additionally, a remote loop back function allows the HSU card to generate three DDS-compatible  
latching loop back codes for the far-end OCU, CSU and DSU equipment. Similarly, the HSU data port may be  
programmed to detect and respond to both latching and non-latching DDS-format OCU, CSU and DSU loop back  
codes initiated from the remote end of the circuit. A time-out option authorizes the HSU port to automatically  
release the loop back after ten minutes. This feature applies to an HSU port that is running at 56 Kbps or for super-  
rate circuits if the loop back code is transmitted in the first super-rate’s DSO. The card can also generate and  
recognize two industry standard in-band loop-up and loop-down codes that act on the entire super-rate circuit.  
Those are the ITU (CCITT) V.54 code and the ANSI Fractional T1 code.  
Additionally, the integral Bit Error Rate Tester (BERT) can be used to generate test patterns and route those towards  
the WAN facility. These test patterns can then be used to verify synchronization and measure circuit quality. For  
further information regarding Performance Monitoring and Diagnostic Capabilities, see Section 13, IMACS System  
Testing and Diagnostics.  
Applications  
There are several business applications the IMACS equipped with an HSU card supports.  
LAN to LAN  
LAN to WAN to LAN  
Work Station to Computer  
Computer to Computer  
Compressed Video  
CAD/CAM  
Call Center  
IMACS and HSU Application Example  
A major Health Maintenance Organization has numerous locations, which have a Central main hospital facility and  
smaller satellite facilities. The HMO cannot afford to fully staff each main and satellite site with specialists. As  
patients enter the satellite facilities, video and audio sessions can be established with the specialists at the Main  
March 2001  
Page 45  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
hospital. Although the satellite sites are not equipped with Intensive Care Units, emergencies can be admitted and  
support solicited from the Main hospital personnel as shown in Figure 13.  
Main  
Medical  
Facility  
Remote  
Medical  
Facility  
IMACS  
Video Codec  
FT1  
1 WAN  
Card  
IMACS  
Video Codec  
FT1  
1 WAN  
Remote  
Medical  
Facility  
IMACS  
Multichannel  
Conferencing Unit  
FT1  
Video Codec  
Figure 13 - Point to MultiPoint One-Way Video and Audio Using HSUs  
March 2001  
Page 46  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 14 describes the various high-speed data cards.  
Table 14—820260, 820360, 821260, 821360, 821460, 821560, 821570 and 821660 High-speed Data Cards  
Model Number  
Number of  
Data Ports  
Physical Interfaces  
Electrical Interfaces  
2
2 female 25-pin DB25 D-connectors ITU-T V.35, RS232,  
RS530/RS449  
Model 820260  
2
2
2
DB25 female connectors  
ITU-T V.11, RS 530  
Model 820360  
Model 821260  
Model 821360  
2 female 25-pin DB25 D-connectors ITU-T V.35 (True V.35)  
2 female 26-pin DB26 D-connectors ITU-T V.35, V.25bis, RS366,  
RS530  
2 DB15 female connectors  
(V25 bis and/or RS-366 dialing  
when used with 8840 PRI Card)  
2
4
2 female 25-pin DB26 D-connectors ITU -T V.35 (True V.35),  
4 female 26-pin DB26 D-connectors RS530, RS-232, V.35 devices  
Model 821460  
Model 821560  
Model 821570 (improved  
clock jitter performance)  
Model 821660  
4 female DB26 connectors RS530, RS-232 and True V.35 devices  
Nx56K and Nx64K where N=1 to 31 (up to 1984 Kbps)-Software Configurable  
by port  
Data Format  
Synchronous  
Data Protocol  
Transparent  
Transmit Clock per  
Port  
Internal or external (software configurable)  
Clock Polarity per Port Normal or inverted (software configurable)  
Data Polarity per Port  
Normal or inverted (software configurable)  
Model 8213 only when used with 8840 PRI Server Card  
2
Dial Capability  
Number of Dialing  
Ports  
Dialing Electrical  
Interface  
EIA RS-366, ITU-T V.25 bis  
2 female 15-pin D-connectors  
Dialing Physical  
Interface  
Errored Seconds, Unavailable Second, Severely Errored Second, Burst Errored  
Second, Loss of Packet Seconds, Loss of Frame Count  
Performance Statistics  
Standards  
Conformance  
ITU-T V.35  
Data Transmission of 48 kbps Using 60-108 kHz Group Band Circuits  
ITU-T V.11 (10/96)  
Electrical characteristics for balanced double-current interchange circuits operating at  
data signaling rates up to 10 Mbps  
ITU-T v.24  
(10/96) - List of definitions for interchange circuits between data terminal equipment  
(DTE) and data circuit-terminating equipment (DCE)  
ITU-T V.28  
Electrical characteristics for unbalanced double-current interchange circuits  
ITU-T G.704 (7/95)  
Synchronous frame structures used at 1544, 6312, 2048, 8488 and 44 736 Kbps  
hierarchical levels  
ITU-T V.25bis  
(Model 8213 only) (10/96) - Automatic answering equipment and general procedures for  
automatic calling equipment on the general switched telephone network including  
procedures for disabling of echo control devices for both manually and automatically  
EIA RS-422  
EIA RS-449  
Electrical characteristics of balanced voltage digital interface circuits  
General purpose 37 position and 9 position interface for DTE and DCE equipment  
employing serial binary data interchanges  
March 2001  
Page 47  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
EIA RS-530  
EIA RS-366  
FCC Part 15  
UL 1950  
High-speed 25 Position Interface for Data Terminal Equipment, Including Alternative 25  
Position Connector.  
Interface Between Data Terminal Equipment and Automatic Calling Equipment for Data  
Communication  
Subpart B  
UL Standard for Safety of Information Technology Equipment  
CE EN 500 81-1  
Electromagnetic compatibility generic emission standard Part 1 Residential,  
commercial and light industry  
CE EN 500 82-1  
CE EN 60 950/A2  
Electromagnetic compatibility generic immunity standard Part 1 Residential,  
commercial and light industry  
Safety of information technology equipment including electrical business  
equipment  
Network Equipment-Building System (NEBS) Requirements: Physical Protection  
BellCore GR-63-CORE  
2. SRU Card  
The 822060/822161 SRU Card allows synchronous or asynchronous connections of up to ten RS-232, low-speed  
and medium-speed (300 bps to 38.4 kbps) data terminals to the integrated access system. Since an SRU port does  
not require a complete 64Kbps time slot, the Sub-Rate card allows the multiplexing of a number of devices into a  
single, subdivided time slot on a WAN card. SRU card ports can also be multiplexed with voice traffic on an  
ADPCM engine. The 822060 accesses user buses A & B, and the 822161 SRU accesses user buses C & D. The  
822061 SRU has equivalent functions as the 822060 with the exception of Idle Pattern changes. The 822460 SRU  
has 4 RS-422 ports that support synchronous and/or asynchronous connections from 300 bps to 38.4 Kbps. The  
Low Delay SRU provides 10 RS-232E ports that support synchronous and/or asynchronous V.14 operations. The  
sub-rate multiplexing is performed by hardware instead of software.  
Each RS-232 port can be independently programmed for synchronous (including HDLC) or asynchronous operation.  
Synchronous operation is available at speeds of 2.4 Kbps up to 38.4 Kbps while for asynchronous the range is 300  
bps up to 38.4 Kbps. Each synchronous port can receive timing from either the DTE device or the system clock. If  
the DTE supplies the transmit clocking, it must be synchronized with the system clocking source. For each  
asynchronous data port, the stop bits, data bits and parity are user configurable. The SRU incorporates a built-in  
V.14 Async-to-sync converter to avoid over-sampling and consequently saves bandwidth. Asynchronous data  
circuits are converted to synchronous mode by the SRU card prior to multiplexing onto a WAN aggregate.  
Sub-rate data ports are multiplexed into industry standard DSO formats. The user may specify the format of the  
DSO that the data port is assigned to. The choices are: DSO-A which allows only one data port to be mapped into  
the DSO and DSO-B which allows multiple data ports from multiple SRU cards in the system to be mapped into the  
same DSO time slot. If the DSO-B format is selected, then the user can specify the type of DSO-B format required  
(b-5, b-10 and b-20) and the sub-rate position that the data port will occupy within the DSO-B frame.  
In b-5 mode, the DSO is divided into five sub-rate positions, each of which are occupied by a data port operating at  
9.6 Kbps, 4.8 Kbps, or 2.4 Kbps. Additionally, one or two 19.2 Kbps circuits are supported in b-5 mode. Each  
would occupy two of the five sub-rate positions. Additionally, data circuits running at 28.8 Kbps or 38.4 Kbps are  
supported in b-5 mode and will occupy three or four of the five available sub-rate positions. In b-10 mode, the DSO  
is divided into ten sub-rate positions, each of which are occupied by a data port operation at 4.8 Kbps or 2.4 Kbps.  
In b-20 mode, the DSO is divided into 20 sub-rate positions, each of which are occupied by a data port operating at  
2.4 Kbps.  
In the application shown in Figure 14, the IMACS with the SRU card (on the right hand side) can either send each  
sub-rate on a separate DS0 (DSO-A format) or groom multiple sub-rate channels into a single DS0 (one of the DSO-  
B formats).  
March 2001  
Page 48  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
IM
ACS  
IMACS w/ SRU  
R
Local  
DTE  
OCU-DP  
CSU/DSU  
T1 carrier  
Network  
Remo
t
e  
Remo
t
e  
V.35  
Remo
t
e  
DTE  
RS232  
Synchronous/Asynchronous  
DTE.
(
300 bps
-
3
8.4 Kbps)  
Figure 14 - IMACS With SRU Card Application  
The SRU card also supports X.50 division 3, an ITU (CCITT) standard for sub-rate multiplexing. The  
maximum bandwidth of the SRU card is 115.2Kbps. The SRU card provides the ability for software  
configurable delay optimization. If delay optimization is used on all 10 ports, the maximum bandwidth  
available will be 76.8Kbps. Software-initiated diagnostics supported on the SRU card is the same as on the  
HSU card. Table 15 describes the SRU card specifications.  
March 2001  
Page 49  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 15—SRU Card Specifications  
Model Number  
822060 SRU Card  
822061 SRU Card  
822160 SRU Card  
822460 SRU Card  
822560 SRU Card  
Operational Interface  
Interface Settings  
Sub-rate Framing Format  
Sub-rate Time slot number  
Synchronous Data  
Format  
# of data ports  
Physical Interfaces  
Electrical Interfaces  
RS-232C, V.24  
RS-232C, V.24  
RS-232C, V.24  
RS-422  
10  
10  
10  
4
10 female 8-pin RJ-48  
10 female 8-pin RJ-48  
10 female 8-pin RJ-48  
4 female 26 pin DB-26  
10 female 8-pin RJ-48  
10  
RS-232E  
DCE—full duplex  
Asynchronous, synchronous, V.14  
X.50, V.14, DSO-A, DSO-B with 5, 10 or 20 divisions per DSO  
1 through 20 depending on sub-rate framing format  
Transparent  
Transmit Clocking  
Speeds  
Software configurable per port; internal or external  
2.4; 4.8; 9.6; 14.4; 19.2; 28.8 and 38.4 Kbps  
Asynchronous Data  
Format  
V.14 or proprietary  
Stop Bits  
Software configurable per port; 1 or 2  
Data Bits  
Parity  
Speeds  
Software configurable per port; 5, 6, 7 or 8  
Software configurable per port; none, odd, even, space or mark  
2.4; 4.8; 9.6; 14.4; 19.2; 28.8 and 38.4 Kbps  
Signaling  
DSR  
Tied to DTR  
CTS  
CTS delay  
RLSD  
Software configurable per port; on, off (tied to RTS)  
Software configurable per port; immediate, 30, 60 or 100 ms  
Software configurable per port; permanently on, follows remote RTS (drop  
on receipt of IDL or CGA RED)  
Standards Compatibility  
Network Equipment-Building System (NEBS) Requirements: Physical  
Protection  
AT&T TR54075  
ITU-T V.24  
ITU-T V.28  
Sub-rate Data Multiplexing - A Service of DATAPHONE Digital Service  
Definitions for Interchange Circuits Between DTE and CE  
Electrical characteristics for unbalanced double-current interchange  
Fundamental Parameters of a Multiplexing Scheme for the International  
Interface Between Synchronous Data Networks (note: does not support  
600bps data  
ITU-T X.50 Division 3  
ITU-T V.14  
Transmission of Start-Stop Characters over Synchronous Bearer Channels  
(using Async to synch converters)  
EIA RS232  
FCC Part 15  
UL 1950  
Interface between DTE and DCE employing serial binary data interchange  
Subpart B  
UL Standard for Safety of Information Technology Equipment  
Electromagnetic compatibility generic emission standard Part 1 Residential,  
commercial and light industry  
CE EN 500 81-1  
CE EN 500 82-1  
Electromagnetic compatibility generic immunity standard Part 1  
Residential, commercial and light industry  
CE EN 60 950/A2  
Safety of information technology equipment including electrical business  
equipment  
March 2001  
Page 50  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
3. FRAD Card  
The 823160 Frame Relay Assembler/Disassembler (FRAD) user card provides eight ports for transport of low speed  
data across Frame Relay Networks. The FRAD can encapsulate HDLC protocols (such as SDLC). Each port can be  
independently configured for asynchronous, transparent synchronous data or HDLC.  
When taking data from the on-board RS-232 port, the FRAD card supports speeds of 2.4, 4.8, 9.6, 14.4, 19.2, 28.8  
and 38.4 Kbps, independently configured on a per port basis. The aggregate Frame Relay encapsulated traffic  
coming out of the WAN card can be configured to transmit at 56Kbps or 64 Kbps.  
When processing HDLC data, the flags and the CRC are removed before assembling the frames. For asynchronous  
data, start and stop bits are removed before the frames are assembled. Other data is treated as a transparent data  
stream and all bits will be encapsulated into transmitted frames. The FRAD card supports proprietary sub-  
addressing over a PVC. This sub-addressing is transparent to the Frame Relay Transport Network, and allows  
multiple ports on a single FRAD to share the same PVC, resulting in lower costs.  
The FRAD card also maintains performance statistics detailing the number of frames transmitted, number of frames  
received, number of octets transmitted, number of octets received, number of frames dropped before being received  
during a 15 minute interval and a status field describing the conditional that caused the dropped packets (DTE port  
down, loop back in progress or port in standby). All these performance statistics are gather for 24 hours, in 1-hour  
intervals. The FRAD card also provides test frame generators for additional diagnostics.  
In the application represented by the Figure 16 , the router on the left (at a remote office) is connected to the IMACS  
via the FRAD card at 9.6Kbps, along with other voice traffic from a PBX. The router traffic is mapped onto a DS0  
on the T1 link to the Central Office where it is separated by a DACS and directed towards a Frame Relay network  
and switched/routed to the destination router at the headquarters. See Figure 15 for an illustration of the FRAD  
Card’s capabilities and Table 16 for the FRAD Card’s specifications.  
March 2001  
Page 51  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
PSTN  
IMACS w/ FRAD  
DACS  
PBX  
Frame  
Relay  
Router  
Figure 15 - IMACS FRAD Card Application  
March 2001  
Page 52  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 16—FRAD Card Specifications  
Model 823160 FRAD Card  
Number of Ports  
Speeds  
10  
2.4; 4.8; 9.6; 14.4; 19.2; 28.8 and 38.4 Kbps  
Physical Interface  
Electrical Interface  
Data Format  
Data Protocol  
DLCI  
10 Female 8-pin RJ-48  
RS232, ITU-T V.28  
Synchronous and asynchronous  
Async or HDLC (SDLC); transparent  
16 to 991  
LMI  
ANSI, CCITT, LMI (Gang of Four)  
5 to 512 bytes  
56 or 64 kbps  
Maximum Frame Size  
Frame Relay Aggregate Rate  
Time Slot Number for WAN  
Diagnostics  
1 through 31 on an WAN (T1/E1) link  
HDLC Test Pattern  
Loop Back  
Active or inactive  
To DTE, to network or remote  
Synchronous Data  
Format  
Transparent  
Transmit Clocking  
Asynchronous Data  
Format  
Software configurable per port; internal or external  
V.14 or proprietary  
Stop Bits  
Software configurable per port; 1 or 2  
Data Bits  
Parity  
Speeds  
Software configurable per port; 5, 6, 7 or 8  
Software configurable per port; none, odd, even, space or mark  
2.4; 4.8; 9.6; 14.4; 19.2; 28.8 and 38.4 Kbps  
Standards Compatibility  
BellCore GR-63-CORE  
Network Equipment-Building System (NEBS) Requirements:  
Physical Protection  
AT&T TR54075  
Sub-rate Data Multiplexing - A Service of DATAPHONE Digital  
Service  
FCC Part 15  
ITU-T V.28  
Subpart B  
Electrical characteristics for unbalanced double current  
interchange currents  
UL 1950  
CE EN 500 81-1  
UL Standard for Safety of Information Technology Equipment  
Electromagnetic compatibility generic emission standard Part 1  
Residential, commercial and light industry  
Electromagnetic compatibility generic immunity standard Part 1  
Residential, commercial and light industry  
Safety of information technology equipment including electrical  
business equipment  
CE EN 500 82-1  
CE EN 60 950/A2  
March 2001  
Page 53  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
4. OCU-DP Card  
The OCU-DP (Office Channel Unit - Data Port) is used to interface directly to DSU/CSUs (Data Service Units  
Channels Service Units) supporting data traffic up to and including 64Kbps. A four-wire circuit can connect the  
OCU-DP card to a DSU/CSU that can be located up to four miles away. In switched 56 Kbps mode, users can  
access the network on an as-needed basis by dial-up commands. The system unit must be equipped to provide -48  
VDC power to fully support the functionality of the OCU-DP card.  
OCU-DP Card Models  
The IMACS supports three cards for support of external CSU/DSUs:  
8249 OCU-DP 2 Port Card  
824160 OCU-DP 5 Port Card  
824660 OCU-DP 10 Port Card  
The 8249 OCU-DP card supports two ports while the 824160 and 824660 are five and ten port cards, respectively.  
All OCU-DP cards support RJ48 female connectors.  
Each OCU-DP port can be independently programmed to operate at 2.4, 4.8, 9.6, 19.2, 56 and 64 Kbps in either  
DSO-A, (one channel per DS0) or DS0-B format, which allows multiple data ports from multiple OCU-DP cards in  
the system to be mapped into the same DS0 time slot. If the DS0-B format is selected, the user then specifies the  
type of DS0-B format required (b-5, b-10 or b-20) and the sub-rate position that the data port occupied by the data  
port within the DS0-B frame.  
In switched-56K mode, an OCU-DP port provides a connection for an external Switched-56K DSU/CSU that will  
perform all call set-up and dialing functions. The OCU-DP card converts the call set-up commands into standard  
signaling and sends the signaling over the WAN facility.  
All OCU-DP cards support a low speed secondary channel that is established in the 8th bit position of the DS0 time  
slot to which the OCU-DP port is assigned. The secondary channel can be used for testing and maintenance of the  
main circuit or for the transmission of other, independent, low speed data. The specification table shows the  
secondary channel rates associated with the standard primary port rates of the OCU-DP card.  
The 8249 OCU-DP card also supports two methods of error correction. The first is known as “Majority Vote” and  
applies to the lower data rates, specifically, 2.4, 4.8 and 9.6 Kbps. The other is known as the BCH (Bose-  
Chaudhuri-Hocquenghem) method and applies to data rates of 19.2 Kbps and 56 Kbps. In the case of a 19.2 Kbps  
circuit, the error correction information is placed in the same DS0 that the circuit occupies. In the case of a 56 Kbps  
circuit, the error correction information is placed in a following, adjacent DS0 time slot on the WAN aggregate.  
On all OCU-DP cards, performance statistics are collected by the system and are available through the user  
interface. Performance statistics include Errored Seconds (any second with an error), Severely Errored Seconds  
(any second with an error rate exceeding 10E-3) and Consecutive Severely Errored Seconds (CSES). They are  
displayed in one-hour intervals for up to 24 hours. CSES are counted by the system once ten consecutive Severely  
Errored Seconds are logged. The counter stops when the system logs ten consecutive non-Severely Errored  
Seconds. An OCU-DP port on the 8249 card may be programmed for OCU mode or CSU mode. OCU mode is the  
most common and is used whenever the OCU-DP port attaches to a CSU/DSU over a four-wire circuit. CSU mode  
allows the card to be connected directly to the digital network.  
Software initiated diagnostics supported by the OCU-DP card include the setting of six different loop backs. Three  
of these act on the OCU-DP card itself and are known as local loop backs and the other three generate loop back  
patterns to remote devices and are known as remote loop backs. Among local loop backs, there are three types:  
Loop backs of the 4-wire analog interface of the OCU-DP port towards the attached CSU  
Loop backs of the 4-wire OCU-DP interface towards the network  
Loop backs towards the network at the point where the OCU-DP card interfaces with the system bus  
March 2001  
Page 54  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
All three remote loop backs are latching loop backs. These latching loop backs are:  
Loop back of the analog interface of the remote OCU-DP device back towards the network  
Loop back of the 4-wire interface of the remote CSU device back towards the network  
Loop backs of the 4-wire interface of the local CSU device towards the network.  
An OCU-DP port may be programmed to detect and respond to both latching and non-latching (i.e., alternating)  
DDS-format OCU loop back codes that are initiated from the remote end of the circuit. A time-out option  
authorizes the OCU-DP port to automatically release the loop back after ten minutes.  
March 2001  
Page 55  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 17 depicts the OCU-DP card’s specifications. For further information regarding Performance Monitoring and  
Diagnostic Capabilities, see Chapter 13, IMACS System Testing and Diagnostics.  
Table 17—OCU-DP Specifications  
Model Number  
Model 8249  
Number of Ports  
Physical Interfaces  
Female 8-pin RJ-48  
Female 8-pin RJ-48  
2
Model 824160  
5
Model 824660  
Data Format  
Data Encoding  
Line Interface  
Speeds  
10  
Female 8-pin RJ-48  
Synchronous—binary, serial  
Bipolar, return to 0, AMI  
4-wire  
2.4; 4.8; 9.6; 14.4; 19.2, 56 and 64 Kbps  
DS0-A, DS0-B with 5, 10 or 20 divisions per DS0  
Majority vote for speeds 9.6kbps or less; BCH for 19.2, 456 and 64kbps (8249  
model only)  
Sub-rate Framing Formatting  
Error Correction  
Secondary port  
As described in AT&T 62310, 62411 Addendum and TA (pass through only) TSY  
000077 and TA TSY000083, a separate lower speed data circuit, which may be  
used for testing and maintenance. Modes are on or off.  
Distances  
Supported  
Primary  
Rate  
Secondary  
Rate  
---  
Line  
Rate  
Loss Limit  
19 Ga.  
(KF)  
133.0  
114.3  
97.6  
22 Ga.  
(KF)  
90.7  
79.1  
65.8  
57.5  
48.3  
42.9  
36.9  
33.9  
35.0  
33.3  
33.3  
24 Ga.  
(KF)  
71.5  
61.9  
51.1  
44.8  
37.1  
32.8  
27.6  
25.1  
24.5  
23.1  
23.1  
26 Ga.  
(KF)  
56.8  
48.7  
40.2  
35.1  
28.4  
25.2  
21.0  
19.9  
17.6  
16.5  
16.5  
dB  
34  
34  
34  
34  
34  
34  
34  
34  
43  
43  
43  
2400  
2400  
2400  
133  
---  
3200  
4800  
4800  
4800  
267  
---  
6400  
86.3  
9600  
9600  
74.2  
9600  
533  
---  
12800  
19200  
25600  
56000  
72000  
72000  
67.5  
19200  
19200  
56000  
56000  
64000  
60.0  
1067  
---  
57.0  
60.7  
2667  
---  
57.6  
57.6  
Primary Port Rate  
56 kbps  
Secondary Port Rate  
2,666 bps  
19.2 kbps  
1,066 bps  
9.6 kbps  
533 bps  
4.8 kbps  
266 bps  
2.4 kbps  
133 bps  
Operational Modes  
Standards Compliance  
AT&T TR62411  
TA-TSY-000077  
Software configurable per line ocu or csu  
Accunet T1.5 Service Description  
Digital Channel Banks- Requirements for Data port Channel Unit Functions, Issue  
3, April 1986  
TA-TSY-000083  
Generic Requirements for the Digital Data System (DDS) Network Office Channel  
Unit, Issue 2, April 1986  
BellCore Pub 62310  
CCITT T1.107-1988  
ANSI T1.107b-1990  
DSO Digital Local Channel Description Interface Specification (August 1993)  
Digital Hierarchy- Format Specifications 1988  
Digital Hierarchy- Supplement to Format Specifications (Synchronous Digital Data  
Format), June 1991  
March 2001  
Page 56  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
5. BRI Card  
The 826xxx line of BRI Cards offers industry standard ISDN BRI “U” or “S/T” Interfaces. Each BRI Card supports  
eight BRI “U” Interfaces for long line circuit provisioning, or “S/T” Interface for local provisioning. The BRI  
Interface provides two bearer and one data channel over two wires (1 pair). The S/T interface provides the same  
functionality over 4-wires (2 pair). In addition to this, each BRI “U” Interface supports 256x Zhone Technologies  
NTUs or Adtran 64/1218 NTUs, providing remote NTU management. With the 826361 and 826461 cards available  
with host release 5.1.X or above, full NTU management and ISDN switch signaling are supported.  
The Basic Rate Interface “U” Interface card offers connectivity to sites located up to 18,000 feet from the integrated  
access system. This distance is influenced by factors such as wire gauge, bridge tap and loading patterns as  
described in ANSI T1.601-1992 specifications. The BRI cards are equipped with eight “U” interfaces that can carry  
one BRI, 2B+D channel. This will give users either two 64 Kbps or one 128 Kbps bearer channels per interface.  
The “U” Interface is also provides optional sealing current for maintaining wire pair performance. When used with  
IMACS WAN and Server Card options, the BRI card supports two transmission protocols (BRITE for the  
826361/826461 models and Zhone Technologies proprietary protocol for 826070/826171 models), facilitating  
leased line or IDSL (2B1Q) provisioning, BRI to PRI operation and BRI (data) to Frame Relay/ATM Operation.  
Either protocol allows the IMACS to extend the reach of an ISDN PBX hundred of miles away from the location of  
the PBX switch as shown in Figure 16. All services are passed to the remote location with no restrictions, enabling  
the end user or agent to use all PBX functionality as if they were locally attached to the switch. Management of this  
solution is transparent to the PBX programmer. All remote extensions are treated as if they are local connections.  
No special programming or management is necessary. For example, if there was an ISDN switch located in San  
Francisco, ISDN capabilities could be transparently transported across the network to a remote call center or other  
customer in San Ramon. There is no technical limit once connected to the network; service could be as far away as  
New York.  
ISDN Terminal Extension  
San Francisco  
Central Office  
NT1  
T1  
NT1  
“U”  
“U”  
IMACS with  
BRITE card  
18k ft ISDN  
Service Limit  
ISDN Switch  
T1  
ISDN Service Area Extension  
San  
Ramon  
CO  
NT1  
“U”  
IMACS with  
BRITE card  
Figure 16 - IMACS BRI Terminal Extension Application  
March 2001  
Page 57  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
The two transmission protocol supports switched connectivity to ISDN capable switches and D channel signaling on  
either a full DS0 or multiplexed 4:1 on a single DS0. The ability to multiplex 4 channels onto one DS0 allows for  
more efficient provisioning. The 826361 and 826461 cards only support 3 DS0s at this time.  
Another application of the BRI card is for leased line, or IDSL (ISDN Digital Subscriber Loop) as shown in Figure  
18. This allows for a DDS type circuit, with 2 * 64 kbps bearer channels over a single wire pair. The leased circuit  
can be any standard 2B1Q (U interface) NTU device that supports “nailed-up” (1 or 2B channels) connections and  
no D channel signaling for the 826070, 826171, and 826270 cards. The 826361 and 826461 cards support a  
standard non-direct OS/NE communication scheme or multipoint eoc (mp-eoc). The mp-eoc is used for sending  
operations messages between the ISDN switch and NE line units.  
The requirements are specified in TR-829. The performance monitoring portion of this specification will not be  
implemented. For the 3-DS0 TDM, the overhead bits are transported between the LUNT and LULT as described in  
TR-397, and for the 4:1 TDM, this is done in a proprietary format. This allows continued customer deployment of  
D4 equipment as shown in Figure 17.  
Leased Line or IDSL (2B1Q)  
IMACS  
2B1Q  
NTU  
IMACS  
2B1Q  
NTU  
DTE  
DTE  
T1/E1 carrier  
Network  
Figure 17 - IMACS BRI Card In A Leased Line or IDSL Application  
C e n t r a l O f f i c e  
T 1  
N T 1  
I M  
A
C S  
w
i t h  
D
4
C
h
a
n
n
e l  
B
a n  
k
B R I T E c a r d  
I S  
w
D
i t c h  
N
S
T 1  
N T 1  
I M  
A
C S  
w
i t h  
B R I T E c a r d  
Figure 18 - Use of Legacy D4 Equipment Application  
BRI Card Models  
In both cases, leased line and BRITE, B channels carrying voice traffic on the BRI card can be compressed through  
the ADPCM card to extend the user’s Servers. The only limitation on BRI traffic is that NTUs or NT1s must be  
located less than 18,000 feet from the system unit.  
March 2001  
Page 58  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
The 826070 BRI “U” Card has software configurable mode operation of LT and NT. It supports up to eight leased  
or BRI terminal extension applications. The 826070 does not support sealing current generation or termination.  
The 826171 BRI “U” Card has all of the functionality of the 826070, however, switching between the LT and NT  
modes must be performed by making a menu selection and changing jumper connections on the card. Also, the  
826171, unlike the 826070 the card supports a user configurable sealing current of 7.5mA or 15.0mA.  
The 826270 BRI “ST” Card is designed to support “S/T” 4-wire interface applications. This card provides TE, NT1  
and NT2 emulation and is commonly used to provide remote extension of four-wire BRI CPE devices from an ISDN  
PBX.  
This section outlines the applicable features in TR-NWT-000397. The LULT has the same master DSL transceiver  
as the LT in the ISDN switch. However, the LULT differs from the LT in several respects that deal with the DSL  
overhead and options for supporting multiplexing. The following list notes some of the key distinctions of the  
LULT from the LT.  
Features of an LT like line unit (LULT):  
The LULT “functional backplane” interface is the IMACS backplane, not a switch.  
The LULT supports 3-DS0 TDM (BRITE) for multiplexing ISDN Basic Access over a carrier system. This  
implies appropriate processing and transport of the DSL overhead information.  
The LULT acts as a multipoint eoc intermediate slave node.  
The LULT has the option of disabling standard processing of the eoc to permit carrier transport of non-ISDN  
applications.  
The LULT supports generic segmented performance monitoring processing.  
Features of an NT like line unit (LUNT):  
This section outlines the applicable features in TR-NWT-000397. The LUNT has the same master DSL transceiver  
as an NT1. However, the LUNT differs from an NT1 in several respects.  
The LUNT “functional backplane” interface is the IMACS backplane, not a T interface.  
The LUNT supports 3-DS0 TDM for multiplexing ISDN Basic Access over a carrier system. This implies  
appropriate processing and transport of the DSL overhead information.  
The LUNT acts as a multipoint eoc intermediate slave node.  
The LUNT has the option of disabling standard processing of the eoc to permit carrier transport of non-ISDN  
applications.  
The LUNT only passes through NT1 power status bits or NT1-in-test-mode bits.  
The LUNT originates nib and aib, as well as pass on any nib values received from the customer direction and  
originated by a downstream line unit.  
The LUNT supports generic segmented performance monitoring processing.  
The LUNT does not require the ANSI T1.601-1992 NT1 dc termination. It provides a simple dc resistive  
signature for metallic testing purposes.  
The 826x70 series of IMACS BRI cards are also designed to support external timing part of the standard  
functionality. All IMACS BRI cards support extensive built in diagnostics and tests. Loop backs can be generated  
on a per channel basis; with choice of loop back generation mode and loop back codes. Built in BERT tests include  
off, mark, space, and 1:1, 1:7, p_1, p_0, p_1:1, p_1:7.  
In addition to all of the software configurable options on the BRI card itself, the BRI card has the ability to remotely  
manage up to eight NTUs. The NTU’s DTE interface type, data rate and asynchronous baud rate are a few options  
that are configurable through the IMACS BRI card interface. This further enhances network manageability by  
accessing all ISDN equipment from a single platform.  
March 2001  
Page 59  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 18 describes the BRI card specifications.  
Table 18—BRI Card Specifications  
Models 826070, 826171, 826270, 826361 and 826461 Basic  
Rate ISDN Cards  
Physical Characteristics  
Number of ports  
8
Capacity per port  
Two B (64 kbps each) and one D (16 kbps)  
channel  
Female 50-pin RJ-27X Telco connector  
Physical Interface  
Electrical Interface  
Model 826070, 826171, 826361 and 826461  
Model 826270  
2-wire, U-interface per ANSI T1.601  
4-wire, S/T interface per ANSI T1.602/ITU  
1.430  
826070 and 826171 Transmission  
Range  
Wire Gauge  
22 AWG (.644 mm) 24 AWG (.511 mm) 26 AWG (.405 mm)  
23 UK SWG  
26,000 ft (7.9 km)  
Distance  
Max 1500m  
Max. 1500m  
25 UK SWG  
22,000 ft, (6.7 km)  
27 US SW  
18,000 ft (5.5 km)  
Distance  
826270 Transmission Range  
NT p-p  
NT s-b  
NT e-b  
Code  
Rate  
Max. 1500m. 35 m between devices  
Alternate Mark Inversion (AMI)  
192 Kbps +/- 100ppm  
Timing  
External and internal (software configurable)  
Remote NTU not applicable for the 8263 and 8264.  
Remote NTU Configuration Options  
(for 256x Zhone Technologies and  
Adtran NTUs  
DTE Interface Type  
Procedural Characteristics  
Data Protocol  
Channel collision arbitration  
Sealing Current  
V.36 or V.24  
Transparent up to 64kbps or 128 kbps  
(Model 8262 only) As per I.430 (D channel bit echo)  
(Model 8261 only)  
Amperage  
Control  
Multidrop Capability  
Phantom Power  
Wattage  
Jumper set-able 7.5mA or 15mA (requires -48VDC power  
Soft set-able options for start time, duration, repeat time  
(Model 8262 only) Max 2  
(Model 8262 manual settings)  
Limited to 90 mA per port.  
Software Configurable Options  
Models 826070 and 826171  
Model 826270  
U termination Network (nt) or User (lt)  
S/T termination TE, NT point-to-Point, NT short-bus, NT extended  
bus  
Termination Mode for 826070 and  
826171  
Lease, Proprietary, Interworking, NTU-1  
Termination Mode for 826270  
Lease, Proprietary Interworking  
March 2001  
Page 60  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 18—BRI Card Specifications (continued)  
B-Channel Mode  
None, B1, B2, B1+B2, or 128 kbps  
D-subchannel  
None, 1, 2, 3 or 4 (used for BRITE mode)  
Sealing Current  
Off or On per port (Models 826361 and 826171 only)  
Design Standards for Models 826070 and 826171  
ANSI T1.601  
ISDN Basic Access Interface for Use on Metallic Loops for  
Application on the Network Side of the NT (layer 1  
Specification) 8261, 8263  
ANSI T1.602  
ISDN Signaling Specification for Application at the User-  
Network Interface – Layer 2 Specification  
ITU-T I.430  
TR-NWT-000397  
GR-000303  
ISDN, Basic User-network Interface - Layer 1 specification  
ISDN Basic Access Transport System Requirements  
Integrated Digital Loop Carrier System Generic Requirements,  
Objectives and Interface  
Design Standards for Model 826270  
ANSI T1.605  
ISDN Basic Access Interface for S and T Reference Layer 1  
Specification  
ITU-T I.430  
TR-NWT-000397  
GR-000303  
ISDN, Basic User-network Interface, Layer 1 specification  
ISDN Basic Access Transport System Requirements  
Integrated Digital Loop Carrier System Generic Requirements,  
Objectives and Interface  
The following is a summary of the general requirements of the LULT and LUNT as described in the TR-NWT-  
000397.  
Function  
DSL master transceiver (2-wire U interface)  
DSL slave transceiver (2-wire U interface)  
Sealing current source  
LULT  
Yes  
LUNT  
Yes  
Notes  
ANSI T1.601.1992 & TR-393  
ANSI T1.601.1992 & TR-393  
Yes  
Sealing current termination  
DC Test Signature  
Metallic Test Access  
Yes  
Yes  
Yes  
Yes  
Yes  
ANSI T1.601-1992  
TR-476  
Loop backs  
6. DSO-DP  
The 825460 DSO Data Port/G.703 Data Unit (DSO-DP/G.703) is a plug-in user card for the system. The DSO-  
DP/G.703 provides a 64 Kbps interface to a DSO of a T1/E1 network. The card supports four (4) ports which  
provide a 64 Kbps interface to a DSO on a T1 or E1 WAN link. Each DSO-DP/G.703 card can be installed in any  
User Slot and provides four (4) DB15 female connectors.  
The DSO-DP/G.703 card can be programmed to operate in either DSO-DP mode or in G.703 mode. In G.703 mode,  
the card supports either co-directional or contra-directional operation and this option can be set on a port-by-port  
basis. In DS0-DP mode, in addition to Transmit Data and Receive Data, the card can be programmed to either  
provide a 64 Kbps bit clock and an 8 kHz byte clock to the attached device or to receive those two clocks from the  
attached device.  
In G.703 Co-Directional mode, the Transmit Data and Receive Data leads are supported. The clock information and  
the data make up a composite signal and the clock must be derived from the data stream. In G.703 Contra-  
Directional mode, the port provides separate Transmit and Receive Clocks to the attached device. Both clocks are  
64 Kbps clocks with embedded 8 kHz Bipolar Violations (BPVs) to mark the byte boundaries.  
March 2001  
Page 61  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Software-initiated diagnostics supported on the DS0-DP/G.703 card include the setting of local loop backs towards  
either the network or the attached DTE equipment. In addition, a remote loop back function allows the DS0-  
DP/G.703 card to generate four DDS-compatible latching loop back codes for the far-end OCU, CSU, DSU or DS0-  
DP equipment respectively. A time-out option authorizes the DS0-DP/G.703 port to automatically release the loop  
back after ten minutes.  
7. BnR IP Concentrator Card  
The 822860 BnR IP Concentrator card provides a means of concentrating network management data from up to 8  
remote IMACS onto a single asynchronous SLIP link for connection to a NMS. Essentially the 822860 takes IP  
management data from the 8 B7R-formatted DSOs and concentrates it onto a single, asynchronous SLIP line which  
can then be connected to an asynchronous terminal server for connection to a LAN-based NMS.  
Management information from remote IMACS systems can be directed to the IMACS containing the 822860 over  
the Facilities Data Link (FDL) or an ESF T1 link as shown in Figure 19. FDL is a 4 Kbps channel normally used to  
manage the T1 link. When the FDL is used to carry IMACS management data it is no longer able to carry T1  
management data as well.  
IMACS  
4Kbps  
FDL  
IMACS  
IMACS  
NMS  
DACS  
IMACS  
T1  
Terminal Server  
IMACS  
38.4Kbps  
IMACS  
Up to 8 DS0s  
IMACS  
IMACS  
IMACS  
Figure 19 - IMACS Using the 822860 For Network Management  
March 2001  
Page 62  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
The remote IMACS systems must be configured with the TCP/IP CPU software option. Remote IMACS units send  
management information in IP packets over the FDL to an intervening AT&T DACS II. The DACS II can be  
configured to convert the IP management information from the FDL channel into a full DS0 using a link level  
protocol called Bit-4 Redundant (B4R). Even though the management information is only 4 Kbps it will occupy the  
full 64 Kbps DS0. The resulting 8 DS0s are then routed over T1 link(s) to the IMACS that contains the 822860.  
Physically the 822860 is the same card as the 822060 SRU card. Both have ten RJ-48 interface ports, but on the  
822860 the first eight are physically disabled and, effectively, replaced by eight “internal” ports used for the DS0s.  
The ninth RJ-48 port is available for maintenance and the tenth RJ-48 port is used for the aggregate SLIP line to the  
terminal server. Table 19 details the BnR IP concentrator card specifications.  
Table 19—B7R IP Concentrator Card Specifications  
822860 External Ports  
Number  
2
Port 9  
Port 10  
Physical Interface  
Electrical Interface  
Procedural Interface  
IP Address  
Available for maintenance and diagnostics (9.6kbps)  
Asynchronous SLIP port for aggregated NMS data (9.6, 19.2, 28.2 and 38.4 kbps  
Female 8-pin RJ-48  
RS232, ITU-T V.28  
DCE—Full Duplex  
Software configurable on port 10  
Subnet Mask  
Options (port 10)  
Data Bits  
Software configurable on port 10  
Software configurable per port; 5, 6, 7 or 8  
Stop Bits  
Software configurable per port; 1 or 2  
Parity  
Software configurable per port; none, odd, even, space or mark  
Internal Ports  
Number  
8
Protocol  
Data Rate  
DS0 using Bit-7 Redundant (B7R or B4R) protocol  
Preset to 4 kbps  
IP Address  
Subnet Mask  
Standards Compatibility  
Of the corresponding remote IMACS  
Software configurable (same for all 8 internal ports)  
EIA RS232  
ITU-T V.28  
Interface between DTE and DCE employing serial binary data interchange  
Electrical characteristics for unbalanced double-current interchange circuits  
7. PortMaster Integrated Office Router (PM-IOR)  
Introduction:  
The Zhone Technologies Integrated Office Router (IOR) integrates Internet/LAN connectivity within the IMACS  
and StreamLine product solutions. From a single customer premises device, the IOR card, in conjunction with other  
voice and data cards, will allow service providers to bundle voice, data, ISDN, and Internet services.  
The IOR is a collaborative effort on the part of Lucent Technologies and Zhone Technologies. The hardware design  
is built from the Lucent model OR-HS, (Office Router, High-speed), and the Zhone Technologies model 821460  
dual port V.35. The model number of the IOR is 828060. The IOR is a single blade device in the form factor of the  
Zhone Technologies modules provides a fully featured IP (IPX) router card that operates in both Zhone  
Technologies IMACS and StreamLine chassis. The versions for the host software supporting the IOR are the  
StreamLine 1.1 and IMACS 3.8/5.1.  
The IOR is fully standards compliant. The card provides secure Internet access, firewall packet filtering, LAN-to-  
LAN connectivity, and management of the communications network.  
March 2001  
Page 63  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
To  
PSTN  
Channelized  
T1  
Voice  
IMACS  
X
To  
Frame  
Relay  
Ethernet  
Repeater/Switch  
Figure 20 - Bundled Voice and Internet Services  
Technical Specifications:  
Product Compatibility  
Routing Protocols  
IMACS 600, 800 or 900 Chassis Releases 3.8 or 5.1  
Routing Information Protocol (RIP), OSPF, Lucent Technologies ComOS,  
UDP, ICMP  
LAN Protocols  
WAN Protocols  
Data Rates  
TCP/IP, IPX  
Point to Point (PPP), Frame Relay (up to 14 PVCs supported, Inverse ARP  
From 56 Kbps to 1.544 (T1) or 2.048 Mbps (E1)  
1 Ethernet 10BaseT LAN, 1 – Asynchronous serial (115.2 Kbps), 1 NxDS0  
Frame Relay or PPP WAN, 1 RJ-45 Console Port  
Frame Relay or WAN Servers, PPP, Connection to WAN or ATM server  
Hardware Interfaces  
Server Connectivity  
Configuration and Management SNMP, Telnet, Out-of-band console remote management, Flash Upgrade  
capability  
March 2001  
Page 64  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
V. Alarm Cards  
The Model 840xxx Alarm Cards provide the capability to input external alarm signals to the IMACS and to output  
alarm signals from the IMACS to an external device. Depending on the model, from 3 to 28 alarms may be input  
and from 4 to 14 alarms can be output.  
The alarm input sensors are current loop detectors, with an operating range of 4 to 20 mA detection. Input sensors  
can be selected as active (they both supply and detect current and, therefore, can not be isolated and provide surge  
protection only) or passive (current sense only, completely isolated passive current detectors). When selected as  
passive sensors, the current source is provided externally and the sensors are Opto-isolated from the source of the  
alarm. If the sensors are configured as active, they can provide current source for the loop as well as current  
detectors, not isolated from the external loop. Depending on the model, power for active sensors can originate from  
network battery (usually +48 VDC) or system voltage (+12 VDC).  
Input alarm conditions are reported on the Active Alarm screens, and may be logged and/or reported in the same  
manner as other IMACS alarms. Alarm reporting can be in the form of an ASCII string or an SNMP trap,  
depending on the network configuration and host software options installed.  
Alarm signals are output via dual-pole, double throw relay switches. Depending on the model, these relays may be  
of Form A (normally open), Form B (normally closed), Form C (switched) or a combination of Form A, B and C  
contacts. All alarm outputs are relay-isolated. Power for these circuits must be provided externally.  
The alarm contacts are connected to the external alarm equipment through on or more (depending on model) 50-pin  
Amphenol connectors located on the front panel of the Alarm Card.  
The Alarm card model 840160 provides 4 input sensors and 4 output Form C closures. It can use either +48VDC or  
+12VDC to power the input sensors. If +12VDC is used, care must be exercised not to ground the circuit. The  
840160 card model also has a -12VDC strapping option that allows it to be used in either European (CE Mark)  
systems or in US systems.  
The Alarm card model 840260 provides 3 input sensors and 3 output Form C closures, one of which can only be  
used to signal power failure of the unit. It can use either +48VDC or +12VDC to power the input sensors. If  
+12VDC is used, care must be exercised not to ground the circuit. The 840260 card model also has a -12VDC  
strapping option that allows it to be used in either European (CE Mark) systems or in US systems.  
The Alarm card model 840360 provides 28 input sensors and 14 output closures (4 Form A, 2 Form B and 8 Form  
C). It can use either +48VDC or +12VDC to power the input sensors. If +12VDC is used, care must be exercised  
not to ground the circuit. The sensors are grouped into two groups of 14 each for the purpose of selecting current  
source, either from the network battery or the system. Within each group, an alarm sensor can be independently  
configured for active or passive operation. The 8403 also has a -12VDC strapping option that allows it to be used in  
either European (CE Mark) systems or in U.S. systems. Additionally, it also includes a buzzer to provide an audible  
alarm. The buzzer can be sounded locally. This capability allows a remote site to transmit an audible alarm. The  
840360 also provides a single FXS phone interface that provides a “Voice Order Wire” capability from a remote site  
and the voice channel can be transported being via a time slot to a central site. This connection is Loop Start only,  
with the “ring” signal being indicated through the buzzer, and is presented via an RJ-11 jack located on the front  
panel of the Alarm card. The buzzer and the phone must both be configured to use the same time slot, but only one  
of the functions can operate at any time.  
March 2001  
Page 65  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 20—Alarm Card Specifications  
Model 840160, 840260, 840360  
Physical Interface  
Female 50-pin RJ-27x Telco connector  
Electrical Interface  
4 to 20 mA Active Current Loop  
Alarm Input Modes  
Alarm Input Trigger  
Alarm Input Power Requirements  
Active/passive (jumper selectable per port)  
External circuit opening/closing (software selectable per port)  
Network batter (+48V DC) or system voltage (+12V DC). Needed  
only in Active Mode  
Alarm Input Power Source through  
jumper selection  
Selection applies to all ports in 840160 and 840260. Selection  
applies to a group of 14 sensors in 840360.  
Active/standby (software selectable per port)  
Major alarm/minor alarm/any alarm (software selectable per port)  
Supplied by external device  
Alarm Output Modes  
Alarm Output Trigger  
Alarm Output Power Source  
Alarm Output Action  
I/O Ports  
Open/close  
840160  
840260  
840360  
User-defined Input  
User-defined Output  
Automatic on power fail  
Model 8403 Buzzer  
Type  
4
3
28  
4 Form C  
0
4 Form C  
1
4 Form A, 2 Form B, 8 Form C  
1 Form C only  
Piezo buzzer  
Tones  
Modes  
3kHz internally generated or user supplied via the network  
Local or remote (software selectable)  
Model 840360 Telephone Port  
Physical Interface  
Type  
RJ11F  
FXS Loop Start  
Loop Resistance  
2400 Ohm  
Loop Current  
18 mA to 32 mA  
600 Ohm  
-10.0 dB to + 5.0 dB in steps of 0.1 dB  
-10.0 dB to +2.0 dB in steps of 0.1 dB  
µ-Law only  
Termination Impedance  
Nominal Transmit TLP  
Nominal Receive TLP  
PCM Coding  
Standards Compatibility  
UL 1950  
CEN 60 950/A2  
UL standard for safety of information technology equipment  
Safety of information technology equipment including electrical  
business equipment  
CEN 50082-1  
Electromagnetic compatibility generic immunity standard part 1  
for commercial, residential and light industry.  
VI. Server Cards  
1. ADPCM Voice Compression Server  
The 887160 ADPCM (Adaptive Differential Pulse Code Modulation) server card is designed to compress digital and  
analog voice traffic for transmission over wide area network links. The level of compression for an individual  
channel is software configurable at 24Kbps, 32Kbps or 40Kbps. This card requires a matching card at the other end  
to decompress the voice channels to normal 64 Kbps operation. A single ADPCM card is capable of compressing  
64 channels of voice simultaneously. Since the ADPCM card is a server card, these 64 channels can be originated  
from a variety of interfaces, including FXS, FXO, E&M, SRU, BRI, and T1/E1. In a 3.x platform, up to two  
ADPCM server cards can be supported per IMACS system for a total of 128 compressed voice channels. In a 5.x  
platform, 3 ADPCM cards could be used to carry a total of 192 voice channels.  
March 2001  
Page 66  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
The sum of the compression rates for the engine pair must equal 64Kbps. A 32Kbps circuit can only be paired with  
a 32Kbps circuit. A 40Kbps circuit can only be paired with a 24Kbps circuit and vice-versa. The ADPCM server  
card can also pair a low speed asynchronous data transmission (19.2Kbps or less) from an SRU port with a 40kbps  
engine. This data path will occupy a 24Kbps engine. Group II FAX is supported in 32Kbps channels and Group III  
FAX is supported in 40Kbps channels.  
Modem support up to 4.8Kbps, and V.32bis to 9.6Kbps is supported in 32Kbps channels. Modem speeds up to  
12Kbps, and V.32bis speeds up to 14.4Kbps is supported in 40Kbps channels. Modem data is not supported in  
24Kbps channels.  
The ADPCM card supports Transition Signaling as defined by ANSI T1.302-1989 with the exception of the Alarm  
bits. ANSI T1.302 specifies signaling at the 32Kbps compression rate. The ADPCM card uses this scheme for  
24Kbps and 40Kbps although it is not included in the standard.  
The ADPCM card can be used in a variety of applications to reduce the number of transmission lines for efficient  
transport of voice traffic. It can be used in:  
PBX-to-PBX trunk application  
Automatic Call Distribution application  
Efficient wireless base station/hub application  
PBX-to-PBX Trunk Application  
Figure 21a shows the IMACS with an ADPCM server is used to compress two T1 or E1 PBX-to-PBX trunks into a  
single trunk. The voice from each PBX is connected via a digital T1 or E1 connection to the IMACS. The voice  
channels are routed to the ADPCM server, where each voice channel is compressed to 32 Kbps. The compressed  
voice is routed to the outbound T1/E1 link to the other IMACS unit, where it is decompressed and placed back into  
two T1 or E1 trunks to the remote PBX. PBX-to-PBX trunk lines can be compressed 2:1 to reduce leased line  
charges. The application is also valid for analog PBXs and key systems.  
T1/E1  
T1/E1  
T1/E1 carrier  
Network  
IMACS  
IMACS  
PBX  
PBX  
Figure 21a - IMACS Using ADPCM for PBX to PBX Application  
March 2001  
Page 67  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Automatic Call Distribution Application  
The ADPCM server can be used to reduce leased line charges in automatic call distribution or remote call center  
applications by increasing the number of voice circuits supported on a single T1 or E1.  
The application shown in Figure 21b illustrates an ISDN-based automatic call distribution system. The IMACS is  
used to provision BRI remotely via BRITE (BRI Terminal Extension). With the IMACS, ten BRI circuits can be  
extended to remote locations over a single T1 line, and 13 over a single E1 line. The IMACS is able to do this by  
placing the 2B+D signal into 2.25 time slots (1 for each B, and .25 (16Kbps) for the D channel).  
The ADPCM server is used to increase the number of BRI circuits supported per T1 or E1 by compressing the B  
channels in voice only applications. This means that a 2B+D channel can be transported in 1.25 time slots (.5 for  
each B, and .25 for the D channel). Hence, 19 BRI circuits (38 voice channels) are transported over a single T1 and  
24 BRI circuits are transported (48 voice channels) over a single E1.  
ISDN or Automatic  
Call Distribution Switch  
BRI-U  
BRI-U  
IMACS  
IMACS  
Voice is compressed  
2:1 for efficient  
Voice Provisioning  
T1/E1  
Backbone  
network  
IMACS  
IMACS  
BRI-U  
BRI-ST  
. . . . . .  
NT1  
BRI-ST  
ISDN Terminals  
Agent Positions  
ISDN Terminals  
Agent Positions  
Figure 21b - IMACS In An ISDN-based ACD System  
March 2001  
Page 68  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Wireless Base Station Application  
In the application shown in Figure 22, the IMACS is used as a channel bank at each of the remote Base Stations. In  
each of the stations, the IMACS is connected via T1/E1 or Analog voice ports to the radio transmission equipment.  
The voice circuits that are destined for the switching center are sent to the ADPCM voice compression server at each  
base station. This compressed voice traffic is then groomed with other Base Station data traffic and transmitted over  
Fractional T1/E1 lines. An IMACS is used at a central location to groom the Fractional T1/E1 lines into two T1s or  
E1s. These two lines are connected to the Switching Center where an IMACS with two ADPCM servers is used to  
decompress the voice circuits and send them to the switch via four T1s or E1s.  
ADPCM Engines at Base Station/Hub/MSO  
Main Switching Office  
Base Station/Hub  
(MSO)  
Base Stations  
6 Fractional T1/E1s  
1
2
Data  
IMACS  
3
IMACS  
4
5
V.35  
E&M/FXS  
V.24  
Alarms  
E1/T1  
T1/E1  
IMACS  
Maint.  
Phone  
V.35  
E&M/FXS  
V.24  
Alarms  
Radio  
Equip.  
E1/T1  
MSO  
Aux.  
Equip  
Switch  
Maint.  
Phone  
Radio  
Equip.  
Cellular  
Packet Data  
Aux.  
Equip  
Cellular  
Packet Data  
Figure 22 - IMACS In A Wireless Base Station Application  
Base Station to MSO voice traffic can be compressed to efficiently backhaul traffic, which reduces line charges. An  
alternative to this application would be to transport the voice from the Base Station to the Hub uncompressed over  
the Fractional T1s and E1s and then perform the voice compression function in the IMACS at the hub. Table 21  
describes the ADPCM Server card specifications.  
March 2001  
Page 69  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 21—ADPCM Server Card Specifications  
Input Voice Channels  
Can originate from any 2-wire or 4-wire voice card or from a DSO on a WAN  
(El/T1 or HDSL) interface. µ-Law & A-Law 64Kbps PCM compatible on a per  
channel basis  
Input Sub-rate Data  
Input BRI traffic  
Modem Data Support  
SRU data traffic at 19.2Kbps or less can be carried on a 24Kbps sub-channel  
B channel voice traffic can be compressed at any of the configurable rates  
Transcoder rate: 24, 32 or 40 Kbps; Modem Data: none, up to 4.8Kbps, V.32  
to 9.6Kbps, up to 12Kbps and V.32 bis to 14.4Kbps  
Fax Support  
Transcoder rate for fax: 24, 32 or 40 Kbps; none, Group II and Group III fax  
Voice Quality  
As measured by Mean Opinion Score (MOS) analysis, a subjective  
evaluation with a range of 0 (poor quality) to 5 (good quality). Toll  
quality voice is accorded a MOS of 4.0 24Kbps transcoder rate MOS is  
3.6-3.8; 32Kbps transcoder rate MOS is 4.0-4.3 and 40Kbps transcoder  
rate MOS is 4.0-4.3  
Echo Cancellation  
Signaling  
Non provided—typically not required  
Transmitted in-band utilizing CAS transitional signaling, as per ANSI  
T1.302—1986 for 32Kbps and modified for use with 24Kbps and  
40Kbps. Note Robbed Bit Signaling Alarm Transmission, as specified  
in ANSI T1.302a-1989 is not supported  
Maximum Card Count  
Transcoder Operation  
Standards Compliance  
3 (with 3.x CPU-2 active with 1 redundant or 3 active, 5.x CPU 3active)  
Compliant to G.761 Alarm Indication and Fault Handling  
ANSI T1.3021989, ANSI T1.302a 1992, ANSI T1.3031989, CE EN  
500- 81-1, CE EN 500-82-1, CE EN 60950/A2, ITU-T G.721, ITU-T  
G.723, ITU-T G.726 12/90  
2. ISDN Primary Rate Interface (PRI) Server  
The PRI Server Card provides flexible access and routing of PRI-based ISDN services. The ISDN PRI Server can  
be used for enabling applications such as Video Conferencing, Video Broadcast, ISDN Grooming, and Fractional  
PRI provisioning. The PRI Server card supports B channel bandwidth of 56K, 64K, 384K, 1536K and Multi-Rate  
speeds where available. Multi-Rate speeds allow the PRI server card to select calls in increments of 64Kbps. In  
areas where Multi-Rate is not supported by the local ISDN switch, an Inverse Mux (IMUX) Server Card should be  
used to aggregate individual 64Kbps calls.  
The PRI card can be utilized with the 8213 Switched HSU Card for RS-366 and V.25bis bandwidth on demand  
dialing. Additionally, regular HSU cards can be used for DTR dialing. The PRI server card supports both the  
Network and User side protocols associated with ISDN PRI services and therefore the IMACS can be used to both  
originate and terminate ISDN calls.  
The following components make up the BRI/PRI solution:  
One 881160 Multi-Server Card  
One 65100 BRI/PRI Service Translation Software Package  
Optional WAN Interfaces with associated Line Interface Modules  
Optional ISDN ‘U’ and “S/T” Interfaces  
March 2001  
Page 70  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Three ISDN PRI Server Cards are supported:  
8840A ISDN PRI Server Card with 1 D Channel  
8840B ISDN PRI Server Card with 2 D Channels  
8840C ISDN PRI Server Card with 8 D Channels  
The cards provide flexible access to PRI-based ISDN services such as Switched 384, Switched T1, and Switched  
56/64. The PRI Server Card (PRI card) provides both local D channel origination and termination and D channel  
consolidation. The PRI Server card is available in three different software versions based on the number of D  
channels (1, 2, or 8) to be supported. It offers a perfect alternative to standalone ISDN access devices when other  
“non-ISDN” voice and data services must be consolidated in addition to ISDN services.  
The 8840B and 8840C ISDN cards can be simultaneously connected to several network and user side ISDN PRI  
facilities. The ISDN PRI card provides D channel support of both the network side protocol and the user side  
protocol. Typically, the IMACS with an ISDN PRI card, supplies the network side protocol on a D channel  
connected to a PBX, and provides the user side protocol on the D channel connected to a carrier switch.  
The 8840C ISDN PRI server card, which supports eight (8) D-channels can be configured to route calls from a PBX,  
multiple PBXs, and DTE devices to multiple ISDN service providers. The 8840x ISDN PRI Server does not support  
BRI-to-PRI translation. This application is supported by the 65100 ISDN BRI-PRI translation software running on  
an 8811xx ACS card.  
NFAS (Non-Facility Associated Signaling)  
All ISDN PRI cards can be configured to support NFAS (Non-Facility Associated Signaling). The IMACS limit for  
NFAS is 191B+D in T1 environments (8 times 24 minus 1 D channel) and 239 B+D in E1 environments (8 times 30  
time slots minus 1 D channel).  
A basic ISDN PRI facility is a T1 link that consists of 23 B channels and 1 D channel (23B+D), or an E1 link that  
consists of 30 B channels and 1 D channel (30B+D). Note that one time slot on any E1 link is reserved for framing  
and maintenance use, and is neither a B channel nor a D channel. The D channel provides signaling for all of the  
(23 or 30) B channels on the facility carrying that D channel.  
However, many ISDN applications have relatively low call rates (i.e., the D channel is not very busy), but need  
more than 23 (or 30) B channels to carry user (bearer) traffic. In these cases, a D channel can be set up to perform  
signaling not only for the B channels on its own facility, but also for B channels on other facilities (i.e., other T1/E1  
WAN links). When a D channel is so provisioned, it is considered to be performing non-facility associated  
signaling (NFAS). The IMACS is limited to 8 WAN links. Thus the IMACS limit for NFAS is 191B+D in T1  
environments (8 times 24 minus 1 D channel) and 239B+D in E1 environments (8 times 30 minus 1).  
Although IMACS supports NFAS, it can only be implemented within private networks or in public networks where  
the service provider supports it. Within EC and EFTA countries NFAS is considered an EC-MOU2 supplementary  
service, which is still at the discussion stage and therefore is not supported by any of the European Service  
Providers.  
Remote Login  
In addition to carrying ISDN signaling information, the D channel can also be used to log into a remote system unit  
to check card status, and perform necessary system maintenance. This unique application does not require B  
channel allocation. The ISDN call is placed on the D channel to the ISDN network and routed to the D channel of  
the remote unit. Coordination with the ISDN facility provider is necessary to obtain the number for the remote  
system unit.  
March 2001  
Page 71  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Applications  
The ISDN PRI Server card can be used in a variety of applications:  
Fractional ISDN PRI provisioning  
Video conferencing  
Integrated ISDN access with SINA  
Video Broadcast  
Router with redundant trunk routing via ISDN  
Router adding incremental bandwidth  
PRI to FXS  
Fractional PRI Provisioning  
An IMACS equipped with a 8840C PRI Server card is used to groom multiple fractional PRI circuits into one or  
more PRI circuits for backhaul to an ISDN switch. Perhaps a customer may not need the entire bandwidth delivered  
by a PRI circuit. The optimal alternative would be to purchase a fractional PRI service delivered over a regular T1  
or E1 circuit. When a service provider has multiple fractional PRI customers, the service provider can deploy the  
IMACS to groom the multiple fractional PRI circuits into one fully utilized PRI T1/E1 circuit, which is back hauled  
to the switch. This concentration of PRI circuits reduced back haul costs for the service provider, and conserves  
T1/E1 ports and D-channels on the ISDN switch itself.  
Figure 23 shows that three customers are subscribing to ISDN services. Each customer is using a fractional PRI  
service. Each customer could be directly connected to the ISDN switch, which would consume three fractional  
T1/E1 circuits, and three D channels. Instead, the 3 fractional ISDN circuits are connected to a PRI Server equipped  
IMACS. The PRI server grooms the B channels in the three fractional ISDN circuits into one circuit. It also grooms  
the three D-channel circuits into a single D channel that is routed to the switch. The IMACS benefits in this  
application include saving on back haul costs, switch port costs and switch system resources.  
Customer 1  
10B+D  
ISDN  
Switch  
23B+D on T1  
30B+D on E1  
Customer 2  
7B+D  
IMACS  
Customer 3  
5B+D  
Figure 23—Fractional PRI Provisioning Using IMACS  
ISDN Video Conferencing and Video Broadcast  
The IMACS is used to connect video-conferencing equipment to an ISDN PRI line. In Figure 24, a video CODEC  
is sharing a PRI line with an ISDN PBX. The IMACS is simultaneously routing calls on a call by call basis to either  
the PBX, the CODEC, or out to the network. The video-conferencing equipment can be connected via an RS-449  
connection with an RS-366 dialer or directly to the IMACS via an ISDN PRI interface. A connection to the  
IMACS via the RS-449/RS-366 combination would require the use of a switched HSU card in the IMACS.  
March 2001  
Page 72  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
PRI  
PRI  
ISDN  
Provider  
IMACS  
PBX  
CODEC  
Figure 24—Video Conferencing System and PBX Sharing A PRI Line  
By grooming the PBX and CODEC PRI circuits onto a single, outbound PRI facility, the IMACS utilizes Dynamic  
Bandwidth Allocation (DBA). The PBX would seize B-channels on a call-by-call basis, utilizing one B-channel for  
every call. The Video Codec would request a pre-determined number of B-channels. For example, if a 384K call  
was required, the Video CODEC requests a single 384K circuit, which would consume six of the B-channels. If the  
ISDN service supports 384K calls, or Multi-Rate services, and the bandwidth is available, the ISDN server card will  
connect the Video CODEC to proper time slots. If the bandwidth is not available, the IMACS rejects the call. If  
384K-bonded service is not supported by the ISDN service, the IMACS must be equipped with an Inverse  
Multiplexer (IMUX) server card. The IMUX server card is capable of bonding or aggregating multiple 64K circuits  
into a single larger capacity circuit.  
Inbound calls would be handled in a similar manner. All inbound calls would be screened by the IMACS’ PRI  
Server card. Calls destined for the PBX would be routed to the PBX, and calls destined for the Video Conference  
Unit would be routed there. If the video Codec was in use, the IMACS will inform the ISDN service that the unit  
was in a busy condition.  
A unique feature of the PRI Server card is its ability to combine multiple ISDN circuits to form a Video Broadcast.  
This feature is very useful for distance learning applications where a central site broadcasts video to multiple remote  
locations. In this application, an IMACS equipped with a PRI server card takes a video source and makes a two-  
way connection with the first remote IMACS video-conference site as shown in Figure 25. Once that connection is  
established, the host IMACS calls up to a total of 32 additional remote video-conference sites and distributes the  
same outbound video feed to all of those sites. These additional sites are in a view-only mode and do not distribute  
video back to the central site. The loss of one or more of the remote sites will not affect the broadcast to the other  
sites. This application can be upgraded to allow two-way audio to each of the sites though the use of analog voice  
cards.  
March 2001  
Page 73  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
T1/E1  
IMACS  
IMACS  
T1/E1  
Backbone  
network  
Video  
Video  
IMACS  
Video  
IMACS  
Video  
Figure 25—IMACS in Video Broadcast Applications  
Integrated ISDN Access with SINA  
The IMACS is used to support both ISDN and non-ISDN services over the same T1/E1 circuit. This multiplexing of  
leased line and ISDN services is commonly referred to as Static Integrated Network Access (SINA).  
As shown in Figure 26, several non-ISDN applications are used including analog voice and data applications, low  
speed SNA data, and non-ISDN PBXs. Several ISDN based applications are being used including video-  
conferencing, dial routers, and an ISDN PBX. The non-ISDN circuits are groomed onto the T1/E1 circuit for  
delivery to the network. ISDN applications are sent to the PRI Server card for concentration and are switched onto  
the same T1/E1 circuit in time slots appropriate for switched ISDN calls. Within the network, these circuits are  
groomed via a cross-connect to the appropriate services.  
Phone  
Non-ISDN  
Services  
PRI  
SINA  
PBX  
IMACS  
ISDN  
Services  
PBX  
Video  
Router  
March 2001  
Page 74  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Figure 26—IMACS Using SINA for ISDN and Leased Line Traffic  
Data Backup and Bandwidth on Demand  
The IMACS with a PRI server is used to back up data networks in the event of a circuit outage. In the example  
shown in Figure 27, an IMACS is used to connect a router to a leased line circuit. The PBX is using the IMACS  
equipped with a PRI server card to connect to the PRI circuit. In normal operation, both the voice traffic and the  
data traffic simply pass through the IMACS. In the event that the leased line circuit is dropped the router will sense  
the loss of data and attempt to dial bandwidth via its second line. This second port can be configured on the IMACS  
to accept dial commands using the V.25bis, or to dial a pre-determined number when the IMACS senses DTR.  
When the router senses that a failure has occurred, it will request bandwidth from the IMACS. If the PRI does not  
have enough bandwidth to satisfy the router’s request, the IMACS rejects the call. The router will then request  
another call with smaller bandwidth requirements and will monitor the original leased line for presence of data.  
When the router detects that the leased line is back in operation, it will switch its transmission path back to its  
original state, and drop the ISDN connection.  
This configuration is utilized to provide bandwidth-on-demand during peak utilization times such as nightly  
backups. With this application, the PBX utilizes the PRI bandwidth on a call-by-call basis during the day, and the  
router utilizes the leased line. At a pre-determined time-of-day, the router would request all or the majority of the  
PRI bandwidth. The router utilizes both the leased circuit and the ISDN circuit for a set period of time. For  
example, the PRI line would be used during the day to carry the voice calls, at night the PRI line would be used to  
increase the bandwidth available for the nightly computer systems backup. The router routes packets over both the  
leased line and the PRI line until the backup was complete. At that time, it would disconnect the PRI call.  
T1/E1  
T1/E1  
PRI  
PRI  
T1/E1  
Backbone  
network  
IMACS  
IMACS  
PBX  
PBX  
V.25bis/DTR  
Dialing  
V.25bis/DTR  
Dialing  
PRI  
Router  
Router  
ISDN  
Network  
Figure 27—IMACS Using A PRI Server Card For Data Backup  
March 2001  
Page 75  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
PRI to FXS Termination  
The IMACS is used to connect calls to an analog modem rack as shown in Figure 28. This application is usually  
used to terminate a mix of ISDN originated calls and analog modem originated calls to the same destination. This is  
common in remote access applications where there is a need to support both existing analog modem applications and  
new digital ISDN connections over the same network facility. End users can migrate as needed from analog  
modems to ISDN, sharing the same facility, and maximizing utilization of network bandwidth. The IMACS  
receives all calls, examines the called number and routes the analog modem calls to the FXS hunt group. ISDN data  
calls are routed directly to the ISDN remote access server. This application only works for inbound calls since the  
modems in the rack cannot be used to dial out through the IMACS over ISDN.  
March 2001  
Page 76  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Modem Rack  
Mail  
Server  
FXS  
PRI  
ISDN  
Network  
IMACS  
LAN  
PRI  
PSTN  
Modem  
ISDN Remote  
Access Server  
Figure 28—PRI to FXS Termination  
Routing Capabilities  
Call Routing  
An IMACS system can be simultaneously connected to several Network and User side ISDN PRI facilities and to a  
user’s data terminal equipment such as a video codec or LAN router. DTE is usually connected to the system’s  
HSU cards.  
Any call originating from a HSU port (with the exception of the Switched HSU card), must be associated with a call  
profile. The call profile specifies which D channel is to carry the call. Any device attached to an HSU port that is  
able to receive incoming calls is assigned a unique number that allows the system to route the incoming call to it.  
Optionally, a shared hunt group phone number can be assigned to the same HSU port.  
When an incoming call is received by the system, it first scans all of the primary HSU or FXS phone numbers to  
attempt a match. If no match is found, the system then searches the list of hunt group numbers to find a match. If a  
match is not found, the system will begin searching the D channel routing tables, for routing of the call to a PRI line.  
If no matches are found, the call is rejected.  
Local Routing  
From an IMACS perspective, devices such as video codecs or PBXs that are directly attached to the system (i.e. do  
not pass through a carrier network to connect to the system) are considered “local” devices. All HSU ports are local  
devices. Any PRI device, such as a PBX, that is connected to an IMACS D channel configured for “Network” side  
is a local device. Local routing is defined as call routing between any two devices. Calls can be locally routed from  
a PRI to a PRI (for example, from a local PBX to another local PBX), or from an HSU to a PRI. HSU to HSU call  
routing is not supported.  
Incoming calls are routed based on the called phone number, not on call profiles. Because the IMACS system does  
not provide billing information, users may want to prohibit local routing of D-channels. For example, a carrier may  
require that all calls are routed through the CO based switch for billing purposes. To provide for this, local routing  
can be disabled.  
If local routing is disabled, any call coming into the system on a network side (i.e. local) D channel will be routed  
only to a user side D channel based on the called number. Even if the called number matches, such a call will never  
be routed to an HSU port or a network side D channel when local routing is disabled. When local routing is  
enabled, then any call coming in on a D channel will be routed to the first matching phone number, regardless of  
whether or not the match is for a local device.  
March 2001  
Page 77  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Bi-directional Default Routing  
Bi-directional Default Routing is provided for automatic routing when a node is configured with two Primary Rate  
D channels as shown in Figure 29. In two channel systems, the user does not have to configure any routing  
information, as all calls received on one D channel are automatically routed to the second D channel. The user only  
needs to enter routing information for those calls destined to a local HSU or FXS ports.  
HSU/FXS  
ISDN  
Switch  
D ch 1  
D ch 2  
IMACS  
PBX  
Default  
Figure 29—Bi-Directional Default Routing  
Alternate Routing  
Alternate routing is provided for calls to take an alternate path in the event of a congested or failed primary trunk.  
When there are more than two Primary Rate D channels, phone numbers can be assigned to more than one D  
channel. Calls placed or routed through the PRI server will now have an alternate route if no bandwidth is available  
on the first specified path. Alternate routing will also take place in the event of a failure of the first Primary Rate  
circuit. In the example shown in Figure 30, the call from D1 is usually routed to D2, as the D channel numbering is  
more specific. However, if the D2 trunk become congested or go out of service, the call will be routed to D3.  
ISDN  
Switch  
415-6xxx  
D2  
Dial 415 - 6xxx  
IMACS  
D1  
ISDN  
Switch  
D3  
PBX  
415-xxxx  
Figure 30—Alternate Routing  
March 2001  
Page 78  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
DPNSS Trunk Routing  
Digital Private Network Signaling System #1 (DPNSS) is the predominant Common Channel Signaling scheme  
used in the United Kingdom for private inter PABX communications. DPNSS Trunk Routing provides low delay  
for multi DPNSS channel provisioning off a single E1 DPNSS aggregate. This is achieved by mapping the B  
channels to dedicated time slots rather than to hunt groups, which in turn provides efficient D channel grooming and  
subsequent billing.  
3. Management Channel Concentrator (MCC) Server  
The Management Communications Concentrator (MCC) provides management connectivity to remote IMACS  
systems. It can concentrate the TCP/IP management traffic from up to 131 remote IMACS networks onto either a  
single, local 10 BASE-T Ethernet port, or encapsulate the information as per RFC1490 on to a Frame Relay link.  
There can be up to 3 MCC server cards in an IMACS chassis in non-redundant operation. The following hardware  
and firmware must be included in an IMACS to add MCC Server operation:  
880360- CPU Control Card with 8 T1/E1 Cross Connect (redundant-capable)  
892260/892360/892460 - 8 T1/E1 Interface card w/ 128K NVRAM.  
881360 - Advanced Communication Server (ACS) with 131 logical ports  
60511 - Host Firmware version 5.0.x  
63110 - MCC Server firmware  
The following protocols are supported by the MCC:  
Ethernet Media Access Control Protocol (MAC)  
Address Resolution Protocol (ARP) (RFC 1122)  
Internet Protocol, version 4. (IP) (RFC 791, RFC950, RFC 1122)  
Internet Control Message Protocol (ICMP) RFC 792  
User Datagram Protocol (UDP) RFC 768  
Routing Information Protocol (RIP) (RFC1812)  
Frame Relay (RFC1490)  
The MCC provides routing between the bxr formatted ports and Ethernet, allowing IP management data of remote  
IMACS’ to be terminated onto a local area network. The MCC can route between any of its interfaces depending on  
its configuration. In addition to the B7R protocol used for T1, and B4R used for E1, a full DS0 is also provided on  
all ports. B7R and full DS0 cannot be combined unless configured in groups of 64.  
The MCC offers far more interfaces and functionality than the BnR, thus replacing it and the terminal server  
required to bring the IP traffic to a LAN. The MCC can be configured to use unnumbered or numbered interfaces.  
If unnumbered interfaces are used, MCC is accessed through the global Ethernet address regardless of what interface  
is used. If numbered interfaces are used, each interface has a local IP address. When unnumbered interfaces are  
selected, the IP address entered on the port is the IP address of the remote device. Similarly, when numbered  
interfaces are used, the IP address entered for any given numbered port is the IP address of the local port itself.  
Unnumbered interfaces help conserving IP addresses as only one address is used per interface. This addressing  
method may not be compatible with HP Openview.  
The MCC routes IP datagrams between all of its interfaces, based on each datagram’s IP destination address.  
Datagrams are directed (or routed) to the interface carrying the sub-net to which the datagram belongs or is being  
transported to, according to the content of the routing table. The routing table may be supplied with dynamic routes  
from the Routing Information Protocol (RIP) when enabled. If no match is found in the routing table, a default route  
can be designated to direct all unresolved datagrams to a specific interface.  
Initial configuration of the MCC can made through the local VT100 port. When a working interface is established  
to the CPU hosting the MCC, subsequent configurations can be done remotely via SNMP/TELNET. All  
March 2001  
Page 79  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
configurable port parameters are permanently stored in NVRAM and downloaded to the card during startup.  
Statistics are available on a per port and protocol basis.  
IP-based management information from IMACS clients is typically provided to the MCC by a Digital Access and  
Cross-connect System (DACS) as Bit Seven Redundant (B7R) or Bit Four Redundant (B4R) DS0 channels on a T1  
or E1 link. The MCC routes IP packets among the 131 available WAN interfaces, the local host CPU and Ethernet.  
Each interface represents a separate network or subnet as specified by the IP address and Netmask combination.  
Three of the 131 are high-speed interfaces that can either be configured as Nx64 kbps (N=1 to 24 for T1 or 1 to 31  
for E1). Those interfaces can independently be configured for the Frame Relay protocol or for transparent HDLC.  
The 128 lower-speed WAN interfaces can be configured in groups of 64, to either be in BnR mode.  
Figure 31 shows FDL channels from the remote IMACS a, b, c, and fed into a DACS II for translation into multiple  
B7R encoded DS0 channels. IMACS I, connected to the DACS II, routes IP datagrams to IMACS II through the  
alternative high-speed interfaces. IMACS II in turn routes datagrams to the Local Ethernet to the NMS.  
Remote IMACS using FDL  
DACS  
IMACS  
IMACS  
1 Nx64 Kbps T1/E1  
IMACS  
IMACS  
w/MCC  
2 Nx64 Kbps T1/E1  
Nx 64Kbps T1/E1  
B7R formatted DS0's from DACS II  
IMACS  
w/MCC  
NMS  
Figure 31—MCC In A Multilevel Concentration Application  
March 2001  
Page 80  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
4. ACS-FRS Advanced Communication Server - Frame Relay Server  
The 881160 FRS card concentrates multiple N x 56K or N x 64K frame relay data streams onto one or more  
Nx56/64K links of the IMACS. In addition to frame relay concentration, the card encapsulates data for Nx56/64K  
HDLC or SDLC data streams. RED frames can be discarded rather than forwarded to the FRS end-point screen.  
The ACS-FRS uses flag sharing, meaning that the closing flag of one frame will be the opening flag of the following  
frame.  
The frame relay server software (v1.8) runs on the card, which provides up to 68 logical ports. Up to 128 permanent  
virtual circuits (PVCs) can be configured on a single card. The aggregate speeds of all ports associated with each  
FRS cannot exceed 8 Mbps.  
The FRS has a maximum of 68 ports. When all four “C” ports are used to interface to other cards such as the HSU,  
64 ports are left to interface to the external cross-connect.  
The FRS card also maintains detailed performance statistics both on a per port and a per PVC level.  
Frame Relay Server Specifications  
There can be up to three Frame Relay server cards in an IMACS chassis in non-redundant operation. The Frame  
Relay Server performance figure of 4000 Frames/Second was obtained using 64 byte frames. The following  
hardware and firmware must be included in an IMACS to add Frame Relay Server operation:  
880360- CPU Control Card with 8 T1/E1 Cross Connect (redundant-capable)  
892360/892460 - 8 T1/E1 Interface card w/ 128K NVRAM  
881160 - Advanced Communication Server (ACS) with 68 logical Frame Relay ports  
60500 - Host Firmware version 5.0.0 or above  
62180 - ACS Frame Relay Server firmware  
Table 22—Frame Relay Server Specifications  
Input/Output Ports  
Input Traffic Ports  
Output Traffic ports  
68 logical ports (maximum)  
T1, E1, fT1, fE1, V.35, RS422, EIA530, OCU-DP, FRAD  
T1, E1, fT1, fE1, V.35, RS422, EIA530, OCU-DP, FRAD  
Output Port types/Input UNI DCE, UNI DTE, NNI, Nx64K/56K FRAD  
Maximum Frame Size  
Traffic Bandwidth  
Performance  
Number of PVCs  
System Capacity  
Management  
4K Bytes  
8 Mbps, Full Duplex  
4,000 Frames per second (maximum)  
128  
Maximum 3 per IMACS  
RFC1315, DTE MIB, Frame Relay Service MIB, SNMP Alarm Traps per RFC 1215  
Craft Interface, SNMP or TELNET  
Connectivity  
LMI Options  
Q.933 Annex A, ANSI T1.617 Annex D, LMI (Gang of 4), None  
CIR = 0 to 2048 Kbps, Bc = 0 to 2048 Kb, Be = 0 to 2048 Kb  
FECN, BECN  
Information Rates  
Congestion Handling  
Circuit Priorities  
4 (Version 2.0 or above)  
March 2001  
Page 81  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Frame Relay Access and Concentration Server  
This section highlights the capabilities of the IMACS Frame Relay server card as a cost-effective, efficient, and  
intelligent high-speed Frame Relay Assembly and Disassembly (FRAD) device and access concentrator in a Frame  
Relay network. This enables the service provider to deliver Frame Relay and Internet services with a high degree of  
quality in an economical fashion. The following is a list of the Zhone Technologies Frame Relay server card key  
benefits:  
Highly efficient assembly, disassembly and concentration of Frame Relay traffic allows for significant Frame Relay  
switch port savings.  
High Frame Relay port density offers significant hardware savings when compared to typical backbone switches  
making it suitable for deployment at the customer premises. Bringing the frame relay network features closer to the  
end-user and CO reduces backhaul charges due to efficient use of the frame relay backbone switch port.  
100% compliance with industry Frame Relay standards enables ready interoperability in multi-vendor networks.  
Support for existing UNI (User to Network Interface) and NNI (Network to Network Interface) standards implies  
that the frame relay server easily integrates into existing, standards-compliant frame relay infrastructure of the  
service provider.  
-
Manageability via SNMP and TELNET eliminates need for separate network management package and  
offers comprehensive diagnostics for both physical and logical network.  
-
Complete Support for physical layer diagnostics. In addition, it provides network access for a wide range of  
devices ranging from high-speed data interfaces (HSU), DDS interfaces (OCU-DP, DS0-DP), IDSL interfaces  
(BRI), and sub-rate data (FRAD).  
-
Comprehensive, standards-based congestion management techniques.  
Standards based congestion management ensure interoperability with existing infrastructure and enables the service  
provider to offer better, more cost-effective Frame Relay services to its subscribers.  
The Frame Relay Server can be deployed in the following application scenarios to provide a very cost-efficient and  
high-quality Frame Relay access to the end-users:  
Frame relay switch port savings  
Frame relay and Internet service provisioning  
IDSL service provisioning  
Grooming and concentration in cellular networks  
Central Office FRAD  
Frame relay concentration at hub sites  
Frame Relay Switch Port Savings  
Figure 32 shows an IMACS equipped with one or more Frame Relay server cards that is utilized at the service  
provider’s Central Office to efficiently concentrate multiple lower speed Frame Relay circuits into a consolidated  
Frame Relay stream into the backbone Frame Relay switch. This results in significant savings in port occupancy on  
the Frame Relay switch. It is amplified by the fact that these channelized ports on the backbone switches are much  
more expensive than their unchannnelized counterparts.  
The presence of 68 highly-integrated channelized Frame Relay ports combined with the statistical multiplexing  
advantages of Frame Relay facilitate the savings by reducing the backbone switch port occupancy by over 2.5 times  
(67 DS0 circuits instead of 24 DS0 circuits on a single channelized T1 trunk). In a typical case this reduces circuit  
cost per DS0 by 20%.  
March 2001  
Page 82  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Without Frame Relay Server:  
DACS  
Channelized Frame Relay  
circuits with smaller CIRs  
Frame Relay  
Network  
With Frame Relay Server:  
Channelized Frame Relay  
circuits with smaller CIRs  
DACS  
Concentrated Frame  
Relay Stream on T1/E1  
Frame Relay  
Network  
IMACS  
Figure 32—IMACS Using Frame Relay Server Cards  
Frame Relay and Internet Service Provisioning  
The inherent flexibility of the IMACS platform and the versatility of the Frame Relay server are brought into  
synergy to provide significant savings to both the service provider and user. An IMACS is used as a CLE  
(Customer Located Equipment) to provide a wide-variety of voice and data services to a multi-tenant premise. The  
service provider can now add Internet services and native Frame Relay services by simply installing a Frame Relay  
server in the existing IMACS as shown in Figure 33. There is no significant addition of new hardware or replacing  
of existing platform or complicated provisioning schemes. The Frame Relay Server also provides a PVC backup  
feature, which the service provider can offer as a premium, uninterrupted service to a customer in case the primary  
link fails.  
The cost benefits are realized by the service provider as a result of:  
The high density of logical Nx56/64K ports on the Frame relay server enables very efficient grooming and  
concentration of Nx56/64K Frame Relay connections to the service provider access links.  
Savings in capital expenditure due to minimal hardware upgrades and ease of provisioning. In addition, the  
remote management capabilities of the IMACS and Frame Relay server improve the quality of service delivered  
thereby lowering costs.  
March 2001  
Page 83  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Multi-tenant Premises  
Service Provider  
Central Office  
X.25 PAD  
Nx56/64  
PSTN  
PBX/Key  
System  
DACS  
DS1/E1  
IMACS  
Backup Link  
Mainframe  
Frame Relay  
Network  
Router  
Nx56/64 or T1/E1  
Figure 33—Frame Relay and Internet Services Using IMACS’ FRAD Server  
IDSL Service Provisioning  
An IMACS with a Frame Relay server can be used for efficient ISDN DSL (IDSL) provisioning for Internet access  
at speeds up to 128K. Each IMACS BRI card provides up to eight IDSL ports over single twisted pair wire. There  
can be up to seven such BRI cards in an IMACS800/900. This arrangement cost-effectively replaces external DDS  
CSU/DSU equipment and offers higher bandwidth.  
Each Frame Relay server supports up to 35 NTUs at 128K over 1 T1 (with 3:1 concentration) or 1 E1 (with 2.5:1  
concentration), thereby taking advantage of frame relay’s statistical multiplexing capabilities. Up to 64 DS0s are  
channelized through the Frame Relay Server ports and are concentrated onto a single port connected to the network.  
Three concentrator ports bring in additional NXDS0s channels to be concentrated onto the single outgoing port as  
shown in Figure 34.  
March 2001  
Page 84  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
2B1Q  
NTU  
BRI Cards provide 2B1Q IDSL termination  
FRS provides IDSL concentration  
Router  
64/128Kbps  
Frame Relay  
Frame Relay  
Network  
Ethernet  
T1/E1  
2B1Q  
IMACS  
NTU  
64/128Kbps  
Frame Relay  
Router  
Ethernet  
64/128Kbps  
Frame Relay  
Support data rates up to 128 kbps over single twisted  
pair over 5Km  
2B1Q  
NTU  
Router  
DDS CSU / DSU replacement with BRI-NTU scenarios.  
Ethernet  
Figure 34—IDSL Service Provisioning  
Grooming and Concentration in Cellular Networks  
Figure 35 shows how a remote cell site uses an IMACS, trademarked “CellDAX” for all cellular environments, to  
transport cellular voice and data traffic to the Mobile Switch Center (MSC). At the MSC, a DCS directs the CDPD  
traffic (typically, a single DS0) from each of the 96 cell sites to the IMACS at same MCS. Because CDPD uses  
HDLC framing the traffic from the 96 DS0s can be encapsulated by the two Frame Relay server cards located in the  
IMACS. Each Frame Relay server can take in 64 DS0s directly into ports. Typically the CDPD traffic is bursty and  
often less than one full DS0 and so can be groomed and concentrated by the Frame Relay server down to 48 or 24  
DS0s depending upon the level of concentration needed. This results in a net savings of two or three T1/E1 spans  
across the regional MSCs respectively. The MD-IS (Mobile Data Intermediate System) then processes the traffic  
and routes it to the appropriate destinations.  
March 2001  
Page 85  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Mobile Switch Office  
T1  
56/64Kbps  
CellDAX  
4 Channelized  
DS1s = 96 DS0s  
DS1  
IMACS  
Mobile  
T1  
Base Station  
2 Frame Relay DS1s  
Cell  
Site  
# 96  
IMACS  
Frame Switch  
MDIS  
Figure 35—Cellular Network Frame Relay Application  
Frame Relay Concentration at Hub Sites  
In the application shown in Figure 36, a corporation, which serves a wide geographical area through multiple branch  
offices, is able to utilize the Frame Relay server’s ability to consolidate and multiplex multiple NX56/64K circuits  
into a single high-speed facility. This significantly reduces its access charges from its service provider for its  
corporate Frame Relay network. Typical examples include banks, health care providers, technology parks, etc.  
The branch offices typically subscribe to a Frame Relay service with a Committed Information Rate (CIR) of  
56/64K. At the Head Office/Data Center the traffic is typically from a “farm” of front-end processors, routers and  
servers. Without an IMACS+FRS at the Head Office/Data Center, multiple circuits would occupy multiple ports in  
the service provider’s switch and would be tariffed for lower individual speeds. With an IMACS+FRS, the multiple  
lower speed circuits are consolidated and groomed into a single/few high-speed (Nx64K) circuit. Since the marginal  
access charge of Frame Relay is lower at higher speeds, due to economies of scale, this could reduce costs.  
March 2001  
Page 86  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
BRANCH OFFICES  
56/64K  
HEAD OFFICE DATA CENTER  
Router  
T1 Frame  
Relay  
FEP  
56/64K  
56/64K  
Frame Relay  
Network  
FEP  
Data Proc  
Application  
FRAD  
IMACS  
FRAD  
Figure 36—Frame Relay Concentration at Corporate Headquarters  
5. ATM SERVER CARD  
Although ATM is being touted as an ubiquitous technology for all business communications services, the reality is  
that it is playing a significant role so far only in backbone campus network for LAN applications for local transport.  
This section highlights the benefits of the various applications of the IMACS 882060 ATM Server card and  
demonstrates how it can effectively and efficiently to deploy various services. The ATM Server Card provides the  
ability to provision legacy voice, data, and video services over an ATM backbone via a DS3, multi-mode and single-  
mode.  
The ATM Server card includes support for efficient, standards-based ATM adaptation of a multitude of legacy  
traffic types. Examples include analog key systems, routers, video codecs and PBXs. Legacy traffic is directed from  
T1, E1, data and voice interfaces to the ATM Server, which then provide ATM adaptation and encapsulation. By  
providing direct, integrated connectivity to the ATM network, the IMACS eliminates the need to run parallel  
networks for ATM and TDM traffic. The ATM Server Card is based on standards adopted by the ATM Forum and  
the ITU. These standards allow the IMACS ATM Server to inter-operate with a wide variety of ATM switches and  
to adapt multiple traffic types for aggregation and transmission across an ATM network. Some of the well-known  
switches include those from FORE, Lucent, NORTEL, GDC, ADC Kentrox.  
Since the ATM Server Card fits in any IMACS server slot, service providers can deploy the IMACS in non-ATM  
access networks today, and easily migrate to ATM based access by simply adding an ATM Server Card. The ATM  
Server Card, combined with the wide range of interfaces on the IMACS, provides the most flexible platform for  
service provisioning in the market today.  
The following is a list of the ATM server card key benefits:  
Standards-based ATM adaptation for voice, video, and data. This feature enables the IMACS to adapt the  
traffic from a wide variety of legacy interfaces to ATM. Therefore there is no need to upgrade or replace  
existing equipment while migrating to ATM solutions. This results in significant savings in capital expenditure.  
Interoperable with deployed ATM switching equipment such as ADC Kentrox, Fore Systems, Lucent, etc. This  
is a key selling point of the ATM server. Because of its interoperability with already deployed ATM switching  
March 2001  
Page 87  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
equipment, it can be easily added with minimal costs when the MIS manager wants to collapse parallel ATM  
and TDM networks into a single ATM network. When an ATM network is installed, typically there is excess  
bandwidth and port capacity that behooves such a merger of networks. For instance, when an ATM switch is  
deployed each line card will have multiple ATM ports out of which only one or two may be used for data  
traffic. The IMACS w/ ATM server can be connected to the unused port(s) thereby consolidating other legacy  
traffic on to the ATM network. This results in significant cost savings for the customer since there is only one  
as opposed to two networks to be managed.  
Provides DSO granularity for virtual circuit input. By providing DS0 granularity, the ATM server is able to  
direct individual lower speed voice and data circuits to unique destinations through out the ATM network. This  
is accomplished without “burning up” multiple physical ports on the ATM switches, which are expensive. The  
ATM server’s highly efficient and cost-effective aggregation of lower speed CBR and VBR virtual circuits  
makes this possible.  
Supports constant and variable bit rate adaptation. By supporting constant and variable bit rate services, the  
ATM server tailors the adaptation to best suit application requirements for quality of service (QoS). E.g.,  
typically voice and video applications require constant guaranteed bandwidth and stringent delay constraint and  
are modeled as CBR traffic. Data, compressed voice and compressed video are amenable to variations in  
bandwidth and delay requirements and are modeled as VBR traffic.  
Manageability via SNMP and TELNET. SNMP and TELNET manageability eliminates need for a separate  
IMACS network management package. The IMACS and its components can be managed from the same  
existing network management device that manages the ATM backbone and other devices.  
The ATM server is deployed in the following application scenarios to provide a very cost-efficient and high-quality  
ATM service to the end-users:  
Interactive Distance Learning/Tele-Medicine  
Legacy Adaptation to ATM  
Analog PBXs/Key Systems  
Digital PBXs  
Nx56K/64K Data terminal equipment  
Video Codecs  
Transparent LAN Extension  
Legacy Adaptation to ATM  
The addition of the ATM Server card further extends the capabilities of the IMACS as a truly integrated access  
platform by efficiently provisioning a multitude of legacy services for transportation over an ATM network as  
shown in Figure 37.  
There are still many legacy services (PBXs, key systems, video codecs etc.) which need a parallel TDM network to  
operate since they are not “ATM-ready.” Two parallel networks drive up the cost of installation, operation and  
maintenance. Since businesses have very significant capital investment in these legacy systems and processes they  
cannot justifiably be fork lifted and replaced by equivalent “ATM-ready” equipment. Furthermore, when a new  
ATM campus network is deployed, typically there is excess bandwidth and port capacity that is under utilized.  
What needs to be added is a cost-effective product for adaptation of all these legacy services to ATM. This would  
enable connecting a multitude of “non-ATM ready” equipment to the ATM network.  
March 2001  
Page 88  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
ATM  
Network  
DS3/OC3c/STM1  
IMACS  
ATM Edge Switch  
Router  
Figure 37—Migrating Legacy Networks to ATM  
Interactive Distance Learning/Tele-Medicine  
The IMACS’ integrated multi-service capabilities supports interactive distance learning applications where the  
central site and the major educational centers are connected through an ATM network and the remote sites are  
accessed via leased T1/E1 lines.  
The video stream (TDM traffic) from the central site is adapted to ATM by the ATM server and multi-cast to the  
sites on the ATM network as shown in Figure 38. The ATM servers located at the Major University locations  
convert the video from ATM to TDM traffic and pass it on to remote sites over leased T1/E1. The IMACS’ ISDN  
PRI server is utilized in conjunction to connect the remote sites to the video-conferencing network over T1/E1  
leased lines. The entire network is managed from a central network management system.  
The same network structure is deployed effectively in a Tele Medicine application in which doctors from central  
medical centers can exchange patient information, X-rays etc. with remote hospitals and provide remote diagnosis.  
March 2001  
Page 89  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
RS36  
V.2  
Video Conf  
System  
Network Management System  
IMACS  
DS3 ATM  
Major University  
T1/E1 Leased Line  
IMACS  
OC3c/STM1  
RS36  
V.2  
Video Conf  
System  
DS3 ATM  
IMACS  
Remote Campus  
OC3c/STM1  
Central Site  
PRI  
PRI  
T1/E1 Leased Line  
RS36  
V.2  
Video Conf  
MCU  
Video Conf  
System  
IMACS  
Major University  
Remote Campus  
DS3 ATM  
IMACS  
RS36  
Video Conf  
V.2  
System  
Figure 38—Interactive Distance Learning Application  
ATM Server Specifications  
Up to three ATM server cards can be functional in an IMACS in a non-redundant configuration. The ATM Server  
card performance figure of 4000 Frames/Second was obtained using 64 byte frames. Table 23 depicts the ATM  
Server card specifications. The following hardware and firmware must be included in an IMACS to add ATM  
Server operation:  
880360- CPU Control Card with 8 T1/E1 Cross Connect (redundant-capable)  
892360/892460 - 8 T1/E1 Interface card w/ 128K NVRAM  
882060- ATM Server card with 1 DS3 ATM UNI port  
60511 - Host Firmware version 5.1.1  
March 2001  
Page 90  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 23—ATM Server Card Specifications  
ATM I/F  
1 DS3 Private UNI 3.1  
Framing  
Cell Delineation  
Clocking  
VPI Support  
VCI Support  
Idle Cell  
TX_RX Scrambling  
Traffic Types  
AALs  
Cbit, M23 for DS3  
HCS (+ PLCP for DS3)  
Line (+PLCP for DS3)  
One configurable VPI bit  
33 - 1023 (configurable) values  
Idle or Unassigned  
ON/OFF  
CBR, VBR  
AAL1, AAL3/4, AAL5  
Number of PVCs  
Performance  
System Capacity  
Management  
Connectivity  
68 VBR, 96 CBR (with multi-user support)  
4,000 FPS @ 64bits/frame  
Maximum 3 per IMACS (1 active)  
DS3 MIB, UNI3.1 ILMI MIB, ATM MIB  
SNMP or TELNET; Access via up to seven (7) Management  
PVCs  
Standards  
ATM Forum UNI3.0, ITU-T I.363, ITU-T G.709,  
BellCore TR-NWT-000253, ATM Forum Circuit-Emulation  
Services over DS1/E1, ATM Forum Service Interoperability  
March 2001  
Page 91  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
6. Internet Protocol Router  
Internet Protocol Router: 883060 (10Base2) and 883160 (10BaseT)  
Introduction:  
IPR is an IP router server card that runs on the ACS hardware. It therefore must be inserted in one of the P slots of  
the Zhone Technologies IMACS concentrator. IPR uses 68360 communication controller and has 4 MB of DRAM.  
To use the IPR card, one must use host version 5.0. The IPR has 4 interfaces: 1 Ethernet 10Base-T or 10Base-2  
LAN interface and 3 Frame Relay WAN interfaces (ports). Ethernet interface supports 10Mbits/sec and 3 Frame  
Relay interfaces together support 2 * T1/E1 access speed. IPR card has no Munich ports. Frame Relay ports can be  
connected through HSU or WAN cards. IPR is an IP router. This means that IPR forwards (routes) packets based on  
IP destination address, as opposed to FRS, that forwards packets based on a Frame Relay data link (dlci) address.  
IPR routes IP datagrams (packets) between Ethernet and Frame Relay PVCs. Frame Relay PVCs can be associated  
with any of the 3 Frame Relay ports. (use of Ethernet is not mandatory, IPR can easily route just between Frame  
Relay PVCs). The maximum number of PVCs supported is 128. IPR also has provisions to automatically forward  
IP packets to and from the host (CPU) IP node of the IMACS box that IPR resides in. It automatically takes care of  
all the IP fragmentation to and from the host (CPU) IP node.  
In addition to routing, IPR v2.0 is capable to bridge packets between Ethernet and Frame Relay bridge PVCs, and  
between Frame Relay bridge PVCs. IPR will forward packets matching an entry in the MAC addresses table,  
configured manually by the user. LAN broadcasts are being forwarded to all bridge PVCs. Because no spanning  
tree or learning algorithm is supported and to avoid loops, there should be no more than one physical connection  
between the same nodes. The maximum number of MAC addresses supported is 9. The maximum number of  
bridge PVCs supported is 9. Bridging function is enabled on host version 5.1.  
IPR(s) can also be (optionally) connected to FRS server card (on the same IMACS), giving the customer an option  
of concentrating Ethernet traffic in addition to other ports of concentration on the FRS card (this is called an  
EtherFrad mode). This connection is possible from IPR port C1 only and is subject to bus allocation conflicts due to  
hardware limitation of the ACS card.  
Maximum Byte Size:  
The maximum number of bytes that an IPR can handle in a single packet is 1528 bytes (this is regardless whether a  
packet arrives from Ethernet or Frame Relay interface).  
SNMP Support:  
IPR has SNMP support for MIB 2, as well as SNMP support for Zhone Technologies Private MIB. IPR has a  
testing/debugging “on-the-fly” support, which includes displaying Routing table, displaying and clearing ARP table,  
displaying and clearing IP statistics, displaying and clearing PVC statistics in 15 minutes intervals for the last 96  
intervals, displaying and clearing frame relay port statistics in 15 minutes intervals for the last 96 intervals,  
displaying and clearing LMI statistics, displaying and clearing Ethernet statistics.  
Standards Support:  
IPR uses a standard encapsulation of IP over Frame Relay (RFC 1490).  
IPR supports RIP (Routing Information Protocol, RFC 1058) for dynamically discovering IP routes from the  
adjacent IP routers on Frame Relay or Ethernet. IPR also supports static routes.  
IPR supports a DCE side of the Inverse ARP Protocol (RFC 1293).  
IPR can use different LMI encapsulations: ANSI, CCITT or LMI (Gang of Four). Each Frame Relay Port can  
be configured as either U-DTE, U-DCE, or NNI type.  
IPR supports Motorola LAPD packet forwarding protocol.  
March 2001  
Page 92  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Uses of IPR:  
IPR can be used for connecting IP LANs together through Frame Relay network.  
IPR card can be used as a gateway to the Internet through Frame Relay network.  
IPR card can be used for connecting IP nodes on Ethernet to the IP nodes on Frame Relay network.  
Application:  
Frame Relay  
PVC between  
IPR-1 and IPR-2  
Ethernet  
LAN 1  
Frame Relay  
Network  
Ethernet  
LAN 2  
IPR-1  
IPR-2  
Frame Relay  
PVC between  
IPR-3 and IPR-2  
Frame Relay  
PVC between  
IPR-1 and IPR-3  
IPR-3  
Ethernet  
LAN 3  
Note: Frame Relay PVCs can be associated with the same or with different Frame Relay ports.  
Routing Server  
The IP Routing Server enables the IMACS to act as a gateway router to the Internet via bundled service deployment  
or in private Intranet network deployment. Specifically, the primary market for the IP Routing Server is Internet  
access via bundled service arrangements (integrated access). The bundled service marketplace is simply the  
provisioning of multiple services over a single T1 or E1 to a customer. Typical bundled service arrangements  
include local voice service, long distance service and a data service. Internet access is one of the possible data  
services. The potential market for this technology is quite extensive. There are over 6.5 million small businesses in  
the US, and about 1.3 million of these have 6 to 20 phone lines. These businesses are prime candidates for bundled  
service arrangements.  
The IMACS platform is unique in that it possesses many of the qualities listed below in a flexible form factor. The  
addition of layer-3 (IP) data services to the product portfolio will further distance Zhone Technologies from the  
competition. As equipment and technologies mature, there is a constant requirement to consolidate communications  
equipment for many reasons, including:  
Lower capital costs  
Integrated management  
Ease of use and installation  
Remote connection efficiency  
March 2001  
Page 93  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Bundled Service Deployment  
The IP Routing Server is targeted at performing boundary routing functions for access to Internet or Intranet based  
services. The standard application for an IMACS in this environment is in bundled service arrangements where the  
IMACS is utilized to integrate voice circuits and an Ethernet-based Internet port at the customer location as shown  
in Figure 39. The carrier would typically switch the voice circuits to the PSTN via a DACS, while the frame relay-  
based data connection from the Ethernet port would be connected to a Frame Relay network for transmission to the  
Internet. An external firewall can be used for providing and maintaining security when connected to the Internet.  
PSTN  
DACS  
PBX/Key  
System  
T1/E1  
IMACS  
Frame Relay  
Network  
Router  
IP Network  
Figure 39 – IP Routing Server For Internet or Intranet Based Services  
Private Intranet Deployment  
A secondary market for the IP Routing Server is private Intranet access. In the application shown in Figure 40, the  
IMACS on the left is connected to a private WAN. It has a single connection to a centralized router, which provides  
full IP routing functionality. The IMACS on the right has two T1 connections, one to each of the two remote  
IMACS, and one connection to the router. Normally, there would be two connections to the router. However, in  
this application, the IMACS on the right includes a Frame Relay Server card, which switches both frame relay  
streams into the router.  
March 2001  
Page 94  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
PBX/Key  
System  
IMACS  
T1/E1  
T1/E1  
PBX/Key  
System  
T1/E1  
IMACS  
IP Network  
PBX/Key  
System  
IMACS  
IP Network  
IP Network  
Figure 40—Private Intranet Deployment Using IP Routing Server Card  
IP Routing Server Specifications  
Up to three IP Routing server cards can be functional in an IMACS in a non-redundant configuration. The processor  
performance figure of 3500 packets/second was obtained using 64 byte packets. Table 24 describes the IP Routing  
Server card specifications. The following hardware and firmware must be included in an IMACS to add IP Server  
operation:  
880360 - CPU Control Card with 8 T1/E1 Cross Connect (redundant-capable)  
892360/892460 - 8 T1/E1 Interface card w/ 128K NVRAM  
883060 - Advanced Communications Server (ACS) with 10Base2 card  
883160 - ACS with 10BaseT card  
60511 - Host Firmware version 5.1.x  
67200 - IP Routing Server firmware  
March 2001  
Page 95  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Table 24—IP Routing Server Card Specifications  
Input/Output  
4 maximum (1 10-BaseT Ethernet, 3 Frame Relay Wide-Area Network)  
LAN Traffic I/O  
Frame Relay Traffic I/O  
Frame Relay Port types  
MTU  
10BaseT, 10Base2  
T1, E1, fT1, fE1, V.35, RS422, EIA530  
UNI DCE, UNI DTE, NNI  
1500 bytes  
Traffic Bandwidth  
Total Buffer Space  
Performance  
4Mbps Full Duplex  
4 Mb DRAM  
3500 Packets Per Second  
No of PVCs  
128  
Routing Table  
ARP Table  
512 entries (up to 128 static entries)  
100 entries (LRU)  
Card Capacity  
Management  
Maximum 3 per IMACS  
RFC 1315 DTE MIB, Frame Relay Service MIB, SNMP Alarm Traps per  
RFC 1215  
Connectivity  
SNMP or TELNET  
LMI Options  
Q.933 Annex A, ANSI T1.617 Annex D, LMI (Gang of 4), None  
CIR = 0 to 2048 Kb/s, Bc = 0 to 2048 Kb, Be = 0 to 2048 Kb  
FECN, BECN  
N392, T391, N393 all configurable  
N392, T391, N393, N391 all configurable  
Point-to-point, hub-and-spoke, fully/ partially meshed subnets, and  
unnumbered IP interfaces.  
Information Rates  
Congestion Handling  
DCE Parameters  
DTE Parameters  
IP subnet Topologies  
7. Low-Bit Rate Voice Server  
The LBRV (Low Bit Rate Voice) Server card allows for the compression of 64Kbps digital voice channels into  
8Kbps (plus overhead) digital sub-channels, and subsequently for the sub-channels to be multiplexed over one, two  
or three composite transmission paths over Wide Area Network (WAN) links. The LBRV Server can accept voice  
inputs from either analog voice ports (such as FXS, FXO, E&M) or from T1/E1 WAN links through the IMACS.  
Each LBRV / ACELP (G.729) voice compression server card supports up to three composite transmission paths at  
speeds of 64k, 128k or 192k, by using one, two or three WAN time slots, respectively. The composite transmission  
paths use HDLC protocol as the transport mechanism. Users assign voice channels to one, two or three transmission  
paths based on the need to route those channels through the network. The composite transmission paths can be  
routed directly to WAN cards or to the Frame Relay Server. When routed to a Frame Relay Server (FRS), the FRS  
provides a FRAD function for the compressed voice frames. No Frame Relay sub-addressing is supported, so all  
voice channels within each composite transmission paths from the ACELP will be treated as a single PVC.  
There are two models of the LBRV server cards: 830060 (8 port) and 831060 (16 port) capacities. A single IMACS  
chassis we can support up to 3 LBRV cards for compression of a maximum of 48 voice ports.  
The LBRV card performs DTMF recognition and re-construction. This means the integrity of DTMF does not  
suffer from the compression/decompression processes. The LBRV card does not support MF signaling between  
switches. The following is a list of the Zhone Technologies LBRV key benefits:  
Simple topologies including Point-to-Point, Star and Mesh LBRV performs a compression and transport  
function. It does NOT perform voice switching and call routing.  
High density of channels and high volume of traffic.  
LBRV solution is competitive with high volumes of traffic. There should be many (24+) voice channels in one  
location.  
High reliability in mission-critical installations.  
March 2001  
Page 96  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
IMACS with LBRV is suited to carrier networks and service organizations where downtime is unacceptable.  
Examples include call centers; help desks, and inter-exchange trunks. IMACS with LBRV offers high reliability  
through:  
-
-
-
-
Hardware redundancy  
Environmental ruggedness  
No moving parts  
Path redundancy (with FRS). It can be achieved through Backup PVC feature, which switches to an  
alternate path upon either Loss of LMI [loss of FR administration connection or WAN CGA alarm (T1/E1  
failure)]  
Carrier networks requiring specialized Telco interfaces.  
IMACS has specialized Telco interfaces found in carrier environments such as :  
-
-
-
-
Coin phone (12/16 kHz or battery reversal)  
64 kbps G.703 co- / contra-directional  
BRI & PRI ISDN voice  
T1 and E1 interface  
The IMACS equipped with the LBRV Server card offers cost-effective applications including:  
-
-
-
Bulk voice compression for remote call center  
Back-hauling voice for new carriers (e.g. centralized voice mail)  
Extending voice access network over VSAT  
Call Center Application  
In the application shown in Figure 41, customer calls originating from the PSTN, are compressed by the LBRV  
server for efficient transmission on the leased E1 trunk, using frame relay. Up to three LBRV servers are used per  
up to 8 IMACS terminals to compress up to 192 voice channels from the PSTN. Groups of two IMACS terminals  
are combined. The first IMACS terminal of each pair uses 3 128 Kb/S channels each carrying 8 compressed voice  
sub-channels (9.646 Kb/S per channel), effectively using only 77.16 Kb/S out of 128 Kb/S. The 3 channels are  
inserted into the second IMACS terminal over a local T1 link. The second IMACS terminal combines its 3 128Kb/S  
channels and the other 3 128 Kb/S channels into a single T1 link feeding into another IMACS terminal equipped  
with the Frame Relay server. Ultimately, 4 T1 links bring the compressed voice signal from all 192 PSTN ports to  
the frame relay IMACS. Although the total occupied bandwidth on all 4 T1 links is 3073 Kb/S (6 x 4 x 128 Kb/S)  
the effective bandwidth used is only about 1852 Kb/S (4 x 2 x 3 x 8 x 9.646). The Frame Relay server takes the  
advantage of this and combines only the effective bandwidth over an E1 unstructured transmission link. This still  
leaves 128 Kb/S of the total E1 bandwidth (1984 Kb/S) for data traffic from a router attached to the IMACS  
terminal via an HSU card. The Frame Relay server IMACS is used at the hub locations to send voice and data  
traffic on a single leased E1 trunk.  
March 2001  
Page 97  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
T1  
T1  
3LBRV  
3LBRV  
T1  
T1  
T1  
T1  
T1  
T1  
T1  
E1 link carries  
192 voice ports + 128Kb/S (for routers)  
T1  
3LBRV  
3LBRV  
3LBRV  
3LBRV  
3LBRV  
3LBRV  
3LBRV  
3LBRV  
T1  
T1  
E1Leased  
Line  
3LBRV  
3LBRV  
3LBRV  
3LBRV  
3LBRV  
3LBRV  
PABX  
1852 k  
FRS  
FRS  
128 k  
PSTN  
T1  
HSU  
2X64K  
HSU  
2X64K  
T1  
T1  
T1  
Router  
Router  
Figure 41—LBRV In a Call Center Application  
Backhauling Voice Application  
The IMACS equipped with an LBRV server, can be used by new wireless carriers, who need to lease Telco facilities  
between their geographically separate Mobile Switching Centers (MSC). They can use the LBRV server shown in  
Figure 42 to use the leased link very efficiently thereby reducing hauling costs.  
March 2001  
Page 98  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
T1/E1  
MSC  
IMACS  
T1/E1  
Central VoiceMail  
Server  
IMACS  
MSC  
T1/E1  
NX64K Leased Line  
IMACS  
T1/E1  
T1/E1  
MSC  
IMACS  
T1/E1  
MSC  
IMACS  
MSC  
Figure 42—Backhauling Voice Application  
Extending Voice Access Application  
The application shown in Figure 43 is similar to the previous one where the LBRV is deployed to utilize the lower-  
speed but expensive VSAT link very efficiently.  
Nx64k  
VSAT Connection  
PSTN  
Switch  
T1/E1  
T1/E1  
VSAT  
VSAT  
IMACS  
IMACS  
RLU  
Modem  
Modem  
Figure 43—LBRV Voice Access Application  
March 2001  
Page 99  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
VII. IMACS System Testing and Diagnostics  
IMACS System Parameters  
System level parameters that are supported include a user-defined node name called the node ID. It can be up to 14  
alphanumeric characters long without spaces and four password-protected access levels that correspond to different  
access and capability levels. Additionally, the IMACS allows users to customize alarm management functions to  
their requirements.  
Password Protection  
The four access levels that are available to users are: “super-user,” “manager,” “operator,” and “viewer”. The  
highest is “super user” which allows flash download of software, full access to all configuration options, diagnostic  
features, and password management. The “operator” access level allows read and write access to all configuration  
and diagnostic functions and the “viewer” access level, which is the lowest, allows read-only access to system status  
and configuration options.  
All four access levels are protected by user-defined passwords. Passwords can be up to 12 alphanumeric characters  
and are case-sensitive. The ability to change passwords is hierarchical in that someone logging in at a certain access  
level may change the passwords associated with their own level and the passwords associated with lower access  
levels. For example, “super user” may change the passwords associated with all four levels. Similarly, “operator”  
may change the password associated with both the “operator” and the “viewer” levels only.  
Port Status Summary  
The IMACS supports the ability to display a summary of the status of each port on every card installed in the  
system. This information is displayed in the main menu screen next to the card type field associated with each slot.  
The user has the option of turning this information on or off with a single keystroke by pressing the “s” key. All  
loop backs that are commanded from the user interface will be represented on the main screen. In addition to the  
Out-Of-Service (OOS) and Reject (REJ) messages that are associated with the status of the entire card, the system  
will describe the status of each port by displaying one of the following letters:  
Letter  
Meaning  
“a”  
“s”  
“l”  
“t”  
“r”  
Port is active  
Port is in standby mode  
Port is in loop back  
Port is in test mode  
Port is the redundant mate of an active port  
(Applies to WAN ports and ADPCM card)  
March 2001  
Page 100  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
IMACS Diagnostic Capabilities  
Status and Alarm Management  
The IMACS supports a comprehensive alarm message generation and reporting capability that provides the system  
operator with a complete view of the operation of the system. Alarm messages that are supported include, Out-Of-  
Service (OOS) condition (any card, module, power supply or ringing generator that fails or is removed from the  
system), No Signal (NOS), Loss of Synchronization (LOS), AIS alarm, CGA-Red alarm, CGA-Yellow alarm,  
Excessive Error Rate (EER), Alarm card sensor (SENSOR), D-channel out of service (DCHAN), Switch to  
redundant card (SWITCH), User card/port alarm (UCA), System reset (RESET), Alarm Cut-Off (ACO), Clock Sync  
alarm (SYNC), Error rate above 10e-3 (EER-3), DS3 PCLP Out of Framing (PLC_OOF), DS3 PCLP Loss of Frame  
(PLC_LOF) and DS3 PCLP Yellow alarm (PLC_YEL).  
The IMACS supports the setting of filters for each alarm message that is generated by the system. These three  
filters define the manner in which the alarm will be reported and take precedence over the designation of the level of  
the alarm.  
Setting the filter of a specific alarm to “report” will cause the system to display the alarm message on the  
screen, log it into the alarm history file and report it to a remote device by dialing a pre-programmed telephone  
number through the built-in modem or by sending an SNMP trap via IP.  
Setting the filter to “log” will (a) display the alarm message on the screen and (b) log it into the alarm history  
file.  
Setting the filter to “ignore” will cause the alarm indication to be ignored by the system.  
In addition to the three filters, each alarm may be designated as “info”, “major”, “minor” or “critical”. When used  
in conjunction with the Model 840X External Alarm card, the occurrence of any alarm designated as “major” will  
trigger a form-C contact on the External Alarm card, which in turn can serve to activate an external device such as a  
bell or light. Similarly, the occurrence of any alarm designated as “minor” would trigger a different contact and,  
therefore, activate a different external indicator.  
The system supports a standard feature known as Alarm Cut-Off (ACO). If the ACO function is enabled, by setting  
it to “log” or “report”, then any major alarm that is set to “report” or “log” will automatically cause an ACO  
message to be generated. The ACO will not disappear until it is manually cleared by the operator.  
This feature is useful in situations where an alarm condition occurs and then clears itself while the system is  
unattended. When the operator returns, there will be no indication on the console screen that anything had  
happened. However, if the ACO function is enabled, then the ACO message will remain on the screen thereby  
notifying the operator that certain events occurred while the node was unattended. The operator can then query the  
alarm history file for further information.  
Alarms may be set to “report” in which case the IMACS will dial a remote device after a “wait” period. The user  
may define the wait period for both Major and Minor alarms. The wait period can be between 1 and 500 seconds for  
a Major alarm and between 1 and 32,000 seconds for a Minor alarm.  
The user may specify in software the remote device’s telephone number, printout retry interval if the remote device  
is busy (1 minute to 60 minutes, in 1 minute intervals) and the maximum number of times (from 1 to 99) that the  
system will attempt to contact the remote device before giving up.  
The user may customize the appearance of alarm messages by specifying the order that the six message elements  
should appear in. Those elements are: (1) slot position (“address”), (2) card type (“model”), (3) alarm type  
(“alarm”), and (4) start and stop time and date stamps (“time”), (5) alarm sequence number “number”, (6) alarm  
severity (“severity”).  
Integral Test Capabilities  
The IMACS provides a comprehensive set of built-in diagnostic tools that enable the operator to remotely  
troubleshoot and resolve problems. In addition to the system-generated alarm messages described above, the  
March 2001  
Page 101  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
integral diagnostic capabilities of the IMACS include Bit Error Rate Testers (BERTs) on data cards, tone generators  
on analog voice cards, the ability to manipulate the analog leads and the digital signaling bits of voice circuits and  
extensive loop back generation and detection capability on many system elements.  
The ability to initiate loop backs at various points in a circuit, coupled with the ability to generate and receive test  
signals and to collect performance and error information, enables the operator to systematically troubleshoot circuit  
problems. It allows the operator to determine if the problem resides in the IMACS system, and whether the problem  
can be isolated down to a specific Field Replaceable Unit (FRU) within the system. Since all of these diagnostic  
tools can be operated from a VT100 terminal, troubleshooting begins immediately without dispatching an on-site  
technician.  
The diagnostic capabilities of the IMACS system are described in the following section. They are divided into four  
categories: (1) WAN diagnostics, (2) voice diagnostics, (3) data diagnostics and (4) cross-connect diagnostics.  
WAN Diagnostics  
Software-initiated diagnostics on T1 and E1 WAN aggregates include looping the WAN signal toward the network  
(line loop back) or the IMACS system (local loop back) and placing any one of the DS0 channels that make up the  
WAN signal in local loop back. See Table 25 for a complete list of diagnostic capabilities.  
Table 25-- Diagnostic Capabilities of Single and Dual WAN Cards  
On-Card Loop backs  
LOOP BACKS  
T1/CSU  
Yes  
Yes  
No  
T1/DSX  
E1/CEPT/HDSL  
T1/E1 Line Loop back Toward Network  
T1/E1 Local Loop back Toward User  
DS0 Channel Loop back Toward Network  
DS0 Channel Loop back Toward User  
Yes  
Yes  
No  
Yes  
Yes  
No  
Yes  
Yes  
Yes  
In-Band Loop back Code Generation  
LOOP BACKS  
Industry-Standard T1/E1 Loop-Up Code  
Industry-Standard T1/E1 Loop-Down Code  
T1/CSU  
Yes  
Yes  
T1/DSX  
T1/DSX  
E1/CEPT/HDSL  
N/A  
N/A  
Yes  
Yes  
In-Band Loop back Code Detection  
LOOP BACKS  
T1/CSU  
E1/CEPT/HDSL  
Industry-Standard T1/E1 Loop-Up Code  
Industry Standard T1/E1 Loop-Down Code  
Yes  
Yes  
Yes  
Yes  
N/A  
N/A  
Bit Error Rate Tester (BERT)  
Patterns Supported  
LOOP BACKS  
All 1s  
All 0s  
1:1  
1:7  
3:24  
T1/CSU  
T1/DSX  
E1/CEPT/HDSL  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
QRSS  
March 2001  
Page 102  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
BERT Direction  
LOOP BACKS  
Toward Network  
T1/CSU  
Yes  
T1/DSX  
E1/CEPT/HDSL  
Yes  
Yes  
Statistics Gathered By BERT  
LOOP BACKS  
Bit Errors (BE)  
Errored Seconds (ES)  
Severely Errored Seconds (SES)  
Consecutive Severely Errored Seconds (CSES)  
Out of Synchronization Seconds (OSS)  
Bit Error Rate (BER)  
T1/CSU  
Yes  
T1/DSX  
E1/CEPT/HDSL  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Elapsed Seconds (ELAP)  
HDSL Errored Seconds  
HDSL Severely Errored Seconds  
HDSL Unavailable Seconds  
N/A  
N/A  
N/A  
N/A  
N/A  
N/A  
Yes*  
Yes*  
Yes*  
*
applicable only for the E1-HDSL plug-in module. Also the same statistics are available for the  
remote end.  
Voice Diagnostics  
The software-initiated diagnostics supported on voice cards include the setting of both analog and digital loop backs  
toward the network and the generation of Quiet Tone and a Digital MilliWatt signal on a port-by-port basis. The  
operator can also monitor and set the state of the analog leads of any FXS, FXO or E&M port. They can set and  
monitor the state of the ABCD signaling bits of the digitized voice signal. In cross-connect systems, test  
functionality also includes the ability to generate test tones (300Hz, 1 kHz and 3 kHz) and transmit those toward the  
user side or the network side of the system. Refer to Table 26 for detailed information on the diagnostic capabilities  
of the voice cards.  
Table 26—Diagnostic Capabilities of Voice Ports  
2-wire  
E&M  
4-wire  
E&M  
4-wire  
Extended  
E&M  
2-wire 2-wire  
FXS  
FXO  
LOOP BACKS  
On-Card Loop backs  
Analog Toward Network  
Digital Toward Network  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
SIGNALING MANIPULATION  
Set Status of Analog Interface Leads  
Set Transmit ABCD Signaling Bits  
Set Receive ABCD Signaling Bits  
Monitor Status of Analog Interface Leads  
Monitor Status of Transmit ABCD Signaling Bits  
Monitor Status of Receive ABCD Signaling Bits  
Yes  
Yes  
Yes*  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes*  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes*  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes*  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes*  
Yes  
Yes  
Yes  
TONE GENERATION  
Tones Supported  
300 Hz  
1 kHz  
3 kHz  
Yes*  
Yes*  
Yes*  
Yes*  
Yes*  
Yes*  
Yes*  
Yes*  
Yes*  
Yes*  
Yes*  
Yes*  
Yes*  
Yes*  
Yes*  
March 2001  
Page 103  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Quiet Tone  
Digital MilliWatt  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Tone Direction  
Toward User  
Toward Network  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
This feature is only supported in Cross-Connect Systems  
Data Diagnostics  
Data diagnostics support varies among data cards. Refer to Table 27 for detailed information on data card  
diagnostics. Generally, data card diagnostics supported include the setting of various levels of loop backs toward  
the network or the attached DTE equipment. Other support includes the ability to generate and respond to industry-  
standard loop-up and loop-down codes that are compatible with DDS, V.54 and/or Fractional T1 (FT1) formats.  
The DS0-DP data card generates and detects DS0-DP loop back codes.  
Table 27—Diagnostic Capabilities of Data Ports  
EIA530  
HSU  
V.35  
HSU  
EIA530/V.35  
HSU  
SRU  
OCU-DP  
2/5/10-port  
DS0-DP  
4-port  
2-port  
2-port  
4-port  
LOOP BACKS  
On-Card Loop backs  
EIA530  
HSU  
2-port  
Yes  
V.35  
HSU  
2-port  
Yes  
EIA530/V.35  
HSU  
SRU  
OCU-DP  
2/5/10-port  
DS0-DP  
4-port  
4-port  
Yes  
Yes  
Toward DTE  
Toward Network  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
In-Band Loop back Code Generation  
EIA530  
HSU  
2-port  
Yes  
Yes  
Yes  
V.35  
HSU  
2-port  
Yes  
Yes  
Yes  
EIA530/V.35  
HSU  
4-port  
Yes  
SRU  
OCU-DP  
2/5/10-port  
DS0-DP  
4-port  
Latching DDS-OCU  
Latching DDS-DSU  
Latching DDS-CSU  
Latching DDS-DS0  
ITU (CCITT) V.54  
Yes  
Yes  
Yes  
No  
Yes  
No  
Yes  
Yes  
No  
Yes  
Yes  
Yes  
Yes  
No  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
No  
ANSI Fractional T1 (FT1)  
Yes  
Yes  
Yes  
No  
No  
No  
Control Lead Handling  
EIA530  
HSU  
2-port  
Yes  
Yes  
Yes  
V.35  
HSU  
2-port  
Yes  
Yes  
Yes  
EIA530/V.35  
HSU  
4-port  
Yes  
SRU  
OCU-DP  
2/5/10-port  
DS0-DP  
4-port  
Set CTS  
Set RLSD  
Set DSR  
Monitor RTS  
Monitor DTR  
Yes  
Yes  
No  
Yes  
No  
N/A  
N/A  
N/A  
N/A  
N/A  
N/A  
N/A  
N/A  
N/A  
N/A  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
March 2001  
Page 104  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Bit Error Rate Tester (BERT)  
Patterns Supported  
EIA530  
HSU  
2-port  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
V.35  
HSU  
2-port  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
EIA530/V.35  
HSU  
4-port  
Yes  
SRU  
OCU-DP  
2/5/10-port  
DS0-DP  
4-port  
All 1s  
All 0s  
1:1  
1:7  
511  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
No  
No  
No  
No  
No  
No  
No  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
2047  
QRSS  
BERT Direction  
EIA530  
HSU  
2-port  
No  
V.35  
HSU  
2-port  
No  
EIA530/V.35  
HSU  
SRU  
OCU-DP  
2/5/10-port  
DS0-DP  
4-port  
4-port  
No  
Yes  
Toward User  
Toward Network  
Yes  
Yes  
Yes  
Yes  
No  
No  
Yes  
Yes  
Statistics Gathered by BERT  
EIA530  
HSU  
2-port  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
V.35  
HSU  
2-port  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
EIA530/V.35  
HSU  
4-port  
Yes  
SRU  
OCU-DP  
2/5/10-port  
DS0-DP  
4-port  
Bit Errors (BE)  
Errored Seconds (ES)  
Severely Errored Seconds (SES)  
Consecutive Severely Errored Seconds (CSES)  
Out of Synchronization Seconds (OSS)  
Bit Error Rate (BER)  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
No  
No  
No  
No  
No  
No  
No  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Elapsed Seconds (ELAP)  
Systems Equipped With Cross-Connect Option  
In systems equipped with Cross-Connect CPUs, the cross-connect element adds another level of testing within the  
node and enhances the system’s diagnostic capabilities. The operator may also monitor and set the state of the  
Transmit and Receive ABCD signaling bits of a digitized voice circuit that is cross-connected between two WANs.  
Refer to Table 28 for detailed information.  
Table 28—Diagnostic Capabilities of Cross-Connect Circuits  
Loop Backs  
Local Loop backs  
Voice  
Without  
Singaling  
Voice  
With  
Signaling  
Single Data Super-rate  
DS0  
Data  
(Nx64Kbp  
s)  
(64Kbps)  
Toward WAN1  
Toward WAN2  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
March 2001  
Page 105  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Bit Error Rate Tester (BERT)  
Patterns Supported  
Voice  
Without  
Singaling  
Voice  
With  
Signaling  
Single Data Super-rate  
DS0  
Data  
(Nx64Kbp  
s)  
(64Kbps)  
All 1s  
All 0s  
1:1  
1:7  
M_OOS  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
BERT Direction  
Voice  
Without  
Singaling  
Voice  
With  
Singaling  
Single Data Super-rate  
DS0  
Data  
(Nx64Kbp  
s)  
(64Kbps)  
Toward WAN 1  
Toward WAN 2  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Tones Supported  
Voice  
Without  
Singaling  
Voice  
With  
Singaling  
Single Data Super-rate  
DS0  
Data  
(Nx64Kbp  
s)  
(64Kbps)  
300 Hz  
1 kHz  
3 kHz  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Tone Direction  
Voice  
Without  
Singaling  
Voice  
With  
Singaling  
Single Data Super-rate  
DS0  
Data  
(Nx64Kbp  
s)  
(64Kbps)  
Toward WAN 1  
Toward WAN 2  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Signaling Manipulation  
Toward WAN 1  
Voice  
Without  
Singaling  
Voice  
With  
Singaling  
Single Data Super-rate  
DS0  
Data  
(Nx64Kbp  
s)  
(64Kbps)  
300 Hz  
1 kHz  
3 kHz  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
Yes  
March 2001  
Page 106  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Toward WAN 2  
Voice  
Without  
Singaling  
Voice  
With  
Singaling  
Single Data Super-rate  
DS0  
Data  
(Nx64Kbp  
s)  
(64Kbps)  
Set Transmit ABCD Signaling Bits  
Monitor Status of Transmit ABCD  
Signaling Bits  
N/A  
N/A  
Yes  
Yes  
N/A  
N/A  
N/A  
N/A  
Monitor Status of Receive ABCD  
Signaling Bits  
N/A  
Yes  
N/A  
N/A  
Benefits of Built-In Diagnostics  
The real power of the integral diagnostics of the IMACS can be fully appreciated when the individual diagnostic  
tools are applied to everyday troubleshooting such as the one illustrated in the following example.  
The environment shown in Figure 44 consists of two IMACS’ connected by a T1 line. These are referred to as the  
Local IMACS and the Remote IMACS respectively. At the local IMACS, the DTE equipment is a co-located  
device providing a 56 Kbps V.35 interface that is connected to a V.35 HSU port. At the Remote IMACS, an OCU-  
DP card that interfaces to the 4-wire DDS tail-circuit extends the 56 Kbps to a third location. Consequently, the  
Remote IMACS is equipped with an OCU-DP card that interfaces to the 4-wire DDS tail-circuit. At the third  
location, the DDS circuit terminates in a generic, third party DSU/CSU that in turn provides a 56 Kbps V.35  
interface to the remote DTE device.  
The system operator can use the diagnostic tool kit to systematically troubleshoot the problem on an end-to-end  
basis and to identify the faulty sub-system, even if it is external to the IMACS. One way to systematically  
troubleshoot the problem is illustrated in Figure 44. While there are many other approaches, in general, the  
procedure to follow is to combine loop backs that are generated either through software commands or via industry-  
standard loop-up codes with Bit Error Rate Tests (BERTs) for data circuits, or test tones for voice circuits. In the  
IMACS, all of those tools are available as integral features of the system and of the various cards. Each test  
determines if a specific sub-system is operating properly. In our example, after each test, the sub-systems that are  
shown to be functioning properly are shaded in gray.  
In Figure 44, the local HSU card is put in Local loop back and a BERT test is run from the DTE. If successful, in  
Figure 44, diagnostics-figure 3, the loop back sequence is advanced by putting the T1 link of the Local IMACS in  
Local loop back and running BERT test again. This also tests the cross-connect element of the local IMACS if there  
is one present. In Figure 44XX, diagnostics-figure 4, the T1 link of the remote IMACS is configured in Line Loop  
back. Alternatively, a loop up code can be sent from the local IMACS to put the T1 link of the remote IMACS in  
Line loop back. This process is repeated until the remote DTE is put in network loop back and tested as shown  
Figure 44, diagnostics-figure 8.  
March 2001  
Page 107  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
Figure 1  
IMACS Product Book, Version 4  
V
.
35 Cross-Connect  
Cross-Connect  
Element  
OC U  
/DP  
Remote  
DTE  
Local  
DTE  
HSU Element  
T1  
T1  
DSU/CSU  
T1 Facility  
DDS Facility  
V.35  
V.35  
Figure 2  
V.35 Cross-Connect  
HSU Element  
Cross-Connect  
Element  
OC U  
/DP  
Remote  
DTE  
Local  
DTE  
T1  
T1  
DSU/CSU  
T1 Facility  
DDS Facility  
V.35  
V.35  
Figure 3  
V.35 Cross-Connect  
HSU Element  
Cross-Connect  
Element  
OC U  
/DP  
Remote  
DTE  
Local  
DTE  
T1  
T1  
DSU/CSU  
T1 Facility  
DDS Facility  
V.35  
V.35  
Figure 4  
V.35 Cross-Connect  
HSU Element  
Cross-Connect  
Element  
OC U  
/DP  
Remote  
DTE  
Local  
DTE  
T1  
T1  
DSU/CSU  
T1 Facility  
DDS Facility  
V.35  
V.35  
Figure 44a - Built-In Diagnostics Example  
March 2001  
Page 108  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
Figure 5  
V.35 Cross-Connect  
HSU Element  
Cross-Connect  
Element  
OC U  
/DP  
Remote  
Local  
DTE  
T1  
T1  
DSU/CSU  
DTE  
T1 Facility  
DDS Facility  
V.35  
V.35  
Figure 6  
V.35 Cross-Connect  
HSU Element  
Cross-Connect  
Element  
OC U  
/DP  
Remote  
DTE  
Local  
DTE  
T1  
T1  
DSU/CSU  
T1 Facility  
DDS Facility  
V.35  
V.35  
Figure 7  
V.35 Cross-Connect  
HSU Element  
Cross-Connect  
Element  
OC U  
/DP  
Remote  
DTE  
Local  
DTE  
T1  
T1  
DSU/CSU  
T1 Facility  
DDS Facility  
V.35  
V.35  
Figure 8  
V.35 Cross-Connect  
HSU Element  
Cross-Connect  
Element  
OC U  
/DP  
Remote  
DTE  
Local  
DTE  
T1  
T1  
DSU/CSU  
T1 Facility  
DDS Facility  
V.35  
V.35  
Figure 9  
V.35 Cross-Connect  
HSU Element  
Cross-Connect  
Element  
OC U  
/DP  
Remote  
DTE  
Local  
DTE  
T1  
T1  
DSU/CSU  
T1 Facility  
DDS Facility  
V.35  
V.35  
Figure 44b - Built-In Diagnostics Example  
IMACS Performance Monitoring  
The IMACS provides non-intrusive performance monitoring of T1 lines and DDS circuits that terminate on OCU-  
DP cards. This capability is built into the system software and does not require any special options or expensive  
external equipment.  
T1 Line Performance Monitoring  
Performance monitoring, statistics gathering and performance reporting of T1 facilities is supported in the IMACS.  
In ESF format, CRC errors, Out-Of-Frame errors, and Controlled Slips are combined to provide line quality and  
performance statistics in accordance with industry standards. In D4 format, Bipolar Violations (BPVs) are used  
instead of CRC errors. The performance statistics are gathered and displayed in fifteen-minute intervals for the  
preceding twenty-four hours. They include Errored Seconds, Unavailable Seconds, Severely Errored Seconds,  
Bursty Errored Seconds, Loss Of Frame Count, and Slipped Seconds.  
In ESF mode, these statistics are available to the system operator as well as to the carrier or service provider over the  
embedded 4 Kbps Facilities Data Link (FDL). Each ESF T1 facility can be independently programmed to support  
framing according to the AT&T 54016 standard or the ANSI T1.403 standard or both simultaneously. Additionally,  
March 2001  
Page 109  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Zhone Technologies, Inc.  
IMACS Product Book, Version 4  
for each T1 in the system, the operator may select an error rate threshold (from 10E-4 to 10E-9) which, if exceeded,  
will cause the system to generate an Excessive Error Rate (EER) alarm.  
DDS Line Performance Monitoring  
The two-port OCU-DP card supports two methods of non-intrusive error correction. The first is Majority Vote and  
applies to lower data rates such as 2.4, 4.8 and 9.6 Kbps. The other is the BCH method and applies to data rates of  
19.2 Kbps and 56 Kbps.  
If an OCU-DP port has error correction enabled, then the system will collect and display statistics on the  
performance of the circuit. Performance statistics include separate incoming (from the T1 network) and outgoing (to  
the 4-wire DDS circuit) Errored Seconds, Severely Errored Seconds and Consecutive Severely Errored Seconds and  
are displayed in one-hour intervals for the preceding twenty-four hours.  
Frame Relay Performance Monitoring  
The Frame Relay Server accumulates performance statistics that can be used to monitor port, circuit and congestion  
characteristics. Statistics are gathered in 15-minute increments for a total of 24 hours. Collected statistics includes  
the:  
Circuit transmit and receive performance  
Circuit user contract compliance information  
Circuit congestion information  
Port transmit and receive information  
ATM Performance Monitoring  
The ATM Server accumulates performance statistics used to monitor the DS3 physical link, the ATM UNI, and  
VBR and CBR circuit characteristics. Statistics are gathered in 15-minute increments for a total of 24 hours.  
Collected statistics include:  
DS3 ATM physical link performance in accordance with DS3 MIB specification  
ATM UNI performance in accordance with ATM Forum UNI 3.0 specification  
AAL 3, 4 and 5 performance in accordance with AToM MIB specification  
AAL 1 and corresponding CBR circuit performance in accordance with ATM Forum’s DS1/E1 circuit  
emulation specification  
VBR circuit performance characteristics  
Conclusion  
While the actual costs of telecommunications equipment has been decreasing over time, the cost associated with the  
logistical, operational and technical support keeping the network running is still expensive. As a result, it is critical  
that communications equipment provides all of the self-diagnostics and test tools needed to troubleshoot and resolve  
problems remotely, even if the problems are external to the equipment.  
The Zhone Technologies IMACS combines the functionality of the most advanced integrated access device  
available on the market today. It is an important asset to the Zhone Technologies product portfolio, which  
incorporates the Zhone Technologies stamp of quality, innovation, engineering, quality assurance and HALT testing.  
The IMACS provides a full suite of network services such as frame relay, FXO, etc. to support a variety of user  
requirements. Furthermore, the IMACS’ unparalleled integral test and diagnostic capabilities eliminate the need for  
external test equipment and in most cases, the need to dispatch personnel to troubleshoot problems.  
March 2001  
Page 110  
Download from Www.Somanuals.com. All Manuals Search And Download.  

Weslo Treadmill WLTL 147090 User Manual
Weslo Treadmill WLTL393120 User Manual
Whirlpool Clothes Dryer 3LG5706XP User Manual
Whirlpool Range FEP310E User Manual
Whirlpool Ventilation Hood RH3730XLB1 User Manual
Whirlpool Washer Dryer LE6098XT User Manual
White Rodgers Thermostat 1C26 User Manual
Woodstock Telephone Accessories D2258 User Manual
Xantech Router 480B 80 User Manual
Xantrex Technology Marine Battery Freedom SW 2000 User Manual