Maxim Switch DS33R11 User Manual

Figure 13-15. Receive Line Interface Timing .......................................................................................................... 330

Figure 13-16. Receive Timing Delay RCLKO to BPCLK......................................................................................... 331

Figure 13-17. Transmit-Side Timin g ........................................................................................................................ 333

Figure 13-18. Transmit-Side Timing, Elastic Store Enabled ................................................................................... 334

Figure 13-19. Transmit Line Interface Timing ......................................................................................................... 334

Figure 13-20. JTAG Interface Timing Diagram ....................................................................................................... 335

Figure 14-1. JTAG Functional Block Diagra m ......................................................................................................... 336

Figure 14-2. TAP Controller State Diagram............................................................................................................. 339

Figure 14-3. JTAG Functional Timing...................................................................................................................... 342

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

LIST OF TABLES

Table 2-1. T1-Related Telecommunications Specification s ...................................................................................... 16

Table 7-1. Detailed Pin Descriptions ......................................................................................................................... 25

Table 9-1. Clocking Options for the Ethernet Interface ............................................................................................. 43

Table 9-2. Reset Functions........................................................................................................................................ 46

Table 9-3. Registers Related to Connections and Queue s ....................................................................................... 52

Table 9-4. Options for Flow Control........................................................................................................................... 53

Table 9-5. Registers Related to Setting the Ethernet Port ........................................................................................ 57

Table 9-6. MAC Control Registers............................................................................................................................. 60

Table 9-7. MAC Status Register s .............................................................................................................................. 60

Table 10-1. T1/E1/J1 Transmit Clock Source ........................................................................................................... 73

Table 10-2. T1 Alarm Criteria .................................................................................................................................... 75

Table 10-3. E1 Sync/Resync Criteria ........................................................................................................................ 76

Table 10-4. E1 Alarm Criteria .................................................................................................................................... 77

Table 10-5 T1 Line Code Violation Counting Option s ............................................................................................... 78

Table 10-6. E1 Line-Code Violation Counting Options.............................................................................................. 78

Table 10-7. T1 Path Code Violation Counting Arrangement s ................................................................................... 79

Table 10-8. T1 Frames Out-of-Sync Counting Arrangements .................................................................................. 80

Table 10-9. Time Slot Numbering Schemes.............................................................................................................. 85

Table 10-10. Idle-Code Array Address Mappin g ....................................................................................................... 86

Table 10-11. Elastic Store Delay After Initialization .................................................................................................. 89

Table 10-12. HDLC Controller Registers................................................................................................................... 94

Table 10-13. Transformer Specifications................................................................................................................. 104

Table 10-14. Transmit Error-Insertion Setup Sequence.......................................................................................... 111

Table 10-15. Error Insertion Examples.................................................................................................................... 111

Table 11-1. Register Address Map.......................................................................................................................... 117

Table 11-2. Global Ethernet Mapper Register Bit Map ........................................................................................... 118

Table 11-3. Arbiter Register Bit Map ....................................................................................................................... 119

Table 11-4. BERT Register Bit Map ........................................................................................................................ 119

Table 11-5. Serial Interface Register Bit Map.......................................................................................................... 120

Table 11-6. Ethernet Interface Register Bit Ma p ..................................................................................................... 122

Table 11-7. MAC Indirect Register Bit Ma p ............................................................................................................. 123

Table 11-8. T1/E1/J1 Transceiver Register Bit Map (Active when CST = 0) .......................................................... 125

Table 13-1. Recommended DC Operating Conditions............................................................................................ 313

Table 13-2. DC Electrical Characteristics................................................................................................................ 313

Table 13-3. Thermal Characteristics ....................................................................................................................... 314

Table 13-4. Theta-JA vs. Airflow ............................................................................................................................. 314

Table 13-5. Transmit MII Interface .......................................................................................................................... 315

Table 13-6. Receive MII Interface ........................................................................................................................... 316

Table 13-7. Transmit RMII Interfac e ........................................................................................................................ 317

Table 13-8. Receive RMII Interfac e ......................................................................................................................... 318

Table 13-9. MDIO Interface ..................................................................................................................................... 319

Table 13-10. Transmit WAN Interfac e ..................................................................................................................... 320

Table 13-11. Receive WAN Interface...................................................................................................................... 321

Table 13-12. SDRAM Interface Timing.................................................................................................................... 322

Table 13-13. AC Characteristics—Microprocessor Bus Timin g .............................................................................. 324

Table 13-14. AC Characteristics: Receive Side ...................................................................................................... 327

Table 13-15. AC Characteristics: Backplane Clock Synthesis................................................................................ 331

Table 13-16. AC Characteristics: Transmit Side ..................................................................................................... 332

Table 13-17. JTAG Interface Timing ....................................................................................................................... 335

Table 14-1. Instruction Codes for IEEE 1149.1 Architecture .................................................................................. 340

Table 14-2. ID Code Structure................................................................................................................................. 341

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

1 DESCRIPTION

The DS33R11 provides interconnection and mapping functionality between Ethernet Packet Systems and T1/E1/J1

WAN Time-Division Multiplexed (TDM) systems. The device is composed of a 10/100 Ethernet MAC, Packet

Arbiter, Committed Information Rate Controller (CIR), HDLC/X.86 (LAPS) Mapper, SDRAM interface, control ports,

Bit Error Rate Tester (BERT), and integrated T1/E1/J1 Transceiver. The packet interface consists of a MII/RMII

Ethernet PHY interface. The Ethernet interface can be configured for 10Mbit/s or 100Mbit/s service. The DS33R11

encapsulates Ethernet traffic with HDLC or X.86 (LAPS) encoding to be transmitted over a T1, E1, or J1 line. The

T1/E1/J1 interface also receives encapsulated Ethernet packets and transmits the extracted packets over the

Ethernet ports. Access is provided to the signals between the Serial port and the integrated T1/E1/J1 Transceiver.

The device includes a software-selectable T1, E1, or J1 single-chip transceiver (SCT) for short-haul and long-haul

applications. The transceiver is composed of an LIU, framer, and two additional HDLC controllers. The transceiver

is software compatible with the DS2155 and DS2156.

The LIU is composed of transmit and receive interfaces and a jitter attenuator. The transmit interface is responsible

for generating the necessary waveshapes for driving the network and providing the correct source impedance

depending on the type of media used. T1 waveform generation includes DSX-1 line build-outs as well as CSU line

build-outs of -7.5dB, -15dB, and -22.5dB. E1 waveform generation includes G.703 waveshapes for both 75Ω coax

and 120Ω twisted cables. The receive interface provides network termination and recovers clock and data from the

network. The receive sensitivity adjusts automatically to the incoming signal and can be programmed for 0 to 43dB

or 0 to 12dB for E1 applications and 0 to 30dB or 0 to 36dB for T1 applications. The jitter attenuator removes

phase jitter from the transmitted or received signal. The crystal-less jitter attenuator requires only a 2.048MHz

MCLK for both E1 and T1 applications (with the option of using a 1.544MHz MCLK in T1 applications) and can be

placed in either transmit or receive data paths. An additional feature of the LIU is a CMI coder/decoder for

interfacing to optical networks.

On the transmit side, clock, data, and frame-sync signals are provided to the framer by the backplane interface

section. The framer inserts the appropriate synchronization framing patterns, alarm information, calculates and

inserts the CRC codes, and provides the B8ZS/HDB3 (zero code suppression) and AMI line coding. The receive-

side framer decodes AMI, B8ZS, and HDB3 line coding, synchronizes to the data stream, reports alarm

information, counts framing/coding/CRC errors, and provides clock/data and frame-sync signals to the backplane

interface section. Diagnostic capabilities include loopbacks, PRBS pattern generation/detection, and 16-bit loop-up

and loop-down code generation and detection.

Both the transmit and receive path have two HDLC controllers. The HDLC controllers transmit and receive data

through the framer block. The HDLC controllers can be assigned to any time slot, group of time slots, portion of a

time slot or to FDL (T1) or Sa bits (E1). Each controller has 128-byte FIFOs, thus reducing the amount of

processor overhead required to manage the flow of data. In addition, built-in support for reducing the processor

time is required in SS7 applications.

The backplane interface provides a versatile method of sending and receiving data from the host system. Elastic

stores provide a method for interfacing to asynchronous systems, converting from a T1/E1 network to a 2.048MHz,

4.096MHz, 8.192MHz, or N x 64kHz system backplane. The elastic stores also manage slip conditions

(asynchronous interface).

An 8-bit parallel microcontroller port provides access for control and configuration of all the features of the device.

The internal 100MHz SDRAM controller interfaces to a 32-bit wide 128Mb SDRAM. The SDRAM is used to buffer

the data from the Ethernet and WAN ports for transport. The external SDRAM can accommodate up to 8192

frames with a maximum frame size of 2016 bytes. Diagnostic capabilities include SDRAM BIST, loopbacks, PRBS

pattern generation/detection, and 16-bit loop-up and loop-down code generation and detection. The DS33R11

operates with a 1.8V core supply and 3.3V I/O supply.

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

The integrated Ethernet Mapper is software compatible with the DS33Z11 Ethernet mapper. There are a few things

to note when porting a DS33Z11 application to this device:

•

The SPI and hardware modes are not supported.

RSER has been renamed to RSERI.

RCLK has been renamed to RCLKI.

TSER has been renamed to TSERO.

TCLK has been renamed to TCLKE.

The integrated T1/E1/J1 transceiver is software compatible with the DS2155 T1/E1/J1 transceiver. There are a few

things to note when porting a DS2155 application to this device:

•

The Facilities Data Link (FDL) support is available through software only. The TLINK, RLINK, TLCLK,

RLCLK pins are not available on the DS33R11.

•

Multiplexed Microprocessor Bus mode is not supported on the DS33R11.

The Extended System Information Bus (ESIB) is not supported on the DS33R11.

The MODEC pins serve the function of the DS2155’s BTS pin.

The interim LIU/Framer clock signals RCLKI, RCLKO have been renamed to RDCLKI, RDCLKO to avoid

confusion with the receive clock connections between the transceiver and the Ethernet mapper.

•

The interim LIU/Framer clock signals TCLKI, TCLKO have been renamed to TDCLKI, TDCLKO to avoid

confusion with the receive clock connections between the transceiver and the Ethernet mapper.

•

RSER has been renamed RSERO.

RCLK has been renamed RCLKO.

TSER has been renamed TSERI.

TCLK has been renamed TCLKT.

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

2 FEATURE HIGHLIGHTS

2.1 General

•

256-pin, 27mm BGA package

1.8V and 3.3V supplies

IEEE 1149.1 JTAG boundary scan

Software access to device ID and silicon revision

Development support includes evaluation kit, driver source code, and reference designs

Reference design routes on a two-layer PC board

Programmable output clocks for fractional T1, E1, H0, and H12 applications

2.2 Microprocessor Interface

•

Parallel control port with 8-bit data bus

Nonmultiplexed Intel and Motorola timing modes

Internal software reset and external hardware reset-input pin

Supports polled or interrupt-driven environments

Software access to device ID and silicon revision

Global interrupt-output pin

2.3 HDLC Ethernet Mapping

•

Dedicated HDLC controller engine for protocol encapsulation

Compatible with polled or interrupt driven environments

Programmable FCS insertion and extraction

Programmable FCS type

Supports FCS error insertion

Programmable packet size limits (Minimum 64 bytes and maximum 2016 bytes)

Supports bit stuffing/destuffing

Selectable packet scrambling/descrambling (X⁴³+1)

Separate FCS errored packet and aborted packet counts

Programmable inter-frame fill for transmit HDLC

2.4 X.86 (Link Access Protocol for SONET/SDH) Ethernet Mapping

•

Programmable X.86 address/control fields for transmit and receive

Programmable 2-byte protocol (SAPI) field for transmit and receive

32 bit FCS

Transmit transparency processing—7E is replaced by 7D, 5E

Transmit transparency processing—7D replaced by 7D, 5D

Receive rate adaptation (7D, DD) is deleted.

Receive transparency processing—7D, 5E is replaced by 7E

Receive transparency processing—7D, 5D is replaced by 7D

Receive abort sequence the LAPS packet is dropped if 7D7E is detect

Self-synchronizing X⁴³+1 payload scrambling.

Frame indication due to bad address/control/SAPI, FCS error, abort sequence or frame size longer

than preset max

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

2.5 Additional HDLC Controllers in the Integrated T1/E1/J1 Transceiver

•

Two additional independent HDLC controllers

Fast load and unload features for FIFOs

SS7 support for FISU transmit and receive

Independent 128-byte Rx and Tx buffers with interrupt support

Access FDL, Sa, or single/multiple DS0 channels

DS0 access includes Nx64 or Nx56

Compatible with polled or interrupt driven environments

Bit-oriented code (BOC) support

2.6 Committed Information Rate (CIR) Controller

•

CIR Rate controller limits transmission of data from the Ethernet interface to the serial interface

CIR granularity at 512kbit/s

CIR averaging for smoothing traffic peaks

2.7 SDRAM Interface

•

Interface for 128Mb, 32-bit-wide SDRAM

SDRAM Interface speed up to 100MHz

Auto refresh timing

Automatic precharge

Master clock provided to the SDRAM

No external components required for SDRAM connectivity

2.8 MAC Interface

•

MAC port with standard MII (less TX_ER) or RMII

10Mbps and 100Mbps Data rates

Configurable DTE or DCE modes

Facilitates auto-negotiation by host microprocessor

Programmable half and full-duplex modes

Flow control for both half-duplex (back-pressure) and full-duplex (PAUSE) modes

Programmable Maximum MAC frame size up to 2016 bytes

Minimum MAC frame size: 64 bytes

Discards frames greater than programmed maximum MAC frame size and runt, nonoctet bounded, or

bad-FCS frames upon reception

•

Configurable for promiscuous broadcast-discard mode.

Programmable threshold for SDRAM queues to initiate flow control and status indication

MAC loopback support for transmit data looped to receive data at the MII/RMII interface

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

2.9 T1/E1/J1 Line Interface

•

Requires only a 2.048MHz master clock for both E1 and T1 operation with the option to use 1.544MHz

for T1 operation

•

Fully software configurable

Short-haul and long-haul applications

Automatic receive sensitivity adjustments

Ranges include 0 to 43dB or 0 to 12dB for E1 applications and 0 to 13dB or 0 to 36dB for T1

applications

•

Receive level indication in 2.5dB steps from -42.5dB to -2.5dB

Internal receive termination option for 75Ω, 100Ω, and 120Ω lines

Internal transmit termination option for 75Ω, 100Ω, and 120Ω lines

Monitor application gain settings of 20dB, 26dB, and 32dB

G.703 receive synchronization-signal mode

Flexible transmit waveform generation

T1 DSX-1 line build-outs

T1 CSU line build-outs of -7.5dB, -15dB, and -22.5dB

E1 waveforms include G.703 waveshapes for both 75Ω coax and 120Ω twisted cables

AIS generation independent of loopbacks

Alternating ones and zeros generation

Square-wave output

Open-drain output option

NRZ format option

Transmitter power-down

Transmitter 50mA short-circuit limiter with current-limit-exceeded indication

Transmit open-circuit-detected indication

Line interface function can be completely decoupled from the framer/formatter

2.10 Clock Synthesizer

•

Output frequencies include 2.048MHz, 4.096MHz, 8.192MHz, and 16.384MHz

Derived from recovered receive clock

2.11 Jitter Attenuator

•

32-bit or 128-bit crystal-less jitter attenuator

Requires only a 2.048MHz master clock for both E1 and T1 operation with the option to use 1.544MHz

for T1 operation

•

Can be placed in either the receive or transmit path or disabled

Limit trip indication

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

2.12 T1/E1/J1 Framer

•

Fully independent transmit and receive functionality

Full receive and transmit path transparency

T1 framing formats include D4 (SLC-96) and ESF

Detailed alarm and status reporting with optional interrupt support

Large path and line error counters for:

T1: BPV, CV, CRC6, and framing bit errors

E1: BPV, CV, CRC4, E-bit, and frame alignment errors

•

Timed or manual update modes

DS1 idle code generation on a per-channel basis in both transmit and receive paths

User-defined

Digital milliwatt

•

ANSI T1.403-1998 Support

RAI-CI detection and generation

AIS-CI detection and generation

E1 ETS 300 011 RAI generation

G.965 V5.2 link detect

Ability to monitor one DS0 channel in both the transmit and receive paths

In-band repeating pattern generators and detectors

Three independent generators and detectors

Patterns from 1 to 8 bits or 16 bits in length

•

RCL, RLOS, RRA, and RAIS alarms interrupt on change-of-state

Flexible signaling support

Software or hardware based

Interrupt generated on change of signaling data

Receive signaling freeze on loss-of-sync, carrier loss, or frame slip

•

Addition of hardware pins to indicate carrier loss and signaling freeze

Automatic RAI generation to ETS 300 011 specifications

Access to Sa and Si bits

Option to extend carrier loss criteria to a 1ms period as per ETS 300 233

Japanese J1 support

Ability to calculate and check CRC6 according to the Japanese standard

Ability to generate Yellow Alarm according to the Japanese standard

2.13 TDM Bus

•

Dual two-frame independent receive and transmit elastic stores

Independent control and clocking

Controlled slip capability with status

Minimum delay mode supported

•

Programmable output clocks for fractional T1, E1, H0, and H12 applications

Hardware signaling capability

Receive signaling reinsertion to a backplane multiframe sync

Availability of signaling in a separate PCM data stream

Signaling freezing

•

Ability to pass the T1 F-bit position through the elastic stores in the 2.048MHz backplane mode

Access to the data streams in between the framer/formatter and the elastic stores

User-selectable synthesized clock output

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

2.14 Test and Diagnostics

•

IEEE 1149.1 support

Programmable on-chip bit error-rate tester (BERT)

Pseudorandom patterns including QRSS

User-defined repetitive patterns

Daly pattern

Error insertion single and continuous

Total bit and errored bit counts

Payload error insertion

Error insertion in the payload portion of the T1 frame in the transmit path

Errors can be inserted over the entire frame or selected channels

Insertion options include continuous and absolute number with selectable insertion rates

F-bit corruption for line testing

Loopbacks: remote, local, analog, and per-channel loopback

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

2.15 Specifications Compliance

The DS33R11 meets relevant telecommunications specifications. The following table provides the specifications

and relevant sections that are applicable to the DS33R11.

Table 2-1. T1-Related Telecommunications Specifications

IEEE 802.3-2002—CSMA/CD access method and physical layer specifications.

RFC1662—PPP in HDLC-like Framing

RFC2615—PPP over SONET/SDH

X.86—Ethernet over LAPS

RMII—Industry Implementation Agreement for “Reduced MII Interface,” Sept 1997

ANSI: T1.403-1995, T1.231–1993, T1.408

AT&T: TR54016, TR62411

ITU-T: G.703, G.704, G.706, G.736, G.775, G.823, G.932, I.431, O.151, Q.161,

Recommendation I.432–03/93 B-ISDN User-Network Interface—Physical Layer Specification

ETSI: ETS 300 011, ETS 300 166, ETS 300 233, CTR12, CTR4

Japanese: JTG.703, JTI.431, JJ-20.11 (CMI Coding Only)

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

3 APPLICATIONS

The DS33R11 is ideal for application areas such as transparent LAN service, LAN extension, and Ethernet delivery

over T1/E1/J1, T3/E3, OC-1/EC-1, G.SHDSL, or HDSL2/4.

For an example of a complete LAN-to-WAN design, refer to Application Note 3411: DS33Z11—Ethernet LAN to

Unframed T1/E1 WAN Bridge, available on our website at www.maxim-ic.com/telecom.

Figure 3-1. Ethernet-to-WAN Extension (With or Without Framing)

RMII, MII

T1/E1/J1

10 Base T

Stream

100 Base T

Inter-Building

LAN Extension

DS33R11

Ethernet

Clock

Sources

SDRAM

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

4 ACRONYMS AND GLOSSARY

•

BERT: Bit Error-Rate Tester

DCE: Data Communication Interface

DTE: Data Terminating Interface

FCS: Frame Check Sequence

HDLC: High-Level Data Link Control

MAC: Media Access Control

MII: Media Independent Interface

RMII: Reduced Media Independent Interface

WAN: Wide Area Network

Note 1: Previous versions of this document used the term “Subscriber” to refer to the Ethernet Interface function.

The register names have been allowed to remain with a “SU.” prefix to avoid register renaming.

Note 2: Previous versions of this document used the term “Line” to refer to the Serial Interface. The register names

have been allowed to remain with a “LI.” prefix to avoid register renaming.

Note 3: The terms “Transmit Queue” and “Receive Queue” are with respect to the Ethernet Interface. The Receive

Queue is the queue for the data that arrives on the MII/RMII interface, is processed by the MAC and stored in the

SDRAM. Transmit queue is for data that arrives from the Serial port, is processed by the HDLC and stored in the

SDRAM to be sent to the MAC transmitter.

Note 4: This data sheet assumes a particular nomenclature of the T1 operating environment. In each 125μs frame

there are 24 8-bit channels plus a framing bit. It is assumed that the framing bit is sent first followed by channel 1.

Each channel is made up of eight bits that are numbered 1 to 8. Bit number 1 is the MSB and is transmitted first.

Bit number 8 is the LSB and is transmitted last. The term “locked” is used to refer to two clock signals that are

phase- or frequency-locked or derived from a common clock (i.e., a 1.544MHz clock can be locked to a 2.048MHz

clock if they share the same 8kHz component). Throughout this data sheet, the following abbreviations are used:

B8ZS

BOC

CRC

Bipolar with 8 Zero Substitution

Bit-Oriented Code

Cyclical Redundancy Check

Superframe (12 frames per multiframe) Multiframe Structure

Extended Superframe (24 frames per multiframe) Multiframe Structure

Facility Data Link

ESF

FDL

FPS

Framing Pattern Sequence in ESF

Signaling Framing Pattern in D4

Terminal Framing Pattern in D4

High-Level Data Link Control

HDLC

Multiframe

SLC–96

Subscriber Loop Carrier—96 Channels

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

5 MAJOR OPERATING MODES

Microprocessor control is possible through the 8-bit parallel control port and provides configuration for all the

features of the device. The Ethernet Link Transport Engine in the device can be configured for HDLC or X.86

encapsulation.

The integrated transceiver can be software configured for T1, E1, or J1 operation. It is composed of a line interface

unit (LIU), framer, two additional HDLC controllers, and a TDM backplane interface, and is controlled via an 8-bit

parallel port configured for Intel or Motorola bus operations.

The LIUs are composed of a transmit interface, receive interface, and a jitter attenuator. The transmit interface is

responsible for generating the necessary waveshapes for driving the network and providing the correct source

impedance depending on the type of media used. T1 waveform generation includes DSX-1 line build-outs as well

as CSU line build-outs of -7.5dB, -15dB, and -22.5dB. E1 waveform generation includes G.703 waveshapes for

both 75Ω coax and 120Ω twisted cables. The receive interface provides network termination and recovers clock

and data from the network. The receive sensitivity adjusts automatically to the incoming signal and can be

programmed for 0dB to 43dB or 0dB to 12dB for E1 applications and 0dB to 15dB or 0dB to 36dB for T1

applications. The jitter attenuator removes phase jitter from the transmitted or received signal. The crystal-less jitter

attenuator requires only a 2.048MHz MCLK for both E1 and T1 applications (with the option of using a 1.544MHz

MCLK in T1 applications) and can be placed in either transmit or receive data paths.

More information on microprocessor control is available in Section 8.1.

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

6 BLOCK DIAGRAMS

Figure 6-1. Main Block Diagram

μP Port

CLAD

SYSCLKI

(RMII MODE)

RXD[0:1]

RX_CLK

CRS_DV

RX_ERR

TTIP

MUX

TRING

HDLC

REF_CLK

REF_CLKO

BERT

ARBITER

HDLC

TX_EN

TXD[0:1]

RTIP

MUX

RRING

MDC

MDIO

JTAG2

JTAG1

SDRAM PORT

NOTE: SOME PINS NOT SHOWN. THE BLOCK IN THE DIAGRAM LABELED “T1/E1/J1 TRANSCEIVER” IS

DIVIDED INTO THREE FUNCTIONAL BLOCKS: LIU, FRAMER, AND BACKPLANE INTERFACE OUTLINED IN

THE FOLLOWING DIAGRAMS.

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

Figure 6-2. Block Diagram of T1/E1/J1 Transceiver

CLOCK

EXTERNAL ACCESS

TO RECEIVE SIGNALS

CLOCK

ADAPTER

HDB3 / B8ZS

SYNC

BACKPLANE

CLOCK SYNTH

LIU

MUX

SINGALING

ALARM DET

HDLCs

BACKPLANE

INTERFACE

CIRCUIT

FRAMER

SINGALING

ALARM GEN

HDLCs

LIU

MUX

CRC GEN

HDB3 / B8ZS

EXTERNAL ACCESS

TO TRANSMIT SIGNALS

LIU

FRAMER

BACKPLANE

INTERFACE

JTAG HOST INTERFACE ESIB

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

Figure 6-3. Receive and Transmit T1/E1/J1 LIU

RCL

VCO / PLL

MUX

32.768MHz

JACLK

RPOS

RCLK

RNEG

RRING

RTIP

TRING

TTIP

TNEG

TCLK

TPOS

INTERNAL

SIGNALS

MUX

FRAMER

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

Figure 6-4. Receive and Transmit T1/E1/J1 Framer

REC

HDLC #1

HDLC #2

128 Byte

FIFO

128 Byte

FIFO

MAPPER

DATA

CLOCK

SYNC

DATA

CLOCK

SYNC

CLOCK

DATA

RPOS

RNEG

RCLK

RECEIVE

FRAMER

SYNC

TPOS

TNEG

TCLK

TRANSMIT

FRAMER

CLOCK

DATA

MAPPER

INTERNAL

SIGNALS

FROM

INTERNAL

SIGNALS

BACKPLANE

INTERFACE

XMIT

HDLC #1

XMIT

HDLC #2

LIU

128 Byte

FIFO

128 Byte

FIFO

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

Figure 6-5. T1/E1/J1 Backplane Interface

Sa BIT/FDL

EXTRACTION

RLINK

RLCLK

RSIG

RSIGFR

SIGNALING

BUFFER

DATA

CLOCK

SYNC

RSYSCLK

RSERO

RCLKO

RSYNC

RMSYNC

ELASTIC

STORE

RFSYNC

RDATA

INTERNAL

SIGNALS

FROM

RCHCLK

RCHBLK

CHANNEL

TIMING

FRAMER

SYNC

TSERI

TSIG

TSSYNC

SIGNALING

BUFFER

Sa/FDL

INSERT

ELASTIC

STORE

DATA

TSYSCLK

TSYNC

CLOCK

TESO

TDATA

TLCLK

TLINK

CHANNEL

TIMING

TCHCLK

TCHBLK

TCLK

MUX

TCLKT

JACLK

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

7 PIN DESCRIPTIONS

7.1 Pin Functional Description

Note that all digital pins are IO pins in JTAG mode. This feature increases the effectiveness of board level ATPG

patterns.

LEGEND: I = input, O = output, Ipu = input with pullup, Oz = output with tri-state, IO = bidirectional pin, IOz = bidirectional pin with tri-state.

Table 7-1. Detailed Pin Descriptions

NAME

TYPE

FUNCTION

MICROPROCESSOR PORT

Address Bit 0: Address bit 0 of the microprocessor interface.

Least Significant Bit.

A18

B18

C18

A17

B17

C17

A16

B16

C16

C15

Address Bit 1: Address bit 1 of the microprocessor interface.

Address Bit 2: Address bit 2 of the microprocessor interface.

Address Bit 3: Address bit 3 of the microprocessor interface.

Address Bit 4: Address bit 4 of the microprocessor interface.

Address Bit 5: Address bit 5 of the microprocessor interface.

Address Bit 6: Address bit 6 of the microprocessor interface.

Address Bit 7: Address bit 7 of the microprocessor interface.

Address Bit 8: Address bit 8 of the microprocessor interface.

Address Bit 9: Address bit 9 of the microprocessor interface.

Data Bit 0: Bidirectional data bit 0 of the microprocessor interface.

Least Significant Bit. Not driven when CS =1 or RST = 0.

Data Bit 1: Bidirectional data bit 1 of the microprocessor interface.

Not driven when CS = 1 or RST = 0.

Data Bit 2: Bidirectional data bit 2 of the microprocessor interface.

Not driven when CS = 1 or RST = 0.

Data Bit 3: Bidirectional data bit 3 of the microprocessor interface.

Not driven when CS = 1 or RST = 0.

Data Bit 4: Bidirectional data bit 4 of the microprocessor interface.

Not driven when CS = 1 or RST = 0.

Data Bit 5: Bidirectional data bit 5 of the microprocessor interface.

Not driven when CS = 1 or RST = 0.

A14

B14

C14

A13

B13

C13

A12

B12

IOZ

Data Bit 6: Bidirectional data bit 6 of the microprocessor interface.

Not driven when CS = 1 or RST = 0.

Data Bit 7: Bidirectional data bit 7 of the microprocessor interface.

Most Significant Bit. Not driven when CS = 1 or RST = 0.

Write (Intel Mode): The DS33R11 captures the contents of the

data bus (D0-D7) on the rising edge of WR and writes them to the

addressed register location. CS must be held low during write

operations.

C11

WR/RW

Read Write (Motorola Mode): Used to indicate read or write

operation. RW must be set high for a register read cycle and low for

a register write cycle.

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

NAME

TYPE

FUNCTION

Read Data Strobe (Intel Mode): The DS33R11 drives the data bus

(D0-D7) with the contents of the addressed register while RD and

CS are both low.

B11

RD/DS

Data Strobe (Motorola Mode): Used to latch data through the

microprocessor interface. DS must be low during read and write

operations.

Chip Select for Protocol Conversion Device: This pin must be

taken low for read/write operations. When CS is high, the RD/DS

and WR signals are ignored.

A11

Chip Select for the T1/E1/J1 Transceiver: Must be low to read or

write the T1/E1/J1 transceiver.

CST

Interrupt Output: Outputs a logic zero when an unmasked

interrupt event is detected. INT is deasserted when all interrupts

have been acknowledged and serviced. Active low. Inactive state is

programmable in register GL.CR1. is deasserted when all

interrupts have been acknowledged and serviced. Active low.

Inactive state is programmable in register GL.CR1.

A10

INT

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

NAME

TYPE

FUNCTION

MII/RMII PHY PORT

Collision Detect (MII): Asserted by the MAC PHY to indicate that a

collision is occurring. In DCE Mode this signal should be connected

to ground. This signal is only valid in half duplex mode, and is

ignored in full duplex mode.

COL_DET

N18

Receive Carrier Sense (MII): Should be asserted (high) when data

from the PHY (RXD[3:0) is valid. For each clock pulse 4 bits arrive

from the PHY. Bit 0 is the least significant bit. In DCE mode,

connect to V_DD.

RX_CRS/

CRS_DV

M19

M20

Carrier Sense/Receive Data Valid (RMII): This signal is asserted

(high) when data is valid from the PHY. For each clock pulse 2 bits

arrive from the PHY. In DCE mode, this signal must be grounded.

Receive Clock (MII): Timing reference for RX_DV, RX_ERR and

RXD[3:0], which are clocked on the rising edge. RX_CLK frequency

is 25MHz for 100Mbit/s operation and 2.5MHz for 10Mbit/s

operation. In DTE mode, this is a clock input provided by the PHY.

In DCE mode, this is an output derived from REF_CLK providing

2.5MHz (10Mbit/s operation) or 25MHz (100Mbit/s operation).

RX_CLK

Receive Data 0 through 3 (MII): Four bits of received data,

sampled synchronously with the rising edge of RX_CLK. For every

clock cycle, the PHY transfers 4 bits to the DS33R11. RXD[0] is the

least significant bit of the data. Data is not considered valid when

RX_DV is low.

RXD[0]

RXD[1]

RXD[2]

RXD[3]

L18

L19

L20

M18

Receive Data 0 through 1 (RMII): Two bits of received data,

sampled synchronously with REF_CLK with 100Mbit/s mode.

Accepted when CRS_DV is asserted. When configured for

10Mbit/s mode, the data is sampled once every 10 clock periods.

Receive Data Valid (MII): This active high signal indicates valid

data from the PHY. The data RXD is ignored if RX_DV is not

asserted high.

RX_DV

K19

Receive Error (MII): Asserted by the MAC PHY for one or more

RX_CLK periods indicating that an error has occurred. Active High

indicates Receive code group is invalid. If CRS_DV is low,

RX_ERR has no effect. This is synchronous with RX_CLK. In DCE

mode, this signal must be grounded.

RX_ERR

K18

Receive Error (RMII): Signal is synchronous to REF_CLK.

Transmit Clock (MII): Timing reference for TX_EN and TXD[3:0].

The TX_CLK frequency is 25MHz for 100Mbit/s operation and

2.5MHz for 10Mbit/s operation.

TX_CLK

H19

In DTE mode, this is a clock input provided by the PHY. In DCE

mode, this is an output derived from REF_CLK providing 2.5MHz

(10Mbit/s operation) or 25MHz (100Mbit/s operation).

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

NAME

TYPE

FUNCTION

Transmit Data 0 through 3(MII): TXD [3:0] is presented

synchronously with the rising edge of TX_CLK. TXD [0] is the least

significant bit of the data. When TX_EN is low the data on TXD

should be ignored.

TXD[0]

F19

TXD[1]

TXD[2]

F18

E20

Transmit Data 0 through 1(RMII): Two bits of data TXD [1:0]

presented synchronously with the rising edge of REF_CLK.

TXD[3]

TX_EN

E19

F20

Transmit Enable (MII): This pin is asserted high when data TXD

[3:0] is being provided by the DS33R11. The signal is deasserted

prior to the first nibble of the next frame. This signal is synchronous

with the rising edge TX_CLK. It is asserted with the first bit of the

preamble.

Transmit Enable (RMII): When this signal is asserted, the data on

TXD [1:0] is valid. This signal is synchronous to the REF_CLK.

Reference Clock (RMII and MII): When in RMII mode, all signals

from the PHY are synchronous to this clock input for both transmit

and receive. This required clock can be up to 50MHz and should

have ±100ppm accuracy.

When in MII mode in DCE operation, the DS33R11 uses this input

to generate the RX_CLK and TX_CLK outputs as required for the

Ethernet PHY interface. When the MII interface is used with DTE

operation, this clock is not required and should be tied low.

REF_CLK

A19

A20

In DCE and RMII modes, this input must have a stable clock input

before setting the RST pin high for normal operation.

Reference Clock Output (RMII and MII): A derived clock output

up to 50MHz, generated by internal division of the SYSCLKI signal.

Frequency accuracy of the REF_CLKO signal will be proportional

to the accuracy of the user-supplied SYSCLKI signal. See Section

9.1.1 for more information.

REF_CLKO

DCE or DTE Selection: The user must set this pin high for DCE

Mode selection or low for DTE Mode. In DCE Mode, the DS33R11

MAC port can be directly connected to another MAC. In DCE

Mode, the Transmit clock (TX_CLK) and Receive clock (RX_CLK)

are output by the DS33R11. Note that there is no software bit

selection of DCEDTES. Note that DCE Mode is only relevant when

the MAC interface is in MII mode.

DCEDTES

RMIIMIIS

G20

G19

RMII or MII Selection: Set high to configure the MAC for RMII

interfacing. Set low for MII interfacing.

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

NAME

TYPE

FUNCTION

PHY MANAGEMENT BUS

Management Data Clock (MII): Clocks management data between

the PHY and DS33R11. The clock is derived from theSYSCLKI,

with a maximum frequency is 1.67MHz. The user must leave this

pin unconnected in the DCE Mode.

MDC

C19

MII Management data IO (MII): Data path for control information

between the PHY and DS33R11. When not used, pull to logic high

externally through a 10kΩ resistor. The MDC and MDIO pins are

used to write or read up to 32 Control and Status Registers in 32

PHY Controllers. This port can also be used to initiate Auto-

Negotiation for the PHY. The user must leave this pin unconnected

in the DCE Mode.

MDIO

C20

SDRAM INTERFACE

SDRAM Column Address Strobe: Active-low output, used to latch

the column address on the rising edge of SDCLKO. It is used with

commands for Bank Activate, Precharge, and Mode Register Write.

SCAS

SRAS

SDRAM Row Address Strobe: Active-low output, used to latch

the row address on rising edge of SDCLKO. It is used with

commands for Bank Activate, Precharge, and Mode Register Write.

V10

SDRAM Chip Select: Active-low output enables SDRAM access.

SDCS

SWE

SDRAM Write Enable: This active-low output enables write

operation and auto precharge.

W10

SDRAM Bank Select: These 2 bits select 1 of 4 banks for the

read/write/precharge operations.

SBA[0]

SBA[1]

Y11

V11

Note: All SDRAM operations are controlled entirely by the

DS33R11. No user programming for SDRAM buffering is required.

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

NAME

SDATA[0]

SDATA[1]

SDATA[2]

SDATA[3]

SDATA[4]

SDATA[5]

SDATA[6]

SDATA[7]

SDATA[8]

SDATA[9]

SDATA[10]

SDATA[11]

SDATA[12]

SDATA[13]

SDATA[14]

SDATA[15]

SDATA[16]

SDATA[17]

SDATA[18]

SDATA[19]

SDATA[20]

SDATA[21]

SDATA[22]

SDATA[23]

SDATA[24]

SDATA[25]

SDATA[26]

SDATA[27]

SDATA[28]

SDATA[29]

SDATA[30]

SDATA[31]

SDA[0]

Y16

Y17

V18

Y19

V19

Y20

U19

W20

U20

T19

T20

Y18

W19

V17

W17

W16

W14

W12

Y15

W15

Y14

V13

W13

Y12

V12

Y10

V14

W11

TYPE

FUNCTION

SDRAM Data Bus Bits 0 to 31: The 32 pins of the SDRAM data

bus are inputs for read operations and outputs for write operations.

At all other times, these pins are high-impedance.

Note: All SDRAM operations are controlled entirely by the

DS33R11. No user programming for SDRAM buffering is required.

SDA[1]

SDA[2]

SDA[3]

SDA[4]

SDA[5]

SDA[6]

SDA[7]

SDA[8]

SDRAM Address Bus 0 to 11: The 12 pins of the SDRAM address

bus output the row address first, followed by the column address.

The row address is determined by SDA0 to SDA11 at the rising

edge of clock. Column address is determined by SDA0-SDA9 and

SDA11 at the rising edge of the clock. SDA10 is used as an auto-

precharge signal.

Note: All SDRAM operations are controlled entirely by the

DS33R11. No user programming for SDRAM buffering is required.

SDA[9]

SDA[10]

SDA[11]

SDMASK[0]

SDMASK[1]

SDMASK[2]

SDMASK[3]

SDRAM Mask 0 through 3: When high, a write is done for that

byte. The least significant byte is SDATA7 to SDATA0. The most

significant byte is SDATA31 to SDATA24.

V16

V15

(4mA)

SDRAM CLK Out: System clock output to the SDRAM. This clock

is a buffered version of SYSCLKI.

SDCLKO

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

NAME

TTIP

TYPE

FUNCTION

T1/E1/J1 ANALOG LINE INTERFACE

Transmit Analog Tip Output for the T1/E1/J1 Transceiver:

Analog line-driver outputs. Two connections are provided to

improve signal quality. These pins connect via a 1:2 step-up

transformer to the network. See Section 10.24 for details.

Transmit Analog Ring Output for the T1/E1/J1 Transceiver:

Analog line-driver outputs. Two connections are provided to

improve signal quality. These pins connect via a 1:2 step-up

transformer to the network. See Section 10.24 for details.

Receive Analog Tip Input for the T1/E1/J1 Transceiver: Analog

input for clock recovery circuitry. These pins connect via a 1:1

transformer to the network. See Section 10.24 for details

Receive Analog Ring Input for the T1/E1/J1 Transceiver:

Analog input for clock recovery circuitry. These pins connect via a

1:1 transformer to the network. See Section 10.24 for details

R1, R2

T1,T2

TRING

RTIP

RRING

T1/E1/J1 TRANSMIT FRAMER INTERFACE

Transmit Serial Data Input to the T1/E1/J1 Framer: Transmit

NRZ serial data. Sampled on the falling edge of TCLKT when the

transmit-side elastic store is disabled. Sampled on the falling edge

of TSYSCLK when the transmit-side elastic store is enabled.

Transmit Clock for the T1/E1/J1 Transceiver: 1.544MHz or a

2.048MHz primary clock. Used to clock data from the TSERI pin

through the transmit-side formatter.

TSERI

TCLKT

Transmit Channel Block for the T1/E1/J1 Transceiver: A user-

programmable output that can be forced high or low during any of

the channels. Synchronous with TCLKT when the transmit-side

elastic store is disabled. Synchronous with TSYSCLK when the

transmit-side elastic store is enabled. Useful for locating individual

channels in drop-and-insert applications, for external per-channel

loopback, and for per-channel conditioning.

Transmit Channel Clock for the T1/E1/J1 Transceiver: A

192kHz (T1) or 256kHz (E1) clock that pulses high during the LSB

of each channel. Can also be programmed to output a gated

transmit-bit clock for fractional T1/E1 applications. Synchronous

with TCLKT when the transmit-side elastic store is disabled.

Synchronous with TSYSCLK when the transmit-side elastic store is

enabled. Useful for parallel-to-serial conversion of channel data.

Transmit System Sync for the T1/E1/J1 Transceiver: Only used

when the transmit-side elastic store is enabled. A pulse at this pin

will establish either frame or multiframe boundaries for the transmit

side. Should be tied low in applications that do not use the transmit-

side elastic store.

Transmit Sync for the T1/E1/J1 Transceiver: A pulse at this pin

will establish either frame or multiframe boundaries for the transmit

side. Can be programmed to output either a frame or multiframe

pulse. If this pin is set to output pulses at frame boundaries, it can

also be set via TR.IOCR1.3 to output double-wide pulses at

signaling frames in T1 mode.

Transmit System Clock for the T1/E1/J1 Transceiver:

1.544MHz, 2.048MHz, 4.096MHz, 8.192MHz, or 16.384MHz clock.

Only used when the transmit-side elastic-store function is enabled.

Should be tied low in applications that do not use the transmit-side

elastic store.

TCHBLK

TCHCLK

TSSYNC

TSYNC

I/O

TSYSCLK

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

NAME

TYPE

FUNCTION

Transmit Signaling Input for the T1/E1/J1 Transceiver: When

enabled, this input will sample signaling bits for insertion into

outgoing PCM data stream. Sampled on the falling edge of TCLKT

when the transmit-side elastic store is disabled. Sampled on the

falling edge of TSYSCLK when the transmit-side elastic store is

enabled.

TSIG

ETHERNET MAPPER TRANSMIT SERIAL INTERFACE

Transmit Serial Data Output from Ethernet Mapper: Output on

the rising edge of TCLKE. Selective clock periods can be skipped

for output of TSERO with a gapped clock input on TCLKE. The

maximum data rate is 52Mbit/s.

Serial Interface Transmit Clock Input to Ethernet Mapper: The

clock reference for TSERO, which is output on the rising edge of

the clock. TCLKE supports gapped clocking, up to a maximum

frequency of 52MHz.

TSERO

TCLKE

Transmit Data Enable (Input): The transmit data enable is

programmable to selectively block/enable the transmit data. The

TDEN signal must occur one clock edge prior to the affected data

bit. The active polarity of TDEN is programmable in register

LI.TSLCR. It is recommended for both T1/E1 and T3/E3

applications that use gapped clocks. The TDEN signal is provided

for interfacing to framers that do not have a gapped clock facility.

TDEN/

TBSYNC

Transmit Byte Sync (Output): This output can be used by an

external Serial to Parallel to convert TSERO stream to byte wide

data. This output indicates the last bit of the byte data sent serially

on TSERO. This signal is only active in the X.86 Mode.

T1/E1/J1 RECEIVE FRAMER INTERFACE

Receive Serial Data for T1/E1/J1 Transceiver: Received NRZ

serial data. Updated on rising edges of RCLKO when the receive-

side elastic store is disabled. Updated on the rising edges of

RSYSCLK when the receive-side elastic store is enabled.

Receive Clock Output from the T1/E1/J1 Framer: 1.544MHz (T1)

RSERO

RCLKO

or 2.048MHz (E1) clock that is used to clock data through the

receive-side framer. Normally connected to the RCLKI input.

Receive Channel Block for the T1/E1/J1 Transceiver: A user-

programmable output that can be forced high or low during any of

the 24 T1 or 32 E1 channels. Synchronous with RCLKO when the

receive-side elastic store is disabled. Synchronous with RSYSCLK

when the receive-side elastic store is enabled. Also useful for

locating individual channels in drop-and-insert applications, for

external per-channel loopback, and for per-channel conditioning.

See the Channel Blocking Registers section.

Receive Channel Clock for the T1/E1/J1 Transceiver: A 192kHz

(T1) or 256kHz (E1) clock that pulses high during the LSB of each

channel can also be programmed to output a gated receive-bit

clock for fractional T1/E1 applications. Synchronous with RCLKO

when the receive-side elastic store is disabled. Synchronous with

RSYSCLK when the receive-side elastic store is enabled. Useful

for parallel-to-serial conversion of channel data.

RCHBLK

RCHCLK

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

NAME

TYPE

FUNCTION

Receive Sync for the T1/E1/J1 Transceiver: An extracted pulse,

one RCLKO wide, is output at this pin, which identifies either frame

(TR.IOCR1.5 = 0) or multiframe (TR.IOCR1.5 = 1) boundaries. If

set to output-frame boundaries then via TR.IOCR1.6, RSYNC can

also be set to output double-wide pulses on signaling frames in T1

mode. If the receive-side elastic store is enabled, then this pin can

be enabled to be an input via TR.IOCR1.4 at which a frame or

multiframe boundary pulse is applied.

RSYNC

I/O

Receive System Clock for the Transceiver: 1.544MHz,

2.048MHz, 4.096MHz, or 8.192MHz clock. Only used when the

receive-side elastic-store function is enabled. Should be tied low in

applications that do not use the receive-side elastic store.

Receive Frame Sync (Pre Receive Elastic Store) for T1/E1/J1

Transceiver: An extracted 8kHz pulse, one RCLKO wide, is output

at this pin, which identifies frame boundaries.

Receive Multiframe Sync for the T1/E1/J1 Transceiver: An

extracted pulse, one RCLKO wide (elastic store disabled) or one

RSYSCLK wide (elastic store enabled), is output at this pin, which

identifies multiframe boundaries.

RSYSCLK

RFSYNC

RMSYNC

Receive Signaling Output: Outputs signaling bits in a PCM

format. Updated on rising edges of RCLKO when the receive-side

elastic store is disabled. Updated on the rising edges of RSYSCLK

when the receive-side elastic store is enabled.

RSIG

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

NAME

TYPE

FUNCTION

ETHERNET MAPPER RECEIVE SERIAL INTERFACE

Receive Serial Data Input to Ethernet Mapper: Receive Serial

RSERI

RCLKI

data arrives on the rising edge of RCLKI. Normally connected to

RSERO.

Serial Interface Receive Clock Input to the Ethernet Mapper:

Reference clock for receive serial data on RSERI. Gapped clocking

is supported, up to the maximum RCLKI frequency of 52 MHz.

Receive Data Enable for the Ethernet Mapper: The receive data

enable is programmable to block the receive data. The RDEN must

be coincident with the RSERI data bit to be blocked or enabled.

The active polarity of RDEN is programmable in register LI.RSLCR.

It is recommended for both T1/E1 and T3/E3 applications that use

gapped clocks. The RDEN signal is provided for interfacing to

framers that do not have a gapped clock facility.

RDEN/

RBSYNC

Receive Byte Synchronization Input: Provides byte

synchronization input to X.86 decoder. This signal will go high at

the last bit of the byte as it arrives. This signal can occur at

maximum rate every 8 bits. Note that a long as the R11 receives

one RBSYNC indicator. The X.86 receiver will determine the byte

boundary. Hence the R11 does not require a continuous 8 bit sync

indicator. A new sync pulse is required if the byte boundary

changes.

T1/E1/J1 FRAMER/LIU INTERIM SIGNALS

Receive Clock Input to the T1/E1/J1 Framer: Clock used to clock

data through the receive-side framer. This pin is normally

connected to RDCLKO. Can be internally connected to RDCLKO

by connecting the LIUC pin high.

Receive Clock Output from the T1/E1/J1 LIU: Buffered

recovered clock from the network. This pin is normally connected to

RDCLKI.

Receive Negative-Data Input: Sampled on the falling edge of

RDCLKI for data to be clocked through the receive-side framer.

RPOSI and RNEGI can be connected together for an NRZ

interface. Can be internally connected to RNEGO by connecting

the LIUC pin high.

Receive Negative Data Output from the T1/E1/J1 LIU: Updated

on the rising edge of RDCLKO with the bipolar data out of the line

interface. This pin is normally tied to RNEGI.

Receive Positive-Data Input to the T1/E1/J1 Framer: Sampled

on the falling edge of RDCLKI for data to be clocked through the

receive-side framer. RPOSI and RNEGI can be connected together

for an NRZ interface. Can be internally connected to RPOSO by

connecting the LIUC pin high.

RDCLKI

RDCLKO

RNEGI

RNEGO

RPOSI

Receive Positive-Data Output from the T1/E1/J1 LIU: Updated

on the rising edge of RDCLKO with bipolar data out of the line

interface. This pin is normally connected to RPOSI.

Receive Data from the T1/E1/J1 Framer: Updated on the rising

edge of RCLKO with the data out of the receive-side framer, before

passing through the Elastic Store.

Serial Interface Transmit Clock Input for the T1/E1/J1 LIU: Line

interface transmit clock. This pin is normally tied to TCLKO. Can be

internally connected to TCLKO by connecting the LIUC pin high.

RPOSO

RDATA

TDCLKI

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

NAME

TYPE

FUNCTION

Transmit Clock Output from the T1/E1/J1 Framer: Buffered

clock that is used to clock data through the transmit-side formatter

(either TCLKT or RDCLKI). This pin is normally tied to TDCLKI.

Transmit Negative-Data Input: Sampled on the falling edge of

TDCLKI for data to be transmitted out onto the T1 line. Can be

internally connected to TNEGO by connecting the LIUC pin high.

TPOSI and TNEGI can be connected together in NRZ applications.

Transmit Negative-Data Output: Updated on the rising edge of

TCLKO with the bipolar data out of the transmit-side formatter. This

pin is normally connected to TNEGI.

Transmit Positive-Data Input: Sampled on the falling edge of

TDCLKI for data to be transmitted out onto the T1 line. Can be

internally connected to TPOSO by connecting the LIUC pin high.

TPOSI and TNEGI can be connected together in NRZ applications.

Transmit Positive-Data Output: Updated on the rising edge of

TCLKO with the bipolar data out of the transmit-side formatter. Can

be programmed to source NRZ data by the output data format

(TR.IOCR1.0) control bit. This pin is normally connected to TPOSI.

Transmit Data: Sampled on the falling edge of TCLKT with data to

be clocked through the transmit-side formatter. This pin is normally

connected to TESO.

TDCLKO

TNEGI

TNEGO

TPOSI

TPOSO

TDATA

TESO

Transmit Elastic Store Output: Updated on the rising edge of

TCLKT with data out of the transmit-side elastic store whether the

elastic store is enabled or not. This pin is normally connected to

TDATA.

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

NAME

TYPE

FUNCTION

HARDWARE AND STATUS PINS

Line Interface Unit Connect: When a logic low is present on this

input pin, the T1/E1/J1 Framer and LIU are not internally

connected. The line interface circuitry will be separated from the

framer/formatter circuitry and the TPOSI, TNEGI, TDCLKI, RPOSI,

RNEGI, and RDCLKI input pins will be active.

LIUC

When a logic high is present on this input pin, the T1/E1/J1 Framer

is internally connected to the LIU. The TPOSI, TNEGI, TDCLKI,

RPOSI, RNEGI, RDCLKI input pins are deactivated. When LIUC is

connected high, the TPOSI, TNEGI, TDCLKI, RPOSI, RNEGI, and

RDCLKI pins should be tied low.

Reset for the Ethernet Mapper: An active low signal on this pin

resets the internal registers and logic of the protocol conversion

device. This pin should remain low until power, SYSCLKI, RX_CLK,

and TX_CLK are stable, then set high for normal operation. This

input requires a clean edge with a rise time of 25ns or less to

properly reset the device.

Test/Reset for the T1/E1/J1 Transceiver: A dual-function pin. A

zero-to-one transition issues a hardware reset to the transceiver

all output and I/O pins (including the parallel control port). Set low

for normal operation. Useful in board-level testing.

Mode Control for Processor Interface:

RST

TSTRST

00 = Read/Write Strobe Used (Intel Mode)

01 = Data Strobe Used (Motorola Mode)

10 = Reserved. Do not use.

MODEC[0],

MODEC[1]

B19,

B20

11 = Reserved. Do not use.

Queue Overflow for Ethernet Mapper: This pin goes high when

the transmit or receive queue has overflowed. This pin will go low

when the high watermark is reached again.

T1/E1/J1 Receive Loss-of-Sync/Loss-of-Transmit Clock: A dual

function output that is controlled by the CCR1.0 control bit. This pin

can be programmed to either toggle high when the synchronizer is

searching for the frame and multiframe or to toggle high if the

TCLKT pin has not been toggled for 5μs.

QOVF

H18

RLOS/LTC

T1/E1/J1 Receive Carrier Loss: Set high when the T1/E1/J1 line

interface detects a carrier loss.

T1/E1/J1 Receive Signaling-Freeze Output: Set high when the

signaling data is frozen by either automatic or manual intervention.

Used to alert downstream equipment of the condition.

RCL

RSIGF

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

NAME

TYPE

FUNCTION

SYSTEM CLOCKS

System Clock In for Ethernet Mapper: 100MHz System Clock

input to the DS33R11, used for internal operation. This clock is

buffered and provided at SDCLKO for the SDRAM interface. The

DS33R11 also provides a divided version output at the REF_CLKO

pin. A clock supply with ±100ppm frequency accuracy is suggested.

Master Clock Input for the T1/E1/J1 Transceiver: A (50ppm)

clock source. This clock is used internally for both clock/data

recovery and for the jitter attenuator for both T1 and E1 modes.

The clock rate can be 16.384MHz, 8.192MHz, 4.096MHz, or

2.048MHz. When using the transceiver in T1-only operation a

1.544MHz (50ppm) clock source can be used.

SYSCLKI

MCLK

Backplane Clock from T1/E1/J1 Transceiver: A user-selectable

synthesized clock output that is referenced to the clock that is

output at the RCLKO pin.

Eight Times Clock from the T1/E1/J1 Transceiver: An 8x clock

that is locked to the recovered network clock provided from the

clock/data recovery block (if the jitter attenuator is enabled on the

receive side) or from the TDCLKI pin (if the jitter attenuator is

enabled on the transmit side).

BPCLK

8XCLK

Quartz Crystal Driver for the T1/E1/J1 Transceiver: A quartz

crystal of 2.048MHz (optional 1.544MHz in T1-only operation) can

be applied across MCLK and XTALD instead of a clock source at

MCLK. Leave open circuited if a clock source is applied at MCLK.

XTALD

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

NAME

TYPE

FUNCTION

JTAG INTERFACE

JTAG Clock 1 for the Ethernet Mapper: This signal is used to

shift data into JTDI1 on the rising edge and out of JTDO1 on the

falling edge.

JTAG Data In 1 for the Ethernet Mapper: Test instructions and

data are clocked into this pin on the rising edge of JTCLK1. This

pin has a 10kΩ pullup resistor.

JTAG Data Out 1 for the Ethernet Mapper: Test instructions and

data are clocked out of this pin on the falling edge of JTCLK1. If not

used, this pin should be left unconnected.

JTCLK1

JTDI1

Ipu

JTDO1

JTAG Mode Select 1 for the Ethernet Mapper: This pin is

sampled on the rising edge of JTCLK1 and is used to place the test

access port into the various defined IEEE 1149.1 states. This pin

has a 10kΩ pullup resistor.

JTAG Reset 1 for the Ethernet Mapper: JTRST1 is used to

asynchronously reset the test access port controller. After power

up, a rising edge on JTRST1 will reset the test port and cause the

device I/O to enter the JTAG DEVICE ID mode. Pulling JTRST1

low restores normal device operation. JTRST1 is pulled HIGH

internally via a 10kΩ resistor operation. If boundary scan is not

used, this pin should be held low.

JTMS1

Ipu

JTRST1

JTAG Clock 2 for the T1/E1/J1 Transceiver: This signal is used

to shift data into JTDI1 on the rising edge and out of JTDO1 on the

falling edge.

JTAG Data In 2 for the T1/E1/J1 Transceiver: Test instructions

and data are clocked into this pin on the rising edge of JTCLK2.

This pin has a 10kΩ pullup resistor.

JTAG Data Out 2 for the T1/E1/J1 Transceiver: Test instructions

and data are clocked out of this pin on the falling edge of JTCLK2.

If not used, this pin should be left unconnected.

JTCLK2

JTDI2

Ipu

JTDO2

JTAG Mode Select 2 for the T1/E1/J1 Transceiver: This pin is

sampled on the rising edge of JTCLK2 and is used to place the

test-access port into the various defined IEEE 1149.1 states. This

pin has a 10kΩ pullup resistor.

JTAG Reset 2 for the T1/E1/J1 Transceiver: JTRST2 is used to

asynchronously reset the test access port controller. After power-

up, JTRST2 must be toggled from low to high. This action will set

the device into the JTAG DEVICE ID mode. Normal device

operation is restored by pulling JTRST2 low. JTRST2 is pulled HIGH

internally via a 10kΩ resistor operation.

JTMS2

Ipu

JTRST2

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

NAME

TYPE

FUNCTION

POWER SUPPLIES

RVDD

RVSS

TVDD

TVSS

K3, L1

J1, J2, K2,

L2, M2

P1, R3, T3,

—

–

Receive Analog Positive Supply: Connect to 3.3V power supply.

Receive Analog Signal Ground: Connect to the common supply

ground.

Transmit Analog Positive Supply: Connect to 3.3V power supply.

Transmit Analog Signal Ground: Connect to the common supply

ground.

–

D1–D17,

E17

N4, P4, R4,

DVDD

DVSS

—

Digital Positive Supply: Connect to 3.3V power supply.

Digital Signal Ground: Connect to the common supply ground.

B10, B15,

C12, F3,

J18, J20,

P18, P19,

R19, R20,

V9, Y9, Y13

D20, F17,

G17, G18,

H17, J17,

K17, L17,

M17, N17,

P17, R17,

R18, T17,

T18, U17

A15, C10,

D8, D9,

VDD1.8

VDD3

VDD1.8: Connect to 1.8V power supply.

VDD3.3: Connect to 3.3V power supply.

D10, D18,

D19, E18,

H20, J19,

K20, N19,

N20, P20,

U4–U16,

U18, V20,

W8, W18,

Y1, Y7

VSS

N.C.

VSS: Connect to the common supply ground.

No Connection. Do not connect these pins. Leave these pins

open.

A9, C6, D6

—

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

Figure 7-1. 256-Ball BGA Pinout

REF_

CLKO

RCHBLK TCHBLK RFSYNC TDATA TSSYNC JTCLK2 JTCLK1

RST

N.C.

INT

VSS

REF_CLK

MODEC MODEC

BPCLK

LIUC

TPOSI

TSIG

RCL

JTDI2

N.C.

JTDO1

JTRST1

CST

JTRST2

JTMS1

VSS

JTMS2

JTDI1

VSS

VDD1.8

VSS

RD/DS

VDD1.8

[0]

[1]

TSYNC TDCLKO TNEGI TSTRST JTDO2

TDEN/

WR/RW VDD1.8

MDC

MDIO

TDCLKI

TCLKT

TNEGO

TESO

N.C.

VSS

DVDD

VDD3

VSS

VDD3

TBSYNC

TXD

[3]

TXD

[2]

TPOSO TSERO

TSERI TSYSCLK

VDD1.8 RSYSCLK

TXD

[1]

TXD

[0]

TCLKE

RCLKI

TX_EN

DCE

DTES

TCHCLK RCHCLK RCLKO RSYNC

VDD3 RMIIMIIS

RSERI

RVSS

RTIP

RSERO RDATA

MCLK

XTALD

8XCLK

RNEGI

QOVF

TX_CLK

VSS

VDD1.8

VSS

RVSS

RPOSI

RVDD

RSIG

VDD1.8

RX_ERR RX_DV

RXD

[0]

RXD

[1]

RXD

[2]

RVDD

RRING

RXD RX_CRS /

[3]

RVSS RDCLKO RDCLKI

RX_CLK

VSS

CRS_DV

RLOS/

LTC

RNEGO RPOSO

DVSS

VSS

VDD3 COL_DEt

VSS

RDEN/

RSIGF

TVSS

TTIP

VDD3

VDD1.8 VDD1.8

VSS

RBSYNC

TTIP

TVSS

VDD3

VSS

VDD1.8 VDD1.8

SDATA

[25]

SDATA

[26]

TRING

TVDD

TRING

SDATA

[22]

SDATA

[24]

TVSS RMSYNC

VSS

SDCS

SWE

VSS

SDATA

[13]

SDATA

[11]

SDATA

[12]

SDATA

[10]

SDATA

[6]

SDATA SDMASK

SBA

[1]

SDA

[8]

SDA

[5]

SDA

[10]

SDMASK SDMASK SDATA

[3]

SDATA

[18]

SDATA

[20]

SYSCLKI VDD1.8

VSS

[8]

[1]

[2]

[29]

SDATA

[15]

SDATA

[0]

SDATA

[14]

SDATA

[9]

SDATA

[5]

SDATA

[7]

SDA

[11]

SDA

[1]

SDA

[6]

SDA

[0]

SDA

[3]

SDATA

[31]

SDATA

[30]

SDATA

[28]

SDATA

[23]

SCAS

VSS

SRAS

VSS

SDATA

[2]

SDATA

[4]

SDATA

[1]

SDATA SDMASK

[3] [0]

SDA

[9]

SBA

[0]

SDA

[7]

SDA

[4]

SDA

[2]

SDATA

[16]

SDATA

[17]

SDATA

[27]

SDATA

[19]

SDATA

[21]

VSS

SDCLKO VDD1.8

VDD1.8

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DS33R11 Ethernet Mapper with Integrated T1/E1/J1 Transceiver

8 FUNCTIONAL DESCRIPTION

The DS33R11 provides interconnection and mapping functionality between Ethernet packet LANs and T1/E1/J1

WAN Time-Division Multiplexed (TDM) systems. The device is composed of a 10/100 Ethernet MAC, packet

arbiter, committed information rate controller (CIR), HDLC/X.86 (LAPS) mapper, SDRAM interface, control ports,

bit error-rate tester (BERT), and integrated T1/E1/J1 transceiver. The packet interface consists of a MII/RMII

Ethernet PHY interface. The Ethernet interface can be configured for 10Mbit/s or 100Mbit/s service. The DS33R11

encapsulates Ethernet traffic with HDLC or X.86 (LAPS) encoding to be transmitted over a T1, E1, or J1 line. The

T1/E1/J1 interface also receives encapsulated Ethernet packets and transmits the extracted packets over the

Ethernet ports. Access is provided to the signals between the serial port and the integrated T1/E1/J1 transceiver.

The Ethernet packet interface supports MII and RMII interfaces, allowing the DSZ33R11 to connect to

commercially available Ethernet PHY and MAC devices. The Ethernet interface can be configured for 10Mbit/s or

100Mbit/s service, in DTE and DCE configurations. The DS33R11 MAC interface rejects frames with bad FCS and

short frames (less than 64 bytes).

Ethernet frames are queued and stored in external 32-bit SDRAM. The DS33R11 SDRAM controller enables

connection to a 128Mb SDRAM without external glue logic, at clock frequencies up to 100MHz. The SDRAM is

used for both the transmit and receive data queues. The receive queue stores data to be sent from the packet

interface to the WAN serial interface. The transmit queue stores data to be sent from the WAN serial interface to

the Ethernet LAN packet interface. The external SDRAM can accommodate up to 8192 frames with a maximum

frame size of 2016 bytes. The sizing of the queues can be adjusted by software. The user can also program high

and low watermarks for each queue that can be used for automatic or manual flow control. The packet data stored

in the SDRAM is encapsulated in HDLC or X.86 (LAPS) to be transmitted over the WAN interface. The device also

provides the capability for bit and packet scrambling.

The WAN interface also receives encapsulated Ethernet packets and transmits the extracted packets over the

Ethernet port. The WAN serial port can operate with a gapped clock, and is designed to be connected to the

integrated T1/E1/J1 transceiver for transmission.

The DS33R11 can be configured through an 8-bit microprocessor interface port. Diagnostic capabilities include

loopbacks, PRBS pattern generation/detection, and 16-bit loop-up/loop-down code generation and detection. The

DS33R11 provides two on-board clock dividers for the system-clock input and reference-clock input for the 802.3

interfaces, further reducing the need for ancillary devices.

The integrated transceiver is a software-selectable T1, E1, or J1 single-chip transceiver (SCT) for short-haul and

long-haul applications. The transceiver is composed of an LIU, framer, HDLC controllers, and a TDM backplane

interface, and is controlled by the 8-bit parallel port. The transceiver is software compatible with the DS2155 and

DS2156.