HARDWARE
GUIDE
®
MegaRAID SCSI 320-2
RAID Controller
N ov e m b e r 2 0 0 2
®
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FCC Regulatory Statement
This device complies with Part 15 of the FCC Rules. Operation is subject to the
following two conditions: (1) this device may not cause harmful interference, and
(2) this device must accept any interference received, including interference that
may cause undesired operation.
Warning:
Changes or modifications to this unit not expressly approved by
the party responsible for compliance could void the user's author-
ity to operate the equipment.
This equipment has been tested and found to comply with the limits for a Class
B digital device, pursuant to Part 15 of the FCC Rules. These limits are designed
to provide reasonable protection against harmful interference in a residential
installation. This equipment generates, uses and can radiate radio frequency
energy and, if not installed and used in accordance with the instructions, may
cause harmful interference to radio communications. However, there is no
guarantee that interference will not occur in a specific installation. If this
equipment does cause harmful interference to radio or television reception, which
can be determined by turning the equipment off and on, try to correct the
interference by one or more of the following measures:
1. Reorient or relocate the receiving antenna.
2. Increase the separation between the equipment and the receiver.
3. Connect the equipment into an outlet on a circuit different from that to which
the receiver is connected.
4. Consult the dealer or an experienced radio/TV technician for help.
Shielded interface cables must be used with this product to ensure compliance
with the Class B FCC limits.
Model Number: Series 518
Disclaimer – LSI Logic certifies only that this product will work correctly when
this product is used with the same jumper settings, the same system
configuration, the same memory module parts, and the same peripherals that
were tested by LSI Logic with this product. The complete list of tested jumper
settings, system Configurations, peripheral devices, and memory modules are
documented in the LSI LOGIC Compatibility Report for this product. Call your LSI
Logic sales representative for a copy of the Compatibility Report for this product.
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Preface
This book is the primary reference and Hardware Guide for the LSI Logic
®
MegaRAID SCSI 320-2 Controller. It contains instructions for installing
the MegaRAID controller and for configuring RAID arrays. It also contains
background information on RAID.
The MegaRAID SCSI 320-2 controller supports single-ended and low-
voltage differential (LVD) SCSI devices on two Ultra320 and Wide SCSI
channels with data transfer rates up to 320 Mbytes/s.
Audience
This document is intended for people who need to install the MegaRAID
SCSI 320-2 Controller in a server and then create and configure RAID
arrays.
Organization
This document has the following chapters and appendixes:
•
•
•
•
•
320-2 and basic SCSI features.
concepts.
the factors to consider when choosing a RAID level.
320-2.
logical drives.
MegaRAID SCSI 320-2 Hardware Guide
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•
•
MegaRAID SCSI 320-2 controller.
implement clustering to enable two independent servers to access
the same shared data storage.
•
•
for the MegaRAID SCSI 320-2 controller.
cables and connectors used with the MegaRAID SCSI 320-2
controller.
•
•
tones generated by the MegaRAID SCSI 320-2 controller.
Technical Support
If you need help installing, configuring, or running the MegaRAID SCSI
320-2 Controller, you may be able to find the information you need at the
MegaRAID support page at http://megaraid.lsilogic.com
If this does not resolve your problem, you can call your LSI Logic OEM
Technical Support representative at 678-728-1250. Before you call,
please complete the MegaRAID Problem Report form.
MegaRAID Problem Report Form
Customer Information
MegaRAID Information
Name:
Today’s Date:
Company:
Address:
City/State:
Country:
Email Address:
Phone:
Date of Purchase:
Invoice Number:
Serial Number:
Cache Memory:
Firmware Version:
BIOS Version:
Fax:
vi
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MegaRAID Problem Report Form (Cont.)
System Information
Motherboard:
BIOS manufacturer:
Operating System:
Op. Sys. Ver.:
BIOS Date:
Video Adapter:
CPU Type/Speed:
MegaRAID
Driver Ver.:
Network Card:
System Memory:
Other disk controllers
installed:
Other adapter cards
Installed:
Description of problem:
Steps necessary to re-create problem:
1.
2.
3.
4.
Preface
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Logical Drive Configuration
Use this form to record the configuration details for your logical drives.
Logical Drive Configuration
Logical
Drive
RAID
Level
Stripe
Size
Logical Drive
Size
Cache
Policy
Read
Policy
Write
Policy
# of Physical
Drives
LD0
LD1
LD2
LD3
LD4
LD5
LD6
LD7
LD8
LD9
LD10
LD11
LD12
LD13
LD14
LD15
LD16
LD17
LD18
LD19
LD20
LD21
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Logical Drive Configuration (Cont.)
Logical
Drive
RAID
Level
Stripe
Size
Logical Drive
Size
Cache
Policy
Read
Policy
Write
Policy
# of Physical
Drives
LD22
LD23
LD24
LD25
LD26
LD27
LD28
LD29
LD30
LD31
LD32
LD33
LD34
LD35
LD36
LD37
LD38
LD39
Preface
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Physical Device Layout
Use this form to record the physical device layout.
Physical Device Layout
Channel 0
Channel 1
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
x
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Physical Device Layout (Cont.)
Channel 0
Channel 1
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
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Physical Device Layout (Cont.)
Channel 0
Channel 1
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
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Physical Device Layout (Cont.)
Channel 0
Channel 1
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Preface
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Contents
Chapter 1
1.7.3
MegaRAID Operating System Driver Installation
Chapter 2
Introduction to RAID
MegaRAID SCSI 320-2 Hardware Guide
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Chapter 3
RAID Levels
Chapter 4
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Chapter 5
Configuring Physical Drives, Arrays, and Logical Drives
Chapter 6
Contents
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6.2.12 Step 12: Run the MegaRAID BIOS Configuration
Chapter 7
Installing and Configuring Clusters
7.3.1
Driver Installation Instructions under Microsoft Windows
2000 Advanced Server
7-3
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Chapter 8
Troubleshooting
Appendix A
A.1.3
Converting Internal Wide to Internal Non-Wide
A.1.4
A.1.5
Converting Internal Wide to Internal Non-Wide
Converting from Internal Wide to Internal Non-Wide
Appendix B
Audible Warnings
Contents
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Contents
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Chapter 1
Overview
®
This chapter provides an overview of the MegaRAID SCSI 320-2
controller. It contains the following sections:
•
•
•
•
•
•
•
The MegaRAID SCSI 320-2 controller has two SCSI channels.
Throughput on each SCSI channel can be as high as 320 Mbytes/s.
MegaRAID supports a low-voltage differential SCSI bus or a single-
ended SCSI bus.
The MegaRAID SCSI 320-2 is a high-performance intelligent PCI-to-
SCSI host adapter with RAID control capabilities. The MegaRAID SCSI
320-2 requires no special motherboard PCI expansion slot. The card
includes an Intel 80303 processor. MegaRAID provides reliability, high
performance, and fault-tolerant disk subsystem management.
1.1 SCSI Channels
The MegaRAID SCSI 320-2 has two Ultra320 SCSI channels. One LSI
Logic dual SCSI controller supports both channels. Each SCSI channel
supports up to fifteen SCSI devices.
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1.2 NVRAM and Flash ROM
A 32 KB x 8 NVRAM stores RAID system configuration information. The
MegaRAID SCSI 320-2 firmware is stored in flash ROM for easy
upgrade.
1.3 SCSI Connectors
The MegaRAID SCSI 320-2 has two ultra high-density 68-pin external
SCSI connectors and two 68-pin internal SCSI connectors for internal
SCSI drives.
1.4 Single-Ended and Differential SCSI Buses
The SCSI standard defines two electrical buses:
•
•
Single-ended bus
Low-voltage differential bus
1.5 Maximum Cable Length for SCSI Standards
that you can use, depending on the SCSI speeds and type of device.
Table 1.1
Maximum Cable Length for SCSI Standards
Single Ended
SCSI
Low-Voltage
Differential SCSI
Maximum # of
Drives
Standard
Ultra SCSI
1.5 m
3 m
12 m
12 m
12 m
12 m
12 m
7
3
Ultra SCSI
Wide Ultra SCSI
Wide Ultra SCSI
Wide Ultra SCSI
15
7
1.5 m
3 m
3
1-2
Overview
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Table 1.1
Standard
Maximum Cable Length for SCSI Standards (Cont.)
Single Ended
SCSI
Low-Voltage
Differential SCSI
Maximum # of
Drives
Ultra 2 SCSI
25 m
12 m
25 m
12 m
12 m
1
7
Ultra 2 SCSI
Wide Ultra 2 SCSI
Wide Ultra 2 SCSI
Ultra320
1
15
15
1.6 SCSI Bus Widths and Maximum Throughput
the SCSI speeds.
Table 1.2
SCSI Bus Widths and Maximum Throughput
SCSI Standard
SCSI Bus Width
SCSI Throughput
Fast Wide SCSI
Wide Ultra SCSI
Wide Ultra 2 SCSI
Wide Ultra 160 SCSI
Ultra 320 SCSI
16 bits
16 bits
16 bits
16 bits
16 bits
20 Mbytes/s
40 Mbytes/s
80 Mbytes/s
160 Mbytes/s
320 Mbytes/s
1.7 Documentation
The MegaRAID SCSI 320-2 documentation set includes:
•
•
•
The MegaRAID SCSI 320-2 Hardware Guide
The MegaRAID Configuration Software Guide
The MegaRAID Operating System Driver Installation Guide
SCSI Bus Widths and Maximum Throughput
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1.7.1 MegaRAID SCSI 320-2 Hardware Guide
The Hardware Guide contains the RAID overview, RAID planning, and
RAID system configuration information you need first. Read this
document first.
1.7.2 MegaRAID Configuration Software Guide
This manual describes the software configuration utilities that you can
use to configure and modify RAID systems:
•
•
•
•
MegaRAID BIOS Configuration Utility
WebBIOS Configuration Utility
MegaRAID Manager
Power Console Plus
1.7.3 MegaRAID Operating System Driver Installation Guide
This manual provides detailed information about installing the MegaRAID
SCSI 320-2 operating system drivers.
1-4
Overview
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Chapter 2
Introduction to RAID
This chapter introduces important RAID concepts. It contains the
following sections:
•
•
•
RAID (Redundant Array of Independent Disks) is a data storage method
in which data, along with parity information, is distributed among two or
more hard disks (called an array) to improve performance and reliability.
The RAID array appears to the host computer as a single storage unit or
as multiple logical units. I/O is expedited because several disks can be
accessed simultaneously. RAID systems provide improved data storage
reliability and fault tolerance compared to single-drive computers. If a
disk drive in a RAID array fails, data can be reconstructed from the data
and parity information on the remaining disk drives.
2.1 RAID Benefits
RAID is widely used because it improves I/O performance and increases
storage subsystem reliability. RAID provides data security through fault
tolerance and redundant data storage. The MegaRAID SCSI 320-2
management software configures and monitors RAID disk arrays.
2.1.1 Improved I/O
Although disk drive capabilities have improved drastically, actual
performance of individual disk drives has been improved only three to
four times in the last decade. RAID provides a way to achieve much
better data throughput.
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2.1.2 Increased Reliability
The electromechanical components of a disk subsystem operate more
slowly, require more power, and generate more noise and vibration than
electronic devices. These factors reduce the reliability of data stored on
disks. RAID provides a way to achieve much better fault tolerance and
data reliability.
2.2 MegaRAID SCSI 320-2 – Host-Based RAID Solution
RAID products are either host-based or external.
The MegaRAID SCSI 320-2 controller is a host-based RAID solution.
The MegaRAID SCSI 320-2 is a PCI adapter card that is installed in any
available PCI expansion slot in a host system.
2.2.1 Host-Based RAID
A host-based RAID product puts all of the RAID intelligence on an
adapter card that is installed in a network server. A host-based RAID
product provides the best performance. MegaRAID SCSI 320-2 is part of
the file server, so it can transmit data directly across the computer’s
buses at data transfer speeds up to 532 Mbytes/s.
The available sequential data transfer rate is determined by the following
factors:
•
•
•
•
•
•
The sustained data transfer rate on the motherboard PCI bus
The sustained data transfer rate on the PCI-to-PCI bridge
The sustained data transfer rate of the SCSI controller
The sustained data transfer rate of the SCSI devices
The number of SCSI channels
The number of SCSI disk drives
Host-based solutions must provide operating system-specific drivers.
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2.2.2 SCSI-to-SCSI External RAID
A SCSI-to-SCSI external RAID product puts the RAID intelligence inside
the RAID chassis and uses a plain SCSI host adapter installed in the
network server. The data transfer rate is limited to the bandwidth of the
SCSI channel. A SCSI-to-SCSI external RAID product that has two Wide
SCSI channels operating at speeds up to 320 Mbytes/s must squeeze
the data into a single Wide SCSI (320 Mbytes/s) channel back to the host
computer.
In SCSI-to-SCSI external RAID products, the disk drive subsystem uses
only a single SCSI ID, which allows you to connect multiple drive
subsystems to a single SCSI controller.
2.3 RAID Overview
RAID is a collection of specifications that describes a system for ensuring
the reliability and stability of data stored on large disk subsystems. A
RAID system can be implemented in a number of different versions (or
RAID levels). MegaRAID SCSI 320-2 supports standard RAID levels 0,
1, and 5, and RAID levels 10 and 50, special RAID versions supported
by the MegaRAID controller.
2.3.1 Physical Array
A RAID array is a collection of physical disk drives governed by the RAID
management software. A RAID array appears to the host computer as
one or more logical drives.
2.3.2 Logical Drive
A logical drive is a partition in a physical array of disks that is made up
of contiguous data segments on the physical disks. A logical drive can
consist of any of the following:
•
•
•
•
An entire physical array
More than one entire physical array
A part of an array
Parts of more than one array
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•
A combination of any two of the above conditions
2.3.3 Consistency Check
A consistency check verifies the correctness of redundant data in a RAID
array. For example, in a system with distributed parity, checking
consistency means computing the parity of the data drives and
comparing the results to the contents of the parity drives.
2.3.4 Fault Tolerance
Fault tolerance is achieved through cooling fans, power supplies, and the
ability to hot swap drives. MegaRAID SCSI 320-2 provides hot swapping
through the hot spare feature. A hot spare drive is an unused online
available drive that MegaRAID SCSI 320-2 instantly plugs into the
system when an active drive fails.
After the hot spare is automatically moved into the RAID subsystem, the
failed drive is automatically rebuilt. The RAID disk array continues to
handle request while the rebuild occurs.
2.3.5 Disk Striping
Disk striping writes data across multiple disk drives instead of just one
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Figure 2.1 Disk Striping
MegaRAID Controller
Segment 1
Segment 5
Segment 9
Segment 2
Segment 6
Segment 10
Segment 3
Segment 7
Segment 11
Segment 4
Segment 8
Segment 12
Disk striping involves partitioning each disk drive’s storage space into
stripes that can vary in size from 2 to 128 Kbytes. These stripes are
interleaved in a repeated, sequential manner. The combined storage
space is composed of stripes from each drive. MegaRAID SCSI 320-2
supports stripe sizes of 2, 4, 8, 16, 32, 64, or 128 Kbytes.
For example, in a four-disk system using only disk striping (as in RAID
level 0), segment 1 is written to disk 1, segment 2 is written to disk 2,
and so on. Disk striping enhances performance because multiple drives
are accessed simultaneously; but disk striping does not provide data
redundancy.
2.3.5.1
Stripe Width
Stripe width is a measure of the number of disks involved in an array
where striping is implemented. For example, a four-disk array with disk
striping has a stripe width of four.
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2.3.5.2
Stripe Size
The stripe size is the length of the interleaved data segments that
MegaRAID SCSI 320-2 writes across multiple drives. MegaRAID SCSI
320-2 supports stripe sizes of 2, 4, 8, 16, 32, 64, or 128 Kbytes.
2.3.6 Disk Mirroring
With disk mirroring (used in RAID 1), data written to one disk drive is
Figure 2.2 Disk Mirroring
MegaRAID Controller
Segment 1
Segment 2
Segment 3
Segment 4
Segment 1 Duplicated
Segment 2 Duplicated
Segment 3 Duplicated
Segment 4 Duplicated
If one disk drive fails, the contents of the other disk drive can be used to
run the system and reconstruct the failed drive. The primary advantage
of disk mirroring is that it provides 100% data redundancy. Since the
contents of the disk drive are completely written to a second drive, it
does not matter if one of the drives fails. Both drives contain the same
data at all times. Either drive can act as the operational drive.
Although disk mirroring provides 100% redundancy, it is expensive
because each drive in the system must be duplicated.
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2.3.7 Disk Spanning
Disk spanning allows multiple disk drives to function like one big drive.
Spanning overcomes lack of disk space and simplifies storage
management by combining existing resources or adding relatively
inexpensive resources. For example, four 60 Gbyte disk drives can be
combined to appear to the operating system as one single 240 Gbyte
drive.
Disk spanning alone does not provide reliability or performance
enhancements. Spanned logical drives must have the same stripe size
a RAID 10 array.
Figure 2.3 Disk Spanning
MegaRAID Controller
Data Flow
RAID 1
RAID 1
Disk 1
Disk 2
Disk 3
Disk 4
Segment 1
Segment 1
Segment 2
Segment 2
Segment 3
Segment 5
Segment 3
Segment 5
Segment 4
Segment 6
Segment 4
Segment 6
RAID 0
The controller supports a span depth of eight. This means that eight
RAID 1, 3, or 5 arrays can be spanned to create one logical drive.
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Table 2.1 Spanning for RAID 10 and RAID 50
Level Description
10
50
Configure RAID 10 by spanning two contiguous RAID 1 logical drives.
The RAID 1 logical drives must have the same stripe size.
Configure RAID 50 by spanning two contiguous RAID 5 logical drives.
The RAID 5 logical drives must have the same stripe size.
Note:
Spanning two contiguous RAID 0 logical drives does not
produce a new RAID level or add fault tolerance. It does
increase the size of the logical volume and improves
performance by doubling the number of spindles.
2.3.8 Parity
Parity generates a set of redundancy data from two or more parent data
sets. The redundancy data can be used to reconstruct one of the parent
data sets. Parity data does not fully duplicate the parent data sets. In
RAID, this method is applied to entire drives (dedicated parity) or to
stripes across all disk drives in an array (distributed parity).
RAID 5 combines distributed parity with disk striping. If a single disk drive
fails, it can be rebuilt from the parity and the data on the remaining
drives. Parity provides redundancy for one drive failure without
duplicating the contents of entire disk drives, but parity generation can
slow the write process.
2.3.9 Hot Spares
A hot spare is an extra, unused disk drive that is part of the disk
subsystem. It is usually in standby mode, ready for service if a drive fails.
Hot spares permit you to replace failed drives without system shutdown
or user intervention.
MegaRAID SCSI 320-2 implements automatic and transparent rebuilds
using hot spare drives, providing a high degree of fault tolerance and
zero downtime. The MegaRAID SCSI 320-2 RAID Management software
allows you to specify physical drives as hot spares. When a hot spare is
needed, the MegaRAID SCSI 320-2 controller assigns the hot spare that
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has a capacity closest to and at least as great as that of the failed drive
to take the place of the failed drive.
Note:
Hot spares are used only in arrays with redundancy—for
example, RAID levels 1, 5, 10, and 50. A hot spare
connected to a specific MegaRAID SCSI 320-2 controller
can be used only to rebuild a drive that is connected to the
same controller.
2.3.10 Hot Swapping
Hot swapping is the manual replacement of a defective physical disk unit
while the computer is still running. When a new drive has been installed,
you must issue a command to rebuild the drive. The MegaRAID
controller can be configured to detect the new disks and to rebuild the
contents of the disk drive automatically.
2.3.11 Disk Rebuild
You rebuild a disk drive by recreating the data that had been stored on
the drive before the drive failed. Rebuilding can be done only in arrays
with data redundancy such as RAID level 1, 5, 10, and 50.
Standby (warm spare) rebuild is employed in a mirrored (RAID 1)
system. If a disk drive fails, an identical drive is immediately available.
The primary data source disk drive is the original disk drive.
A hot spare can be used to rebuild disk drives in RAID 1, 5, 10, or 50
systems. If a hot spare is not available, the failed disk drive must be
replaced with a new disk drive so the data on the failed drive can be
rebuilt.
The MegaRAID SCSI 320-2 controller automatically and transparently
rebuilds failed drives with user-definable rebuild rates. If a hot spare is
available, the rebuild starts automatically when a drive fails. MegaRAID
SCSI 320-2 automatically restarts the system and the rebuild if the
system goes down during a rebuild.
2.3.11.1 Rebuild Rate
The rebuild rate is the fraction of the compute cycles dedicated to
rebuilding failed drives. A rebuild rate of 100% means the system is
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totally dedicated to rebuilding the failed drive. The MegaRAID SCSI 320-
2 rebuild rate can be configured between 0% and 100%. At 0%, the
rebuild is only done if the system is not doing anything else. At 100%,
the rebuild has a higher priority than any other system activity.
2.3.12 Logical Drive States
Table 2.2
Logical Drive States
Description
State
Optimal
Drive operating condition is good. All configured drives are
online.
Degraded
Drive operating condition is not optimal. A configured drive has
failed or is offline.
Failed
Offline
Drive has failed.
Drive is not available to MegaRAID SCSI 320-2.
2.3.13 SCSI Drive States
Table 2.3
State
SCSI Drive States
Description
Online
(ONLIN)
The drive is functioning normally and is a part of a configured
logical drive.
Ready
(READY)
The drive is functioning normally but is not part of a
configured logical drive and is not designated as a hot spare.
Hot Spare
(HOTSP)
The drive is powered up and ready for use as a spare in case
an online drive fails.
Fail (FAIL)
A fault has occurred in the drive, placing it out of service.
Rebuild (REB) The drive is being rebuilt with data from a failed drive.
2-10
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2.3.14 Disk Array Types
Table 2.4
Type
Disk Array Types
Description
Software-
Based
The array is managed by software running in a host computer
using the host CPU bandwidth. The disadvantages associated
with this method are the load on the host CPU and the need
for different software for each operating system.
SCSI to SCSI The array controller resides outside of the host computer and
communicates with the host via a SCSI adapter in the host.
Array management software runs in the controller. It is
transparent to the host and independent of the host operating
system. The disadvantage is the limited data transfer rate of
the SCSI channel between the SCSI adapter and the array
controller.
Bus-Based
The array controller resides on the bus (for example, a PCI or
EISA bus) in the host computer and has its own CPU to
generate parity and handle other RAID functions. A bus-based
controller can transfer data at the speed of the host bus but is
limited to the bus it is designed for. MegaRAID SCSI 320-2
resides on a PCI bus, which can handle data transfer at up to
132 Mbytes/s. With MegaRAID SCSI 320-2, the channel can
handle data transfer rates up to 320 Mbytes/s per SCSI
channel.
2.3.15 Enclosure Management
Enclosure management is the intelligent monitoring of the disk
subsystem by software and/or hardware.
The disk subsystem can be part of the host computer or can be separate
from it. Enclosure management helps you stay informed of events in the
disk subsystem, such as a drive or power supply failure. Enclosure
management increases the fault tolerance of the disk subsystem.
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Chapter 3
RAID Levels
This chapter describes each supported RAID level and the factors to
consider when choosing a RAID level. It contains the following sections:
•
•
•
•
•
•
3.1 Selecting a RAID Level
To ensure the best performance, you should select the optimal RAID
level when you create a system drive. The optimal RAID level for your
disk array depends on a number of factors:
•
•
•
•
The number of drives in the disk array
The capacity of the drives in the array
The need for data redundancy
The disk performance requirements
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3.2 RAID 0
RAID 0 provides disk striping across all drives in the RAID subsystem.
RAID 0 does not provide any data redundancy, but does offer the best
performance of any RAID level. RAID 0 breaks up data into smaller
blocks and then writes a block to each drive in the array. The size of each
block is determined by the stripe size parameter, set during the creation
of the RAID set. RAID 0 offers high bandwidth. By breaking up a large
file into smaller blocks, MegaRAID SCSI 320-2 can use several drives to
read or write the file faster. RAID 0 involves no parity calculations to
complicate the write operation. This makes RAID 0 ideal for applications
that require high bandwidth but do not require fault tolerance.
Uses
RAID 0 provides high data throughput, especially for large
files. Suitable for any environment that does not require
fault tolerance.
Strong Points
Weak Points
Drives
Provides increased data throughput for large files. No
capacity loss penalty for parity.
Does not provide fault tolerance. All data lost if any drive
fails.
1 to 30
The initiator takes one ID per channel. This leaves 15 IDs
available for each channel.
Figure 3.1 shows a RAID 0 array with four disk drives.
3-2
RAID Levels
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Figure 3.1 RAID 0 Array
MegaRAID Controller
Segment 1
Segment 5
Segment 9
Segment 2
Segment 6
Segment 10
Segment 3
Segment 7
Segment 11
Segment 4
Segment 8
Segment 12
3.3 RAID 1
In RAID 1, the MegaRAID SCSI 320-2 duplicates all data from one drive
to a second drive. RAID 1 provides complete data redundancy, but at the
cost of doubling the required data storage capacity.
Uses
Use RAID 1 for small databases or any other environment
that requires fault tolerance but small capacity.
Strong Points Provides complete data redundancy. RAID 1 is ideal for any
application that requires fault tolerance and minimal capacity.
Weak Points
Drives
Requires twice as many disk drives. Performance is impaired
during drive rebuilds.
2
RAID 1
3-3
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Figure 3.2 RAID 1 Array
MegaRAID Controller
Segment 1
Segment 2
Segment 3
Segment 4
Segment 1 Duplicated
Segment 2 Duplicated
Segment 3 Duplicated
Segment 4 Duplicated
3.4 RAID 5
RAID 5 includes disk striping at the byte level and parity. In RAID 5, the
parity information is written to several drives. RAID 5 is best suited for
networks that perform many small I/O transactions simultaneously.
RAID 5 addresses the bottleneck issue for random I/O operations. Since
each drive contains both data and parity, numerous writes can take place
concurrently. In addition, robust caching algorithms and hardware based
3-4
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exclusive-or assist make RAID 5 performance exceptional in many
different environments.
Uses
Provides high data throughput, especially for large files.
Use RAID 5 for transaction processing applications,
because each drive can read and write independently. If a
drive fails, the MegaRAID SCSI 320-2 uses the distributed
parity data to recreate all missing information. Use also for
office automation and online customer service that requires
fault tolerance. Use for any application that has high read
request rates but low write request rates.
Strong Points
Weak Points
Provides data redundancy and good performance in most
environments
Disk drive performance is reduced if a drive is being rebuilt.
Environments with few processes do not perform as well
because the RAID overhead is not offset by the
performance gains in handling simultaneous processes.
Drives
3 to 30
Figure 3.3 shows a RAID 5 array with six disk drives.
Figure 3.3 RAID 5 Array
MegaRAID Controller
Note: Parity is distributed
across drives in the array.
Data Flow
Disk 1
Disk 2
Disk 3
Disk 4
Disk 5
Disk 6
Segment 1
Segment 7
Parity (9–12)
Segment 2
Segment 8
Segment 3
Segment 9
Parity (5–8)
Segment 4
Segment 10
Segment 5
Segment 11
Parity (1–4)
Segment 6
Segment 12
RAID 5
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3.5 RAID 10
RAID 10 is a combination of RAID 0 and RAID 1. RAID 10 has mirrored
drives. RAID 10 breaks up data into smaller blocks, and then stripes the
blocks of data to each RAID 1 RAID set. Each RAID 1 RAID set then
duplicates its data to its other drive. The size of each block is determined
by the stripe size parameter, which is set during the creation of the RAID
set. RAID 10 can sustain one to four drive failures while maintaining data
integrity, if each failed disk is in a different RAID 1 array.
Uses
Works best for data storage that must have 100%
redundancy of mirrored arrays and that also needs the
enhanced I/O performance of RAID 0 (striped arrays). RAID
10 works well for medium-sized databases or any
environment that requires a higher degree of fault tolerance
and moderate to medium capacity.
Strong Points
Weak Points
Drives
Provides both high data transfer rates and complete data
redundancy.
Requires twice as many drives as all other RAID levels
except RAID 1.
4 to 30 (must be a multiple of 2)
Figure 3.4 shows a RAID 10 array with four disk drives.
3-6
RAID Levels
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Figure 3.4 RAID 10 Array
MegaRAID Controller
Data Flow
RAID 1
RAID 1
Disk 1
Disk 2
Disk 3
Disk 4
Segment 1
Segment 1
Segment 2
Segment 2
Segment 3
Segment 5
Segment 3
Segment 5
Segment 4
Segment 6
Segment 4
Segment 6
RAID 0
3.6 RAID 50
RAID 50 provides the features of both RAID 0 and RAID 5, including both
parity and disk striping across multiple drives. RAID 50 is best
implemented on two RAID 5 disk arrays with data striped across both
disk arrays. RAID 50 breaks up data into smaller blocks, and then stripes
the blocks of data to each RAID 5 RAID set. RAID 5 breaks up data into
smaller blocks, calculates parity by performing an exclusive-or on the
blocks, and then writes the blocks of data and parity to each drive in the
array. The size of each block is determined by the stripe size parameter,
which is set during the creation of the RAID set.
RAID 50
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RAID 50 can sustain one to four drive failures while maintaining data
integrity, if each failed disk is in a different RAID 5 array.
Uses
Works best when used with data that requires high
reliability, high request rates, high data transfer, and
medium to large capacity.
Strong Points
Provides high data throughput, data redundancy, and very
good performance.
Weak Points
Drives
Requires 2 to 4 times as many parity drives as RAID 5.
6 to 30
The initiator takes one ID per channel. This leaves 15 IDs
available for each channel.
Figure 3.5 shows a RAID 50 array with six disk drives.
Figure 3.5 RAID 50 Array
MegaRAID Controller
Data Flow
RAID 5
RAID 5
Disk 4
Disk 5
Disk 6
Disk 1
Disk 2
Disk 3
Segment 1
Segment 6
Parity (9-10)
Segment 2
Parity (5-6)
Segment 9
Parity (1-2)
Segment 5
Segment 10
Segment 3
Segment 8
Parity (11-12)
Segment 4
Parity (7-8)
Segment 11
Parity (3-4)
Segment 7
Segment 12
RAID 0
3-8
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Chapter 4
Features
This chapter explains the features of the MegaRAID SCSI 320-2. It
contains the following sections:
•
•
•
•
•
•
•
•
•
•
•
•
MegaRAID is a family of high performance intelligent PCI-to-SCSI host
adapters with RAID control capabilities. The MegaRAID SCSI 320-2 has
two SCSI channels that support Ultra320 and Wide SCSI with data
transfer rates of up to 320 Mbytes/s. Each SCSI channel supports up to
15 Wide devices and up to seven non-Wide devices.
MegaRAID SCSI 320-2 features include:
•
•
Remote configuration and array management through MegaRAID
WebBIOS
High-performance I/O migration path while preserving existing PCI-
SCSI software
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•
•
•
•
SCSI data transfers up to 320 Mbytes/s
Synchronous operation on a wide LVD SCSI bus
Up to 15 LVD SCSI devices on each of the Wide buses
Up to 256 Mbytes of 3.3 V PC100 (or faster) SDRAM cache memory
in one single-sided or double-sided DIMM socket (Cache memory is
used for read and write-back caching and for RAID 5 parity
generation.)
•
Non-volatile random access memory (NVRAM) storage for RAID
configuration data
•
•
•
•
•
•
•
•
•
•
Audible alarm
Direct memory access (DMA) chaining support
Separate DRAM bus
Support for differential or single-ended SCSI with active termination
Up to 12 MegaRAID 320-2 cards per system
Support for up to 15 SCSI devices per channel
Support for RAID levels 0, 1, 5, 10, and 50
Support for scatter/gather and tagged command queuing
Ability to multithread up to 256 commands simultaneously
Support for multiple rebuilds and consistency checks with
transparent user-definable priority setting
•
•
•
•
•
•
•
•
•
Support for variable stripe sizes for all logical drives
Automatic detection of failed drives
Automatic and transparent rebuild of hot spare drives
Hot swap of new drives without taking the system down
Optional battery backup for up to 72 hours of data retention
Server clustering support
Optional firmware provides multi-initiator support
Server failover
Software drivers for major operating systems
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4.1 SMART Technology
The MegaRAID Self Monitoring Analysis and Reporting Technology
(SMART) feature detects up to 70% of all predictable drive failures.
SMART monitors the internal performance of all motors, heads, and drive
electronics. You can recover from drive failures through online physical
drive migration.
4.2 Configuration on Disk
Configuration on Disk (drive roaming) saves configuration information
both in nonvolatile random access memory (NVRAM) on the MegaRAID
SCSI 320-2, and on the disk drives it controls. If the MegaRAID SCSI
320-2 is replaced, the new MegaRAID controller can detect the actual
RAID configuration, maintaining the integrity of the data on each drive,
even if the drives have changed channel and/or target ID.
4.3 Configuration Features
Table 4.1
Configuration Features
Specification
Feature
RAID levels
0, 1, 5, 10, and 50
2
SCSI channels
Maximum number of drives per channel 15
Array interface to host
PCI bus master
PCI 2.2
Supports write invalidate
Wide Ultra320
Drive interface
Upgradable cache memory sizes
Cache function
32, 64, 128, or 256 Mbytes
Write-back, Write-through, Adaptive
Read Ahead, Non Read Ahead,
Read Ahead
SMART Technology
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Table 4.1
Configuration Features (Cont.)
Feature
Specification
Multiple logical drives/arrays per
controller
Up to 40 logical drives per controller
12
Maximum number of MegaRAID
controllers per system
Online capacity expansion
Hot spare support
Yes
Yes
Yes
Yes
Yes
Yes
2
Flashable firmware
Hot swap devices supported
Non-disk devices supported
Mixed capacity hard drives
Number of internal SCSI connectors
Number of external SCSI connectors
2
Support for hard drives with capacities Yes
of more than 8 Gbytes
Clustering support (Failover control)
Online RAID level migration
Yes
Yes
Yes
No reboot necessary after expansion
More than 200 Qtags per physical drive Yes
Hardware clustering support on the
board
Yes
User-specified rebuild rate
Yes
4-4
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4.4 Array Performance Features
Table 4.2
Array Performance Features
Feature
Specification
Host data transfer rate
Drive data transfer rate
Stripe sizes
532 Mbytes/s
320 Mbytes/s
2, 4, 8, 16, 32, 64, or 128 Kbytes
4.5 RAID Management Features
Table 4.3
RAID Management Features
Specification
Feature
Support for SNMP
Yes
Yes
Yes
Yes
Yes
Yes
Performance Monitor provided
Remote control and monitoring
Drive roaming
Support for concurrent multiple stripe sizes
Windows NT, 2000, XP, and .NET server support using a GUI
client utility
Array Performance Features
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4.6 Fault Tolerance Features
Table 4.4
Fault Tolerance Features
Feature
Specification
Support for SMART
Yes
Optional battery backup for cache Standard. Provided on the MegaRAID
memory
Controller. Up to 72 hours data retention
Enclosure management
SCSI-accessed fault-tolerant enclosure
(SAF-TE) compliant
Drive failure detection
Automatic
Drive rebuild using hot spares
Parity generation and checking
Automatic and transparent
Software and hardware
4.7 Software Utilities
Table 4.5
Software Utilities
Specification
Feature
FlexRAID reconfiguration on the fly
FlexRAID RAID level migration on the fly
FlexRAID online capacity expansion
Yes
Yes
Yes
Remote configuration and management over the Internet Yes
Graphical user interface
Yes
Yes
Yes
Yes
Yes
Diagnostic utility
Management utility
Bootup configuration using MegaRAID Manager
Online read, write, and cache policy switching
4-6
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4.8 Operating System Software Drivers
MegaRAID SCSI 320-2 includes a DOS software configuration utility, and
drivers for:
•
•
•
•
•
•
•
Windows NT 4.0
Windows 2000
Windows .NET
Windows XP
Novell NetWare 5.1, 6.0
Red Hat Linux 7.2, 7.3
DOS version 6.xx or later
The DOS drivers for MegaRAID are contained in the firmware on the
MegaRAID controller, except for the DOS ASPI and CD drivers. Call your
LSI OEM support representative or access the web site at
www.lsilogic.com for information about drivers for other operating
systems.
4.9 MegaRAID SCSI 320-2 Specifications
Table 4.6
Parameter
MegaRAID SCSI 320-2 Specifications
Specification
Card size
Processor
6.875" x 4.2" (half length PCI)
Intel 80303 @ 100 MHz
SCSI processor
Bus type
One LSI Logic 53C1030 SCSI controller
PCI 2.2
Bus data transfer rate Up to 266 Mbytes/s
Cache configuration
Firmware
64 or 128Mbyte DIMM
1 MB 8 flash ROM
Operating System Software Drivers
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Table 4.6
Parameter
MegaRAID SCSI 320-2 Specifications (Cont.)
Specification
Nonvolatile RAM
Memory type
32 KB 8 for storing RAID configuration
One 72-bit 168-pin SDRAM DIMM socket provides
write-through or write-back caching on a logical drive
basis. It also provides adaptive read-ahead.
Operating voltage
SCSI controller
5.00 V 0.25 V and 3.3 V +/- 0.3 V
2 SCSI controllers for Ultra320 and Wide support
SCSI data transfer rate Up to 320 Mbytes/s
SCSI bus
Low voltage differential or SE
SCSI termination
Termination disable
Active, low-voltage differential, or single-ended
Automatic through cable detection
Devices per SCSI
channel
Up to 15 wide or seven non-wide SCSI devices. Up to
6 non-disk SCSI drives per MegaRAID controller.
SCSI device types
supported
Synchronous or Asynchronous. Disk and non-disk.
RAID levels supported 0, 1, 5, 10, and 50
SCSI connectors
Two 68-pin internal high-density connectors for 16-bit
SCSI devices.
Two ultra-high density 68-pin external connectors
SCSI cables
Serial port
Up to 25 m if using low voltage differential
3-pin RS232C-compatible connector, used for test
purposes only
4.10 MegaRAID Components
4.10.1 CPU
The MegaRAID SCSI 320-2 controller uses the 64-bit Intel 80303
Intelligent I/O processor with an embedded 32-bit 80960 Jx RISC
processor that runs at 100 MHz. This processor directs all functions of
the controller including command processing, PCI and SCSI bus
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transfers, RAID processing, drive rebuilding, cache management, and
error recovery.
4.10.2 Cache Memory
Cache memory resides in a single 72-bit DIMM socket that requires one
unbuffered 3.3 V SDRAM single-sided or double-sided DIMM. Possible
configurations are 32, 64, 128, or 256 Mbytes.
MegaRAID supports write-through or write-back caching, which can be
selected for each logical drive. To improve performance in sequential disk
accesses, MegaRAID does not use read-ahead caching for the current
logical drive. The default setting for the read policy is Normal, meaning
no read-ahead caching. You can disable read-ahead caching.
Warning: Write caching is not recommended for the physical drives.
When write cache is enabled, loss of data can occur when
power is interrupted.
4.10.3 MegaRAID BIOS
The BIOS resides on a 1 MB or 2 MB 8 flash ROM for easy upgrade.
The MegaRAID BIOS supports INT 13h calls to boot DOS without
special software or device drivers. The MegaRAID BIOS provides an
extensive setup utility that can be accessed by pressing <Ctrl> <M> at
BIOS initialization. The MegaRAID Configuration Utility is described in
the MegaRAID Configuration Software Guide.
4.10.4 Onboard Speaker
The MegaRAID SCSI 320-2 has an onboard tone generator for audible
warnings when system errors occur. Audible warnings can be generated
through this speaker. The audible warnings are listed in Appendix B.
4.10.5 Serial Port
The MegaRAID SCSI 320-2 has a 3-pin RS232C-compatible serial port
connector, which is used for test purposes only.
MegaRAID Components
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4.10.6 SCSI Bus
The MegaRAID SCSI 320-2 controller has two Ultra320 Wide SCSI
channels that support low voltage differential SCSI devices with active
termination. Both synchronous and asynchronous devices are supported.
The MegaRAID controller provides automatic termination disable via
cable detection. Each channel supports up to 15 wide or seven non-wide
SCSI devices at speeds up to 320 Mbytes/s per SCSI channel. The
MegaRAID controller supports up to six non-disk devices per controller.
The SCSI bus mode defaults to LVD for each SCSI channel. If a single-
ended device is attached to a SCSI channel, the MegaRAID controller
automatically switches to SE mode for that SCSI channel.
4.10.7 SCSI Connectors
The MegaRAID SCSI 320-2 has two types of SCSI connectors:
•
•
Two 68-pin high density internal connectors
Two 68-pin very-high-density external connectors
4.10.8 SCSI Termination
The MegaRAID SCSI 320-2 uses active termination on the SCSI bus,
conforming to Alternative 2 of the SCSI-2 specifications. Termination
enable/disable is automatic through cable detection.
4.10.9 SCSI Firmware
The MegaRAID SCSI 320-2 firmware handles all RAID and SCSI
Table 4.7
Feature
SCSI Firmware
Description
Disconnect/
reconnect
Optimizes SCSI bus seek
Tagged command
queuing
Multiple tags to improve random access
Multiple address/count pairs
Scatter/gather
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Table 4.7
Feature
SCSI Firmware (Cont.)
Description
Multi-threading
Stripe size
Rebuild
Up to 255 simultaneous commands with elevator sorting
and concatenation of requests per SCSI channel
Variable for all logical drives: 2, 4, 8, 16, 32, 64, or
128 Kbytes
Multiple rebuilds and consistency checks, with user-
definable priority
4.11 RAID Management
RAID management is provided by software utilities that manage and
configure the RAID system and MegaRAID SCSI 320-2, create and
manage multiple disk arrays, control and monitor multiple RAID servers,
provide error statistics logging, and provide online maintenance. They
include:
•
•
•
•
MegaRAID BIOS Configuration Utility
WebBIOS Configuration Utility
Power Console Plus
MegaRAID Manager
4.11.1 MegaRAID BIOS Configuration Utility
The BIOS Configuration Utility (<Ctrl><M>) is used to configure and
maintain RAID arrays, format hard drives, and manage the RAID system.
It is independent of any operating system. See the MegaRAID
Configuration Software Guide for additional information.
4.11.2 WebBIOS Configuration Utility
The WebBIOS Configuration Utility is an HTML-based utility used to
configure and maintain RAID arrays, format hard drives, and manage the
RAID system. It is independent of any operating system. See the
MegaRAID Configuration Software Guide for additional information.
RAID Management
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4.11.3 Power Console Plus
Power Console Plus runs in Windows NT, 2000, XP, and .NET. It
configures, monitors, and maintains multiple RAID servers from any
network node or a remote location. See the MegaRAID Configuration
Software Guide for additional information.
4.11.4 MegaRAID Manager
MegaRAID Manager is a character-based, non-GUI utility for Linux and
Novell NetWare that changes policies and parameters, and monitors
RAID systems. See the MegaRAID Configuration Software Guide for
additional information.
4.12 Compatibility
MegaRAID SCSI 320-2 compatibility issues include:
•
•
•
Server management
SCSI device compatibility
Software compatibility
4.12.1 Server Management
As a simple network management protocol (SNMP) agent, MegaRAID
SCSI 320-2 supports all SNMP managers.
4.12.2 SCSI Device Compatibility
The MegaRAID SCSI 320-2 supports SCSI hard drives, CD-ROM drives,
and tape drives.
4.12.3 Software
All SCSI backup and utility software should work with the MegaRAID
SCSI 320-2. This software is not provided with the MegaRAID controller.
4-12
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Chapter 5
Configuring Physical Drives,
Arrays, and Logical Drives
This chapter explains how to configure SCSI physical drives, arrays, and
logical drives connected to the MegaRAID SCSI 320-2 controller. It
contains the following sections:
•
•
•
•
•
5.1 Configuring SCSI Physical Drives
SCSI physical drives must be organized into logical drives. The arrays
and logical drives that you construct must be able to support the RAID
level that you select. The MegaRAID SCSI 320-2 controller has two SCSI
channels.
5.1.1 Distributing Drives
Distribute the disk drives across all channels for optimal performance. It
is best to stripe across channels instead of down channels. Performance
is most affected for sequential reads and writes. The MegaRAID SCSI
320-2 controller supports SCSI CD-ROM drives, SCSI tape drives, and
other SCSI devices as well as SCSI hard disk drives. For optimal
performance, all non-disk SCSI devices should be attached to one SCSI
channel.
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5.1.2 Basic Configuration Rules
You should observe the following guidelines when connecting and
configuring SCSI devices in a RAID array:
•
•
Attach non-disk SCSI devices to a single SCSI channel that does not
have any disk drives.
Distribute the SCSI hard disk drives equally among all available SCSI
channels except any SCSI channel that is being reserved for non-
disk drives.
•
•
You can place up to 30 physical disk drives in a logical array,
depending on the RAID level.
An array can contain SCSI devices that reside on an array on any
channel.
•
•
Include all drives that have the same capacity in the same array.
Make sure any hot spare has a capacity that is at least as large as
the largest drive that may be replaced by the hot spare.
•
When replacing a failed drive, make sure that the replacement drive
has a capacity that is at least as large as the drive being replaced.
Note:
Be sure to back up your data regularly, even when using
RAID.
5.1.3 Current Physical Device Configuration
devices on SCSI channels 0 and 1.
Table 5.1
Physical Device Configuration
SCSI ID Device Description
Termination?
SCSI Channel 0
0
1
2
3
5-2
Configuring Physical Drives, Arrays, and Logical Drives
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Table 5.1
Physical Device Configuration (Cont.)
SCSI ID Device Description
Termination?
4
5
6
8
9
10
11
12
13
14
15
SCSI Channel 1
0
1
2
3
4
5
6
8
9
10
11
12
13
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Table 5.1
Physical Device Configuration (Cont.)
SCSI ID Device Description
Termination?
14
15
5.1.4 Logical Drive Configuration
Logical Drive Configuration
Table 5.2
Logical
Drive
RAID
Level
Stripe
Size
Logical Drive
Size
Cache
Policy
Read
Policy
Write
Policy
# of Physical
Drives
LD0
LD1
LD2
LD3
LD4
LD5
LD6
LD7
LD8
LD9
LD10
LD11
LD12
LD13
LD14
LD15
LD16
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Table 5.2
Logical Drive Configuration (Cont.)
Logical
Drive
RAID
Level
Stripe
Size
Logical Drive
Size
Cache
Policy
Read
Policy
Write
Policy
# of Physical
Drives
LD17
LD18
LD19
LD20
LD21
LD22
LD23
LD24
LD25
LD26
LD27
LD28
LD29
LD30
LD31
LD32
LD33
LD34
LD35
LD36
LD37
LD38
LD39
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5.1.5 Physical Device Layout
Table 5.3
Physical Device Layout
Channel 0
Channel 1
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
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Table 5.3
Physical Device Layout (Cont.)
Channel 0
Channel 1
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
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Table 5.3
Physical Device Layout (Cont.)
Channel 0
Channel 1
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
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Table 5.3
Physical Device Layout (Cont.)
Channel 0
Channel 1
Target ID
Device type
Logical drive number/Drive number
Manufacturer/Model number
Firmware level
5.2 Configuring Arrays
Connect the physical drives to the MegaRAID SCSI 320-2, configure the
drives, then initialize them. The number of physical disk drives that an
array can support depends on the firmware version.
For the MegaRAID SCSI 320-2, an array can consist of up to 30 physical
disk drives, depending on the RAID level (see Chapter 3 for more
information). This controller supports up to 40 logical drives per
controller. The number of drives in an array determines the RAID levels
that can be supported.
5.2.1 Arranging Arrays
You must arrange the arrays to provide additional organization for the
drive array. You must arrange arrays so that you can create system drives
that can function as boot devices.
You can sequentially arrange arrays with an identical number of drives
so that the drives in the group are spanned. Spanned drives can be
treated as one large drive. Data can be striped across multiple arrays as
one logical drive.
You can create spanned drives by using the MegaRAID Configuration
Utility or the MegaRAID Manager. See the MegaRAID Configuration
Software Guide for additional information.
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5.2.2 Creating Hot Spares
Any drive that is present, formatted, and initialized, but is not included in
a array or logical drive is automatically designated as a hot spare.
You can also designate drives as hot spares using the MegaRAID BIOS
Configuration Utility, the MegaRAID Manager, or Power Console Plus.
See the MegaRAID Configuration Software Guide for additional
information.
5.3 Creating Logical Drives
Logical drives are arrays or spanned arrays that are presented to the
operating system. You must create one or more logical drives.
The logical drive capacity can include all or any portion of an array. The
logical drive capacity can also be larger than an array by using spanning.
The MegaRAID SCSI 320-2 supports up to 40 logical drives.
5.3.1 Configuration Strategies
The most important factors in RAID array configuration are: drive
capacity, drive availability (fault tolerance), and drive performance. You
cannot configure a logical drive that optimizes all three factors, but it is
easy to choose a logical drive configuration that maximizes one factor at
the expense of the other two factors, although needs are seldom that
simple.
5.3.1.1
Maximize Capacity
RAID 0 achieves maximum drive capacity, but does not provide data
redundancy. Maximum drive capacity for each RAID level is shown
below. OEM-level firmware that can span up to 4 logical drives is
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drives required, and the capacity.
Table 5.4
Capacity for RAID Levels
RAID
Level Description
Drives
Required
Capacity
0
Striping
without parity
1 – 30
(Number of disks) X capacity of
smallest disk
1
5
Mirroring
2
(Capacity of smallest disk) X (1)
Striping with
floating parity
drive
3 – 30
(Number of disks) X (capacity of
smallest disk) - (capacity of 1 disk)
10
50
Mirroring and 4 – 30
(Number of disks) X (capacity of
smallest disk) / (2)
Striping
(Must be a
multiple of 2.)
RAID 5 and
Striping
6 – 30 (Must (Number of disks) X (capacity of
be a multiple smallest disk) – (capacity of 1 disk X
of the # of
arrays.)
number of arrays)
5.3.1.2
Maximizing Drive Availability
You can maximize the availability of data on the physical disk drive in the
describes the levels of fault tolerance for the RAID levels.
Table 5.5
Fault Tolerance for RAID Levels
RAID Level Fault Tolerance Protection
0
1
5
No fault tolerance.
100% protection through data mirroring.
100% protection through striping and parity. The data is striped
and parity data is written across a number of physical disk
drives.
10
50
100% protection through data mirroring.
100% protection through data striping and parity. All data is
striped and parity data is written across all drives in two or
more arrays.
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5.3.1.3
Maximizing Drive Performance
You can configure an array for optimal performance. But optimal drive
configuration for one type of application will probably not be optimal for
characteristics for RAID drive arrays at each RAID level.
Table 5.6
Performance Characteristics for RAID Levels
RAID Level Performance Characteristics
0
Excellent for all types of I/O activity, but provides no data
security.
1
5
Provides data redundancy and good performance.
Provides data redundancy and good performance in most
environments.
10
50
Provides data redundancy and excellent performance.
Provides data redundancy and very good performance.
5.3.2 Assigning RAID Levels
shows the drives required per RAID level.
Table 5.7
Number of Physical Drives per RAID Level
RAID
Level
Minimum # of Physical Drives Maximum # of Physical Drives
0
1
1
2
3
4
6
30
2
5
30
30
30
10
50
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5.4 Configuring Logical Drives
After you have installed the MegaRAID SCSI 320-2 controller in the
server and have attached all physical disk drives, perform the following
actions to prepare a RAID array:
1. Optimize the MegaRAID SCSI 320-2 controller options for your
system. See Chapter 3 for additional information.
2. Press <Ctrl><M> to run the MegaRAID Manager.
3. If necessary, perform a low-level format of the SCSI drives that will
be included in the array and the drives to be used for hot spares.
4. Customize the RAID array and define and configure one or more
logical drives by selecting Easy Configuration or New Configuration.
5. Create and configure one or more system drives (logical drives) by
selecting the RAID level, cache policy, read policy, and write policy.
6. Save the configuration.
7. Initialize the system drives.
After initialization, you can install the operating system.
5.4.1 Optimizing Data Storage
5.4.1.1
Data Access Requirements
Each type of data stored in the disk subsystem has a different frequency
of read and write activity. If you know the data access requirements, you
can more successfully determine a strategy for optimizing the disk
subsystem capacity, availability, and performance.
Servers that support Video on Demand typically read the data often, but
write data infrequently. Both the read and write operations tend to be
long. Data stored on a general-purpose file server involves relatively
short read and write operations with relatively small files.
5.4.1.2
Array Functions
You must first define the major purpose of the disk array. Will this disk
array increase the system storage capacity for general-purpose file and
print servers? Does this disk array support any software system that
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must be available 24 hours per day? Will the information stored in this
disk array contain large audio or video files that must be available on
demand? Will this disk array contain data from an imaging system? You
must identify the purpose of the data to be stored in the disk subsystem
before you can confidently choose a RAID level and a RAID
configuration.
5.5 Planning the Array Configuration
Table 5.8
Question
Factors for Planning the Array Configuration
Answer
Number of MegaRAID SCSI channels
Number of physical disk drives in the array
Purpose of this array. Rank the following factors:
Maximize drive capacity
Maximize the safety of the data (fault tolerance)
Maximize hard drive performance and throughput
Number of hot spares
Amount of cache memory installed on MegaRAID SCSI 320-1
Are all of the disk drives and the server protected by an
uninterruptible power supply?
5.5.1 Using the Array Configuration Planner
capacity for all possible drive configurations for an array consisting of one
to eight drives. This table does not take into account any hot spare
(standby) drives. You should always have a hot spare drive in case of
drive failure. RAID 1 requires two drives, RAID 10 at least four, and RAID
50 at least six.
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Table 5.9 Array Configuration Planner
Possible
Relative
Fault
Tolerance
Effective
Capacity
# of Drives RAID Levels Performance
1
2
2
3
3
4
4
4
5
5
6
6
6
6
7
7
8
8
8
8
RAID 0
RAID 0
RAID 1
RAID 0
RAID 5
RAID 0
RAID 5
RAID 10
RAID 0
RAID 5
RAID 0
RAID 5
RAID 10
RAID 50
RAID 0
RAID 5
RAID 0
RAID 5
RAID 10
RAID 50
Excellent
Excellent
Good
No
No
100%
100%
50%
Yes
No
Excellent
Good
100%
67%
Yes
No
Excellent
Good
100%
75%
Yes
Yes
No
Excellent
Excellent
Good
50%
100%
80%
Yes
No
Excellent
Good
100%
83%
Yes
Yes
Yes
No
Excellent
Good
50%
67%
Excellent
Good
100%
86%
Yes
No
Excellent
Good
100%
87%
Yes
Yes
Yes
Excellent
Good
50%
75%
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Chapter 6
Hardware Installation
This chapter explains how to install the MegaRAID SCSI 320-2 controller.
It contains the following sections:
•
•
•
6.1 Hardware Requirements
You must have the following in order to install the MegaRAID SCSI 320-1
controller and create arrays:
•
A host computer with the following:
–
A motherboard with 5 V/3.3 V PCI expansion slots that has an
available expansion slot
–
–
–
Support for PCI version 2.2 or later
Intel Pentium, Pentium Pro, or more powerful CPU
Floppy drive, color monitor, VGA adapter card, mouse, and
keyboard
•
•
The MegaRAID SCSI 320-2 Installation CD
The necessary internal and/or external SCSI cables and terminators
(this depends on the number and type of SCSI devices to be
attached)
•
•
An Uninterruptible Power Supply (UPS) for the entire system
Ultra320 SCSI disk drives and other SCSI devices, as desired
Important: The MegaRAID SCSI 320-2 controller must be installed in
a PCI expansion slot.
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6.1.1 Optional Equipment
You may also want to install SCSI cables that interconnect the
MegaRAID SCSI 320-2 to external SCSI devices.
6.2 Installation Steps
The MegaRAID SCSI 320-2 provides extensive customization options. If
you need only basic MegaRAID SCSI 320-2 features and your computer
does not use other adapter cards with resource settings that may conflict
with MegaRAID SCSI 320-2 settings, even custom installation can be
quick and easy.
detail in the following pages.
Table 6.1
Hardware Installation Steps
Step Action
Additional Information
1
Unpack the MegaRAID controller and
inspect for damage. Make sure all items
are in the package.
If damaged, call your LSI
Logic OEM support
representative.
2
3
4
Turn the computer off and remove the
power cord, and remove the cover.
Install cache memory on the MegaRAID
card.
32 Mbytes minimum cache
memory is required.
Check the jumper settings on the
MegaRAID SCSI 320-2 controller.
MegaRAID SCSI 320-2
jumper settings.
5
6
Set SCSI termination.
Set SCSI terminator power (TermPWR).
Connect the battery harness.
7
Optional
8
Install the MegaRAID SCSI 320-2 card.
Connect the SCSI cables to SCSI devices.
Set the target IDs for the SCSI devices.
9
10
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Table 6.1
Hardware Installation Steps (Cont.)
Step Action
Additional Information
11
Replace the computer cover and turn the Be sure the SCSI devices
power on.
are powered up before, or
at the same time as, the
host computer.
12
13
Run the MegaRAID BIOS Configuration
Utility.
Optional.
Install software drivers for the desired
operating systems.
6.2.1 Step 1: Unpack
Unpack and install the hardware in a static-free environment. Remove
the MegaRAID SCSI 320-2 controller card from the anti-static bag and
inspect it for damage. If the card appears damaged, or if any item listed
below is missing, contact LSI Logic or your MegaRAID OEM support
representative. The MegaRAID SCSI 320-2 controller is shipped with the
following:
•
The Driver and Documentation CD, which contains these items:
–
–
–
–
–
The MegaRAID Configuration Software Guide
The MegaRAID Operating System Driver Installation Guide
The MegaRAID SCSI 320-2 Hardware Guide
The software license agreement
The MegaRAID configuration utilities for DOS
•
The warranty registration card
6.2.2 Step 2: Power Down
Turn off the computer, remove the power cord, then remove the cover.
Make sure the computer is turned off and disconnected from any
networks before installing the controller card.
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6.2.3 Step 3: Install Cache Memory
Important: A minimum of 32 Mbytes of cache memory is required. The
cache memory must be installed before the MegaRAID
controller is operational.
Install cache memory DIMMs on the MegaRAID controller card in the
cache memory socket. Use a 72-bit 3.3 V single-sided or double-sided
168-pin unbuffered DIMM. Lay the controller card component-side up on
a clean static-free surface. The memory socket is mounted flush with the
MegaRAID card, so the DIMM is parallel to the MegaRAID card when
properly installed. The DIMM clicks into place, indicating proper seating
in the socket. The MegaRAID card is shown lying on a flat surface below.
Figure 6.1 Installing DIMM Memory
6.2.3.1
Installing or Changing Memory
Important: The battery pack harness or cable must be disconnected
from J10 on the MegaRAID SCSI 320-2 Ultra320 card
before you add or remove memory.
Perform the following steps to install or change memory:
1. Bring down the operating system properly. Make sure that cache
memory has been flushed.
You must perform a system reset if operating under DOS. When the
computer reboots, the MegaRAID controller will flush cache memory.
2. Turn the computer power off. Disconnect the power cables from the
computer.
3. Remove the computer cover.
4. Disconnect the battery pack cable from the MegaRAID controller.
5. Remove the MegaRAID controller.
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6. You can now add or remove DRAM modules from the MegaRAID
controller, as described above.
7. Reattach the battery pack harness to J10 on the MegaRAID
controller.
8. Reinstall the MegaRAID controller in the computer. Follow the
instructions in this chapter.
9. Replace the computer cover and turn the computer power on.
6.2.3.2
Recommended Memory Vendors
Call LSI Logic Technical Support at 678-728-1250 for a current list of
recommended memory vendors.
6.2.4 Step 4: Check Jumper Settings
Make sure the jumper settings on the MegaRAID SCSI 320-2 card are
correct. The jumpers are set at the factory and you probably do not need
Table 6.2
Item
Jumpers for the MegaRAID SCSI 320-2
Description
Type
J2
J3
SCSI activity LED connector
Write pending indicator
4-pin header
2-pin header
3-pin header
3-pin header
3-pin header
2-pin header
2-pin header
2-pin header
J4
SCSI Termination Enable Channel 0
SCSI Termination Enable Channel 1
Battery connector
J5
J10
J16
J17
J18
BIOS Enable
Termination Power Channel 0
Termination Power Channel 1
Figure 6.2 shows the location of these items on the MegaRAID SCSI
320-2 controller.
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Figure 6.2 MegaRAID SCSI 320-2 Controller Layout
J4 J5
Internal High-Density
SCSI Connectors
J2
J3
Channel 0
Channel 1
DIMM Socket
J10
J17
External
Very-High
Density
J16
SCSI
Connectors
J18
6.2.4.1
6.2.4.2
6.2.4.3
J2 SCSI Activity LED
J2 is a four-pin connector that attaches to a cable that connects to the
hard disk LED mounted on the computer enclosure. The LED indicates
data transfers (SCSI bus activity.)
J3 Dirty Cache LED
J3 is a two-pin header for the dirty cache LED. This can be connected
to an LED on the computer enclosure. The LED will be lit when data in
the cache has not yet been written to the storage device.
J4/J5 Termination Enable
J4 and J5 are three-pin headers that specify the type of SCSI termination
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settings. Leave at the default setting (jumper on pins 1 and 2) to allow
the MegaRAID controller to automatically set its own SCSI termination.
Table 6.3
Pinout for J4/J5 Termination Enable
Type of SCSI Termination
J4/J5 Setting
Software control of SCSI termination using drive
detection (default).
Short pins 1-2
Permanently disable all onboard SCSI termination.
Permanently enable all onboard SCSI termination.
Short pins 2-3
OPEN
6.2.4.4
J10 Battery Pack Connector
J10 is a 3-pin connector that attaches to the optional battery pack.
Table 6.4
J10 External Battery Pinout
Pin
Signal Description
3
2
1
+BATT Terminal (red wire)
Thermistor (white wire)
-BATT Terminal (black wire)
6.2.4.5
J16 Onboard BIOS Enable
J16 is a 2-pin header that enables or disables the MegaRAID onboard
BIOS. The onboard BIOS should be enabled (J16 unjumpered) for
Table 6.5
Pinout for J16 BIOS Enable
Onboard BIOS Status
J16 Setting
Unjumpered
Jumpered
Enabled
Disabled
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6.2.4.6
J17/J18 SCSI Bus Termination Power
J17 and J18 are 2-pin jumpers that control the termination power setting
for channel 0 and channel 1, respectively. Leave both jumpers at the
default setting (jumper installed on pins 1 and 2) to allow the PCI bus to
provide termination power. (When the jumpers are removed, the SCSI
bus provides termination power.)
6.2.5 Step 5: Set Termination
Each MegaRAID SCSI channel can be individually configured for
termination enable mode by setting the J4 and J5 jumpers. You must
terminate the SCSI bus properly. Set termination at both ends of the
SCSI cable. The SCSI bus is an electrical transmission line and must be
terminated properly to minimize reflections and losses.
For a disk array, set SCSI bus termination so that removing or adding a
SCSI device does not disturb termination. An easy way to do this is to
connect the card to one end of the SCSI cable and to connect a
terminator module at the other end of the cable. The connectors between
the two ends can connect SCSI devices. Disable termination on the SCSI
devices. See the manual for each SCSI device to disable termination.
6.2.5.1
6.2.5.2
6-8
SCSI Termination
You can let the card automatically provide SCSI termination at one end
of the SCSI bus. You can terminate the other end of the SCSI bus by
attaching an external SCSI terminator module to the end of the cable or
by attaching a SCSI device that internally terminates the SCSI bus at the
end of the SCSI channel.
Use standard external SCSI terminators on a SCSI channel operating at
10 Mbytes/s or higher synchronous data transfer.
Terminating Internal SCSI Disk Arrays
Set the termination so that SCSI termination and termination power are
intact when any hard drive is removed from a SCSI channel, as shown
termination to be controlled by software. (See Section 6.2.4.3, “J4/J5
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Figure 6.3 Termination of Internal SCSI Disk Arrays
Terminator
ID2
ID1 – No Termination
ID0 – Boot Drive
No Termination
MegaRAID SCSI 320-2 Controller
Host Computer
6.2.5.3
Terminating External Disk Arrays
In most array enclosures, the end of the SCSI cable has an independent
SCSI terminator module that is not part of any SCSI drive. In this way,
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SCSI termination is not disturbed when any drive is removed, as shown
Figure 6.4 Terminating External Disk Arrays
External
SCSI Drives
ID 0
ID 1
ID 2
ID 3
ID 4
ID 5
ID 6
Termination
Enabled
6.2.5.4
Terminating Internal and External Disk Arrays
You can use both internal and external drives with the MegaRAID SCSI
320-2. You still must make sure that the proper SCSI termination and
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Figure 6.5 Terminating Internal and External Disk Arrays
Host Computer
Terminator
ID2
External
SCSI Drives
ID1 – No Termination
ID 0
ID 1
ID0 – Boot Drive
No Termination
ID 2
ID 3
ID 4
ID 5
ID 6*
Note: *Termination enabled from
last SCSI drive
MegaRAID 320-2
Host Computer
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6.2.5.5
Connecting Non-Disk SCSI Devices
SCSI tape drives and SCSI CD-ROM drives must each have a unique
SCSI ID regardless of the SCSI channel they are attached to. The
general rule for Unix systems is:
•
•
Tape drive set to SCSI ID 2
CD-ROM drive set to SCSI ID 5
Make sure that no hard drives are attached to the same SCSI Channel
as the non-disk SCSI devices. Drive performance will be significantly
degraded if SCSI hard disk drives are attached to this channel.
Figure 6.6 Connecting Non-Disk SCSI Devices
Host Computer
Internal SCSI Drives
ID0
Boot Drive
No Termination
ID1
No Termination
ID2
Termination
Enabled
Termination
Enabled
No Termination
ID2
ID5
External SCSI
CD-ROM Drive
External SCSI
Tape Drive
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6.2.6 Step 6 Set SCSI Terminator Power
J17 and J18 control the termination power setting for the MegaRAID
320-2 SCSI channels, as explained in Section 6.2.4.6, “J17/J18 SCSI
and 2 of J17 and J18), the PCI bus supplies termination power.
See the documentation for each SCSI device for information about
enabling TermPWR.
Important: The SCSI channels need Termination power to operate. If
a channel is not being used and no auxiliary power source
is connected, change the jumper setting for that channel to
supply TermPWR from the PCI bus.
6.2.7 Step 7: Install Battery Pack (Optional)
You can install a battery pack on the RAID controller using the J10
connector. The battery pack provides emergency power to the
MegaRAID 320-2 SCSI controller in the event of power failure.
•
•
LSI Logic Part Number: BAT-NIMH-3.6-02
Description: Battery, NIMH, 3.6 V, 600 mA onboard battery pack
with mounting brackets
You install the battery pack by attaching it to the controller board through
the backside of the board, using the three holes in the board. Then
connect the three wires from the battery pack to J10, the external battery
installed battery pack (upper right corner).
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Figure 6.7 MegaRAID Controller with Backup Battery Module
6.2.7.1
Configuring the Battery Pack
After you install the MegaRAID controller you must configure the battery
pack in the BIOS Configuration Utility. To do this, you select the Objects
menu options.
Table 6.6
Backup Battery Menu Options
Explanation
Menu Item
Battery Pack
PRESENT appears if the battery pack is properly installed;
ABSENT if it is not.
Temperature
Voltage
GOOD appears if the temperature is within the normal range.
HIGH appears if the module is too hot.
GOOD appears if the voltage is within the normal range. BAD
appears if the voltage is out of range.
Fast Charging COMPLETED appears if the fast charge cycle is done.
CHARGING appears if the battery pack is charging.
No. of Cycles Must be configured when you first install a battery pack. When
you select this option, a small pop-up window appears asking
if you want to reset the charge cycles. Select YES to reset the
number of cycles to zero.
After 1100 charge cycles, the life of the battery pack is
assumed to be over and you must replace it.
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6.2.7.2
Charging the Battery Pack
The battery pack is shipped uncharged, and you must charge it for
6 hours before you can use it. The battery pack will not supply power for
the full data retention time until it is fully charged.
It is a good idea to set the MegaRAID controller cache write policy option
to Write-Through during the battery pack charging period. After the
battery pack is fully charged, you can change the cache write policy to
Write-Back.
6.2.7.3
Changing the Battery Pack
The MegaRAID configuration software warns you when the battery pack
must be replaced. A new battery pack should be installed every 1 to 5
years. The procedure for changing the battery pack is as follows:
1. Bring down the operating system properly. Make sure that cache
memory has been flushed. You must perform a system reset if
operating under DOS.
When the computer reboots, the MegaRAID SCSI 320-2 Ultra320
controller flushes cache memory.
2. Turn the computer power off and remove the computer cover.
3. Remove the MegaRAID controller.
4. Disconnect the battery pack cable or harness from J10 on the
MegaRAID SCSI 320-2 Ultra320 controller.
5. Install a new battery pack and connect the new battery pack to J10.
6. Disable write-back caching using MegaRAID Manager or Power
Console Plus.
6.2.7.4
Disposing of a Battery Pack
Warning: Do not dispose of the MegaRAID battery pack by fire.
Do not mutilate the battery pack. Do not damage it in
any way. Toxic chemicals can be released if it is
damaged. Do not short-circuit the battery pack.
The material in the battery pack contains heavy metals that can
contaminate the environment. Federal, state, and local laws prohibit
disposal of some rechargeable batteries in public landfills. These
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batteries must be sent to a specific location for proper disposal. Call the
Rechargeable Battery Recycling Corporation at 352-376-6693 (FAX:
352-376-6658) for an authorized battery disposal site near you. For a list
of battery disposal sites, write to:
Rechargeable Battery Recycling Corporation
2293 NW 41st Street
Gainesville FL 32606
Voice: 352-376-6693
FAX: 352-376-6658
Important: Most used Nickel-Metal Hydride batteries are not classified
as hazardous waste under the federal RCRA (Resource
Conservation and Recovery Act). Although Minnesota law
requires that Nickel-Metal Hydride batteries be labeled
“easily removable” from consumer products, and that
Nickel-Metal Hydride batteries must be collected by
manufacturers, the Minnesota Pollution Control Agency
(MPCA) has granted a temporary exemption from these
requirements.
LSI Logic reminds you that you must comply with all applicable battery
disposal and hazardous material handling laws and regulations in the
country or other jurisdiction where you are using an optional battery pack
on the MegaRAID SCSI 320-2 controller.
6.2.8 Step 8: Install MegaRAID SCSI 320-2
Select a 3.3 V or 5 V PCI slot and align the MegaRAID SCSI 320-1
controller bus connector with the slot. Insert the MegaRAID SCSI 320-2
to make sure that the card is properly seated in the slot. The bottom
edge of the controller card should be flush with the slot. Attach the
bracket to the computer frame with the bracket screw.
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Figure 6.8 Installing the MegaRAID SCSI 320-2 Controller
Bracket Screw
32-bit slots
(3.3 V)
64-bit slots
(5 V)
6.2.9 Step 9: Connect SCSI Devices
Use SCSI cables to connect SCSI devices to the MegaRAID SCSI 320-1.
The MegaRAID SCSI 320-2 has the following connectors:
•
•
Two internal high-density 68-pin SCSI connectors: J7 is for SCSI
channel 0, J8 is for SCSI channel 1.
Two external very high-density 68-pin SCSI connector: J9 is for SCSI
channel 0, J19 is for SCSI channel 1.
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Use this procedure to connect SCSI devices:
1. Disable termination on any SCSI device that does not sit at the end
of the SCSI bus.
2. Configure all SCSI devices to supply TermPWR.
3. Set proper target IDs (TIDs) for each SCSI device.
4. Distribute SCSI devices evenly across the SCSI channels for
optimum performance.
5. Do not exceed the maximum cable length for the number and type
6. Try to connect all non-disk SCSI devices to a SCSI channel that has
no SCSI disk drives connected to it.
6.2.9.1
Cable Suggestions
System throughput problems can occur if SCSI cable use is not
maximized. Here are some cabling guidelines:
•
•
Use the shortest SCSI cables.
LVD mode cable lengths should be no more than 25 meters with two
devices and no more than 12 meters with eight devices.
•
•
•
•
•
•
Use active termination.
Avoid clustering the stubs.
Cable stub length should be no more than 0.1 meter (4 inches).
Route SCSI cables carefully.
Use high-impedance cables.
Do not mix cable types (choose flat cable for inside the enclosure,
and round shielded cables for outside the enclosure.)
•
Ribbon cables have fairly good cross-talk rejection characteristics.
6.2.10 Step 10: Set Target IDs
Set target identifiers (TIDs) on the SCSI devices. Each device in a
specific SCSI channel must have a unique TID in that channel. Non-disk
devices (CD-ROM or tapes) should have unique SCSI IDs regardless of
the channel where they are connected. See the documentation for each
SCSI device to set the TIDs. The MegaRAID SCSI 320-2 controller
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automatically occupies TID 7 on each SCSI channel. Eight-bit SCSI
devices can only use the TIDs from 0 to 6. 16-bit devices can use the
TIDs from 0 to 15. The arbitration priority for a SCSI device depends on
Table 6.7
Priority of Target IDs
Highest
Priority
Lowest
15 14 ...
TID
7
6
5
...
2
1
0
9
8
Important: Non-disk devices (CD-ROM or tape drive) should have
unique SCSI IDs regardless of the channel they are
connected to. ID 0 cannot be used for non-disk devices
because they are limited to IDs 1 through 6. There is a limit
of six IDs per controller for non-disk devices.
6.2.10.1 Example of MegaRAID SCSI 320-2 ID Mapping
Table 6.8
ID
Example of Mapping for SCSI 320-2
Channel 0
Channel 1
0
1
A1-1
A2-1
CD
A1-2
CD
2
A2-3
A2-6
A3-1
Tape
A5-1
Reserved
A5-3
A5-7
A6-2
A6-5
3
A2-5
CD
4
5
A4-1
Optical
Reserved
A5-2
A5-6
A6-1
A6-4
6
7
8
9
10
11
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Table 6.8
ID
Example of Mapping for SCSI 320-2 (Cont.)
Channel 0
Channel 1
12
13
14
15
A6-7
A7-2
A7-5
A7-8
A6-8
A7-3
A7-6
A8-1
6.2.11 Step 11: Power Up
Replace the computer cover and reconnect the AC power cords. Turn
power on to the host computer. Set up the power supplies so that the
SCSI devices are powered up at the same time as or before the host
computer. If the computer is powered up before a SCSI device, the
device might not be recognized.
During boot, the MegaRAID SCSI 320-2 BIOS message appears:
MegaRAID SCSI 320-2 Disk Array Adapter BIOS Version x.xx
date
Copyright (c) LSI Logic Corporation
Firmware Initializing... [ Scanning SCSI Device ..(etc.).. ]
The firmware takes several seconds to initialize. During this time the
adapter scans the SCSI channel(s). When ready, the following appears:
Host Adapter-1 Firmware Version x.xx DRAM Size 16 MB
0 Logical Drives found on the Host Adapter
0 Logical Drives handled by BIOS
Press <Ctrl><M> to run MegaRAID BIOS Configuration Utility
The <Ctrl><M> utility prompt times out after several seconds. The
MegaRAID SCSI 320-2 host adapter (controller) number, firmware
version, and cache DRAM size are displayed in the second portion of the
BIOS message. The numbering of the controllers follows the PCI slot
scanning order used by the host motherboard.
6.2.12 Step 12: Run the MegaRAID BIOS Configuration Utility
Press <Ctrl><M> to run the MegaRAID BIOS Configuration Utility. See
the MegaRAID Configuration Software Guide for more information.
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6.2.13 Step 13: Install the Operating System Driver
MegaRAID can operate under MS-DOS or any DOS-compatible
operating system using the standard AT BIOS INT 13h Hard Disk Drive
interface. To operate with other operating systems, you must install
software drivers. MegaRAID provides software drivers on the Driver and
Documentation CD for the following operating systems:
•
•
MS-DOS version 6.xx or later
Microsoft Windows NT 4.0, Windows 2000, Windows XP, Windows
.NET
•
•
Novell NetWare 5.1, 6.0
Red Hat Linux 7.2, 7.3
Note:
Refer to the MegaRAID Driver Installation Guide for the
procedures used to install operating system drivers.
6.3 Summary
This chapter discussed hardware installation. Configure the RAID system
using software configuration utilities. See the MegaRAID Configuration
Software Guide for all information about MegaRAID SCSI 320-2 software
Table 6.9
Configuration Utilities and Operating Systems
Configuration Utility
Operating System
MegaRAID BIOS Configuration Utility
WebBIOS Configuration Utility
MegaRAID Manager
Independent of the operating system
Independent of the operating system
DOS
Red Hat Linux 7.2, 7.3
Novell NetWare 5.1, 6.0
Power Console Plus
Microsoft Windows NT
Windows 2000
Windows XP
Windows .NET
Summary
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Chapter 7
Installing and Configuring
Clusters
This chapter explains how clusters work and how to install and configure
them. It has the following sections:
•
•
•
•
•
7.1 Overview
Physically, a cluster is a grouping of two independent servers that can
access the same shared data storage and provide services to a common
set of clients. With current technology, this usually means servers
connected to common I/O buses and a common network for client
access.
Logically, a cluster is a single management unit. Any server can provide
any available service to any authorized client. The servers must have
access to the same shared data and must share a common security
model. Again, with current technology, this generally means that the
servers in a cluster will have the same architecture and run the same
version of the same operating system.
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7.2 Benefits of Clusters
Clusters provide three basic benefits:
•
•
•
Improved application and data availability
Scalability of hardware resources
Simplified management of large or rapidly growing systems
7.3 Installation and Configuration
Use the following procedure to install and configure your system as part
of a cluster.
1. Unpack the controller, following the instructions in Chapter 6.
2. Set the hardware termination for the controller as “always on”. See
information.
3. Configure the IDs for the drives in the enclosure.
4. Install one controller at a time. Press <Ctrl> <M> at BIOS
attach the disks yet.
5. Set the controller to Cluster Mode in the Objects > Adapter > Cluster
Mode menu.
6. Disable the BIOS in the Objects > Adapter > Enable/Disable BIOS
menu.
7. Change the initiator ID in the Objects > Adapter > Initiator ID menu.
8. Power down the first server.
9. Attach the controller to the shared array.
10. Configure the first controller to the desired arrays using the Configure
> New Configuration menu.
Note:
Use the whole array size of any created array. Do not
create partitions of different sizes on the RAID arrays from
the BIOS Configuration Utility (<Ctrl><M>), because they
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cannot be failed over individually when assigned driver
letters in Windows 2000.
11. Follow the on-screen instructions to create arrays and save the
configuration.
13. Power down the second server.
14. Attach the cables for the second controller to the shared enclosure
and power up the second server.
15. If a configuration mismatch occurs, enter the <Ctrl> <M> utility, then
go to the Configure-> View/Add Configuration > View Disk menu to
view the disk configuration.
16. Save the configuration.
17. Proceed to the driver installation for a Microsoft cluster environment.
7.3.1 Driver Installation Instructions under Microsoft Windows 2000
Advanced Server
After the hardware is set up for the MS cluster configuration, perform the
following procedure to configure the driver under Microsoft Windows
2000 Advanced Server
When the controller is added after a Windows 2000 Advanced Server
installation, the operating system detects the controller.
1. When the Found New Hardware Wizard screen displays the detected
hardware device, click on Next.
2. When the next screen appears, select Search for a suitable
driver…. and click on Next.
The Locate Driver Files screen appears.
3. Insert the floppy diskette with the appropriate driver disk for Windows
2000, then select Floppy disk drives on the screen and click on
Next.
The Wizard detects the device driver on the diskette and the
"Completing the upgrade device driver" wizard displays the name of
the controller.
4. Click on Finish to complete the installation.
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system.
After the cluster is installed, and both nodes are in the Microsoft
Windows 2000 Advanced Server, installation will detect a SCSI
processor device.
6. On the Found New Hardware Wizard prompt, choose to display a list
of the known drivers, so that you can select a specific driver.
7. Click on Next.
8. Select the driver that you want to install for the device. If you have a
disk with the driver you want to install, click on Have Disk.
9. Select Other devices from the list of hardware types, then click on
Next.
10. Insert the disk containing the driver into the selected drive and click
on OK.
11. Select the processor device and click on Next.
12. On the final screen, click on Finish to complete the installation.
13. Repeat the process on the peer system.
7.3.2 Network Requirements
The network requirements for clustering are:
•
•
A unique NetBIOS cluster name
Five unique, static IP addresses:
–
–
–
Two addresses are for the network adapters on the internal
network
Two addresses are for the network adapters on the external
network
One address is for the cluster itself
•
•
A domain user account for Cluster Service (all nodes must be part
of the same domain.)
Two network adapters for each node—one for connection to the
external network and the other for the node-to-node internal cluster
network. If you do not use two network adapters for each node, your
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configuration is unsupported. HCL certification requires a separate
private network adapter.
7.3.3 Shared Disk Requirements
Disks can be shared by the nodes. The requirements for sharing disks
are as follows:
•
•
Physically attach all shared disks, including the quorum disk, to the
shared bus.
Make sure that all disks attached to the shared bus are seen from
all nodes. You can check this at the setup level in <Ctrl> <M> (the
page 7-27, for installation information.
•
Assign unique SCSI identification numbers to the SCSI devices and
terminate the devices properly. Refer to the storage enclosure
manual for information about installing and terminating SCSI devices.
•
•
Configure all shared disks as basic (not dynamic).
Format all partitions on the disks as NTFS.
It is best to use fault-tolerant RAID configurations for all disks. This
includes RAID levels 1, 5, 10, or 50.
7.4 Cluster Installation
7.4.1 Installation Overview
During installation, some nodes are shut down, and other nodes are
rebooted. This is necessary to ensure uncorrupted data on disks
attached to the shared storage bus. Data corruption can occur when
multiple nodes try to write simultaneously to the same disk, if that disk
is not yet protected by the cluster software.
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during each step.
Table 7.1
Step
Nodes and Storage Devices
Node 1 Node 2 Storage Comments
Set Up Networks
On
On
Off
Make sure that power to all storage devices
on the shared bus is turned off. Power on
all nodes.
Set up Shared Disks
On
Off
On
Power down all nodes. Next, power on the
shared storage, then power on the first
node.
Verify Disk Configuration Off
Configure the First Node On
On
Off
On
On
On
On
On
On
Shut down the first node. Power on the
second node.
Shut down all nodes. Power on the first
node.
Configure the Second
Node
On
On
Power on the second node after the first
node was successfully configured.
Post-installation
All nodes should be active.
Before installing the Cluster Service software you must follow the steps
below:
•
Install Windows 2000 Advanced Server or Windows 2000 Datacenter
Server on each node
•
•
Set up networks
Set up disks
Note:
These steps must be completed on every cluster node
before proceeding with the installation of Cluster Service on
the first node.
To configure the Cluster Service on a Windows 2000-based server, you
must be able to log on as administrator or have administrative
permissions on each node. Each node must be a member server, or
must be a domain controller inside the same domain. A mix of domain
controllers and member servers in a cluster is not acceptable.
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7.4.2 Installing Microsoft Windows 2000
Install Microsoft Windows 2000 on each node. See your Windows 2000
manual for information.
Log on as administrator before you install the Cluster Services.
7.4.3 Setting Up Networks
Note:
Do not allow both nodes to access the shared storage
device before the Cluster Service is installed. In order to
prevent this, power down any shared storage devices and
then power up nodes one at a time. Install the Clustering
Service on at least one node and make sure it is online
before you power up the second node.
Install at least two network card adapters per each cluster node. One
network card adapter card is used to access the public network. The
second network card adapter is used to access the cluster nodes.
The network card adapter that is used to access the cluster nodes
establishes the following:
•
•
•
Node to node communications
Cluster status signals
Cluster Management
Check to make sure that all the network connections are correct.
Network cards that access the public network must be connected to the
public network. Network cards that access the cluster nodes must
connect to each other.
Verify that all network connections are correct, with private network
adapters connected to other private network adapters only, and public
network adapters connected to the public network. View the Network and
Dial-up Connections screen to check the connections.
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Note:
Use crossover cables for the network card adapters that
access the cluster nodes. If you do not use the crossover
cables properly, the system will not detect the network card
adapter that accesses the cluster nodes. If the network
card adapter is not detected, then you cannot configure the
network adapters during the Cluster Service installation.
However, if you install Cluster Service on both nodes, and
both nodes are powered on, you can add the adapter as a
cluster resource and configure it properly for the cluster
node network in Cluster Administrator.
7.4.4 Configuring the Cluster Node Network Adapter
Note:
The wiring determines which network adapter is private and
which is public. For the purposes of this chapter, the first
network adapter (Local Area Connection) is connected to
the public network, and the second network adapter (Local
Area Connection 2) is connected to the private cluster
network. This may not be the case in your network.
7.4.4.1
Renaming the Local Area Connections
In order to make the network connection more clear, you can change the
name of the Local Area Connection (2). Renaming it will help you identify
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the connection and correctly assign it. Follow these steps to change the
name:
1. Right-click on the Local Area Connection 2 icon.
2. Click on Rename.
3. In the text box, type
Private Cluster Connection
and then press Enter.
4. Repeat steps 1-3 to change the name of the public LAN network
adapter to Public Cluster Connection.
5. The renamed icons should look like those in the picture above. Close
the Networking and Dial-up Connections window. The new
connection names automatically replicate to other cluster servers as
the servers are brought online.
7.4.5 Setting Up the First Node in Your Cluster
Follow these steps to set up the first node in your cluster.
1. Right-click on My Network Places, then click on Properties.
2. Right-click the Private Connection icon.
3. Click on Status. The Private Connection Status window shows the
connection status, as well as the speed of connection.
If the window shows that the network is disconnected, examine
cables and connections to resolve the problem before proceeding.
4. Click on Close
5. Right-click Private Connection again
6. Click on Properties.
7. Click on Configure.
8. Click on Advanced. The network card adapter properties window
displays.
9. You should set network adapters on the private network to the actual
speed of the network, rather than the default automated speed
selection.
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Select the network speed from the drop-down list. Do not use “Auto-
select” as the setting for speed. Some adapters can drop packets
while determining the speed.
Set the network adapter speed by clicking the appropriate option,
such as Media Type or Speed.
10. Configure identically all network adapters in the cluster that are
attached to the same network, so they use the same Duplex Mode,
Flow Control, Media Type, and so on. These settings should stay the
same even if the hardware is different.
11. Click on Transmission Control Protocol/Internet Protocol
(TCP/IP).
12. Click on Properties.
13. Click on the radio-button for Use the following IP address.
14. Enter the IP addresses you want to use for the private network.
15. Type in the subnet mask for the network.
16. Click the Advanced radio button, then select the WINS tab.
17. Select Disable NetBIOS over TCP/IP.
18. Click OK to return to the previous menu. Perform this step for the
private network adapter only.
7.4.6 Configuring the Public Network Adapter
Note:
It is strongly recommended that you use static IP
addresses for all network adapters in the cluster. This
includes both the network adapter used to access the
cluster nodes and the network adapter used to access the
LAN (Local Area Network). If you must use a dynamic IP
address through DHCP, access to the cluster could be
terminated and become unavailable if the DHCP server
goes down or goes offline.
The use of long lease periods is recommended to assure that a
dynamically assigned IP address remains valid in the event that the
DHCP server is temporarily lost. In all cases, set static IP addresses for
the private network connector. Note that Cluster Service will recognize
only one network interface per subnet.
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7.4.7 Verifying Connectivity and Name Resolution
Perform the following steps to verify that the network adapters are
working properly:
Note:
Before proceeding, you must know the IP address for each
network card adapter in the cluster. You can obtain it by
using the IPCONFIG command on each node.
1. Click on Start.
2. Click on Run.
3. Type cmd in the text box.
4. Click on OK.
5. Type ipconfig /all and press Enter. IP information displays for all
network adapters in the machine.
6. If you do not already have the command prompt on your screen, click
on Start.
7. Click on Run.
8. In the text box, type:
cmd
9. Click on OK.
10. Type
ping ipaddress
where ipaddress is the IP address for the corresponding network
adapter in the other node. For example, assume that the IP
addresses are set as follows:
Node Network Name
Network Adapter IP Address
1
1
2
2
Public Cluster Connection
192.168.0.171
10.1.1.1
Private Cluster Connection
Public Cluster Connection
Private Cluster Connection
192.168.0.172
10.1.1.2
In this example, you would type:
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Ping 192.168.0.172
Ping 10.1.1.1
and
from Node 1.
Then you would type:
Ping 192.168.0.172
and
10.1.1.1
from Node 2.
To confirm name resolution, ping each node from a client using the
node’s machine name instead of its IP number.
7.4.8 Verifying Domain Membership
All nodes in the cluster have to be members of the same domain and
capable of accessing a domain controller and a DNS Server. You can
configure them as either member servers or domain controllers. If you
plan to configure one node as a domain controller, you should configure
all other nodes as domain controllers in the same domain as well.
7.4.9 Setting Up a Cluster User Account
The Cluster Service requires a domain user account that the Cluster
Service can run under. You must create the user account before installing
the Cluster Service. The reason for this is that setup requires a user
name and password. This user account should not belong to a user on
the domain. Follow these steps to set up a cluster user account.
1. Click on Start.
2. Point to Programs, then point to Administrative Tools.
3. Click on Active Directory Users and Computers.
4. Click the plus sign (+) to expand the domain name (if it is not already
expanded.)
5. Click on Users.
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6. Right-click on Users.
7. Point to New and click on User.
8. Type in the cluster name and click on Next.
9. Set the password settings to User Cannot Change Password and
Password Never Expires.
10. Click on Next, then click on Finish to create this user.
Note:
If your company’s security policy does not allow the use of
passwords that never expire, you must renew the password
on each node before password expiration. You must also
update the Cluster Service configuration.
11. Right-click on Cluster in the left pane of the Active Directory Users
and Computers snap-in.
12. Select Properties from the context menu.
13. Click on Add Members to a Group.
14. Click on Administrators and click on OK. This gives the new user
account administrative privileges on this computer.
15. Close the Active Directory Users and Computers snap-in.
7.4.10 Setting Up Shared Disks
Warning: Make sure that Windows 2000 Advanced Server or
Windows 2000 Datacenter Server and the Cluster Service
are installed and running on one node before you start an
operating system on another node. If the operating system
is started on other nodes before you install and configure
Cluster Service and run it on at least one node, the cluster
disks will have a high chance of becoming corrupted.
To continue, power off all nodes. Power up the shared storage devices.
Once the shared storage device is powered up, power up node one.
7.4.10.1 Quorum Disk
The quorum disk stores cluster configuration database checkpoints and
log files that help manage the cluster. Windows 2000 makes the following
quorum disk recommendations:
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•
•
Create a small partition [Use a minimum of 50 Mbytes as a quorum
disk. Windows 2000 generally recommends a quorum disk to be 500
Mbytes.]
Dedicate a separate disk for a quorum resource. The failure of the
quorum disk would cause the entire cluster to fail; therefore,
Windows 2000 strongly recommends that you use a volume on a
RAID disk array.
During the Cluster Service installation, you have to provide the drive
letter for the quorum disk.
Note:
For our example, we use the letter E for the quorum disk
drive letter.
7.4.11 Configuring Shared Disks
Perform the following steps to configure the shared disks:
1. Right-click on My Computer.
2. Click on Manage, then click on Storage.
3. Double-click on Disk Management.
4. Make sure that all shared disks are formatted as NTFS and are
designated as Basic. If you connect a new drive, the Write Signature
and Upgrade Disk Wizard starts automatically.
If this occurs, click on Next to go through the wizard. The wizard sets
the disk to dynamic, but you can uncheck it at this point to set it to
basic.
To reset the disk to Basic, right-click on Disk # (where # identifies
the disk that you are working with) and click on Revert to Basic
Disk.
5. Right-click on unallocated disk space.
6. Click on Create Partition…
The Create Partition Wizard begins.
7. Click on Next twice.
8. Enter the desired partition size in Mbytes and click on Next.
9. Accept the default drive letter assignment by clicking on Next.
10. Click on Next to format and create a partition.
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7.4.12 Assigning Drive Letters
After you have configured the bus, disks, and partitions, you must assign
drive letters to each partition on each clustered disk. Follow these steps
to assign drive letters.
Note:
Mountpoints is a feature of the file system that lets you
mount a file system using an existing directory without
assigning a drive letter. Mountpoints is not supported on
clusters. Any external disk that is used as a cluster
resource must be partitioned using NTFS partitions and
must have a drive letter assigned to it.
1. Right-click on the desired partition and select Change Drive Letter
and Path.
2. Select a new drive letter.
3. Repeat steps 1 and 2 for each shared disk.
4. Close the Computer Management window.
7.4.13 Verifying Disk Access and Functionality
Perform the following steps to verify disk access and functionality:
1. Click on Start.
2. Click on Programs. Click on Accessories, then click on Notepad.
3. Type some words into Notepad and use the File/Save As command
to save it as a test file called test.txt. Close Notepad.
4. Double-click on the My Documents icon.
5. Right-click on test.txt and click on Copy.
6. Close the window.
7. Double-click on My Computer.
8. Double-click on a shared drive partition.
9. Click on Edit and click on Paste.
10. A copy of the file should now exist on the shared disk.
11. Double-click on test.txt to open it on the shared disk.
12. Close the file.
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13. Highlight the file and press the Del key to delete it from the clustered
disk.
14. Repeat the process for all clustered disks to make sure they can be
accessed from the first node.
After you complete the procedure, shut down the first node, power on the
second node and repeat the procedure above. Repeat again for any
additional nodes. After you have verified that all nodes can read and
write from the disks, turn off all nodes except the first, and continue with
this guide.
7.4.14 Installing Cluster Service Software
Before you begin the Cluster Service Software installation on the first
node, make sure that all other nodes are either powered down or
stopped and that all shared storage devices are powered on.
To create the cluster, you must provide the cluster information. The
Cluster Configuration Wizard allows you to input this information. Follow
these steps to use the Wizard:
1. Click on Start.
2. Click on Settings, then click on Control Panel.
3. Double-click on Add/Remove Programs.
4. Double-click on Add/Remove Windows Components.
5. Select Cluster Service, then click on Next.
Cluster Service files are located on the Windows 2000 Advanced
Server or Windows 2000 Datacenter Server CD-ROM.
6. Enter x:\i386 (where x is the drive letter of your CD-ROM). If you
installed Windows 2000 from a network, enter the appropriate
network path instead. (If the Windows 2000 Setup flashscreen
displays, close it.)
7. Click on OK. The Cluster Service Configuration Window displays.
8. Click on Next.
The Hardware Configuration Certification window appears.
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9. Click on I Understand to accept the condition that Cluster Service
is supported only on hardware listed on the Hardware Compatibility
List.
This is the first node in the cluster; therefore, you must create the
cluster itself.
10. Select the first node in the cluster, as shown below and then click on
Next.
11. Enter a name for the cluster (up to 15 characters), and click on Next.
(In our example, the cluster is named ClusterOne.)
12. Type the user name of the Cluster Service account that you created
during the pre-installation. (In our example, the user name is cluster.)
Do not enter a password.
13. Type the domain name, then click on Next.
At this point the Cluster Service Configuration Wizard validates the
user account and password.
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14. Click on Next.
The Add or Remove Managed Disks screen displays next. This
screen is in the following section about configuring cluster disks.
7.4.15 Configuring Cluster Disks
Windows 2000 Managed Disks displays all SCSI disks, as shown on the
screen below. It displays SCSI disks that do not reside on the same bus
as the system disk. Because of this, a node that has multiple SCSI buses
will list SCSI disks that are not to be used as shared storage. You must
remove any SCSI disks that are internal to the node and not to be shared
storage.
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In production clustering scenarios, you need to use more than one
private network for cluster communication to avoid having a single point
of failure. Cluster Service can use private networks for cluster status
signals and cluster management. This provides more security than using
a public network for these roles. In addition, you can use a public network
for cluster management, or you can use a mixed network for both private
and public communications.
In any case, verify that at least two networks are used for cluster
communication; using a single network for node-to-node communication
creates a potential single point of failure. We recommend that you use
multiple networks, with at least one network configured as a private link
between nodes and other connections through a public network. If you
use more than one private network, make sure that each uses a different
subnet, as Cluster Service recognizes only one network interface per
subnet.
This document assumes that only two networks are in use. It describes
how you can configure these networks as one mixed and one private
network.
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The order in which the Cluster Service Configuration Wizard presents
these networks can vary. In this example, the public network is presented
first.
Follow these steps to configure the clustered disks:
1. The Add or Remove Managed Disks dialog box specifies disks on
the shared SCSI bus that will be used by Cluster Service. Add or
remove disks as necessary, then click on Next.
The following screen displays.
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2. Click on Next in the Configure Cluster Networks dialog box.
3. Verify that the network name and IP address correspond to the
network interface for the public network.
4. Check the box Enable this network for cluster use.
5. Select the option All communications (mixed network), as shown
below, and click on Next.
The next dialog box configures the private network. Make sure that
the network name and IP address correspond to the network
interface used for the private network.
6. Check the box Enable this network for cluster use.
7. Select the option Internal cluster communications only, then click
on Next.
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In this example, both networks are configured so that both can be
used for internal cluster communication. The next dialog window
offers an option to modify the order in which the networks are used.
Because Private Cluster Connection represents a direct connection
between nodes, it remains at the top of the list.
In normal operation, this connection is used for cluster
communication. In case of the Private Cluster Connection failure,
Cluster Service automatically switches to the next network on the
list—in this case Public Cluster Connection.
8. Verify that the first connection in the list is the Private Cluster
Connection, then click on Next.
Note:
Always set the order of the connections so that the Private
Cluster Connection is first in the list.
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9. Enter the unique cluster IP address and Subnet mask for your
network, then click on Next.
The Cluster Service Configuration Wizard shown below automatically
associates the cluster IP address with one of the public or mixed
networks. It uses the subnet mask to select the correct network.
10. Click Finish to complete the cluster configuration on the first node.
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The Cluster Service Setup Wizard completes the setup process for
the first node by copying the files needed to complete the installation
of Cluster Service.
After the files are copied, the Cluster Service registry entries are
created, the log files on the quorum resource are created, and the
Cluster Service is started on the first node.
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11. When a dialog box appears telling you that Cluster Service has
started successfully. Click on OK.
12. Close the Add/Remove Programs window.
7.4.16 Validating the Cluster Installation
Use the Cluster Administrator snap-in to validate the Cluster Service
installation on the first node. Follow these steps to validate the cluster
installation.
1. Click on Start.
2. Click on Programs.
3. Click on Administrative Tools.
4. Click on Cluster Administrator.
The Cluster Administrator screen displays. If your snap-in window is
similar to the one shown in the screen, your Cluster Service was
successfully installed on the first node. You are now ready to install
Cluster Service on the second node.
7.4.17 Configuring the Second Node
Note:
For this procedure, have node one and all shared disks
powered on, then power up the second node.
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Installation of Cluster Service on the second node takes less time than
on the first node. Setup configures the Cluster Service network settings
on the second node based on the configuration of the first node.
Installation of Cluster Service on the second node begins the same way
as installation on the first node. The first node must be running during
installation of the second node.
Follow the same procedures used to install Cluster Service on the first
node, with the following differences:
1. In the Create or Join a Cluster dialog box, select The second or
next node in the cluster, then click Next.
2. Enter the cluster name that was previously created (it is MyCluster
in this example), and click Next.
3. Leave Connect to cluster as unchecked. The Cluster Service
Configuration Wizard automatically supplies the name of the user
account selected when you installed the first node. Always use the
same account you used when you set up the first cluster node.
4. Enter the password for the account (if there is one), then click Next.
5. At the next dialog box, click Finish to complete configuration.
The Cluster Service will start.
6. Click OK.
7. Close Add/Remove Programs.
8. If you install additional nodes, repeat the preceding steps to install
Cluster Service on all other nodes.
7.4.18 Verifying Installation
There are several ways to verify that Cluster Service was successfully
installed. Here is a simple one:
1. Click Start, click Programs, click Administrative Tools, then click
Cluster Administrator.
The presence of two nodes (pictured below) shows that a cluster
exists and is in operation.
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2. Right-click the group Disk Group 1 and select the option Move. This
option moves the group and all its resources to another node. After
a short period of time, the Disk F: G: will be brought online on the
second node. If you watch the screen, you will see this shift. Close
the Cluster Administrator snap-in.
Congratulations! You have completed installing Cluster Service on all
nodes. The server cluster is fully operational. Now, you are ready to
install cluster resources, such as file shares, printer spoolers, cluster
aware services like IIS, Message Queuing, Distributed Transaction
Coordinator, DHCP, WINS, or cluster aware applications like Exchange
or SQL Server.
7.5 Installing SCSI Drives
This information is provided as a generic instruction set for SCSI drive
installations. If the SCSI hard disk vendor’s instructions conflict with the
instructions in this section, always use the instructions supplied by the
vendor.
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The SCSI bus listed in the hardware requirements must be configured
prior to installation of Cluster Services. This includes:
•
•
Configuring the SCSI devices.
Configuring the SCSI controllers and hard disks to work properly on
a shared SCSI bus.
•
Properly terminating the bus. The shared SCSI bus must have a
terminator at each end of the bus. It is possible to have multiple
shared SCSI buses between the nodes of a cluster.
In addition to the information on the next page, refer to the
documentation from the SCSI device manufacturer or the SCSI
specifications, which can be ordered from the American National
Standards Institute (ANSI). The ANSI web site contains a catalog that
you can search for the SCSI specifications.
7.5.1 Configuring the SCSI Devices
Each device on the shared SCSI bus must have a unique SCSI ID. Since
most SCSI controllers default to SCSI ID 7, part of configuring the shared
SCSI bus will be to change the SCSI ID on one controller to a different
SCSI ID, such as SCSI ID 6. If there is more than one disk that will be
on the shared SCSI bus, each disk must also have a unique SCSI ID.
Some SCSI controllers reset the SCSI bus when they initialize at boot
time. If this occurs, the bus reset can interrupt any data transfers
between the other node and disks on the shared SCSI bus. Therefore,
SCSI bus resets should be disabled if possible.
7.5.2 Terminating the Shared SCSI Bus
You can connect Y cables to devices if the device is at the end of the
SCSI bus. You can then attach a terminator to one branch of the Y cable
to terminate the SCSI bus. This method of termination requires either
disabling or removing any internal terminators the device has.
Note:
Any devices that are not at the end of the shared bus must
have their internal termination disabled.
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Chapter 8
Troubleshooting
This chapter provides troubleshooting information for the MegaRAID
SCSI 320-2 controller. It contains the following sections:
•
•
•
•
8.1 General Troubleshooting
solutions.
Table 8.1
Problem
General Problems and Suggested Solutions
Suggested Solution
Some operating systems do not load in Check the system BIOS configuration for PCI interrupt
a computer with a MegaRAID SCSI
320-2 controller.
assignments. Make sure some Interrupts are assigned for
PCI.
Initialize the logical drive before installing the operating
system.
One of the hard drives in the array fails Check the drive error counts using Power Console Plus.
often.
(See the MegaRAID Configuration Software Guide for more
information.)
Format the drive.
Rebuild the drive
If the drive continues to fail, replace it with another drive with
the same capacity.
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Table 8.1
Problem
General Problems and Suggested Solutions (Cont.)
Suggested Solution
Pressed <Ctrl><M>. Ran
Check the drives IDs on each channel to make sure each
Megaconf.exe and tried to make a new device has a different ID.
configuration. The system hangs when
scanning devices.
Check the termination. The device at the end of the channel
must be terminated.
Replace the drive cable.
Multiple drives connected to the
Set the drives to spin on command. This will allow
MegaRAID SCSI 320-2 use the same MegaRAID SCSI 320-2 to spin two devices simultaneously.
power supply. There is a problem
spinning the drives all at once.
Pressing <Ctrl><M> or running
megaconf.exe does not display the
Management Menu.
These utilities require a color monitor.
At system power-up with the
At least 32 Mbytes of memory must be installed before
MegaRAID installed, the screen display power-up.
is garbled.
Cannot flash or update the EEPROM. You may need a new EEPROM.
Make sure that TERMPWR is being properly provided to
each peripheral device populated channel.
Firmware Initializing...
appears and remains on the screen.
Make sure that each end of the channel chain is properly
terminated using the recommended terminator type for the
peripheral device. The channel is automatically terminated
at the MegaRAID SCSI 320-2 card if only one cable is
connected to a channel.
Make sure that memory modules are PC100 or faster.
Make sure that the MegaRAID SCSI 320-2 controller is
properly seated in the PCI slot.
What is the maximum number of
MegaRAID adapters per computer?
Currently, all the utilities and drivers support up to 12
MegaRAID adapters per system.
What SCSI IDs can a non-hard disk
device have and what is maximum
number allowed per adapter?
Non-hard disk devices can accommodate only SCSI IDs 1,
2, 3, 4, 5, or 6, regardless of the channel used. A maximum
of six non-hard disk devices are supported per MegaRAID
SCSI 320-2 adapter.
Why does a failed logical array still get To maintain the DOS Path statement integrity.
a drive assignment?
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8.2 BIOS Boot Error Messages
boot the system, and suggested solutions.
Table 8.2
Message
BIOS Boot Error Messages
Problem
Suggested Solution
Adapter BIOS Disabled. The MegaRAID BIOS is Enable the BIOS using the MegaRAID BIOS
No Logical Drives
Handled by BIOS
disabled. Sometimes the Configuration Utility.
BIOS is disabled to
prevent booting from the
BIOS.
Host Adapter at
Baseport xxxx Not
Responding
The BIOS cannot
communicate with the
adapter firmware.
Make sure the MegaRAID SCSI 320-2 is
properly installed.
Try moving the MegaRAID controller to another
slot.
Run the MegaRAID Manager Diagnostics to
verify that the MegaRAID controller is
functioning properly
No MegaRAID SCSI
320-2 Adapter
The BIOS cannot
communicate with the
adapter firmware.
Make sure the MegaRAID SCSI 320-2 is
properly installed.
Try moving the MegaRAID card to another PCI
slot.
Run the MegaRAID Manager Diagnostics to
verify that MegaRAID is functioning properly.
Configuration of
nonvolatile RAM
(NVRAM) and drives
mismatch.
Run View/Add
Configuration option of
Configuration Utility.
Press any key to run the
Configuration Utility.
The configuration stored 1. Press a key to run MegaRAID Manager.
in the MegaRAID SCSI
320-2 adapter does not
match the configuration
stored in the drives.
2. Select View/Add Configuration from the
Configure menu.
3. Use View/Add Configuration to examine
both the configuration in NVRAM and the
configuration stored on the disk drives.
4. Resolve the problem by selecting one of the
configurations.
1 Logical Drive Failed
A logical drive failed to
sign on.
Make sure all physical drives are properly
connected and are powered on.
Run MegaRAID Manager to find out if any
physical drives are not responding. Reconnect,
replace, or rebuild any drive that is not
responding.
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Table 8.2
Message
BIOS Boot Error Messages (Cont.)
Problem
Suggested Solution
X Logical Drives
Degraded
x number of logical
drives signed on in a
degraded state.
Make sure all physical drives are properly
connected and are powered on.
Run MegaRAID Manager to find if any physical
drives are not responding. Reconnect, replace,
or rebuild any drive that is not responding.
1 Logical Drive
Degraded
A logical drive signed on Make sure all physical drives are properly
in a degraded state.
connected and are powered on.
Run MegaRAID Manager to find out if any
physical drives are not responding. Reconnect,
replace, or rebuild any drive that is not
responding.
Insufficient memory to
run BIOS. Press any key memory to run
Not enough MegaRAID Make sure MegaRAID memory has been
properly installed.
to continue…
MegaRAID BIOS.
Insufficient Memory
Not enough memory on Make sure MegaRAID memory has been
the MegaRAID adapter
to support the current
configuration.
properly installed.
The following SCSI IDs The physical drives with Make sure the physical drives are properly
are not responding:
Channel x:a.b.c
SCSI IDs a, b, and c are connected and are powered on.
not responding on SCSI
channel x.
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8.3 Other BIOS Error Messages
suggested solutions.
Table 8.3
Message
Other BIOS Error Messages
Problem
Suggested Solution
Following SCSI disk
not found and no
empty slot available
for mapping it
The physical disk roaming
feature did not find the
physical disk with the
displayed SCSI ID. No slot is
available to map the physical
drive. MegaRAID cannot
resolve the physical drives
into the current configuration.
Reconfigure the array.
Following SCSI IDs
have the same data y, feature found the same data
The physical drive roaming
Remove the drive or drives that should not
be used.
z
on two or more physical drive
on channel x with SCSI IDs a,
b, and c. MegaRAID cannot
determine the drive that has
the duplicate information.
Channel x: a, b, c
Unresolved
configuration
mismatch between
disks and NVRAM on on the drives.
the adapter
The configuration stored in the 1. Press a key to run MegaRAID Manager.
MegaRAID NVRAM does not
match the configuration stored
2. Select View/Add Configuration from the
Configure menu.
3. Use View/Add Configuration to examine
both the configuration in NVRAM and the
configuration stored on the disk drives.
4. Resolve the problem by selecting one of
the configurations.
8.4 Other Potential Problems
Other Potential Problems
Table 8.4
Topic
Information
DOS ASPI
MEGASPI.SYS, the MegaRAID DOS ASPI manager, uses 6 Kbytes of system
memory once it is loaded.
Other BIOS Error Messages
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Table 8.4
Topic
Other Potential Problems (Cont.)
Information
CD drives under
DOS
At this time, copied CDs are not accessible from DOS even after loading
MEGASPI.SYS and MEGACDR.SYS.
Physical drive errors To display the MegaRAID Manager Media Error and Other Error options, select
the Objects menu, then Physical Drive. Select a physical drive and press <F2>.
The windows displays the number of errors.
A Media Error is an error that occurred while actually transferring data. An
Other Error is an error that occurs at the hardware level because of a device
failure, poor cabling, bad termination, signal loss, etc.
Virtual sizing
The FlexRAID virtual sizing option enables RAID expansion. FlexRAID virtual
sizing must be enabled to increase the size of a logical drive or add a physical
drive to an existing logical drive. Run MegaRAID Manager by pressing <Ctrl>
<M> to enable FlexRAID virtual sizing. Select the Objects menu, then select
the Logical Drive menu. Select View/Update Parameters. Set FlexRAID Virtual
Sizing to Enabled.
BSD Unix
We do not provide a driver for BSDI Unix. MegaRAID SCSI 320-2 does not
support BSDI Unix.
Multiple LUNs
MegaRAID SCSI 320-2 supports one logical unit number (LUN) per each target
ID. No multiple LUN devices are supported.
MegaRAID power
requirements
The maximum MegaRAID SCSI 320-2 power requirements are 15 W at 5 V
and 3 A.
SCSI bus
The ANSI specification dictates the following:
requirements
• The maximum signal path length between terminators is 3 meters when
using up to 4 maximum capacitance (25 pF) devices and 1.5 meters when
using more than 4 devices.
• SCSI devices should be uniformly spaced between terminators, with the end
devices located as close as possible to the terminators.
• The characteristic impedance of the cable should be 90 +/- 6 ohms for the
/REQ and /ACK signals and 90 +/- 10 ohms for all other signals.
• The stub length (the distance from the controller's external connector to the
mainline SCSI bus) shall not exceed 0.1m (approximately 4 inches).
• The spacing of devices on the mainline SCSI bus should be at least three
times the stub length.
• All signal lines shall be terminated once at both ends of the bus powered
by the TERMPWR line.
8-6
Troubleshooting
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Table 8.4
Topic
Other Potential Problems (Cont.)
Information
Windows NT
Installation
When Windows NT is installed using a bootable CD, the devices on the
MegaRAID SCSI 320-2 are not recognized until after the initial reboot. The
Microsoft documented workaround is in SETUP.TXT, which is on the CD.
Perform the following steps to install drivers when Setup recognizes a
supported SCSI host adapter but doesn’t make the devices attached to it
available for use:
1. Restart Windows NT Setup.
2. Press <F6> to prevent Windows NT Setup from performing disk controller
detection when Windows NT Setup displays the following:
Setup is inspecting your computer's hardware configuration...,
This allows you to install the driver from the drivers disk you created. All
SCSI adapters must be installed manually.
3. Press <S> to display a list of supported SCSI host adapters when Windows
NT Setup displays the following:
Setup could not determine the type of one or more mass storage
devices installed in your system, or you have chosen to
manually specify an adapter,
4. Select Other from the bottom of the list.
5. Insert the drivers disk you made when prompted to do so and select Mega-
RAID from this list.
In some cases, Windows NT Setup repeatedly prompts to swap disks.
Windows NT will recognize any devices attached to this adapter.
6. Repeat this step for each host adapter not already recognized by Windows
NT Setup.
Other Potential Problems
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8-8
Troubleshooting
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Appendix A
SCSI Cables and
Connectors
The MegaRAID SCSI 320-2 provides several different types of SCSI
connectors. The connectors are:
•
•
Two 68-pin high density internal connectors
Two 68-pin very high density external connectors
A.1 68-Pin High-Density SCSI Internal Connector
Each SCSI channel on the MegaRAID SCSI 320-2 controller has a
68-pin high density 0.050 inch pitch unshielded connector.
These connectors provide all signals needed to connect the MegaRAID
SCSI 320-2 to Wide SCSI devices. The connector pinouts are for a
single-ended primary bus (P-CABLE) as specified in SCSI-3 Parallel
Interface X3T9.2, Project 885-D, revision 12b, dated July 2, 1993.
The cable assemblies that interface with the 68-pin connector are:
•
•
Flat ribbon or twisted pair cable for connecting internal Wide SCSI
devices
Round shielded cable for connecting external Wide SCSI devices
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A.1.1 Cable Assembly for Internal Wide SCSI Devices
The cable assembly for connecting internal Wide SCSI devices is shown
below.
Pin 1
Connectors: 68 Position Plug (Male)
AMP – 786090-7
Cable: Flat Ribbon or Twisted-Pair
Flat Cable
68 Conductor 0.025 Centerline
30 AWG
Pin 1
Pin 1
A-2
SCSI Cables and Connectors
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A.1.2 Connecting Internal and External Wide Devices
The cable assembly for connecting internal Wide and external Wide
SCSI devices is shown below.
A
Connector A: 68 Position Panel
Mount Receptacle with 4-40 Holes
(Female)
Pin 1
AMP – 786096-7
Note: To convert to 2-56 holes, use
screwlock kit 749087-1,
749087-2, or 750644-1 from
AMP
Pin 1
B
Connectors B: 68 Position Plug
(Male)
AMP – 786090-7
Cable: Flat Ribbon or Twisted-Pair
Flat Cable
Pin 1
68 Conductor 0.025 Centerline
30 AWG
B
68-Pin High-Density SCSI Internal Connector
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A.1.3 Converting Internal Wide to Internal Non-Wide (Type 2)
The cable assembly for converting internal Wide SCSI connectors to
internal non-Wide (Type 2) SCSI connectors is shown below.
Pin 1
68 Position
Connector
50 Position
Connector
Contact Number
Contact Number
A
6
40
7
1
2
3
4
41
Pin 1
B
49
16
50
17
51
18
52
19
20
21
22
23
24
25
26
27
Open
Open
Open
Pin 1
B
Connector A: 68 Position Plug (Male)
AMP– 749925-5
29
63
30
64
47
48
49
50
Connector B: 50 Position IDC
Receptacle (Female)
AMP – 499252-4, 1-746285-0,
1-746288-0
Table 1: Connector Contact
Connection for Wide to Non-Wide
Conversion
Wire: Twisted-Pair Flat Cable or
Laminated Discrete Wire Cable
25 Pair 0.050 Centerline
28 AWG
A-4
SCSI Cables and Connectors
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A.1.4 Converting Internal Wide to Internal Non-Wide (Type 30)
The cable assembly for converting internal Wide SCSI connectors to
internal non-Wide (Type 30) SCSI connectors is shown below.
Pin 1
Connector A: 68 Position Plug
(Male)
A
AMP– 749925-5
Connector B: 50 Position Plug
(Male)
AMP – 749925-3
Pin 1
Wire: Twisted-Pair Flat Cable or
B
Laminated Discrete Wire Cable
25 Pair 0.050 Centerline
28 AWG
A.1.5 Converting from Internal Wide to Internal Non-Wide (Type 3)
The cable assembly for converting internal Wide SCSI connectors to
internal non-Wide (Type 3) SCSI connectors is shown below.
Pin 1
A
Connector A: 68 Position Plug (Male)
AMP– 786090-7
Connector B: 50 Position Plug (Male)
AMP – 786090-7
Pin 1
Wire: Flat Ribbon or Twisted-Pair Flat
Cable 50 Conductor 0.025 Centerline
30 AWG
B
68-Pin High-Density SCSI Internal Connector
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A.2 SCSI Cable and Connector Vendors
Table A.1 SCSI Cable Vendors
Manufacturer
Telephone Number
Cables To Go
Voice: 800-826-7904 Fax: 800-331-2841
Voice: 800-877-1985
System Connection
Technical Cable Concepts
GWC
Voice: 714-835-1081
Voice: 800-659-1599
Table A.2
SCSI Connector Vendors
Connector Part Number
Manufacturer
Back Shell Part Number
AMP
749111-4
749193-1
Fujitsu
Honda
FCN-237R050-G/F
PCS-XE50MA
FCN-230C050-D/E
PCS-E50LA
A-6
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A.3 High-Density 68-Pin Connector Pinout for SE SCSI
single-ended SCSI.
Table A.3
High-Density 68-Pin Connector Pinout (SE SCSI)
Connector Cable
Cable Connector
Signal
Pin
Pin
Pin
Pin
Signal
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
1
1
2
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
-DB(12)
-DB(13)
-DB(14)
-DB(15)
-DB(P1)
-DB(0)
2
3
4
3
5
6
4
7
8
5
9
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
6
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
7
-DB(1)
8
-DB(2)
9
-DB(3)
10
11
12
13
14
15
16
-DB(4)
-DB(5)
-DB(6)
-DB(7)
-DB(P)
SWAP L
SHELF_OK
TERMPWR
TERMPWR
Reserved
FAULT_CLK H
-ATN
TERMPWR 17
TERMPWR 18
Reserved
Ground
Ground
19
20
21
High-Density 68-Pin Connector Pinout for SE SCSI
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Table A.3
Signal
High-Density 68-Pin Connector Pinout (SE SCSI)
Connector Cable
Cable Connector
Pin
Pin
Pin
Pin
Signal
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
Ground
22
23
24
25
26
27
28
29
30
31
32
33
34
43
45
47
49
51
53
55
57
59
61
63
65
67
44
46
48
50
52
54
56
58
60
62
64
66
68
56
57
58
59
60
61
62
63
64
65
66
67
68
FAULT_DATA H
-BSY
-ACK
-RST
-MSG
-SEL
-C/D
-REQ
-I/O
-DB(8)
-DB(9)
-DB(10)
-DB(11)
The following applies to the high-density SCSI connector described in
•
•
A hyphen before a signal name indicates that signal is active low.
The connector pin refers to the conductor position when using 0.025
inch centerline flat ribbon cable with a high-density connector
(AMPLIMITE.050 Series connectors).
•
•
Eight-bit devices connected to the P-Cable must leave the following
signals open: -DB (8), -DB (9), -DB (10), -DB (11), -DB(12), -DB (13),
-DB (14), -DB 15), and -DB (P1).
All other signals should be connected as defined.
Caution: Lines labeled RESERVED should be connected to Ground
in the bus terminator assemblies or in the end devices on
the SCSI cable. RESERVED lines should be open in the
other SCSI devices, but can be connected to Ground.
A-8
SCSI Cables and Connectors
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A.4 68-Pin Connector Pinout for LVD SCSI
Table A.4
68-Pin Connector Pinout for LVD SCSI
Connector Cable
Pin Pin
Cable
Pin
Connector
Pin
Signal
Signal
+DB(12)
+DB(13)
+DB(14)
+DB(15)
+DB(P1)
+DB(0)
1
1
2
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
-DB(12)
-DB(13)
-DB(14)
-DB(15)
-DB(P1)
-DB(0)
2
3
4
3
5
6
4
7
8
5
9
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
6
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
+DB(1)
7
-DB(1)
+DB(2)
8
-DB(2)
+DB(3)
9
-DB(3)
+DB(4)
10
11
12
13
14
15
16
17
18
19
20
21
22
-DB(4)
+DB(5)
-DB(5)
+DB(6)
-DB(6)
+DB(7)
-DB(7)
+DB(P)
Ground
DIFFSENS
TERMPWR
TERMPWR
Reserved
Ground
+ATN
-DB(P)
Ground
Ground
TERMPWR
TERMPWR
Reserved
Ground
-ATN
Ground
Ground
68-Pin Connector Pinout for LVD SCSI
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Table A.4
Signal
68-Pin Connector Pinout for LVD SCSI (Cont.)
Connector Cable
Cable
Pin
Connector
Pin
Pin
Pin
Signal
+BSY
+ACK
+RST
+MSG
+SEL
23
24
25
26
27
28
29
30
31
32
33
34
45
47
49
51
53
55
57
59
61
63
65
67
46
48
50
52
54
56
58
60
62
64
66
68
57
58
59
60
61
62
63
64
65
66
67
68
-BSY
-ACK
-RST
-MSG
-SEL
+C/D
-C/D
+REQ
+I/O
-REQ
-I/O
+DB(8)
+DB(9)
+DB(10)
+DB(11)
-DB(8)
-DB(9)
-DB(10)
-DB(11)
Note:
The “connector pin” in the table refers to the conductor
position when using flat-ribbon cable.
A-10
SCSI Cables and Connectors
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Appendix B
Audible Warnings
The MegaRAID SCSI 320-1 RAID controller has an onboard tone
generator that indicates events and errors.
Note:
This is available only if the optional series 502 Battery
Backup Unit (BBU) is installed.
Table B.1
Audible Warnings and Descriptions
Tone Pattern
Meaning
Examples
Three seconds on
and one second off offline.
A logical drive is
One or more drives in a RAID 0
configuration failed.
Two or more drives in a RAID 1,
or 5 configuration failed.
One second on and A logical drive is run- One drive in a RAID 5 configura-
one second off
ning in degraded
mode.
tion failed.
One second on and An automatically initi- While you were away from the
three seconds off ated rebuild has been system, a disk drive in a RAID 1,
completed.
or 5 configuration failed and was
rebuilt.
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B-2
Audible Warnings
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Appendix C
Glossary
Array
A grouping of individual disk drives that combines the storage space on
the disk drives into a single segment of contiguous storage space.
MegaRAID can group disk drives on one or more SCSI channels into an
array.
Array
Management
Software
Software that provides common control and management for a disk array.
Array management software most often executes in a disk controller or
intelligent host bus adapter, but it can also execute in a host computer.
When array management software executes in a disk controller or
adapter, it is often called firmware.
Array Spanning
Array spanning by a logical drive combines storage space in two arrays
of disk drives into a single, contiguous storage space in a logical drive.
MegaRAID logical drives can span consecutively numbered arrays that
have the same number of disk drives. Array spanning promotes RAID
levels 1 and 5 to RAID levels 10 and 50, respectively. See also Disk
Spanning.
Asynchronous
Operations
Operations that bear no relationship to each other in time and can
overlap. The concept of asynchronous I/O operations is central to
independent access arrays in throughput-intensive applications.
Cache I/O
A small amount of fast memory that holds recently accessed data.
Caching speeds subsequent access to the same data. It is most often
applied to processor-memory access, but it can also be used to store a
copy of data accessible over a network. When data is read from or
written to main memory, a copy is also saved in cache memory with the
associated main memory address. The cache memory software monitors
the addresses of subsequent reads to see if the required data is already
stored in cache memory. If it is already in cache memory (a cache hit),
the data is read from cache memory immediately and the main memory
read is aborted (or not started.) If the data is not cached (a cache miss),
it is fetched from main memory and saved in cache memory.
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Channel
An electrical path for the transfer of data and control information between
a disk and a disk controller.
Consistency
Check
An examination of the disk system to determine whether all conditions
are valid for the specified configuration (such as parity.)
Cold Swap
A cold swap requires that you turn the power off before replacing a
defective disk drive in a disk subsystem.
Data Transfer
Capacity
The amount of data per unit time moved through a channel. For disk I/O,
data transfer capacity (bandwidth) is expressed in megabytes per second
(Mbytes/s).
Degraded
Disk
Used to describe a disk drive that has become non-functional or has
decreased in performance.
A nonvolatile, randomly addressable, rewritable mass storage device,
including both rotating magnetic and optical disks and solid-state disks,
or nonvolatile electronic storage elements. It does not include specialized
devices such as write-once-read-many (WORM) optical disks, nor does
it include so-called RAM disks implemented using software to control a
dedicated portion of a host computer volatile random access memory.
Disk Array
A collection of disks from one or more disk subsystems combined with
array management software. The software controls the disks and
presents them to the array operating environment as one or more virtual
disks.
Disk Duplexing
Disk Mirroring
A variation on disk mirroring in which a second disk adapter or host
adapter and redundant disk drives are present.
Writing duplicate data to more than one (usually two) disk drives to
protect against data loss in the event of device failure. Disk mirroring is
a common feature of RAID systems.
Disk Spanning
Disk spanning allows multiple disk drives to function like one big drive.
Spanning overcomes lack of disk space and simplifies storage
management by combining existing resources or adding relatively
inexpensive resources. For example, four 36 Gbyte disk drives can be
combined to appear to the operating system as one single 144 Gbyte
drive. See also Array Spanning and Spanning.
Disk Striping
A type of disk array mapping. Consecutive stripes of data are mapped
round-robin to consecutive array members. A striped array (RAID 0)
C-2
Glossary
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provides high I/O performance at low cost, but provides lowers data
reliability than any of its member disks.
Disk Subsystem A collection of disks and the hardware that connects them to one or more
host computers. The hardware can include an intelligent controller, or the
disks can attach directly to a host computer I/O bus adapter.
Double
Buffering
A technique that achieves maximum data transfer bandwidth by
constantly keeping two I/O requests for adjacent data outstanding. A
software component begins a double-buffered I/O stream by issuing two
requests in rapid sequence. Thereafter, each time an I/O request
completes, another is immediately issued. If the disk subsystem is
capable of processing requests fast enough, double buffering allows data
to be transferred at the full-volume transfer rate.
Failed Drive
Fast SCSI
A drive that has ceased to function or consistently functions improperly.
A variant on the SCSI-2 standard. It uses the same 8-bit bus as the
original SCSI-1, but runs at up to 10 Mbytes (double the speed of SCSI-
1.)
Firmware
Software stored in read-only memory (ROM) or Programmable ROM
(PROM). Firmware often controls the behavior of a system when it is first
turned on. A typical example would be a monitor program in a computer
that loads the full operating system from disk or from a network and then
passes control to the operating system.
FlexRAID Power The FlexRAID Power Fail option allows a reconstruction to restart if a
Fail Option
power failure occurs. This is the advantage of this option. The
disadvantage is, once the reconstruction is active, the performance is
slower because an additional activity is added.
Format
The process of writing zeros to all data fields in a physical drive (disk
drive) to map out unreadable or bad sectors. Because most disk drives
are factory formatted, formatting is usually only done if a hard disk
generates many media errors.
GByte
Gigabyte. Shorthand for 1,000,000,000 (10 to the ninth power) bytes.
One Gbyte is equivalent to 1,000 Mbytes.
Host-based
Array
A disk array with an array management software in its host computer
rather than in a disk subsystem.
C-3
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Host Computer
Hot Spare
Any computer to which disks are directly attached. Mainframes, servers,
workstations, and personal computers can all be considered host
computers.
A stand-by disk drive ready for use if a drive in an array fails. A hot spare
does not contain any user data. Up to eight disk drives can be assigned
as hot spares for an adapter. A hot spare can be dedicated to a single
redundant array, or it can be part of the global hot-spare pool for all
arrays controlled by the adapter.
Hot Swapping
I/O Driver
The substitution of a replacement unit in a disk subsystem for a defective
one, where the substitution can be performed while the subsystem is
running. Hot swaps are done manually.
A host computer software component (usually part of the operating
system) that controls the operation of peripheral controllers or adapters
attached to the host computer. I/O drivers communicate between
applications and I/O devices, and in some cases they participate in data
transfer.
Initialization
The process of writing zeros to the data fields of a logical drive and
generating the corresponding parity to put the logical drive in a Ready
state. Initializing erases previous data and generates parity so that the
logical drive will pass a consistency check. Arrays can work without
initialization, but they can fail a consistency check because the parity
fields have not been generated.
Logical Disk
Logical Drive
A set of contiguous chunks on a physical disk. Logical disks are used in
array implementations as constituents of logical volumes or partitions.
Logical disks are normally transparent to the host environment, except
when the array containing them is being configured.
A virtual drive within an array that can consist of more than one physical
drive. Logical drives divide the contiguous storage space of an array of
disk drives or a spanned group of arrays of drives. The storage space in
a logical drive is spread across all the physical drives in the array or
spanned arrays. Configure at least one logical drive for each array.
Mapping
The conversion between multiple data addressing schemes, especially
conversions between member disk block addresses and block addresses
of the virtual disks presented to the operating environment by array
management software.
C-4
Glossary
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Mbyte
(Megabyte) An abbreviation for 1,000,000 (10 to the sixth power) bytes.
One Mbyte equals 1,000 Kbytes (kilobytes).
Multi-threaded
Having multiple concurrent or pseudo-concurrent execution sequences.
Used to describe processes in computer systems. Multi-threaded
processes allow throughput-intensive applications to efficiently use a disk
array to increase I/O performance.
Operating
Environment
The operating environment includes the host computer where the array
is attached, any I/O buses and adapters, the host operating system, and
any additional software required to operate the array. For host-based
arrays, the operating environment includes I/O driver software for the
member disks, but does not include array management software, which
is regarded as part of the array itself.
Parity
Parity is an extra bit added to a byte or word to reveal errors in storage
(in RAM or disk) or transmission. Parity is used to generate a set of
redundancy data from two or more parent data sets. The redundancy
data can be used to reconstruct one of the parent data sets, although it
does not fully duplicate the parent data sets. In RAID, this method is
applied to entire drives or stripes across all disk drives in an array. Parity
data is distributed among all the drives in the system. If a single disk
drive fails, the drive can be rebuilt from the parity of the respective data
on the remaining drives.
Partition
An array virtual disk made up of logical disks rather than physical ones.
Also known as logical volume.
Physical Disk
A hard disk drive that stores data. A hard disk drive consists of one or
more rigid magnetic discs rotating about a central axle with associated
read/write heads and electronics.
Physical Disk
Roaming
The ability of some adapters to detect when disk drives have been
moved to a different slot in the computer—for example, after a hot swap.
Protocol
A set of formal rules describing how to transmit data, especially across
a network. Low level protocols define the electrical and physical
standards to be observed, bit- and byte- ordering, and the transmission
and error detection and correction of the bit stream. High level protocols
deal with the data formatting, including the message syntax, the terminal-
to-computer dialogue, character sets, and sequencing of messages.
C-5
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RAID
Redundant Array of Independent Disks. A data storage method in which
data, along with parity information, is distributed among two or more hard
disks (called an array) to improve performance and reliability. A RAID
disk subsystem improves I/O performance on a server using only a single
drive. The RAID array appears to the host server as a single storage unit.
I/O is expedited because several disks can be accessed simultaneously.
RAID Levels
A style of redundancy applied to a logical drive. It can increase the
performance of the logical drive and can decrease usable capacity. Each
logical drive must have a RAID level assigned to it. The RAID level drive
requirements are: RAID 0 requires one or more physical drives, RAID 1
requires exactly two physical drives, RAID 5 requires at least three
physical drives. RAID levels 10 and 50 result when logical drives span
arrays. RAID 10 results when a RAID 1 logical drive spans arrays. RAID
50 results when a RAID 5 logical drive spans arrays.
RAID Migration
RAID migration is used to move between optimal RAID levels or to
change from a degraded redundant logical drive to an optimal RAID 0.
In Novell, the utility used for RAID migration is MEGAMGR; in
Windows NT, it is Power Console Plus. If a RAID 1 array is being
converted to a RAID 0 array, instead of performing RAID migration, one
drive can be removed and the other reconfigured on the controller as a
RAID 0. This is due to the same data being written to each drive.
Read-Ahead
A memory caching capability in some adapters that allows them to read
sequentially ahead of requested data and store the additional data in
cache memory, anticipating that the additional data will be needed soon.
Read-Ahead supplies sequential data faster, but it is not as effective
when accessing random data.
Ready State
Rebuild
A condition in which a workable disk drive is neither online nor a hot
spare and is available to add to an array or to designate as a hot spare.
The regeneration of all data from a failed disk in a RAID level 1, or 5
array to a replacement disk. A disk rebuild normally occurs without
interruption of application access to data stored on the array virtual disk.
Rebuild Rate
Reconstruct
The percentage of CPU resources devoted to rebuilding.
The act of remaking a logical drive after changing RAID levels or adding
a physical drive to an existing array.
C-6
Glossary
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Redundancy
The provision of multiple interchangeable components to perform a
single function to cope with failures or errors. Redundancy normally
applies to hardware; disk mirroring is a common form of hardware
redundancy.
Replacement
Disk
A disk available to replace a failed member disk in a RAID array.
Replacement
Unit
A component or collection of components in a disk subsystem that is
always replaced as a unit when any part of the collection fails. Typical
replacement units in a disk subsystem includes disks, controller logic
boards, power supplies, and cables. Also called a hot spare.
SAF-TE
SCSI
SCSI-accessed fault-tolerant enclosure. An industry protocol for
managing RAID enclosures and reporting enclosure environmental
information.
(Small computer system interface) A processor-independent standard for
system-level interfacing between a computer and intelligent devices,
including hard disks, floppy disks, CD-ROM, printers, scanners, etc.
Multiple SCSI devices can be connected to a single host adapter on the
computer's bus. SCSI transfers eight or 16 bits in parallel and can
operate in either asynchronous or synchronous modes. The synchronous
transfer rate is up to 320 Mbytes/s (for Ultra320 SCSI). SCSI connections
normally use single-ended drivers, as opposed to differential drivers.
SCSI Channel
MegaRAID controls the disk drives through SCSI-2 buses (channels)
over which the system transfers data in either Fast and Wide or Ultra
SCSI mode. Each adapter can control up to three SCSI channels.
Internal and external disk drives can be mixed on channels 0 and 1, but
not on channel 2.
SCSI Drive State A SCSI physical drive can be in one of these states:
•
•
Online: Powered-on and operational.
Ready: Functioning normally, but not part of a configured logical
drive and not designated as a hot spare.
•
Hot Spare: Powered-on stand-by disk drive, ready for use if an
online disk fails.
•
•
Fail: Out of service, due to a fault occurring on the drive.
Rebuild: Currently being rebuilt with data from a failed drive.
C-7
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Service
Provider
The Service Provider (SP) is a program that resides in the desktop
system or server and is responsible for all DMI activities. This layer
collects management information from products (whether system
hardware, peripherals, or software), stores that information in the DMI
database, and passes it to management applications as requested.
SNMP
Simple Network Management Protocol. The most widely used protocol
for communicating management information between the managed
elements of a network and a network manager. SNMP focuses primarily
on the network backbone. The Internet standard protocol that manages
nodes on an Internet Protocol (IP) network.
Spanning
Array spanning by a logical drive combines storage space in two arrays
of disk drives into a single, contiguous storage space in a logical drive.
MegaRAID logical drives can span consecutively numbered arrays that
each consist of the same number of disk drives. Array spanning
promotes RAID levels 1 and 5 to RAID levels 10 and 50, respectively.
See also Disk Spanning.
Spare
A disk drive available to back up the data of other drives.
Stripe Size
The amount of data contiguously written to each disk. You can specify
stripe sizes of 4, 8, 16, 32, 64, and 128 Kbytes for each logical drive. For
best performance, choose a stripe size equal to or smaller than the block
size used by the host computer.
Stripe Width
Striping
The number of disk drives across which the data is striped.
Segmentation of logically sequential data, such as a single file, so that
segments can be written to multiple physical devices in a round-robin
fashion. This technique is useful if the processor can read or write data
faster than a single disk can supply or accept it. While data is being
transferred from the first disk, the second disk can locate the next
segment. Data striping is used in some modern databases and in certain
RAID devices.
Terminator
A resistor connected to a signal wire in a bus or network for impedance
matching to prevent reflections—for example, a 50 ohm resistor
connected across the end of an Ethernet cable. SCSI buses and some
LocalTalk wiring schemes also require terminators.
C-8
Glossary
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Ultra320
A subset of Ultra3 SCSI that allows a maximum throughput of 320
Mbytes/s, which is twice as fast as Wide Ultra2 SCSI. Ultra320 SCSI
provides 320 Mbytes/s on a 16-bit connection.
Virtual Sizing
FlexRAID virtual sizing is used to create a logical drive up to 80 Gbytes.
A maximum of 40 logical drives can be configured on a RAID controller,
and RAID migration is possible for all logical drives except the fortieth.
Because it is not possible to do migration on the last logical drive, the
maximum space available for RAID migration is 560 Gbytes.
Wide SCSI
A variant on the SCSI-2 interface. Wide SCSI uses a 16-bit bus, double
the width of the original SCSI-1. Wide SCSI devices cannot be
connected to a SCSI-1 bus. Like Fast SCSI, Wide SCSI supports transfer
rates up to 20 Mbytes/s.
C-9
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C-10
Glossary
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Index
Validation 7-25
Cluster Node Network Adapter
Configuration 7-8
Numerics
0 DIMM socket 6-4
160M and Wide SCSI 4-1
Cluster Service
Assigning Drive Letters 7-15
Cluster Node Network Adapter 7-8
Cluster User Account 7-12
Configuring Cluster Disks 7-18
Connectivity and Name Resolution 7-11
Disk Access and Functionality 7-15
Domain Membership 7-12
SCSI Drive Installations 7-27
Setting Up Networks 7-7
68-pin connector pinout for LVD SCSI A-9
68-Pin High Density Connectors A-1
A
AMI Part Number
Battery 6-13
AMPLIMITE .050 Series connectors A-8
Array C-1
Shared Disks Configuration 7-14
Shared Disks Setup 7-13
Software Installation 7-16
Array Configuration Planner 5-15
Array management software C-1
Array performance features 4-5
Array spanning C-1
Assigning Drive Letters 7-15
Assigning RAID levels 5-12
Asynchronous operations C-1
Audible Warnings B-1
Validating the Cluster Installation 7-25
Cluster User Account
Setup 7-12
Clustering
Network Requirements 7-4
Shared Disk Requirements 7-5
Cold swap C-2
Automatic failed drive detection and rebuild 4-6
Compatibility 4-12
Components 4-8
Configuration on Disk 4-3
Configuration Strategies 5-10
Configuring Arrays 5-9
Configuring Logical Drives 5-13
Configuring SCSI Physical Drives
Distributing Drives 5-1
Configuring SCSI physical drives 5-1
Connecting internal and external Wide devices A-3
Converting from internal Wide to internal non-Wide (Type 3) A-5
Converting internal Wide to internal non-Wide A-4
Converting internal Wide to internal non-Wide (Type 30) A-5
CPU 4-8
B
Battery Pack 6-13
BIOS Boot Error Messages 8-3
BIOS Configuration Utility 6-20
BIOS message 6-20
Bus Data Transfer Rate 4-7
Bus Type 4-7
Bus-based 2-11
C
Cable assembly for internal Wide SCSI devices A-2
Cables To Go A-6
Cache Configuration 4-7
Cache I/O C-1
Creating hot spares 5-10
Creating logical drives 5-10
Cache Memory 4-9
Installing 6-4
Card Size 4-7
D
Changing DRAM Modules 6-15
Changing the Battery Pack 6-15
Channel C-2
Charging the Battery Pack 6-15
Cluster Configuration Wizard 7-16
Cluster Disks
Configuration 7-18
Cluster Installation 7-5
Overview 7-5
Data redundancy
Using mirroring 2-6
Data transfer capacity C-2
Dedicated parity 2-8
Devices per SCSI Channel 4-8
DIMM socket 6-4
DIMMs 6-4
MegaRAID SCSI 320-2 Hardware Guide
IX-1
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Disconnect/reconnect 4-10
Disk C-2
J
Disk Access and Functionality 7-15
Disk array C-2
Disk Array Types 2-11
Disk duplexing C-2
Disk rebuild 2-9
J10 External Battery 6-7
Jumpers
Setting 6-5
L
Disk subsystem C-3
Disposing of a Battery Pack 6-15
Documentation 1-3
DOS 4-7
Linux
Red Hat 4-7
Logical disk C-4
Logical drive states 2-10
Double buffering C-3
Drive roaming 4-3
Drivers 6-21
M
Mapping C-4
MB C-5
E
MegaRAID BIOS 4-9
MegaRAID BIOS Configuration Utility 4-11
MegaRAID SCSI 320-1 card
Installing 6-16
Enclosure management 2-11
F
MegaRAID SCSI 320-1 card layout 6-5
MegaRAID Specifications
Bus Data Transfer Rate 4-7
Bus Type 4-7
Fail 2-10
Failed 2-10
Failed drive C-3
Fast SCSI C-3
Fault tolerance 2-4
Fault tolerance features 4-6
Features 4-1
Cache Configuration 4-7
Card Size 4-7
Devices per SCSI Channel 4-8
Firmware 4-7
Nonvolatile RAM 4-8
Operating Voltage 4-8
Processor 4-7
RAID Levels Supported 4-8
SCSI Bus 4-8
Flash ROM 1-2
FlexRAID Power Fail option C-3
Format C-3
G
SCSI cables 4-8
SCSI Connectors 4-8
SCSI Controller 4-8
SCSI Data Transfer Rate 4-8
SCSI Device Types Supported 4-8
Serial Port 4-8
GB C-3
Glossary C-1
GWC A-6
Termination Disable 4-8
Mirroring 2-6
H
MS-DOS 6-21
Multi-threaded C-5
Multi-threading 4-11
Hardware Installation 6-1
High-density 68-pin SCSI connector pinout A-7
High-density single-ended connector A-8
Host computer C-4
Host-based array C-3
N
Host-based RAID solution 2-2
Nonvolatile RAM 4-8
NVRAM 1-2
Using during disk rebuild 2-9
I
O
I/O driver C-4
Offline 2-10
Initialization C-4
Install Cache Memory 6-4
Install Drivers 6-21
Installation steps
Custom 6-2
Onboard Speaker 4-9
Online
Drive state 2-10
Operating environment C-5
Operating system software drivers 4-7
Operating Voltage 4-8
Optimal 2-10
Optimizing Data Storage 5-13
IX-2
Index
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OS/2 2.x 4-12
Other BIOS error messages 8-5
SCSI Cable Vendors A-6
SCSI cables 4-8
Connecting 6-17
SCSI cables and connectors A-1
SCSI channel C-7
P
SCSI Connector Vendors A-6
SCSI Connectors 4-8
SCSI connectors 4-10
SCSI Controller 4-8
SCSI Data Transfer Rate 4-8
SCSI Device Compatibility 4-12
SCSI Device Types Supported 4-8
SCSI Devices
Partition C-5
Physical array 2-3
Physical disk C-5
Physical disk roaming C-5
Physical drive 2-3
Processor 4-7
Configuration 7-28
Product specifications 4-7
Protocol C-5
SCSI Drive Installations 7-27
SCSI Drive State C-7
SCSI firmware 4-10
SCSI Termination 4-8
Set 6-8
SCSI terminator power (TermPWR
Setting) 6-13
SCSI to SCSI 2-11
SCSI-to-SCSI RAID product 2-3
Serial Port 4-8
R
RAID C-6
Benefits 2-1
Introduction to 2-1
RAID 0 3-2
RAID 1 3-3
Spanning to configure RAID 10 2-8
RAID 10 3-6
Configuring 2-8
RAID 5 3-4
Spanning to make RAID 50 2-8
RAID 50 3-7
Serial port 4-9
Server management 4-12
Service provider C-8
Setting SCSI termination 6-8
Shared Disks
Configuration 7-14
Setup 7-13
Shared SCSI Bus
Termination 7-28
SMART Technology 4-3
SNMP C-8
Configuring 2-8
RAID benefits
Improved I/O 2-1
Increased reliability 2-2
RAID Levels Supported 4-8
RAID management 4-11
RAID management features 4-5
RAID migration C-6
RAID overview 2-3
Read-ahead C-6
Ready 2-10
Ready state C-6
Rebuilding a disk 2-9
Reconnect 4-10
SNMP agent 4-12
SNMP managers 4-12
Software utilities 4-6
Software-based 2-11
Spare C-8
Standby rebuild 2-9
Striping C-8
System Connection A-6
Reconstruct C-6
Reconstruction C-6
Red Hat Linux 6-21
RedAlert 4-12
Redundancy C-7
Replacement disk C-7
Replacement unit C-7
T
Tagged command queuing 4-10
Target IDs
Setting 6-18
Technical Cable Concepts A-6
Technical Support 1-vi
Termination Disable 4-8
Terminator C-8
S
SAF-TE C-7
Scatter/gather 4-10
Troubleshooting 8-1
SCO Unix 4-12
SCSI C-7
U
SCSI backup and utility software 4-12
SCSI bus 4-10
SCSI bus widths and maximum throughput 1-3
SCSI buses 1-2
Ultra3-SCSI (320M) C-9
UnixWare 4-12
Unpack 6-3
Index
IX-3
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