 |
Options
| Step
4 - Select Memory Options |
- Memory options are engineered specifically for use with this series and include
additional components, which are integral to the system architecture.
|
- Memory options consist of a series of base modules that contain one memory array. A
second array (called ² upgrades²
in the table) may be added to a base module in the factory or in the field.
|
|
0.5-GB GS80/160/320 base memory
module |
3X-MS8AA-AB |
|
0.5-GB GS80/160/320 memory DIMM
upgrade |
3X-MS8AA-AU |
|
1-GB GS80/160/320 base memory
module |
3X-MS8AA-BB |
|
1-GB GS80/160/320 memory DIMM
upgrade |
3X-MS8AA-BU |
|
2-GB GS80/160/320 base memory
module |
3X-MS8AA-CB |
|
2-GB GS80/160/320 memory DIMM
upgrade |
3X-MS8AA-CU |
|
4-GB GS80/160/320 base memory
module |
3X-MS8AA-DB |
|
4-GB GS80/160/320 memory DIMM
upgrade |
3X-MS8AA-DU |
| |
| Memory
Configuration Guidelines |
| Memory options should
be selected in the context of the application's sensitivity to memory bandwidth and memory
capacity, and the number of hardware partitions. This will determine the number of memory
base modules and upgrades needed. The total capacity required will determine the size of
the arrays to be chosen. |
The configuration of
memory may influence the performance of applications, and there are numerous ways to
configure the choices of memory base modules and upgrade DIMMs. The following general
guidelines can lead to several configuration choices. Application-specific guidelines will
help narrow down the choices.
- Configuring for capacity: The highest capacity is achieved when the 3X-MS8AA-DB/DU
combination is used.
- Configuring for performance: Interleaved operations reduce the average latency and
increase the memory throughput over non-interleaved operations. Each memory base module is
capable of 4-way interleaving with one array (no upgrades added) or 8-way interleaving
with two arrays (base module plus one upgrade). A system drawer is configured with eight
arrays (four base modules plus four array upgrades) provides 32-way interleaving and has
the maximum potential memory bandwidth. Refer to ² Memory
Applications Examples² below to determine which applications
gain the most benefit from this bandwidth.
- Memory modules should be configured in powers of 2: That is, 0, 1, 2, or 4 base modules
in a system drawer. Upgrades should also be installed in powers of 2: 0, 1, 2, or 4 base
modules in a system drawer.
- Although mixed-capacity memory modules may be configured, the highest bandwidth is
achieved when a system drawer is populated with eight identical arrays: four base modules
and four upgrades. The next-highest bandwidth would be four base modules (four arrays).
- If it is not possible to match the capacities of all the arrays, the next best choice is
to configure pairs of identical base modules, or base module/upgrade combinations. For
example, a configuration of two 2-GB base modules (3X-MS8AA-CB), each with a 1-GB upgrade
(3X-MS8AA-BU) is a better choice than a configuration of three 2-GB modules (3X-MS8AA-CB).
|
| |
| Memory Application
Examples |
Configuring memory is
a compromise between cost, total memory capacity, and memory bandwidth requirements. The
behavior of the application must be used to define the most-desired configuration. Some
applications are sensitive to memory capacity, some are sensitive to memory bandwidth,
some are sensitive to neither. If actual application measurements are not available, the
following may be used as guidelines:
- Large memory (VLM) applications, in which large amounts of memory can substantially
reduce I/O, may be optimized for total memory capacity and future capacity growth. In VLM
applications, the right balance might be one memory base module, with upgrade, for every
two CPUs. This would result in one memory array per CPU.
- Typical commercial applications, such as transaction processing (OLTP) and multi-user
timesharing, usually operate efficiently from cache and may not be materially affected by
memory bandwidth. Memory configuration is a balance between memory bandwidth and future
capacity growth. It is advisable to match the number of arrays to the number of CPUs.
- Data mining can benefit from additional memory bandwidth. It is best to match the number
of memory base modules to the number of CPUs.
- The most demanding high-performance technical applications (HPTC) achieve a performance
level that is directly proportional to memory bandwidth. In these cases, configure one
memory base module, with upgrade, per CPU. This results in two memory arrays per CPU.
The following table represents how 8 GB could be configured in a 4-CPU QBB system
drawer in each of the four referenced applications. The numbers under each application
represent how many of each memory option should be ordered. |
| |
| Memory Configuration Examples
– Configuring a system drawer with a total of 8 GB for specific applications |
| |
Application |
| |
|
VLM |
OLTP, Timesharing |
Data Mining |
HPTC |
| 1-GB base module |
(3X-MS8AA-BB) |
- |
- |
- |
4 |
| 1-GB upgrade |
(3X-MS8AA-BU) |
- |
- |
- |
4 |
| 2-GB base module |
(3X-MS8AA-CB) |
2 |
2 |
4 |
- |
| 2-GB upgrade |
(3X-MS8AA-CU) |
2 |
2 |
- |
- |
| The following additional
configuration options utilizing the 4-GB base module are available: |
| 4-GB base module |
(3X-MS8AA-DB) |
2 |
2 |
N/R |
N/R |
| 4-GB upgrade |
(3X-MS8AA-DU) |
- |
- |
|
|
| NOTE: N/R
= Not recommended - For these applications, configure either
four or eight like-sized memory options rather than one or two. |
| |
| Step 5 - Evaluate
Configuration Requirements to Support Optional Partitioning |
| Configuration Requirements for Partitions |
- Configuring partitions requires some attention to detail with respect to minimum
requirements for option selection, population, and option placement.
|
- A single AlphaServer GS80 Model 8 can be divided into two logical hardware partitions,
each running an instance of Tru64 UNIX or an instance of OpenVMS. Each partition is
allocated its own dedicated ² shared-nothing² set of hardware resources: System Drawer (s), CPU module(s),
memory module(s), and I/O.
|
- Multiple-drawer (QBB) hard partitions within a GS80 server do not provide complete
hardware failure isolation across hard partitions. Single hard partitioned drawers (QBBs)
within the server do provide hardware failure isolation.
|
- Each hardware partition is viewed as a unique node, from a system point-of-view, with
its own instance of Tru64 UNIX or OpenVMS operating system and application software,
independent system console, and error log.
|
- In the AlphaServer GS80, each of the two hardware partitions is defined by a single
system drawer.
|
- One system management console (3X-DS8xA-xx) and one console hub (3X-DS8AA-AA)
recommended per system.
|
- Supported option rules apply for maximum configurations of each AlphaServer GS80 system
partition. Care must be exercised to ensure that any planned reconfiguration of hardware
partitions will not violate option support rules.
|
| |
| Minimum Hardware Required per AlphaServer
GS80 Hardware Partition |
| Each hardware partition requires one system
drawer and that drawer must be configured with the minimum hardware listed below. Each
system drawer can be configured with additional hardware once this minimum requirement is
met. |
- One Alpha 21264 6/1001-MHz CPU module
|
- One 3X-MS8AA-BB/CB/DB memory module (1 GB, 2 GB, 4 GB)
|
- One 3X-KFWHA-BA system I/O module and one 3X-DWWPA-AA master PCI drawer. Depending upon
the configuration, this may require the use of a 3X-H9A20-AD/AE/AF expansion cabinet.
|
- AlphaServer GS80 systems are normally configured according to standard module placement
rules, and are shipped with one copy of the operating system installed at the factory
(Tru64 UNIX or OpenVMS). However, systems with hardware partitions offer hardware and
software configuration flexibility. Factory Integration Services (VIS) are recommended to
enable custom module configuration and factory installation of multiple copies of the
operating system on hardware partitioned systems.
|
| |
| Optimizing System Resources |
| The following configuration guidelines can be
used to improve performance in systems or in each partition of a hardware-partitioned
system. |
- Balance the resources in the system (or hardware partition) based upon the available
backplane space and the proposed option populations:
- Sparsely configured systems, those that are using half or less than half of their
available capacity for CPUs, memory, and PCI drawers, should be configured with the
options concentrated in as few system drawers as possible. For example, a GS80 Model 8
with four CPUs, four memory modules, and two PCI drawers would usually be configured in
the first system drawer. The first system drawer would be ²
active² and the second system drawer would be available for
expansion.
- Densely populated systems, those that are using more than half of their available
capacity for CPUs, memory, and PCI drawers, should be configured with the options spread
out across both system drawers.
|
- Configure active system drawers symmetrically, each with CPUs, memory, and PCI drawers.
|
- Configure the I/O adapters so that each active system drawer has direct access to the
most frequently accessed data.
|
| |
| System Software Required for AlphaServer
GS80 Hardware Partition Support |
| Software Licensing for Hardware Partitions |
- Base systems include operating system license (Tru64 UNIX or OpenVMS) that licenses up
to two hardware partitions
|
| User and capacity-based licensing is
unaffected by hardware partitions. Examples: |
- If a product is licensed for 200 concurrent users, these users can be split among the
partitions, but cannot exceed 200 total users.
|
- If users have a departmental (license code ² G² ) capacity license for a product, that license can be loaded into
the license databases on each of the hardware partitions.
|
| |
| Licensing Partitioned AlphaServer GS80
Systems for Both OpenVMS and Tru64 UNIX |
- If the system requires both OpenVMS and Tru64 UNIX operating systems be licensed, one
operating system license is included in the base system and the second is added as a line
item. The second operating system license upgrade, which includes the license for only one
CPU, would be added to the order using the following part numbers. Order appropriate media
and documentation kits from Step 13.
|
|
OpenVMS software upgrade for GS80 |
QB-63PAG-AG |
|
Tru64 UNIX software upgrade for
GS80 |
QB-595AM-AA |
| |
- Only those SMP processors intended for use with the second operating system must be
similarly licensed. Use the following license-only part numbers to add an SMP license for
any CPUs intended for use with the second operating system:
|
|
OpenVMS Alpha SMP license for
GS80 |
QL-MT1A9-6Q |
|
Tru64 UNIX Alpha SMP license for
GS80 |
QL-MT4A9-6Q |
| |
- The order of licensing is not important, but the following examples are similarly
constructed for clarity: The configuration starts with a Tru64 UNIX base system part
number and the addition of OpenVMS licenses.
|
Example 1: 8-CPU GS80
system in which all processors are licensed for both OpenVMS and Tru64 UNIX:
- Base system order would include a DA-A80BE-Ax and seven 3X-KN8AB-AB SMP upgrade CPUs
- Add one QB-63PAG-AG OpenVMS software upgrade and seven QL-MT1A9-6Q OpenVMS Alpha SMP
licenses
|
| |
Example 2: 8-CPU GS80
system in which all the processors are licensed for Tru64 UNIX and four processors are
also licensed for OpenVMS
- Base system order would include a DA-A80AE-Ax and seven 3X-KN8AB-AB SMP upgrade CPUs
- Add one QB-63PAG-AG OpenVMS software upgrade and three QL-MT1A9-6Q OpenVMS Alpha SMP
licenses
|
- User and capacity-based licenses would be added for the second operating system
environment as though it were a standalone system.
|
| |
| Step
6 - Configure Packaging Options |
| Step
6a - Redundant (N+1) Power Supplies |
- Power supplies included with Model 4 and Model 8 systems can support all combinations of
CPUs, memory, and I/O that can be configured within the system boxes.
|
- Additional 48V power regulators can be ordered to provide N+1 power redundancy.
|
- For Model 4 systems, order one power supply to achieve N+1 capability; for Model 8
systems, order two power supplies to achieve N+1 capability.
|
|
1000 W 48V power
supply |
H7510-AA |
| |
| Step
6b - Internal System Expansion |
- AlphaServer GS80 Model 4 and Model 8 systems can support one additional PCI drawer
(master or expansion) or one BA36R or
DS-SL13R-xx StorageWorksä shelf in the system
cabinet.
|
| |
| Internal
StorageWorks Expansion |
- System cabinet provides space for one forward facing StorageWorks shelf. There are two
configuration options:
- One BA36R-RC/RD StorageWorks shelf; shelf holds a maximum of two 5.25-inch devices and
one 3.5-inch device or seven 3.5-inch devices or
- One DS-SL13x-xx Ultra3 SCSI (LVD) shelf; shelf supports a maximum of 14 Ultra3 disk
drives
|
|
- Each UltraSCSI StorageWorks shelf requires a SCSI controller and a SCSI cable to connect
controller to shelf
|
|
|
- StorageWorks drives are listed in a subsequent section
|
|
| |
|
|
| Configuring BA36R StorageWorks
Shelf |
UltraSCSI single-channel SE
StorageWorks shelf includes 16-bit I/O personality module (DS-BA35X-FA), 180W ac power
supply, dc fans, and RETMA rackmounting hardware; supports 16-bit UltraSCSI devices and
some 8-bit narrow SCSI devices depending on compliance with minimum revision levels |
BA36R-RC |
|
UltraSCSI dual-channel SE
StorageWorks shelf, includes 16-bit I/O personality module
(DSBA35X-FB), 180W ac power supply, dc fans, and RETMA rackmounting hardware; supports
16-bit UltraSCSI devices and some 8-bit narrow SCSI devices depending on compliance with
minimum revision levels |
BA36R-RD |
|
UltraSCSI StorageWorks
Differential personality card; installs in BA36R-RC and is cabled to the KZPBA-CB or
3X-KZPBA-CC; field installed only |
DS-BA35X-DA |
| |
| Configuring DS-SL13R-xx Ultra3
(LVD) Shelf |
- Single-bus Ultra3 shelf requires a 3X-KZPCA-AA Ultra2 (LVD) SCSI adapter or
DS-KZPCC-xx RAID controller and a SCSI cable to connect controller to shelf
|
|
|
- Split-bus Ultra3 shelf requires two 3X-KZPCA-AA Ultra2 (LVD) SCSI adapters or
DS-KZPCC-xx RAID controllers and SCSI cables to connect controller to shelf
|
|
|
- Ultra3 shelves connected to 3X-KZPCA-AA adapters in the power cabinet require BN38C-02
2-meter cables; DS-KZPCC-xx RAID controllers require BN37A-02
2-meter cables.
|
|
|
- Ultra3 shelves connected to 3X-KZPCA-AA adapters in an attached expander cabinet require
BN38C-10 10-meter cables; DS-KZPCC-xx RAID controllers require BN37A-10 10-meter cables.
|
|
|
- Ultra3 shelves connected to 3X-KZPCA-AA adapters in a remote expander cabinet require 10
20-meter BN38C-xx cables, depending upon physical cabinet location;
DS-KZPCC-xx RAID controllers require BN37A-xx cables.
|
|
|
- Ultra3 Universal drives are listed in a subsequent section
|
|
|
StorageWorks Model
4314R Ultra3 SCSI (LVD) single-bus Universal drive rack-mount shelf, International except
Japan |
DS-SL13R-AA |
|
StorageWorks Model
4314R Ultra3 SCSI (LVD) single-bus Universal drive rack-mount shelf, Japan |
DS-SL13R-AJ |
|
StorageWorks Model
4354R Ultra3 SCSI (LVD) split-bus Universal drive rack-mount shelf, International except
Japan |
DS-SL13R-BA |
|
StorageWorks Model
4354R Ultra3 SCSI (LVD) split-bus Universal drive rack-mount shelf, Japan |
DS-SL13R-BJ |
| |
| Power Option for
BA36R Shelves |
- Additional power supply provides N+1 power for StorageWorks shelves; power supply uses
3.5-inch slot in StorageWorks shelf reducing total number of devices supported by one
|
|
- StorageWorks drives are listed in a subsequent section
|
|
|
180W redundant power supply for
StorageWorks shelf; includes power cord |
CK-BA35X-HH |
| |
|
|
| Power Option for DS-SL13R-xx
Shelves |
- Additional power supply provides N+1 power for 4314R Ultra3 (LVD) StorageWorks shelves;
power supply uses a dedicated location in the shelf.
|
|
|
- Not required for 4354R shelves.
|
|
|
Redundant power supply for 4314R
Ultra3 (LVD) StorageWorks shelf, North America |
DS-SE2UP-AA |
|
Redundant power supply for 4314R
Ultra3 (LVD) StorageWorks shelf, International |
DS-SE2UP-AI |
| |
|
|
| System I/O
Expansion |
- Model 4 systems support up to two PCI drawers; Model 8 systems support up to four PCI
drawers. One PCI drawer included in Model 4 and Model 8 base systems.
|
|
- Model 4 and Model 8 system cabinets provide space for one additional PCI drawer or one
internal storage shelf.
|
|
|
- Additional PCI drawers and storage shelves can be configured in 3X-H9A20-AD/AE/AF I/O
expansion cabinets, described in a subsequent section.
|
|
|
- All PCI drawers contain 14 PCI slots configured into four PCI buses; two of the buses
have four slots each, the other two buses have three slots each.
|
|
|
- There are two types of PCI drawers: expansion drawers and master drawers. Base system
configurations include one PCI master drawer with 12 configurable PCI slots.
|
|
|
- Expansion drawers contain 14 PCI slots and N+1 redundant power system; expansion drawers
are used for most PCI expansion applications.
|
|
|
- Optional master PCI drawers contain 13 configurable PCI slots, N+1 redundant power
system, plus the console ports and storage devices required for use as a system console.
(These devices are listed on page 2. Note that the Fast Ethernet adapter is not included
in optional master PCI drawers.) Optional master PCI drawers have two applications:
- As redundant console sub-systems
- As consoles for individual partitions in hardware partitioned systems
|
|
|
- PCI drawers are connected to a drawer utilizing a 3X-KFWHA-BA system I/O module that
connects to the PCI drawer using two BN39B cables.
|
|
| |
|
|
| PCI Drawer
Expansion |
- PCI drawers are connected to a drawer utilizing a 3X-KFWHA-BA system I/O module that
connects to the PCI drawer using two BN39B cables.
|
|
- Maximum one additional drawer in the system power cabinet see ²
External Expansion Cabinets² for more details.
|
|
|
- PCI drawers can be split between multiple system drawers as long as all system drawers
are contained within the same hardware partition.
|
|
|
- PCI drawers mounted in a common H9A20 Expansion Cabinet can server multiple systems.
|
|
|
Master PCI shelf mount box for
system and I/O expansion cabinets with standard I/O PCI module and 13 PCI expansion slots.
(The 1st master comes standard with all systems and includes a standard dual Ethernet
network card and the system module and cable pair for connection to the system drawer). |
3X-DWWPA-AA
|
|
Expansion PCI shelf mount box for
system and I/O expansion cabinets with 14 PCI expansion slots |
3X-DWWPA-BA |
|
System I/O module for connecting
to master or expansion PCI shelves |
3X-KFWHA-BA |
|
I/O module cable for connection
between I/O module and master or expansion PCI shelves is mounted in system cabinet; two
are mandatory per system I/O module |
BN39B-04
|
| |
|
|
| Step 6c - External Expansion Cabinets |
- Additional PCI drawers and storage shelves can be installed in an optional
3X-H9A20-AD/AE/AF expansion cabinet. One 3X-H9A20-AD/AE/AF expansion cabinet is supported
|
- The 3X-H9A20-AD/AE/AF I/O expansion cabinet can be configured to hold all disk BA36R
StorageWorks shelves or
DS-SL13R-xx Ultra3 StorageWorks shelves or combination of StorageWorks shelves and PCI
drawers.
- If no PCI drawers are configured, cabinet supports up to eight BA36R or five DS-SL13R-xx
StorageWorks shelves.
- If one PCI drawer is configured, cabinet supports up to five BA36R or four DS-SL13R-xx
StorageWorks shelves.
- If two PCI drawers are configured, cabinet supports up to four BA36R or three
DS-SL13R-xx StorageWorks shelves.
- If three PCI drawers are configured, cabinet supports up to two BA36R or two DS-SL13R-xx
StorageWorks shelves.
|
| |
- BA36R and DSSL13x-xx StorageWorks shelves can be combined in the same expansion cabinet,
but cannot be factory configured
|
|
Black I/O expansion cabinet for
use with GS80 systems, includes two 120V single-phase power controllers and cords for use
in US and Canada – does not support dual AC input configurations |
3X-H9A20-AD |
|
Black I/O expansion cabinet for
use with GS80 systems, includes two 220-240V single-phase power controllers and cords for
use in Europe – supports dual AC input configurations |
3X-H9A20-AE |
|
Black I/O expansion cabinet for
use with GS80 systems, includes two 200-240V single-phase power controllers and cords for
use in U.S., Canada, and Japan – supports dual AC input configurations |
3X-H9A20-AF |
- If large quantities of disks are required, the use of StorageWorks Storage Array
cabinets and components is highly recommended.
|
- Systems installed in the US and Canada may use the 3X-H9A20-AD cabinet when 120V input
power is required. In all other cases, the 3X-H9A20-AF cabinet is preferred because of the
ability to support dual AC input.
|
- 3X-H9A20-AD/AE/AF cabinets may be joined to a GS80 system. PCI drawers placed in these
cabinets require 7-meter I/O cables.
|
- 3X-H9A20-AD/AE/AF cabinets may be placed up to 6 meters from the system cabinet.
Multiple expander cabinets may be connected to one another or placed separately. Each
group of free-standing H9A20 cabinets requires an end-panel trim kit (CK-H9A20-AB).
|
- PCI drawers placed in remote cabinets require 10-meter I/O cables.
|
|
Black end-panel trim kit for
remote 3X-H9A20-AD/AE/AF cabinets |
CK-H9A20-AB |
|
I/O module cables for connection
between I/O module and master or expansion PCI drawers mounted in 3X-H9A20-AD/AE/AF
expansion cabinet adjacent to system; two cables (BN39B-07 or BN39B-10) are mandatory per
PCI drawer. |
BN39B-07 |
|
I/O module cables for connection
between I/O module and master or expansion PCI drawers mounted in second expansion cabinet
or in remote 3X-H9A20-AD/AE/AF expansion cabinets; two cables (BN39B-07 or BN39B-10) are
mandatory per PCI drawer. |
BN39B-10 |
| |
| Step 7 - Storage |
| Step 7a - PCI UltraSCSI Adapters and Controllers |
- Tru64 UNIX can support more SCSI controllers per hardware partition than can be
configured in the AlphaServer GS80 system. Refer to the ²
Supported Options List² for specific rules.
|
- OpenVMS supports 24 KZPBA-CB/3X-KZPBA-CC SCSI controllers per system.
|
- Each master PCI drawer contains an embedded SCSI controllers that must be included in
the total count of SCSI controllers configured in the system (or partition). Tru64 UNIX
counts FIS disk and CD-ROM as an embedded SCSI device. OpenVMS counts the FIS disk only as
an embedded SCSI device. Therefore, one (OpenVMS) or two (Tru64 UNIX) SCSI controllers per
master PCI drawer must be included in the total count of SCSI devices in the system.
|
- For cluster configurations, use Y cable (BN39A-0G).
|
- Manufacturing may substitute correct cable lengths depending on configuration.
|
| NOTE: ² Per System² quantities apply to
systems or to each hardware partition. The SCSI adapters included in the base system or in
3x-DWWPA-AA master PCI drawers must be included in this calculation. |
| |
| |
Maximum #
Supported |
|
| |
Tru64 UNIX |
OpenVMS |
|
| |
Per System |
Per
System Drawer |
Per PCI Drawer |
Per
System |
Per
System Drawer |
Per PCI Drawer |
|
| PCI Fibre Channel adapter (uses
one PCI slot); requires Fibre Channel with SC connector for adapter |
26/54* |
26/26* |
13 |
26 |
26 |
13 |
DS-KGPSA-CA |
| 2-GB, PCI Fibre Channel adapter,
(uses one PCI slot); requires Fibre Channel cable with LC connector for adapter |
54 |
26 |
13 |
26 |
26 |
4 |
DS-KGPSA-DA |
Fibre Channel SC-SC cable
(BNGBX-xx),
xx=02, 03, 05, 10, 15, 30, 50 meters |
|
|
|
|
|
|
BNGBX-xx |
| Fibre Channel SC-LC cable,
2-meter (2976), 5-meter (2977), 15-meter (2978), 30-meter (3458), 50-meter (3459) |
|
|
|
|
|
|
3R-Axxxx-AA |
| Fibre Channel LC-LC cable,
2-meter (2979), 5-meter (2980), 15-meter (2981), 30-meter (3454), 50-meter (3455) |
|
|
|
|
|
|
3R-Axxxx-AA |
| |
| PCI 1-port UltraSCSI single-ended
host adapter (uses one PCI slot) |
8 |
8 |
8 |
8 |
8 |
8 |
KZPBA-CA |
| PCI 1-port UltraSCSI differential
host adapter (uses one PCI slot); requires BN38C-xx cable |
24/54* |
24/26* |
12/13* |
24 |
24 |
12 |
3X-KZPBA-CC |
VHDCI male-to-68-pin HD male
UltraSCSI cable xx=02, 05, 10, 20
(use -02 for connecting SCSI adapter to SCSI devices when both PCI shelf and StorageWorks
shelf are in system cabinet or in adjacent expansion cabinet; use -05, -10, and -20 for
connecting SCSI adapter to SCSI devices when the PCI shelf and StorageWorks shelf are in
two different cabinets) |
|
|
|
|
|
|
BN38C-xx |
| NOTE:
* = Tru64 UNIX V5.1 required to support 54 adapters per partition and 13 adapters
per PCI drawer. Tru64 UNIX 4.0G supports 24 adapters per partition |
| PCI 1-port Ultra 2 (LVD) SCSI
adapter, 32-bit, single-channel (uses one PCI slot); includes external 68-pin HD
connectors; requires BN38C-xx cable to connect adapter to Ultra2 or Ultra3 shelf; HSZxx
RAID controllers not supported |
8 |
8 |
8 |
8 |
8 |
8 |
3X-KZPCA-AA |
68-pin HD male-to-VHDCI male
UltraSCSI cable;
xx=02, 03, 05, 10, 20 meter |
|
|
|
|
|
|
BN38C-xx |
| |
| PCI 2-channel Ultra3 (LVD) SCSI
adapter, 64-bit/66-MHz (uses one PCI slot); includes internal 68-pin HD and external
68-pin VHDCI connectors; requires 3X-BC56J-xx cable to connect adapter to DS-SL13R-Bx/
DS-SSL14-xx Ultra3 shelf. NOTE:
OpenVMS 7.2-2, or later, is required; maximum cable length is 12 meters. |
- |
- |
- |
4 |
4 |
4 |
3X-KZPEA-DB |
68-pin VHDCI male-to-VHDCI male
UltraSCSI cable;
xx = 02, 03, 04, for 6, 12, and 24 meters respectively |
|
|
|
|
|
|
3X-BC56J-xx |
| |
| PCI 1-channel Ultra2 (LVD) SCSI
RAID controller, 16-MB cache, (uses one PCI slot); supports 14 disks per channel with
DS-SL13R-xx Ultra3 shelves; requires BN37A-xx cable to connect adapter to DS-SL13R-xx
Ultra3 shelf. |
8** |
8 |
8 |
- |
- |
- |
DS-KZPCC-AC |
| PCI 3-channel Ultra2 (LVD) SCSI
RAID controller, 64-MB cache, (uses one PCI slot); supports 14 disks per channel with
DS-SL13R-xx Ultra3 shelves; requires BN37A-xx cable to connect adapter to DS-SL13R-xx
Ultra3 shelf. |
8** |
8 |
8 |
- |
- |
- |
DS-KZPCC-CE |
68-pin VHDCI male-to-VHDCI male
UltraSCSI cable;
xx=02, 03, 05, 10, 20 meter |
|
|
|
|
|
|
BN37A-xx |
| NOTE:
** = Requires a Graphics Adapter or Graphical Display Station for its configuration
utility (other than the base system console). |
| |
NOTE:
- Use 2-meter cable to connect adapters, controllers, and shelf within the GS80 cabinet.
- Use 10-meter cable to connect adapters, controllers to shelves in attached H9A20
expander cabinets.
- Use 10-25-meter cables to connect adapters, controllers to shelves in remote expander
cabinets.
|
| |
|
|
| CI Adapters (OpenVMS only) |
PCI CI adapter, maximum 26 per
system or hardware partition (12 per drawer, six per PCI drawer); requires two PCI slots |
CIPCA-BA |
|
Computer interconnect cable set,
connects CIPCA to star coupler; select length xx=10, 20, 45 meters |
BNCIA-xx |
| |
| Step
7b - Internal Storage |
UltraSCSI Storage
Devices
(for use with BA356) |
9.1-GB 10,000 rpm 16-bit
UltraSCSI disk drive SBB |
DS-RZ1DD-VW |
| 18.2-GB 10,000 rpm 16-bit
UltraSCSI disk drive SBB |
DS-RZ1ED-VW |
|
36.4-GB 10,000 rpm 16-bit
UltraSCSI disk drive SBB |
DS-RZ1FC-VW |
| |
|
|
UltraSCSI Tape
Devices
(for use with BA356) |
12/24-GB 4 mm DAT SCSI tape drive
in 3.5-inch StorageWorks carrier |
DS-TLZ10-VA |
| 40/80-GB DLT SCSI tape drive in
5.25-inch StorageWorks carrier |
DS-TZ90N-VW |
| |
|
|
Ultra3 SCSI (LVD)
Storage Devices
(for use with DS-SL13R-xx) |
18.2-GB Ultra3 SCSI 10,000 rpm
Universal 1-inch disk drive |
3R-A0585-AA |
| 18.2-GB Ultra3 SCSI 15,000 rpm
Universal 1-inch disk drive |
3R-A1543-AA |
|
36.4-GB Ultra3 SCSI 10,000 rpm
Universal 1-inch disk drive |
3R-A0919-AA |
|
36.4-GB Ultra3 SCSI 15,000 rpm
Universal 1-inch disk drive |
3R-A3079-AA |
|
72.8-GB Ultra3 SCSI 10,000 rpm
Universal 1-inch disk drive |
3R-A3050-AA |
| |
|
|
Ultra2 SCSI (LVD)
Tape Devices
(for use with DS-SL13R-xx) |
AIT-351B, 35-GB tape drive
embedded in hot plug Universal carrier |
3R-A2396-AA |
| AIT-50, 50-GB tape drive embedded
in hot plug Universal carrier |
3R-A2779-AA |
|
SDT-10,000, 20/40-GB DAT tape
drive embedded in hot plug Universal carrier |
3R-A2780-AA |
| |
| Step 7c - Tape Devices |
| 3U Rackmount Tape Drive
Enclosure |
3U LVD Rackmount Tape Drive
Enclosure for use in H9Axx Series Cabinets, 0 drives, carbon black |
274338-B21 |
|
Rackmount kit for H9Axx Series
Cabinet, carbon black – required for mounting 3U Rackmount Tape Drive Enclosure in
H9Axx cabinets |
3R-A3804-AA |
|
NOTE: The
3U Tape Drive Enclosure supports up to four internal half-height removable devices, or up
to two full height devices. Select up to four AIT or DAT devices, or two DLT/SDLT devices
with 3U Rackmount Tape Drive Enclosure (274338-B21), or select preconfigured
configurations listed below. |
|
| |
|
|
| Tape Drives for
Use in 3U Rackmount Tape Drive Enclosure |
AIT 35/70-GB 3U internal tape
drive, carbon black; requires 3X-KZPCA-AA LVD adapter |
216884-B21 |
| AIT 50/100-GB 3U internal tape
drive, carbon black; requires 3X-KZPCA-AA LVD adapter |
3R-A3753-AA
157766-B22 |
|
DAT 20/40-GB 3U internal tape
drive, carbon black; requires 3X-KZPCA-AA LVD adapter |
3R-A3752-AA
157769-B22 |
|
DLT8000 40/80-GB internal tape
drive, carbon black; requires 3X-KZPCA-AA LVD adapter |
146196-B22 |
|
SDLT 110/220-GB internal tape
drive, carbon black; requires 3X-KZPCA-AA LVD adapter |
192106-B25 |
|
SDLT 160/320-GB internal tape
drive, carbon black; requires 3X-KZPCA-AA LVD adapter |
257319-B21 |
| |
|
|
| Preconfigured
Configurations |
AIT 50-GB, 3U rackmount kit,
carbon black |
274333-B21 |
| DLT 40/80-GB, 3U rackmount kit,
carbon black |
274332-B21 |
|
DLT 40/80-GB, dual-drive, 3U
rackmount kit, carbon black |
274335-B21 |
|
SDLT 110/220-GB, single drive, 3U
rackmount kit, carbon black |
274331-B21 |
|
SDLT 110/220-GB, dual-drive, 3U
rackmount kit, carbon black |
274334-B21 |
| |
|
|
| 5U Rackmount Tape Drive
Enclosure |
5U LVD Rackmount Tape Drive
Enclosure, carbon black, or use in H9Axx Series Cabinet, 0 drives |
274339-B21 |
|
Rackmount Kit for H9Axx Series
Cabinet, carbon black – required for mounting 5U Rackmount Tape Drive Enclosure in
H9Axx cabinets |
254795-001 |
|
NOTE: The
5U Rackmount Tape Drive Enclosure supports four full-height devices; select up to four DLT
or SDLT devices with 274339-B21, or select preconfigured configurations listed below. |
|
| |
|
|
| Tape Drives for
Use in 5U Tape Drive Enclosure |
DLT8000 40/80-GB tape drive,
requires 3X-KZPCA-AA LVD adapter, carbon black |
146196-B22 |
| SDLT 110/220-GB tape drive,
requires 3X-KZP | |
