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HP OpenVMS Systems Documentation |
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Guidelines for OpenVMS Cluster Configurations
C.1.3 General Configuration GuidelinesThe same configuration rules that apply to OpenVMS Cluster systems on a LAN also apply to a multiple-site OpenVMS Cluster configuration that includes ATM, DS3, or FDDI intersite interconnect. General LAN configuration rules are stated in the following documentation:
Some configuration guidelines are unique to multiple-site OpenVMS Clusters; these guidelines are described in Section C.4.4.
Figure C-3 Multiple-Site OpenVMS Cluster Configuration with Cluster over IP 
Node East1, East2, West1, and West2 can be part of the same or
different LAN. Cluster traffic is routable. Nodes in the east use
cluster over IP to communicate with nodes in the west, which are at
geographically distant sites. Node East1 and Node West1 forms a Virtual
Circuit (VC). The VC consists of IP channels for SCS traffic. However,
nodes in the east use LAN between themselves for cluster communication.
Node East1 will form a virtual circuit using a LAN channel with Node
East2.
Since VMS Version 5.4--3, FDDI has been the most common method to connect two distant OpenVMS Cluster sites. Using high-speed FDDI fiber-optic cables, you can connect sites with an intersite cable-route distance of up to 25 miles (40 km), the cable route distance between sites. You can connect sites using these FDDI methods:
Additional OpenVMS Cluster configuration guidelines and system management information can be found in this manual and in HP OpenVMS Cluster Systems. See the HP OpenVMS Version 8.4 Release Notes for information about ordering the current version of these manuals.
The inherent flexibility of OpenVMS Cluster systems and improved
OpenVMS Cluster LAN protocols also allow you to connect multiple
OpenVMS Cluster sites using the ATM or DS3 or both communications
services.
This section provides an overview of the ATM and DS3 wide area network (WAN) services, describes how you can bridge an FDDI interconnect to the ATM or DS3 or both communications services, and provides guidelines for using these services to configure multiple-site OpenVMS Cluster systems. The ATM and DS3 services provide long-distance, point-to-point communications that you can configure into your OpenVMS Cluster system to gain WAN connectivity. The ATM and DS3 services are available from most common telephone service carriers and other sources.
ATM and DS3 services are approved for use with the following OpenVMS versions:
The following sections describe the ATM and DS3 communication services
and how to configure these services into multiple-site OpenVMS Cluster
systems.
The ATM communications service that uses the SONET physical layer (ATM/SONET) provides full-duplex communications (that is, the bit rate is available simultaneously in both directions as shown in Figure C-4). ATM/SONET is compatible with multiple standard bit rates. The SONET OC-3 service at 155 Mb/s full-duplex rate is the best match to FDDI's 100 Mb/s bit rate. ATM/SONET OC-3 is a standard service available in most parts of the world. In Europe, ATM/SONET is a high-performance alternative to the older E3 standard. Figure C-4 ATM/SONET OC-3 Service 
To transmit data, ATM frames (packets) are broken into
cells for transmission by the ATM service. Each cell
has 53 bytes, of which 5 bytes are reserved for header information and
48 bytes are available for data. At the destination of the
transmission, the cells are reassembled into ATM frames. The use of
cells permits ATM suppliers to multiplex and demultiplex multiple data
streams efficiently at differing bit rates. This conversion of frames
into cells and back is transparent to higher layers.
The DS3 communications service provides full-duplex communications as shown in Figure C-5. DS3 (also known as T3) provides the T3 standard bit rate of 45 Mb/s. T3 is the standard service available in North America and many other parts of the world. Figure C-5 DS3 Service 
C.4.3 FDDI-to-WAN BridgesYou can use FDDI-to-WAN (for example, FDDI-to-ATM or FDDI-to-DS3 or both) bridges to configure an OpenVMS Cluster with nodes in geographically separate sites, such as the one shown in Figure C-6. In this figure, the OpenVMS Cluster nodes at each site communicate as though the two sites are connected by FDDI. The FDDI-to-WAN bridges make the existence of ATM and DS3 transparent to the OpenVMS Cluster software. Figure C-6 Multiple-Site OpenVMS Cluster Configuration Connected by DS3 
In Figure C-6, the FDDI-to-DS3 bridges and DS3 operate as follows:
HP recommends using the GIGAswitch/FDDI system to construct FDDI-to-WAN
bridges. The GIGAswitch/FDDI, combined with the DEFGT WAN T3/SONET
option card, was used during qualification testing of the ATM and DS3
communications services in multiple-site OpenVMS Cluster systems.
When configuring a multiple-site OpenVMS Cluster, you must ensure that
the intersite link's delay, bandwidth, availability, and bit error rate
characteristics meet application needs. This section describes the
requirements and provides recommendations for meeting those
requirements.
To be a configuration approved by HP, a multiple-site OpenVMS Cluster must comply with the following rules:
C.4.4.2 RecommendationsWhen configuring the DS3 interconnect, apply the configuration guidelines for OpenVMS Cluster systems interconnected by LAN that are stated in the OpenVMS Cluster Software SPD (SPD 29.78.nn) and in this manual. OpenVMS Cluster members at each site can include any mix of satellites, systems, and other interconnects, such as CI and DSSI. This section provides additional recommendations for configuring a multiple-site OpenVMS Cluster system. The GIGAswitch with the WAN T3/SONET option card provides a full-duplex, 155 Mb/s ATM/SONET link. The entire bandwidth of the link is dedicated to the WAN option card. However, the GIGAswitch/FDDI's internal design is based on full-duplex extensions to FDDI. Thus, the GIGAswitch/FDDI's design limits the ATM/SONET link's capacity to 100 Mb/s in each direction. The GIGAswitch with the WAN T3/SONET option card provides several protocol options that can be used over a DS3 link. Use the DS3 link in clear channel mode, which dedicates its entire bandwidth to the WAN option card. The DS3 link capacity varies with the protocol option selected. Protocol options are described in Table C-1.
1Asynchronous transfer mode 2ATM Adaptation Layer 3Physical Layer Convergence Protocol 4High-Speed Datalink Control For maximum link capacity, HP recommends configuring the WAN T3/SONET option card to use ATM AAL--5 mode with PLCP disabled. The intersite bandwidth can limit application locking and I/O performance (including volume shadowing or RAID set copy times) and the performance of the lock manager. To promote reasonable response time, HP recommends that average traffic in either direction over an intersite link not exceed 60% of the link's bandwidth in that direction for any 10-second interval. Otherwise, queuing delays within the FDDI-to-WAN bridges can adversely affect application performance. Remember to account for both OpenVMS Cluster communications (such as locking and I/O) and network communications (such as TCP/IP, LAT, and DECnet) when calculating link utilization. An intersite link introduces a one-way delay of up to 1 ms per 100 miles of intersite cable route distance plus the delays through the FDDI-to-WAN bridges at each end. HP recommends that you consider the effects of intersite delays on application response time and throughput. For example, intersite link one-way path delays have the following components:
Calculate the delays for a round trip as follows: WAN round-trip delay = 2 x (N miles x 0.01 ms per mile + 2 x 0.5 ms per FDDI-WAN bridge) An I/O write operation that is MSCP served requires a minimum of two round-trip packet exchanges: WAN I/O write delay = 2 x WAN round-trip delay Thus, an I/O write over a 100-mile WAN link takes at least 8 ms longer than the same I/O write over a short, local FDDI. Similarly, a lock operation typically requires a round-trip exchange of packets: WAN lock operation delay = WAN round-trip delay An I/O operation with N locks to synchronize it incurs the following delay due to WAN: WAN locked I/O operation delay = (N x WAN lock operation delay) + WAN I/O delay The bit error ratio (BER) parameter is an important measure of the frequency that bit errors are likely to occur on the intersite link. You should consider the effects of bit errors on application throughput and responsiveness when configuring a multiple-site OpenVMS Cluster. Intersite link bit errors can result in packets being lost and retransmitted with consequent delays in application I/O response time (see Section C.4.6). You can expect application delays ranging from a few hundred milliseconds to a few seconds each time a bit error causes a packet to be lost. Interruptions of intersite link service can result in the resources at one or more sites becoming unavailable until connectivity is restored (see Section C.4.5). Sites with nodes contributing quorum votes should have a local system disk or disks for those nodes. A large, multiple-site OpenVMS Cluster requires a system management staff trained to support an environment that consists of a large number of diverse systems that are used by many people performing varied tasks.
You can provide portions of a DS3 link with microwave radio equipment.
The specifications in Section C.4.6 apply to any DS3 link. The BER and
availability of microwave radio portions of a DS3 link are affected by
local weather and the length of the microwave portion of the link.
Consider working with a microwave consultant who is familiar with your
local environment if you plan to use microwaves as portions of a DS3
link.
If the FDDI-to-WAN bridges and the link that connects multiple sites become temporarily unavailable, the following events could occur:
Many communication service carriers offer availability-enhancing
options, such as path diversity, protective switching, and other
options that can significantly increase the intersite link's
availability.
This section describes the requirements for successful communications and performance with the WAN communications services. To assist you in communicating your requirements to a WAN service supplier, this section uses WAN specification terminology and definitions commonly used by telecommunications service providers. These requirements and goals are derived from a combination of Bellcore Communications Research specifications and a Digital analysis of error effects on OpenVMS Clusters. Table C-2 describes terminology that will help you understand the Bellcore and OpenVMS Cluster requirements and goals used in Table C-3. Use the Bellcore and OpenVMS Cluster requirements for ATM/SONET - OC3 and DS3 service error performance (quality) specified in Table C-3 to help you assess the impact of the service supplier's service quality, availability, down time, and service-interruption frequency goals on the system.
1Application pauses may occur every hour or so (similar to what is described under OpenVMS Cluster Requirements) because of packet loss caused by bit error. 2Pauses are due to a virtual circuit retransmit timeout resulting from a lost packet on one or more NISCA transport virtual circuits. Each pause might last from a few hundred milliseconds to a few seconds.
1Application requirements might need to be more rigorous than those shown in the OpenVMS Cluster Requirements column. 2Averaged over many days. 3Does not include any burst errored seconds occurring in the measurement period. 4The average number of channel down-time periods occurring during a year. This parameter is useful for specifying how often a channel might become unavailable. Table Key
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