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RFC3116 - Methodology for ATM Benchmarking

王朝other·作者佚名  2008-05-31
窄屏简体版  字體: |||超大  

Network Working Group J. Dunn

Request for Comments: 3116 C. Martin

Category: Informational ANC, Inc.

June 2001

Methodology for ATM Benchmarking

Status of this Memo

This memo provides information for the Internet community. It does

not specify an Internet standard of any kind. Distribution of this

memo is unlimited.

Copyright Notice

Copyright (C) The Internet Society (2001). All Rights Reserved.

Abstract

This document discusses and defines a number of tests that may be

used to describe the performance characteristics of ATM (Asynchronous

Transfer Mode) based switching devices. In addition to defining the

tests this document also describes specific formats for reporting the

results of the tests.

This memo is a prodUCt of the Benchmarking Methodology Working Group

(BMWG) of the Internet Engineering Task Force (IETF).

Table of Contents

1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 4

2. Background . . . . . . . . . . . . . . . . . . . . . . . . . . 5

2.1. Test Device Requirements . . . . . . . . . . . . . . . . . . 5

2.2. Systems Under Test (SUTs). . . . . . . . . . . . . . . . . . 5

2.3. Test Result Evaluation . . . . . . . . . . . . . . . . . . . 5

2.4. Requirements . . . . . . . . . . . . . . . . . . . . . . . . 5

2.5. Test Configurations for SONET. . . . . . . . . . . . . . . . 6

2.6. SUT Configuration. . . . . . . . . . . . . . . . . . . . . . 7

2.7. Frame Formats. . . . . . . . . . . . . . . . . . . . . . . . 8

2.8. Frame Sizes. . . . . . . . . . . . . . . . . . . . . . . . . 8

2.9. Verifying Received IP PDU's. . . . . . . . . . . . . . . . . 9

2.10. Modifiers . . . . . . . . . . . . . . . . . . . . . . . . . 9

2.10.1. Management IP PDU's . . . . . . . . . . . . . . . . . . . 9

2.10.2. Routing Update IP PDU's . . . . . . . . . . . . . . . . . 10

2.11. Filters . . . . . . . . . . . . . . . . . . . . . . . . . . 10

2.11.1. Filter Addresses. . . . . . . . . . . . . . . . . . . . . 11

2.12. Protocol Addresses. . . . . . . . . . . . . . . . . . . . . 12

2.13. Route Set Up. . . . . . . . . . . . . . . . . . . . . . . . 12

2.14. Bidirectional Traffic . . . . . . . . . . . . . . . . . . . 12

2.15. Single Stream Path. . . . . . . . . . . . . . . . . . . . . 12

2.16. Multi-port. . . . . . . . . . . . . . . . . . . . . . . . . 13

2.17. Multiple Protocols. . . . . . . . . . . . . . . . . . . . . 14

2.18. Multiple IP PDU Sizes . . . . . . . . . . . . . . . . . . . 14

2.19. Testing Beyond a Single SUT . . . . . . . . . . . . . . . . 14

2.20. Maximum IP PDU Rate . . . . . . . . . . . . . . . . . . . . 15

2.21. Busty Traffic . . . . . . . . . . . . . . . . . . . . . . . 15

2.22. Trial Description . . . . . . . . . . . . . . . . . . . . . 16

2.23. Trial Duration. . . . . . . . . . . . . . . . . . . . . . . 16

2.24. Address Resolution. . . . . . . . . . . . . . . . . . . . . 16

2.25. Synchronized Payload Bit Pattern. . . . . . . . . . . . . . 16

2.26. Burst Traffic Descriptors . . . . . . . . . . . . . . . . . 17

3. Performance Metrics. . . . . . . . . . . . . . . . . . . . . . 17

3.1. Physical Layer-SONET . . . . . . . . . . . . . . . . . . . . 17

3.1.1. Pointer Movements. . . . . . . . . . . . . . . . . . . . . 17

3.1.1.1. Pointer Movement Propagation . . . . . . . . . . . . . . 17

3.1.1.2. Cell Loss due to Pointer Movement. . . . . . . . . . . . 19

3.1.1.3. IP Packet Loss due to Pointer Movement . . . . . . . . . 20

3.1.2. Transport Overhead (TOH) Error Count . . . . . . . . . . . 21

3.1.2.1. TOH Error Propagation. . . . . . . . . . . . . . . . . . 21

3.1.2.2. Cell Loss due to TOH Error . . . . . . . . . . . . . . . 22

3.1.2.3. IP Packet Loss due to TOH Error. . . . . . . . . . . . . 23

3.1.3. Path Overhead (POH) Error Count. . . . . . . . . . . . . . 24

3.1.3.1. POH Error Propagation. . . . . . . . . . . . . . . . . . 24

3.1.3.2. Cell Loss due to POH Error . . . . . . . . . . . . . . . 25

3.1.3.3. IP Packet Loss due to POH Error. . . . . . . . . . . . . 26

3.2. ATM Layer. . . . . . . . . . . . . . . . . . . . . . . . . . 27

3.2.1. Two-Point Cell Delay Variation (CDV) . . . . . . . . . . . 27

3.2.1.1. Test Setup . . . . . . . . . . . . . . . . . . . . . . . 27

3.2.1.2. Two-point CDV/Steady Load/One VCC. . . . . . . . . . . . 27

3.2.1.3. Two-point CDV/Steady Load/Twelve VCCs. . . . . . . . . . 28

3.2.1.4. Two-point CDV/Steady Load/Maximum VCCs . . . . . . . . . 30

3.2.1.5. Two-point CDV/Bursty VBR Load/One VCC. . . . . . . . . . 31

3.2.1.6. Two-point CDV/Bursty VBR Load/Twelve VCCs. . . . . . . . 32

3.2.1.7. Two-point CDV/Bursty VBR Load/Maximum VCCs . . . . . . . 34

3.2.1.8. Two-point CDV/Mixed Load/Three VCC's . . . . . . . . . . 35

3.2.1.9. Two-point CDV/Mixed Load/Twelve VCCs . . . . . . . . . . 36

3.2.1.10. Two-point CDV/Mixed Load/Maximum VCCs . . . . . . . . . 38

3.2.2. Cell Error Ratio (CER) . . . . . . . . . . . . . . . . . . 39

3.2.2.1. Test Setup . . . . . . . . . . . . . . . . . . . . . . . 39

3.2.2.2. CER/Steady Load/One VCC. . . . . . . . . . . . . . . . . 40

3.2.2.3. CER/Steady Load/Twelve VCCs. . . . . . . . . . . . . . . 41

3.2.2.4. CER/Steady Load/Maximum VCCs . . . . . . . . . . . . . . 42

3.2.2.5. CER/Bursty VBR Load/One VCC. . . . . . . . . . . . . . . 43

3.2.2.6. CER/Bursty VBR Load/Twelve VCCs. . . . . . . . . . . . . 44

3.2.2.7. CER/Bursty VBR Load/Maximum VCCs . . . . . . . . . . . . 46

3.2.3. Cell Loss Ratio (CLR). . . . . . . . . . . . . . . . . . . 47

3.2.3.1. CLR/Steady Load/One VCC. . . . . . . . . . . . . . . . . 47

3.2.3.2. CLR/Steady Load/Twelve VCCs. . . . . . . . . . . . . . . 48

3.2.3.3. CLR/Steady Load/Maximum VCCs . . . . . . . . . . . . . . 49

3.2.3.4. CLR/Bursty VBR Load/One VCC. . . . . . . . . . . . . . . 51

3.2.3.5. CLR/Bursty VBR Load/Twelve VCCs. . . . . . . . . . . . . 52

3.2.3.6. CLR/Bursty VBR Load/Maximum VCCs . . . . . . . . . . . . 53

3.2.4. Cell Misinsertion Rate (CMR) . . . . . . . . . . . . . . . 54

3.2.4.1. CMR/Steady Load/One VCC. . . . . . . . . . . . . . . . . 54

3.2.4.2. CMR/Steady Load/Twelve VCCs. . . . . . . . . . . . . . . 55

3.2.4.3. CMR/Steady Load/Maximum VCCs . . . . . . . . . . . . . . 57

3.2.4.4. CMR/Bursty VBR Load/One VCC. . . . . . . . . . . . . . . 58

3.2.4.5. CMR/Bursty VBR Load/Twelve VCCs. . . . . . . . . . . . . 59

3.2.4.6. CMR/Bursty VBR Load/Maximum VCCs . . . . . . . . . . . . 60

3.2.5. CRC Error Ratio (CRC-ER) . . . . . . . . . . . . . . . . . 62

3.2.5.1. CRC-ER/Steady Load/One VCC . . . . . . . . . . . . . . . 62

3.2.5.2. CRC-ER/Steady Load/Twelve VCCs . . . . . . . . . . . . . 63

3.2.5.3. CRC-ER/Steady Load/Maximum VCCs. . . . . . . . . . . . . 64

3.2.5.4. CRC-ER/Bursty VBR Load/One VCC . . . . . . . . . . . . . 65

3.2.5.5. CRC-ER/Bursty VBR Load/Twelve VCCs . . . . . . . . . . . 66

3.2.5.6. CRC-ER/Bursty VBR Load/Maximum VCCs. . . . . . . . . . . 68

3.2.5.7. CRC-ER/Bursty UBR Load/One VCC . . . . . . . . . . . . . 69

3.2.5.8. CRC-ER/Bursty UBR Load/Twelve VCCs . . . . . . . . . . . 70

3.2.5.9. CRC-ER/Bursty UBR Load/Maximum VCCs. . . . . . . . . . . 71

3.2.5.10. CRC-ER/Bursty Mixed Load/Three VCC. . . . . . . . . . . 73

3.2.5.11. CRC-ER/Bursty Mixed Load/Twelve VCCs. . . . . . . . . . 74

3.2.5.12. CRC-ER/Bursty Mixed Load/Maximum VCCs . . . . . . . . . 75

3.2.6. Cell Transfer Delay (CTD). . . . . . . . . . . . . . . . . 76

3.2.6.1. Test Setup . . . . . . . . . . . . . . . . . . . . . . . 76

3.2.6.2. CTD/Steady Load/One VCC. . . . . . . . . . . . . . . . . 77

3.2.6.3. CTD/Steady Load/Twelve VCCs. . . . . . . . . . . . . . . 78

3.2.6.4. CTD/Steady Load/Maximum VCCs . . . . . . . . . . . . . . 79

3.2.6.5. CTD/Bursty VBR Load/One VCC. . . . . . . . . . . . . . . 81

3.2.6.6. CTD/Bursty VBR Load/Twelve VCCs. . . . . . . . . . . . . 82

3.2.6.7. CTD/Bursty VBR Load/Maximum VCCs . . . . . . . . . . . . 83

3.2.6.8. CTD/Bursty UBR Load/One VCC. . . . . . . . . . . . . . . 85

3.2.6.9. CTD/Bursty UBR Load/Twelve VCCs. . . . . . . . . . . . . 86

3.2.6.10. CTD/Bursty UBR Load/Maximum VCCs. . . . . . . . . . . . 87

3.2.6.11. CTD/Mixed Load/Three VCC's. . . . . . . . . . . . . . . 88

3.2.6.12. CTD/Mixed Load/Twelve VCCs. . . . . . . . . . . . . . . 90

3.2.6.13. CTD/Mixed Load/Maximum VCCs . . . . . . . . . . . . . . 91

3.3. ATM Adaptation Layer (AAL) Type 5 (AAL5) . . . . . . . . . . 93

3.3.1. IP Packet Loss due to AAL5 Re-assembly Errors. . . . . . . 93

3.3.2. AAL5 Re-assembly Time. . . . . . . . . . . . . . . . . . . 94

3.3.3. AAL5 CRC Error Ratio . . . . . . . . . . . . . . . . . . . 95

3.3.3.1. Test Setup . . . . . . . . . . . . . . . . . . . . . . . 95

3.3.3.2. AAL5-CRC-ER/Steady Load/One VCC. . . . . . . . . . . . . 95

3.3.3.3. AAL5-CRC-ER/Steady Load/Twelve VCCs. . . . . . . . . . . 96

3.3.3.4. AAL5-CRC-ER/Steady Load/Maximum VCCs . . . . . . . . . . 97

3.3.3.5. AAL5-CRC-ER/Bursty VBR Load/One VCC. . . . . . . . . . . 99

3.3.3.6. AAL5-CRC-ER/Bursty VBR Load/Twelve VCCs. . . . . . . . .100

3.3.3.7. AAL5-CRC-ER/Bursty VBR Load/Maximum VCCs . . . . . . . .101

3.3.3.8. AAL5-CRC-ER/Mixed Load/Three VCC's . . . . . . . . . . .102

3.3.3.9. AAL5-CRC-ER/Mixed Load/Twelve VCCs . . . . . . . . . . .104

3.3.3.10. AAL5-CRC-ER/Mixed Load/Maximum VCCs . . . . . . . . . .105

3.4. ATM Service: Signaling . . . . . . . . . . . . . . . . . . .106

3.4.1. CAC Denial Time and Connection Establishment Time. . . . .106

3.4.2. Connection Teardown Time . . . . . . . . . . . . . . . . .107

3.4.3. Crankback Time . . . . . . . . . . . . . . . . . . . . . .108

3.4.4. Route Update Response Time . . . . . . . . . . . . . . . .109

3.5. ATM Service: ILMI. . . . . . . . . . . . . . . . . . . . . .110

3.5.1. MIB Alignment Time . . . . . . . . . . . . . . . . . . . .110

3.5.2. Address Registration Time. . . . . . . . . . . . . . . . .111

4. Security Considerations . . . . . . . . . . . . . . . . . . .112

5. Notices. . . . . . . . . . . . . . . . . . . . . . . . . . . .112

6. References . . . . . . . . . . . . . . . . . . . . . . . . . .113

7. Authors' Addresses . . . . . . . . . . . . . . . . . . . . . .113

APPENDIX A . . . . . . . . . . . . . . . . . . . . . . . . . . .114

APPENDIX B . . . . . . . . . . . . . . . . . . . . . . . . . . .114

APPENDIX C . . . . . . . . . . . . . . . . . . . . . . . . . . .116

Full Copyright Statement . . . . . . . . . . . . . . . . . . . .127

1. Introduction

This document defines a specific set of tests that vendors can use to

measure and report the performance characteristics of ATM network

devices. The results of these tests will provide the user comparable

data from different vendors with which to evaluate these devices.

The methods defined in this memo are based on RFC2544 "Benchmarking

Methodology for Network Interconnect Devices".

The document "Terminology for ATM Benchmarking" (RFC2761), defines

many of the terms that are used in this document. The terminology

document should be consulted before attempting to make use of this

document.

The BMWG produces two major classes of documents: Benchmarking

Terminology documents and Benchmarking Methodology documents. The

Terminology documents present the benchmarks and other related terms.

The Methodology documents define the procedures required to collect

the benchmarks cited in the corresponding Terminology documents.

2. Background

2.1. Test Device Requirements

This document is based on the requirement that a test device is

available. The test device can either be off the shelf or can be

easily built with current technologies. The test device must have a

transmitting and receiving port for the interface type under test.

The test device must be configured to transmit test PDUs and to

analyze received PDUs. The test device should be able to transmit

and analyze received data at the same time.

2.2. Systems Under Test (SUTs)

There are a number of tests described in this document that do not

apply to each SUT. Vendors should perform all of the tests that can

be supported by a specific product type. It will take some time to

perform all of the recommended tests under all of the recommended

conditions.

2.3. Test Result Evaluation

Performing all of the tests in this document will result in a great

deal of data. The applicability of this data to the evaluation of a

particular SUT will depend on its eXPected use and the configuration

of the network in which it will be used. For example, the time

required by a switch to provide ILMI services will not be a pertinent

measurement in a network that does not use the ILMI protocol, such as

an ATM WAN. Evaluating data relevant to a particular network

installation may require considerable experience, which may not be

readily available. Finally, test selection and evaluation of test

results must be done with an understanding of generally accepted

testing practices regarding repeatability, variance and the

statistical significance of a small numbers of trials.

2.4. Requirements

In this document, the Words that are used to define the significance

of each particular requirement are capitalized. These words are:

* "MUST" This word, or the words "REQUIRED" and "SHALL" mean that

the item is an absolute requirement of the specification.

* "SHOULD" This word or the adjective "RECOMMENDED" means that there

may exist valid reasons in particular circumstances to ignore this

item, but the full implications should be understood and the case

carefully weighed before choosing a different course.

* "MAY" This word or the adjective "OPTIONAL" means that this item

is truly optional. One vendor may choose to include the item

because a particular marketplace requires it or because it

enhances the product, for example; another vendor may omit the

same item.

An implementation is not compliant if it fails to satisfy one or more

of the MUST requirements for the protocols it implements. An

implementation that satisfies all the MUST and all the SHOULD

requirements for its protocols is said to be "unconditionally

compliant"; one that satisfies all the MUST requirements but not all

the SHOULD requirements for its protocols is said to be

"conditionally compliant".

2.5. Test Configurations for SONET

The test device can be connected to the SUT in a variety of

configurations depending on the test point. The following

configurations will be used for the tests described in this document.

1) Uni-directional connection: The test devices transmit port

(labeled Tx) is connected to the SUT receive port (labeled Rx).

The SUTs transmit port is connected to the test device receive

port (see Figure 1). In this configuration, the test device can

verify that all transmitted packets are acknowledged correctly.

Note that this configuration does not verify internal system

functions, but verifies one port on the SUT.

+-------------+ +-------------+

Tx-------------->Rx

Test Rx<--------------Tx SUT

Device

+-------------+ +-------------+

Figure 1

2) Bi-directional connection: The test devices first transmit port is

connected to the SUTs first receive port. The SUTs first transmit

port is connected to the test devices first receive port. The

test devices second transmit port is connected to the SUTs second

receive port. The SUTs second transmit port is connected to the

test devices second receive port (see Figure 2). In this

configuration, the test device can determine if all of the

transmitted packets were received and forwarded correctly. Note

that this configuration does verify internal system functions,

since it verifies two ports on the SUT.

+-------------+ +-------------+

Test Tx-------------->Rx

Device Rx<--------------Tx SUT

Tx Rx Tx Rx

+-------------+ +-------------+

^ ^

+------------------------+

---------------------------------

Figure 2

3) Uni-directional passthrough connection: The test devices first

transmit port is connected to the SUT1 receive port. The SUT1

transmit port is connected to the test devices first receive port.

The test devices second transmit port is connected to the SUT2

receive port. The SUT2 transmit port is connected to the test

devices second receive port (see Figure 3). In this

configuration, the test device can determine if all of the packets

transmitted by SUT1 were correctly acknowledged by SUT2. Note

that this configuration does not verify internal system functions,

but verifies one port on each SUT.

+-------------+ +-------------+ +-------------+

Tx---------->Rx Tx---------->Rx

SUT1 Rx<----------Tx Test Rx<----------Tx SUT2

Device

+-------------+ +-------------+ +-------------+

Figure 3

2.6. SUT Configuration

The SUT MUST be configured as described in the SUT users guide.

Specifically, it is expected that all of the supported protocols will

be configured and enabled. It is expected that all of the tests will

be run without changing the configuration or setup of the SUT in any

way other than that required to do the specific test. For example,

it is not acceptable to disable all but one transport protocol when

testing the throughput of that protocol. If PNNI or BISUP is used to

initiate switched virtual connections (SVCs), the SUT configuration

SHOULD include the normally recommended routing update intervals and

keep alive frequency. The specific version of the software and the

exact SUT configuration, including what functions are disabled and

used during the tests MUST be included as part of the report of the

results.

2.7. Frame formats

The formats of the test IP PDUs to use for TCP/IP and UPC/IP over ATM

are shown in Appendix C: Test Frame Formats. Note that these IP PDUs

are in accordance with RFC2225. These exact IP PDU formats SHOULD

be used in the tests described in this document for this

protocol/media combination. These IP PDUs will be used as a template

for testing other protocol/media combinations. The specific formats

that are used to define the test IP PDUs for a particular test series

MUST be included in the report of the results.

2.8. Frame sizes

All of the described tests SHOULD be performed using a number of IP

PDU sizes. Specifically, the sizes SHOULD include the maximum and

minimum legitimate sizes for the protocol under test on the media

under test and enough sizes in between to be able to get a full

characterization of the SUT performance. Except where noted, at

least five IP PDU sizes SHOULD be tested for each test condition.

Theoretically the minimum size UDP Echo request IP PDU would consist

of an IP header (minimum length 20 octets), a UDP header (8 octets),

AAL5 trailer (8 octets) and an LLC/SNAP code point header (8 octets);

therefore, the minimum size PDU will fit into one ATM cell. The

theoretical maximum IP PDU size is determined by the size of the

length field in the IP header. In almost all cases the actual

maximum and minimum sizes are determined by the limitations of the

media. In the case of ATM, the maximum IP PDU size SHOULD be the ATM

MTU size, which is 9180 octets.

In theory it would be ideal to distribute the IP PDU sizes in a way

that would evenly distribute the theoretical IP PDU rates. These

recommendations incorporate this theory but specify IP PDU sizes,

which are easy to understand and remember. In addition, many of the

same IP PDU sizes are specified on each of the media types to allow

for easy performance comparisons.

Note: The inclusion of an unrealistically small IP PDU size on some

of the media types (i.e., with little or no space for data) is to

help characterize the per-IP PDU processing overhead of the SUT.

The IP PDU sizes that will be used are:

44, 64, 128, 256, 1024, 1518, 2048, 4472, 9180

The minimum size IP PDU for UDP on ATM is 44 octets, the minimum size

of 44 is recommended to allow direct comparison to token ring

performance. The IP PDU size of 4472 is recommended instead of the

theoretical FDDI maximum size of 4500 octets in order to permit the

same type of comparison. An IP (i.e., not UDP) IP PDU may be used in

addition if a higher data rate is desired, in which case the minimum

IP PDU size is 28 octets.

2.9. Verifying received IP PDUs

The test equipment SHOULD discard any IP PDUs received during a test

run that are not actual forwarded test IP PDUs. For example, keep-

alive and routing update IP PDUs SHOULD NOT be included in the count

of received IP PDUs. In any case, the test equipment SHOULD verify

the length of the received IP PDUs and check that they match the

expected length.

Preferably, the test equipment SHOULD include sequence numbers in the

transmitted IP PDUs and check for these numbers on the received IP

PDUs. If this is done, the reported results SHOULD include, in

addition to the number of IP PDUs dropped, the number of IP PDUs that

were received out of order, the number of duplicate IP PDUs received

and the number of gaps in the received IP PDU numbering sequence.

This functionality is required for some of the described tests.

2.10. Modifiers

It is useful to characterize the SUTs performance under a number of

conditions. Some of these conditions are noted below. The reported

results SHOULD include as many of these conditions as the test

equipment is able to generate. The suite of tests SHOULD be run

first without any modifying conditions, then repeated under each of

the modifying conditions separately. To preserve the ability to

compare the results of these tests, any IP PDUs that are required to

generate the modifying conditions (excluding management queries) will

be included in the same data stream as that of the normal test IP

PDUs and in place of one of the test IP PDUs. They MUST not be

supplied to the SUT on a separate network port.

2.10.1. Management IP PDUs

Most ATM data networks now make use of ILMI, signaling and OAM. In

many environments, there can be a number of management stations

sending queries to the same SUT at the same time.

Management queries MUST be made in accordance with the applicable

specification, e.g., ILMI sysUpTime getNext requests will be made in

accordance with ILMI 4.0. The response to the query MUST be verified

by the test equipment. Note that, for each management protocol in

use, this requires that the test equipment implement the associated

protocol state machine. One example of the specific query IP PDU

(ICMP) that should be used is shown in Appendix C.

2.10.2. Routing update IP PDUs

The processing of PNNI updates could have a significant impact on the

ability of a switch to forward cells and complete calls. If PNNI is

configured on the SUT, one routing update MUST be transmitted before

the first test IP PDU is transmitted during the trial. The test

SHOULD verify that the SUT has properly processed the routing update.

PNNI routing update IP PDUs SHOULD be sent at the rate specified in

Appendix B. Appendix C defines one routing update PDU for the TCP/IP

over ATM example. The routing updates are designed to change the

routing on a number of networks that are not involved in the

forwarding of the test data. The first IP PDU sets the routing table

state to "A", the second one changes the state to "B". The IP PDUs

MUST be alternated during the trial. The test SHOULD verify that the

SUT has properly processed the routing update.

2.11. Filters

Filters are added to switches to selectively inhibit the forwarding

of cells that would normally be forwarded. This is usually done to

implement security controls on the data that is accepted between one

area and another. Different products have different capabilities to

implement filters. Filters are applicable only if the SUT supports

the filtering feature.

The SUT SHOULD be first configured to add one filter condition and

the tests performed. This filter SHOULD permit the forwarding of the

test data stream. This filter SHOULD be of the form as described in

the SUT Users Guide.

The SUT SHOULD be then reconfigured to implement a total of 25

filters. The first 24 of these filters SHOULD be based on 24

separate ATM NSAP Network Prefix addresses.

The 24 ATM NSAP Network Prefix addresses SHOULD not be any that are

represented in the test data stream. The last filter SHOULD permit

the forwarding of the test data stream. By "first" and "last" we

mean to ensure that in the second case, 25 conditions must be checked

before the data IP over ATM PDUs will match the conditions that

permit the forwarding of the IP PDU. Of course, if the SUT reorders

the filters or does not use a linear scan of the filter rules the

effect of the sequence in which the filters are input is properly

lost.

The exact filters configuration command lines used SHOULD be included

with the report of the results.

2.11.1. Filter Addresses

Two sets of filter addresses are required, one for the single filter

case and one for the 25 filter case.

The single filter case should permit traffic from ATM address [Switch

Network Prefix] 00 00 00 00 00 01 00 to ATM address [Switch Network

Prefix] 00 00 00 00 00 02 00 and deny all other traffic. Note that

the 13 octet Switch Network Prefix MUST be configured before this

test can be run.

The 25 filter case should follow the following sequence.

deny [Switch Network Prefix] 00 00 00 00 00 01 00

to [Switch Network Prefix] 00 00 00 00 00 03 00

deny [Switch Network Prefix] 00 00 00 00 00 01 00

to [Switch Network Prefix] 00 00 00 00 00 04 00

deny [Switch Network Prefix] 00 00 00 00 00 01 00

to [Switch Network Prefix] 00 00 00 00 00 05 00

...

deny [Switch Network Prefix] 00 00 00 00 00 01 00

to [Switch Network Prefix] 00 00 00 00 00 0C 00

deny [Switch Network Prefix] 00 00 00 00 00 01 00

to [Switch Network Prefix] 00 00 00 00 00 0D 00

allow [Switch Network Prefix] 00 00 00 00 00 01 00

to [Switch Network Prefix] 00 00 00 00 00 02 00

deny [Switch Network Prefix] 00 00 00 00 00 01 00

to [Switch Network Prefix] 00 00 00 00 00 0E 00

deny [Switch Network Prefix] 00 00 00 00 00 01 00

to [Switch Network Prefix] 00 00 00 00 00 0F 00

...

deny [Switch Network Prefix] 00 00 00 00 00 01 00

to [Switch Network Prefix] 00 00 00 00 00 18 00

deny all else

All previous filter conditions should be cleared from the switch

before this sequence is entered. The sequence is selected to test to

see if the switch sorts the filter conditions or accepts them in the

order that they were entered. Both of these procedures will result

in a greater impact on performance than will some form of hash

coding.

2.12. Protocol addresses

It is easier to implement these tests using a single logical stream

of data, with one source ATM address and one destination ATM address,

and for some conditions like the filters described above, a practical

requirement. Networks in the real world are not limited to single

streams of data. The test suite SHOULD be first run with a single

ATM source and destination address pair. The tests SHOULD then be

repeated with using a random destination address. In the case of

testing single switches, the addresses SHOULD be random and uniformly

distributed over a range of 256 seven octet user parts. In the case

of testing multiple interconnected switches, the addresses SHOULD be

random and uniformly distributed over the 256 network prefixes, each

of which should support 256 seven octet user parts. The specific

address ranges to use for ATM are shown in Appendix A. IP to ATM

address mapping MUST be accomplished as described in RFC2225.

2.13. Route Set Up

It is not reasonable that all of the routing information necessary to

forward the test stream, especially in the multiple address case,

will be manually set up. If PNNI and/or ILMI are running, at the

start of each trial a routing update MUST be sent to the SUT. This

routing update MUST include all of the ATM addresses that will be

required for the trial. This routing update will have to be repeated

at the interval required by PNNI or ILMI. An example of the format

and repetition interval of the update IP PDUs is given in Appendix B

(interval and size) and Appendix C (format).

2.14. Bidirectional traffic

Bidirectional performance tests SHOULD be run with the same data rate

being offered from each direction. The sum of the data rates should

not exceed the theoretical limit for the media.

2.15. Single stream path

The full suite of tests SHOULD be run with the appropriate modifiers

for a single receive and transmit port on the SUT. If the internal

design of the SUT has multiple distinct pathways, for example,

multiple interface cards each with multiple network ports, then all

possible permutations of pathways SHOULD be tested separately. If

multiple interconnected switches are tested, the test MUST specify

routes, which allow only one path between source and destination ATM

addresses.

2.16. Multi-port

Many switch products provide several network ports on the same

interface module. Each port on an interface module SHOULD be

stimulated in an identical manner. Specifically, half of the ports

on each module SHOULD be receive ports and half SHOULD be transmit

ports. For example if a SUT has two interface module each of which

has four ports, two ports on each interface module be receive ports

and two will be transmit ports. Each receive port MUST be offered

the same data rate. The addresses in the input data streams SHOULD

be set so that an IP PDU will be directed to each of the transmit

ports in sequence. That is, all transmit ports will receive an

identical distribution of IP PDUs from a particular receive port.

Consider the following 6 port SUT:

--------------

--------- Rx A Tx X--------

--------- Rx B Tx Y--------

--------- Rx C Tx Z--------

--------------

The addressing of the data streams for each of the inputs SHOULD be:

stream sent to Rx A:

IP PDU to Tx X, IP PDU to Tx Y, IP PDU to Tx Z

stream sent to Rx B:

IP PDU to Tx X, IP PDU to Tx Y, IP PDU to Tx Z

stream sent to Rx C

IP PDU to Tx X, IP PDU to Tx Y, IP PDU to Tx Z

Note: Each stream contains the same sequence of IP destination

addresses; therefore, each transmit port will receive 3 IP PDUs

simultaneously. This procedure ensures that the SUT will have to

process multiple IP PDUs addressed to the same transmit port

simultaneously.

The same configuration MAY be used to perform a bi-directional

multi-stream test. In this case all of the ports are considered both

receive and transmit ports. Each data stream MUST consist of IP PDUs

whose addresses correspond to the ATM addresses all of the other

ports.

2.17. Multiple protocols

This document does not address the issue of testing the effects of a

mixed protocol environment other than to suggest that if such tests

are wanted then PDUs SHOULD be distributed between all of the test

protocols. The distribution MAY approximate the conditions on the

network in which the SUT would be used.

2.18. Multiple IP PDU sizes

This document does not address the issue of testing the effects of a

mixed IP PDU size environment other than to suggest that, if such

tests are required, then IP PDU size SHOULD be evenly distributed

among all of the PDU sizes listed in this document. The distribution

MAY approximate the conditions on the network in which the SUT would

be used.

2.19. Testing beyond a single SUT

In the performance testing of a single SUT, the paradigm can be

described as applying some input to a SUT and monitoring the output.

The results of which can be used to form a basis of characterization

of that device under those test conditions.

This model is useful when the test input and output are homogeneous

(e.g., 64-byte IP, AAL5 PDUs into the SUT; 64 byte IP, AAL5 PDUs

out).

By extending the single SUT test model, reasonable benchmarks

regarding multiple SUTs or heterogeneous environments may be

collected. In this extension, the single SUT is replaced by a system

of interconnected network SUTs. This test methodology would support

the benchmarking of a variety of device/media/service/protocol

combinations. For example, a configuration for a LAN-to-WAN-to-LAN

test might be:

(1) ATM UNI -> SUT 1 -> BISUP -> SUT 2 -> ATM UNI

Or an extended LAN configuration might be:

(2) ATM UNI -> SUT 1 -> PNNI Network -> SUT 2 -> ATM UNI

In both examples 1 and 2, end-to-end benchmarks of each system could

be empirically ascertained. Other behavior may be characterized

through the use of intermediate devices. In example 2, the

configuration may be used to give an indication of the effect of PNNI

routing on IP throughput.

Because multiple SUTs are treated as a single system, there are

limitations to this methodology. For instance, this methodology may

yield an aggregate benchmark for a tested system. That benchmark

alone, however, may not necessarily reflect asymmetries in behavior

between the SUTs, latencies introduced by other apparatus (e.g.,

CSUs/DSUs, switches), etc.

Further, care must be used when comparing benchmarks of different

systems by ensuring that the SUTs' features and configuration of the

tested systems have the appropriate common denominators to allow

comparison.

2.20. Maximum IP PDU rate

The maximum IP PDU rates that should be used when testing LAN

connections SHOULD be the listed theoretical maximum rate for the IP

PDU size on the media.

The maximum IP PDU rate that should be used when testing WAN

connections SHOULD be greater than the listed theoretical maximum

rate for the IP PDU size on that speed connection. The higher rate

for WAN tests is to compensate for the fact that some vendors employ

various forms of header compression.

A list of maximum IP PDU rates for LAN connections is included in

Appendix B.

2.21. Bursty traffic

It is convenient to measure the SUT performance under steady state

load; however, this is an unrealistic way to gauge the functioning of

a SUT. Actual network traffic normally consists of bursts of IP

PDUs.

Some of the tests described below SHOULD be performed with both

constant bit rate, bursty Unspecified Bit Rate (UBR) Best Effort

[AF-TM4.1] and Variable Bit Rate Non-real Time (VBR-nrt) Best Effort

[AF-TM4.1]. The IP PDUs within a burst are transmitted with the

minimum legitimate inter-IP PDU gap.

The objective of the test is to determine the minimum interval

between bursts that the SUT can process with no IP PDU loss. Tests

SHOULD be run with burst sizes of 10% of Maximum Burst Size (MBS),

20% of MBS, 50% of MBS and 100% MBS. Note that the number of IP PDUs

in each burst will depend on the PDU size. For UBR, the MBS refers

to the associated VBR traffic parameters.

2.22. Trial description

A particular test consists of multiple trials. Each trial returns

one piece of information, for example the loss rate at a particular

input IP PDU rate. Each trial consists of five of phases:

a) If the SUT is a switch supporting PNNI, send the routing update to

the SUT receive port and wait two seconds to be sure that the

routing has settled.

b) Send an ATM ARP PDU to determine the ATM address corresponding to

the destination IP address. The formats of the ATM ARP PDU that

should be used are shown in the Test Frame Formats document and

MUST be in accordance with RFC2225.

c) Stimulate SUT with traffic load.

d) Wait for two seconds for any residual IP PDUs to be received.

e) Wait for at least five seconds for the SUT to restabilize.

2.23. Trial duration

The objective of the tests defined in this document is to accurately

characterize the behavior of a particular piece of network equipment

under varying traffic loads. The choice of test duration must be a

compromise between this objective and keeping the duration of the

benchmarking test suite within reasonable bounds. The SUT SHOULD be

stimulated for at least 60 seconds. If this time period results in a

high variance in the test results, the SUT SHOULD be stimulated for

at least 300 seconds.

2.24. Address resolution

The SUT MUST be able to respond to address resolution requests sent

by another SUT, an ATM ARP server or the test equipment in accordance

with RFC2225.

2.25. Synchronized Payload Bit Pattern.

Some measurements assume that both the transmitter and receiver

payload information is synchronized. Synchronization MUST be

achieved by supplying a known bit pattern to both the transmitter and

receiver. This bit pattern MUST be one of the following: PRBS-15,

PRBS-23, 0xFF00, or 0xAA55.

2.26. Burst Traffic Descriptors.

Some measurements require busty traffic patterns. These patterns

MUST conform to one of the following traffic descriptors:

1) PCR=100% allotted line rate, SCR=50% allotted line rate, and MBS=8192

2) PCR=100% allotted line rate, SCR=50% allotted line rate, and MBS=4096

3) PCR=90% allotted line rate, SCR=50% allotted line rate, and MBS=8192

4) PCR=90% allotted line rate, SCR=50% allotted line rate, and MBS=4096

5) PCR=90% allotted line rate, SCR=45% allotted line rate, and MBS=8192

6) PCR=90% allotted line rate, SCR=45% allotted line rate, and MBS=4096

7) PCR=80% allotted line rate, SCR=40% allotted line rate, and MBS=65536

8) PCR=80% allotted line rate, SCR=40% allotted line rate, and MBS=32768

The allotted line rate refers to the total available line rate

divided by the number of VCCs in use.

3. Performance Metrics

3.1. Physical Layer-SONET

3.1.1. Pointer Movements

3.1.1.1. Pointer Movement Propagation.

Objective: To determine that the SUT does not propagate pointer

movements as defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the uni-directional

configuration.

2) Send a specific number of IP PDUs at a specific rate through the

SUT. Since this test is not a throughput test, the rate should

not be greater than 90% of line rate. The cell payload SHOULD

contain valid IP PDUs. The IP PDUs MUST be encapsulated in AAL5.

3) Count the IP PDUs that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test, else lower the test device

traffic rate until the counts are the same.

4) Inject one forward payload pointer movement. Verify that the SUT

does not change the pointer.

5) Inject one forward payload pointer movement every 1 second.

Verify that the SUT does not change the pointer.

6) Discontinue the payload pointer movement.

7) Inject five forward payload pointer movements every 1 second.

Verify that the SUT does not change the pointer.

8) Discontinue the payload pointer movement.

9) Inject one backward payload pointer movement. Verify that the

SUT does not change the pointer.

10) Inject one backward payload pointer movement every 1 second.

Verify that the SUT does not change the pointer.

11) Discontinue the payload pointer movement.

12) Inject five backward payload pointer movements every 1 second.

Verify that the SUT does not change the pointer.

13) Discontinue the payload pointer movement.

Reporting Format:

The results of the pointer movement propagation test SHOULD be

reported in a form of a table. The rows SHOULD be labeled single

pointer movement, one pointer movement per second, and five

pointer movements per second. The columns SHOULD be labeled

pointer movement and loss of pointer. The elements of the table

SHOULD be either True or False, indicating whether the particular

condition was observed for each test.

The table MUST also indicate the IP PDU size in octets and traffic

rate in IP PDUs per second as generated by the test device.

3.1.1.2. Cell Loss due to Pointer Movement.

Objective: To determine if the SUT will drop cells due to pointer

movements as defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the uni-directional

configuration.

2) Send a specific number of cells at a specific rate through the

SUT. Since this test is not a throughput test, the rate should

not be greater than 90% of line rate. The cell payload SHOULD

contain valid IP PDUs. The IP PDUs MUST be encapsulated in AAL5.

3) Count the cells that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

4) Inject one forward payload pointer movement. Verify that the SUT

does not drop any cells.

5) Inject one forward payload pointer movement every 1 second.

Verify that the SUT does not drop any cells.

6) Discontinue the payload pointer movement.

7) Inject five forward payload pointer movements every 1 second.

Verify that the SUT does not drop any cells.

8) Discontinue the payload pointer movement.

9) Inject one backward payload pointer movement. Verify that the

SUT does not drop any cells.

10) Inject one backward payload pointer movement every 1 second.

Verify that the SUT does not drop any cells.

11) Discontinue the payload pointer movement.

12) Inject five backward payload pointer movements every 1 second.

Verify that the SUT does not drop any cells.

13) Discontinue the payload pointer movement.

Reporting Format:

The results of the cell loss due to pointer movement test SHOULD

be reported in a form of a table. The rows SHOULD be labeled

single pointer movement, one pointer movement per second, and five

pointer movements per second. The columns SHOULD be labeled cell

loss and number of cells lost. The elements of column 1 SHOULD be

either True or False, indicating whether the particular condition

was observed for each test. The elements of column 2 SHOULD be

non-negative integers.

The table MUST also indicate the traffic rate in IP PDUs per

second as generated by the test device.

3.1.1.3. IP Packet Loss due to Pointer Movement.

Objective: To determine if the SUT will drop IP packets due to

pointer movements as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the uni-directional

configuration.

2) Send a specific number of IP packets at a specific rate through

the SUT. Since this test is not a throughput test, the rate

should not be greater than 90% of line rate. The IP PDUs MUST be

encapsulated in AAL5.

3) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

4) Inject one forward payload pointer movement. Verify that the SUT

does not drop any packets.

5) Inject one forward payload pointer movement every 1 second.

Verify that the SUT does not drop any packets.

6) Discontinue the payload pointer movement.

7) Inject five forward payload pointer movements every 1 second.

Verify that the SUT does not drop any packets.

8) Discontinue the payload pointer movement.

9) Inject one backward payload pointer movement. Verify that the

SUT does not drop any packets.

10) Inject one backward payload pointer movement every 1 second.

Verify that the SUT does not drop any packets.

11) Discontinue the payload pointer movement.

12) Inject five backward payload pointer movements every 1 second.

Verify that the SUT does not drop any packets.

13) Discontinue the payload pointer movement.

Reporting Format:

The results of the IP packet loss due to pointer movement test

SHOULD be reported in a form of a table. The rows SHOULD be

labeled single pointer movement, one pointer movement per second,

and five pointer movements per second. The columns SHOULD be

labeled packet loss and number of packets lost. The elements of

column 1 SHOULD be either True or False, indicating whether the

particular condition was observed for each test. The elements of

column 2 SHOULD be non-negative integers.

The table MUST also indicate the packet size in octets and traffic

rate in packets per second as generated by the test device.

3.1.2. Transport Overhead (TOH) Error Count

3.1.2.1. TOH Error Propagation.

Objective: To determine that the SUT does not propagate TOH errors as

defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the uni-directional

configuration.

2) Send a specific number of IP PDUs at a specific rate through the

SUT. Since this test is not a throughput test, the rate should

not be greater than 90% of line rate. The cell payload SHOULD

contain valid IP PDUs. The IP PDUs MUST be encapsulated in AAL5.

3) Count the IP PDUs that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test, else lower the test device

traffic rate until the counts are the same.

4) Inject one error in the first bit of the A1 and A2 Frameword.

Verify that the SUT does not propagate the error.

5) Inject one error in the first bit of the A1 and A2 Frameword

every 1 second. Verify that the SUT does not propagate the

error.

6) Discontinue the Frameword error.

7) Inject one error in the first bit of the A1 and A2 Frameword for

4 consecutive IP PDUs in every 6 IP PDUs. Verify that the SUT

indicates Loss of Frame.

8) Discontinue the Frameword error.

Reporting Format:

The results of the TOH error propagation test SHOULD be reported

in a form of a table. The rows SHOULD be labeled single error,

one error per second, and four consecutive errors every 6 IP PDUs.

The columns SHOULD be labeled error propagated and loss of IP PDU.

The elements of the table SHOULD be either True or False,

indicating whether the particular condition was observed for each

test.

The table MUST also indicate the IP PDU size in octets and traffic

rate in IP PDUs per second as generated by the test device.

3.1.2.2. c TOH Error.

Objective: To determine if the SUT will drop cells due TOH Errors as

defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the uni-directional

configuration.

2) Send a specific number of cells at a specific rate through the

SUT. Since this test is not a throughput test, the rate should

not be greater than 90% of line rate. The cell payload SHOULD

contain valid IP PDUs. The IP PDUs MUST be encapsulated in AAL5.

3) Count the cells that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

4) Inject one error in the first bit of the A1 and A2 Frameword.

Verify that the SUT does not drop any cells.

5) Inject one error in the first bit of the A1 and A2 Frameword

every 1 second. Verify that the SUT does not drop any cells.

6) Discontinue the Frameword error.

7) Inject one error in the first bit of the A1 and A2 Frameword for

4 consecutive IP PDUs in every 6 IP PDUs. Verify that the SUT

does drop cells.

8) Discontinue the Frameword error.

Reporting Format:

The results of the Cell Loss due to TOH errors test SHOULD be

reported in a form of a table. The rows SHOULD be labeled single

error, one error per second, and four consecutive errors every 6

IP PDUs. The columns SHOULD be labeled cell loss and number of

cells lost. The elements of column 1 SHOULD be either True or

False, indicating whether the particular condition was observed

for each test. The elements of column 2 SHOULD be non-negative

integers.

The table MUST also indicate the traffic rate in IP PDUs per

second as generated by the test device.

3.1.2.3. IP Packet Loss due to TOH Error.

Objective: To determine if the SUT will drop IP packets due to TOH

errors as defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the uni-directional

configuration.

2) Send a specific number of IP packets at a specific rate through

the SUT. Since this test is not a throughput test, the rate

should not be greater than 90% of line rate. The IP PDUs MUST be

encapsulated in AAL5.

3) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

4) Inject one error in the first bit of the A1 and A2 Frameword.

Verify that the SUT does not drop any packets.

5) Inject one error in the first bit of the A1 and A2 Frameword

every 1 second. Verify that the SUT does not drop any packets.

6) Discontinue the Frameword error.

7) Inject one error in the first bit of the A1 and A2 Frameword for

4 consecutive IP PDUs in every 6 IP PDUs. Verify that the SUT

does drop packets.

8) Discontinue the Frameword error.

Reporting Format:

The results of the IP packet loss due to TOH errors test SHOULD be

reported in a form of a table. The rows SHOULD be labeled single

error, one error per second, and four consecutive errors every 6

IP PDUs. The columns SHOULD be labeled packet loss and number of

packets lost. The elements of column 1 SHOULD be either True or

False, indicating whether the particular condition was observed

for each test. The elements of column 2 SHOULD be non-negative

integers.

The table MUST also indicate the packet size in octets and traffic

rate in packets per second as generated by the test device.

3.1.3. Path Overhead (POH) Error Count

3.1.3.1. POH Error Propagation.

Objective: To determine that the SUT does not propagate POH errors as

defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the uni-directional

configuration.

2) Send a specific number of IP PDUs at a specific rate through the

SUT. Since this test is not a throughput test, the rate should

not be greater than 90% of line rate. The cell payload SHOULD

contain valid IP PDUs. The IP PDUs MUST be encapsulated in AAL5.

3) Count the IP PDUs that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test, else lower the test device

traffic rate until the counts are the same.

4) Inject one error in the B3 (Path BIP8) byte. Verify that the SUT

does not propagate the error.

5) Inject one error in the B3 byte every 1 second. Verify that the

SUT does not propagate the error.

6) Discontinue the POH error.

Reporting Format:

The results of the POH error propagation test SHOULD be reported

in a form of a table. The rows SHOULD be labeled single error

and one error per second. The columns SHOULD be labeled error

propagated and loss of IP PDU. The elements of the table SHOULD

be either True or False, indicating whether the particular

condition was observed for each test.

The table MUST also indicate the IP PDU size in octets and

traffic rate in IP PDUs per second as generated by the test

device.

3.1.3.2. Cell Loss due to POH Error.

Objective: To determine if the SUT will drop cells due POH Errors as

defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the uni-directional

configuration.

2) Send a specific number of cells at a specific rate through the

SUT. Since this test is not a throughput test, the rate should

not be greater than 90% of line rate. The cell payload SHOULD

contain valid IP PDUs. The IP PDUs MUST be encapsulated in AAL5.

3) Count the cells that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

4) Inject one error in the B3 (Path BIP8) byte. Verify that the SUT

does not drop any cells.

5) Inject one error in the B3 byte every 1 second. Verify that the

SUT does not drop any cells.

6) Discontinue the POH error.

Reporting Format:

The results of the Cell Loss due to POH errors test SHOULD be

reported in a form of a table. The rows SHOULD be labeled single

error and one error per second. The columns SHOULD be labeled

cell loss and number of cells lost. The elements of column 1

SHOULD be either True or False, indicating whether the particular

condition was observed for each test. The elements of column 2

SHOULD be non-negative integers.

The table MUST also indicate the traffic rate in IP PDUs per

second as generated by the test device.

3.1.3.3. IP Packet Loss due to POH Error.

Objective: To determine if the SUT will drop IP packets due to POH

errors as defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the uni-directional

configuration.

2) Send a specific number of IP packets at a specific rate through

the SUT. Since this test is not a throughput test, the rate

should not be greater than 90% of line rate. The IP PDUs MUST be

encapsulated in AAL5.

3) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

4) Inject one error in the B3 (Path BIP8) byte. Verify that the SUT

does not drop any packets.

5) Inject one error in the B3 byte every 1 second. Verify that the

SUT does not drop any packets.

6) Discontinue the POH error.

Reporting Format:

The results of the IP packet loss due to POH errors test SHOULD be

reported in a form of a table. The rows SHOULD be labeled single

error and one error per second. The columns SHOULD be labeled

packet loss and number of packets lost. The elements of column 1

SHOULD be either True or False, indicating whether the particular

condition was observed for each test. The elements of column 2

SHOULD be non-negative integers.

The table MUST also indicate the packet size in octets and traffic

rate in packets per second as generated by the test device.

3.2. ATM Layer

3.2.1. Two-Point Cell Delay Variation (CDV)

3.2.1.1. Test Setup

The cell delay measurements assume that both the transmitter and

receiver timestamp information is synchronized. Synchronization

SHOULD be achieved by supplying a common clock signal (minimum of 100

Mhz or 10 ns resolution) to both the transmitter and receiver. The

maximum timestamp values MUST be recorded to ensure synchronization

in the case of counter rollover. The cell delay measurements SHOULD

utilize the O.191 cell (ITUT-O.191) encapsulated in a valid IP

packet. If the O.191 cell is not available, a test cell encapsulated

in a valid IP packet MAY be used. The test cell MUST contain a

transmit timestamp which can be correlated with a receive timestamp.

A description of the test cell MUST be included in the test results.

The description MUST include the timestamp length (in bits), counter

rollover value, and the timestamp accuracy (in ns).

3.2.1.2. Two-point CDV/Steady Load/One VCC

Objective: To determine the SUT variation in cell transfer delay with

one VCC as defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as either a CBR,

VBR, or UBR connection. The VPI/VCI MUST not be one of the

reserved ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific constant rate through the SUT via the defined test VCC.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device.

Reporting Format:

The results of the Two-point CDV/Steady Load/One VCC test SHOULD

be reported in a form of text, graph, and histogram.

The text results SHOULD display the numerical values of the CDV.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, maximum

and minimum CDV during the test in us, and peak-to-peak CDV in us.

The graph results SHOULD display the cell delay values. The x-

coordinate SHOULD be the test run time in either seconds, minutes

or days depending on the total length of the test. The x-

coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the cell delay in us. The integration time per point MUST be

indicated.

The histogram results SHOULD display the peak-to-peak cell delay.

The x-coordinate SHOULD be the cell delay in us with at least 256

bins. The y-coordinate SHOULD be the number of cells observed in

each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

bearer class of the created VCC MUST also be indicated.

3.2.1.3. Two-point CDV/Steady Load/Twelve VCCs

Objective: To determine the SUT variation in cell transfer delay with

twelve VCCs as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC's MUST be configured as either a CBR, VBR,

or UBR connection. The VPI/VCIs MUST not be one of the reserved

ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific constant rate through the SUT via the defined test VCCs.

All of the VPI/VCI pairs will generate traffic at the same

traffic rate. Since this test is not a throughput test, the rate

should not be greater than 90% of line rate. The IP PDUs MUST be

encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCCs.

Reporting Format:

The results of the Two-point CDV/Steady Load/Twelve VCCs test

SHOULD be reported in a form of text, graph, and histograms.

The text results SHOULD display the numerical values of the CDV.

The values given SHOULD include: time period of test in s, test

VPI/VCI values, total number of cells transmitted and received on

each VCC during the test in positive integers, maximum and minimum

CDV on each VCC during the test in us, and peak-to-peak CDV on

each VCC in us.

The graph results SHOULD display the cell delay values. The x-

coordinate SHOULD be the test run time in either seconds, minutes

or days depending on the total length of the test. The x-

coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the cell delay for each VCC in ms. There SHOULD be 12 curves

on the graph, one curves indicated and labeled for each VCC. The

integration time per point MUST be indicated.

The histograms SHOULD display the peak-to-peak cell delay. There

will be one histogram for each VCC. The x-coordinate SHOULD be

the cell delay in us with at least 256 bins. The y-coordinate

SHOULD be the number of cells observed in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

bearer class of the created VCC MUST also be indicated.

3.2.1.4. Two-point CDV/Steady Load/Maximum VCCs

Objective: To determine the SUT variation in cell transfer delay with

the maximum number VCCs supported on the SUT as defined in RFC2761

"Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC's MUST be configured as either a CBR, VBR, or UBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific constant rate through the SUT via the defined test VCCs.

All of the VPI/VCI pairs will generate traffic at the same

traffic rate. Since this test is not a throughput test, the rate

should not be greater than 90% of line rate. The IP PDUs MUST be

encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCCs.

Reporting Format:

The results of the Two-point CDV/Steady Load/Maximum VCCs test

SHOULD be reported in a form of text, graphs, and histograms.

The text results SHOULD display the numerical values of the CDV.

The values given SHOULD include: time period of test in s, test

VPI/VCI values, total number of cells transmitted and received on

each VCC during the test in positive integers, maximum and minimum

CDV on each VCC during the test in us, and peak-to-peak CDV on

each VCC in us.

The graph results SHOULD display the cell delay values. There

will be (Max number of VCCs/10) graphs, with 10 VCCs indicated on

each graph. The x-coordinate SHOULD be the test run time in

either seconds, minutes or days depending on the total length of

the test. The x-coordinate time SHOULD be configurable. The y-

coordinate SHOULD be the cell delay for each VCC in us. There

SHOULD be no more than 10 curves on each graph, one curve

indicated and labeled for each VCC. The integration time per

point MUST be indicated.

The histograms SHOULD display the peak-to-peak cell delay. There

will be one histogram for each VCC. The x-coordinate SHOULD be

the cell delay in us with at least 256 bins. The y-coordinate

SHOULD be the number of cells observed in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

bearer class of the created VCC MUST also be indicated.

3.2.1.5. Two-point CDV/Bursty VBR Load/One VCC

Objective: To determine the SUT variation in cell transfer delay with

one VCC as defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as either a CBR

or VBR connection. The VPI/VCI MUST not be one of the reserved

ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific VBR through the SUT via the defined test VCC. Since

this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device.

Reporting Format:

The results of the Two-point CDV/Bursty VBR Load/One VCC test

SHOULD be reported in a form of text, graph, and histogram.

The text results SHOULD display the numerical values of the CDV.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, maximum

and minimum CDV during the test in us, and peak-to-peak CDV in us.

The graph results SHOULD display the cell delay values. The x-

coordinate SHOULD be the test run time in either seconds, minutes

or days depending on the total length of the test. The x-

coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the cell delay in us. The integration time per point MUST be

indicated.

The histogram results SHOULD display the peak-to-peak cell delay.

The x-coordinate SHOULD be the cell delay in us with at least 256

bins. The y-coordinate SHOULD be the number of cells observed in

each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.1.6. Two-point CDV/Bursty VBR Load/Twelve VCCs

Objective: To determine the SUT variation in cell transfer delay with

twelve VCCs as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC's MUST be configured as either a CBR or VBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific VBR through the SUT via the defined test VCCs. All of

the VPI/VCI pairs will generate traffic at the same traffic rate.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCCs.

Reporting Format:

The results of the Two-point CDV/Bursty VBR Load/Twelve VCCs test

SHOULD be reported in a form of text, graph, and histograms.

The text results SHOULD display the numerical values of the CDV.

The values given SHOULD include: time period of test in s, test

VPI/VCI values, total number of cells transmitted and received on

each VCC during the test in positive integers, maximum and minimum

CDV on each VCC during the test in us, and peak-to-peak CDV on

each VCC in us.

The graph results SHOULD display the cell delay values. The x-

coordinate SHOULD be the test run time in either seconds, minutes

or days depending on the total length of the test. The x-

coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the cell delay for each VCC in ms. There SHOULD be 12 curves

on the graph, one curves indicated and labeled for each VCC. The

integration time per point MUST be indicated.

The histograms SHOULD display the peak-to-peak cell delay. There

will be one histogram for each VCC. The x-coordinate SHOULD be

the cell delay in us with at least 256 bins. The y-coordinate

SHOULD be the number of cells observed in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.1.7. Two-point CDV/Bursty VBR Load/Maximum VCCs

Objective: To determine the SUT variation in cell transfer delay with

the maximum number VCCs supported on the SUT as defined in RFC2761

"Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC's MUST be configured as either a CBR or VBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific VBR through the SUT via the defined test VCCs. All of

the VPI/VCI pairs will generate traffic at the same traffic rate.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCCs.

Reporting Format:

The results of the Two-point CDV/Bursty VBR Load/Maximum VCCs test

SHOULD be reported in a form of text, graphs, and histograms.

The text results SHOULD display the numerical values of the CDV.

The values given SHOULD include: time period of test in s, test

VPI/VCI values, total number of cells transmitted and received on

each VCC during the test in positive integers, maximum and minimum

CDV on each VCC during the test in us, and peak-to-peak CDV on

each VCC in us.

The graph results SHOULD display the cell delay values. There

will be (Max number of VCCs/10) graphs, with 10 VCCs indicated on

each graph. The x-coordinate SHOULD be the test run time in

either seconds, minutes or days depending on the total length of

the test. The x-coordinate time SHOULD be configurable. The y-

coordinate SHOULD be the cell delay for each VCC in us. There

SHOULD be no more than 10 curves on each graph, one curve

indicated and labeled for each VCC. The integration time per

point MUST be indicated.

The histograms SHOULD display the peak-to-peak cell delay. There

will be one histogram for each VCC. The x-coordinate SHOULD be

the cell delay in us with at least 256 bins. The y-coordinate

SHOULD be the number of cells observed in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.1.8. Two-point CDV/Mixed Load/Three VCC's

Objective: To determine the SUT variation in cell transfer delay with

three VCC's as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with three VCC's. Each VCC

MUST be defined as a different Bearer class: one CBR, one UBR and

one VBR. Each VCC SHOULD contain one VPI/VCI. The VPI/VCI MUST

not be one of the reserved ATM signaling channels (e.g., [0,5],

[0,16]).

3) Send a specific number of IP packets containing timestamps

through the SUT via the defined test VCCs. Each generated VCC

stream MUST match the corresponding VCC Bearer class. All of the

VPI/VCI pairs will generate traffic at the same traffic rate.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCC's.

Reporting Format:

The results of the Two-point CDV/Mixed Load/Three VCC test SHOULD

be reported in a form of text, graph, and histogram.

The text results SHOULD display the numerical values of the CDV.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, maximum

and minimum CDV during the test in us, and peak-to-peak CDV in us.

The graph results SHOULD display the cell delay values. The x-

coordinate SHOULD be the test run time in either seconds, minutes

or days depending on the total length of the test. The x-

coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the cell delay in us. The integration time per point MUST be

indicated.

The histogram results SHOULD display the peak-to-peak cell delay.

The x-coordinate SHOULD be the cell delay in us with at least 256

bins. The y-coordinate SHOULD be the number of cells observed in

each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.1.9. Two-point CDV/Mixed Load/Twelve VCCs

Objective: To determine the SUT variation in cell transfer delay with

twelve VCCs as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCC's. Each VCC

MUST be defined as one of the Bearer classes for a total of four

CBR, four UBR and four VBR VCC's. Each VCC SHOULD contain one

VPI/VCI. The VPI/VCI MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps

through the SUT via the defined test VCCs. Each generated VCC

stream MUST match the corresponding VCC Bearer class. All of the

VPI/VCI pairs will generate traffic at the same traffic rate.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCCs.

Reporting Format:

The results of the Two-point CDV/Mixed Load/Twelve VCCs test

SHOULD be reported in a form of text, graph, and histograms.

The text results SHOULD display the numerical values of the CDV.

The values given SHOULD include: time period of test in s, test

VPI/VCI values, total number of cells transmitted and received on

each VCC during the test in positive integers, maximum and minimum

CDV on each VCC during the test in us, and peak-to-peak CDV on

each VCC in us.

The graph results SHOULD display the cell delay values. The x-

coordinate SHOULD be the test run time in either seconds, minutes

or days depending on the total length of the test. The x-

coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the cell delay for each VCC in ms. There SHOULD be 12 curves

on the graph, one curves indicated and labeled for each VCC. The

integration time per point MUST be indicated.

The histograms SHOULD display the peak-to-peak cell delay. There

will be one histogram for each VCC. The x-coordinate SHOULD be

the cell delay in us with at least 256 bins. The y-coordinate

SHOULD be the number of cells observed in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.1.10. Two-point CDV/Mixed Load/Maximum VCCs

Objective: To determine the SUT variation in cell transfer delay with

the maximum number VCCs supported on the SUT as defined in RFC2761

"Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. Each VCC MUST be defined as one of the Bearer classes for a

total of (max VCC/3) CBR, (max VCC/3) UBR and (max VCC/3) VBR

VCC's. If the maximum number of VCC's is not divisible by 3, the

total for each bearer class MUST be within 3 VCC's of each other.

The VPI/VCI MUST not be one of the reserved ATM signaling

channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps

through the SUT via the defined test VCCs. Each generated VCC

stream MUST match the corresponding VCC Bearer class. All of the

VPI/VCI pairs will generate traffic at the same traffic rate.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCCs.

Reporting Format:

The results of the Two-point CDV/Mixed Load/Maximum VCCs test

SHOULD be reported in a form of text, graphs, and histograms.

The text results SHOULD display the numerical values of the CDV.

The values given SHOULD include: time period of test in s, test

VPI/VCI values, total number of cells transmitted and received on

each VCC during the test in positive integers, maximum and minimum

CDV on each VCC during the test in us, and peak-to-peak CDV on

each VCC in us.

The graph results SHOULD display the cell delay values. There

will be (Max number of VCCs/10) graphs, with 10 VCCs indicated on

each graph. The x-coordinate SHOULD be the test run time in

either seconds, minutes or days depending on the total length of

the test. The x-coordinate time SHOULD be configurable. The y-

coordinate SHOULD be the cell delay for each VCC in us. There

SHOULD be no more than 10 curves on each graph, one curve

indicated and labeled for each VCC. The integration time per

point MUST be indicated.

The histograms SHOULD display the peak-to-peak cell delay. There

will be one histogram for each VCC. The x-coordinate SHOULD be

the cell delay in us with at least 256 bins. The y-coordinate

SHOULD be the number of cells observed in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.2. Cell Error Ratio (CER)

3.2.2.1. Test Setup

The cell error ratio measurements assume that both the transmitter

and receiver payload information is synchronized. Synchronization

MUST be achieved by supplying a known bit pattern to both the

transmitter and receiver. If this bit pattern is longer than the

packet size, the receiver MUST synchronize with the transmitter

before tests can be run.

3.2.2.2. CER/Steady Load/One VCC

Objective: To determine the SUT ratio of errored cells on one VCC in

a transmission in relation to the total cells sent as defined in RFC

2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as either a CBR,

VBR, or UBR connection. The VPI/VCI MUST not be one of the

reserved ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing one of the

specified bit patterns at a constant rate through the SUT via the

defined test VCC. Since this test is not a throughput test, the

rate should not be greater than 90% of line rate. The IP PDUs

MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the number of bit errors at the receiver end of the test

device.

Reporting Format:

The results of the CER/Steady Load/One VCC test SHOULD be reported

in a form of text and graph.

The text results SHOULD display the numerical values of the CER.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CER for the entire test.

The graph results SHOULD display the cell error ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CER. The integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.2.2.3. CER/Steady Load/Twelve VCCs

Objective: To determine the SUT ratio of errored cells on twelve VCCs

in a transmission in relation to the total cells sent as defined in

RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC's MUST be configured as either a CBR, VBR,

or UBR connection. The VPI/VCIs MUST not be one of the reserved

ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing one of the

specified bit patterns at a constant rate through the SUT via the

defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of bit errors at the receiver end of the test

device for all VCCs.

Reporting Format:

The results of the CER/Steady Load/Twelve VCCs test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CER.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CER for the entire test.

The graph results SHOULD display the cell error ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CER for each VCC. There should be 12 curves on the graph,

on curve indicated and labeled for each VCC. The integration time

per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.2.2.4. CER/Steady Load/Maximum VCCs

Objective: To determine the SUT ratio of errored cells with the

maximum number VCCs supported on the SUT in a transmission in

relation to the total cells sent as defined in RFC2761 "Terminology

for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC's MUST be configured as either a CBR, VBR, or UBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing one of the

specified bit patterns at a constant rate through the SUT via the

defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of bit errors at the receiver end of the test

device for all VCCs.

Reporting Format:

The results of the CER/Steady Load/Maximum VCCs test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CER.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CER for the entire test.

The graph results SHOULD display the cell error ratio values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the CER for each VCC. There SHOULD be

no more than 10 curves on each graph, one curve indicated and

labeled for each VCC. The integration time per point MUST be

indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.2.2.5. CER/Bursty VBR Load/One VCC

Objective: To determine the SUT ratio of errored cells on one VCC in

a transmission in relation to the total cells sent as defined in RFC

2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as either a CBR

or VBR connection. The VPI/VCI MUST not be one of the reserved

ATM signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and

MBS must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific VBR rate through the SUT via

the defined test VCC. Since this test is not a throughput test,

the rate should not be greater than 90% of line rate. The IP

PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the number of bit errors at the receiver end of the test

device.

Reporting Format:

The results of the CER/Bursty VBR Load/One VCC test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CER.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CER for the entire test.

The graph results SHOULD display the cell error ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CER. The integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.2.2.6. CER/Bursty VBR Load/Twelve VCCs

Objective: To determine the SUT ratio of errored cells on twelve VCCs

in a transmission in relation to the total cells sent as defined in

RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC's MUST be configured as either a CBR or VBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and MBS

must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific VBR rate through the SUT via

the defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The PCR, SCR, and MBS must be indicated. The IP PDUs MUST

be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of bit errors at the receiver end of the test

device for all VCCs.

Reporting Format:

The results of the CER/Bursty VBR Load/Twelve VCCs test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CER.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CER for the entire test.

The graph results SHOULD display the cell error ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CER for each VCC. There should be 12 curves on the graph,

on curve indicated and labeled for each VCC. The integration time

per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.2.2.7. CER/Bursty VBR Load/Maximum VCCs

Objective: To determine the SUT ratio of errored cells with the

maximum number VCCs supported on the SUT in a transmission in

relation to the total cells sent as defined in RFC2761 "Terminology

for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC's MUST be configured as either a CBR or VBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and MBS

must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific VBR rate through the SUT via

the defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of bit errors at the receiver end of the test

device for all VCCs.

Reporting Format:

The results of the CER/Bursty VBR Load/Maximum VCCs test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CER.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CER for the entire test.

The graph results SHOULD display the cell error ratio values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the CER for each VCC. There SHOULD be

no more than 10 curves on each graph, one curve indicated and

labeled for each VCC. The integration time per point MUST be

indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.2.3. Cell Loss Ratio (CLR)

3.2.3.1. CLR/Steady Load/One VCC

Objective: To determine the SUT ratio of lost cells on one VCC in a

transmission in relation to the total cells sent as defined in RFC

2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as either a CBR,

VBR, or UBR connection. The VPI/VCI MUST not be one of the

reserved ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets at a specific constant rate

through the SUT via the defined test VCC. Since this test is not

a throughput test, the rate should not be greater than 90% of

line rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the number of cells transmitted and received on the test

device.

Reporting Format:

The results of the CLR/Steady Load/One VCC test SHOULD be reported

in a form of text and graph.

The text results SHOULD display the numerical values of the CLR.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CLR for the entire test.

The graph results SHOULD display the Cell Loss ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CLR. The integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.3.2. CLR/Steady Load/Twelve VCCs

Objective: To determine the SUT ratio of lost cells on twelve VCCs in

a transmission in relation to the total cells sent as defined in RFC

2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC's MUST be configured as either a CBR, VBR,

or UBR connection. The VPI/VCIs MUST not be one of the reserved

ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets at a specific constant rate

through the SUT via the defined test VCCs. All of the VPI/VCI

pairs will generate traffic at the same traffic rate. Since this

test is not a throughput test, the rate should not be greater

than 90% of line rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of cells transmitted and received per VCC on

the test device.

Reporting Format:

The results of the CLR/Steady Load/Twelve VCCs test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CLR.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CLR for the entire test.

The graph results SHOULD display the Cell Loss ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CLR for each VCC. There should be 12 curves on the graph,

on curve indicated and labeled for each VCC. The integration time

per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.3.3. CLR/Steady Load/Maximum VCCs

Objective: To determine the SUT ratio of lost cells with the maximum

number VCCs supported on the SUT in a transmission in relation to the

total cells sent as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC's MUST be configured as either a CBR, VBR, or UBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets at a specific constant rate

through the SUT via the defined test VCCs. All of the VPI/VCI

pairs will generate traffic at the same traffic rate. Since this

test is not a throughput test, the rate should not be greater

than 90% of line rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of cells transmitted and received per VCC on

the test device.

Reporting Format:

The results of the CLR/Steady Load/Maximum VCCs test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CLR.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CLR for the entire test.

The graph results SHOULD display the Cell Loss ratio values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the CLR for each VCC. There SHOULD be

no more than 10 curves on each graph, one curve indicated and

labeled for each VCC. The integration time per point MUST be

indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.3.4. CLR/Bursty VBR Load/One VCC

Objective: To determine the SUT ratio of lost cells on one VCC in a

transmission in relation to the total cells sent as defined in RFC

2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as either a CBR

or VBR connection. The VPI/VCI MUST not be one of the reserved

ATM signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and

MBS must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific rate through the SUT via the

defined test VCC. Since this test is not a throughput test, the

rate should not be greater than 90% of line rate. The IP PDUs

MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the number of cells transmitted and received on the test

device.

Reporting Format:

The results of the CLR/Bursty VBR Load/One VCC test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CLR.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CLR for the entire test.

The graph results SHOULD display the Cell Loss ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CLR. The integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.3.5. CLR/Bursty VBR Load/Twelve VCCs

Objective: To determine the SUT ratio of lost cells on twelve VCCs in

a transmission in relation to the total cells sent as defined in RFC

2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC MUST be configured as either a CBR or VBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and MBS

must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific rate through the SUT via the

defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The PCR, SCR, and MBS must be indicated. The IP PDUs MUST

be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of cells transmitted and received per VCC on

the test device.

Reporting Format:

The results of the CLR/Bursty VBR Load/Twelve VCCs test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CLR.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CLR for the entire test.

The graph results SHOULD display the Cell Loss ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CLR for each VCC. There should be 12 curves on the graph,

on curve indicated and labeled for each VCC. The integration time

per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.3.6. CLR/Bursty VBR Load/Maximum VCCs

Objective: To determine the SUT ratio of lost cells with the maximum

number VCCs supported on the SUT in a transmission in relation to the

total cells sent as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC MUST be configured as either a CBR or VBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and MBS

must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific rate through the SUT via the

defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of cells transmitted and received per VCC on

the test device.

Reporting Format:

The results of the CLR/Bursty VBR Load/Maximum VCCs test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CLR.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CLR for the entire test.

The graph results SHOULD display the Cell Loss ratio values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the CLR for each VCC. There SHOULD be

no more than 10 curves on each graph, one curve indicated and

labeled for each VCC. The integration time per point MUST be

indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.4. Cell Misinsertion Rate (CMR)

3.2.4.1. CMR/Steady Load/One VCC

Objective: To determine the SUT ratio of cell misinsertion on one VCC

in a transmission in relation to the total cells sent as defined in

RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC MUST be

configured as either a CBR, VBR, or UBR connection. The VCC

SHOULD contain one VPI/VCI. The VPI/VCI MUST not be one of the

reserved ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets at a specific constant rate

through the SUT via the defined test VCC. Since this test is not

a throughput test, the rate should not be greater than 90% of

line rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the number of cell misinsertion errors at the receiver end

of the test device.

Reporting Format:

The results of the CMR/Steady Load/One VCC test SHOULD be reported

in a form of text and graph.

The text results SHOULD display the numerical values of the CMR.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CMR for the entire test.

The graph results SHOULD display the Cell misinsertion rate

values. The x-coordinate SHOULD be the test run time in either

seconds, minutes or days depending on the total length of the

test. The x-coordinate time SHOULD be configurable. The y-

coordinate SHOULD be the CMR. The integration time per point MUST

be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.4.2. CMR/Steady Load/Twelve VCCs

Objective: To determine the SUT rate of misinserted cells on twelve

VCCs in a transmission in relation to the total cells sent as defined

in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC's MUST be configured as either a CBR, VBR,

or UBR connection. The VPI/VCIs MUST not be one of the reserved

ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets at a specific constant rate

through the SUT via the defined test VCCs. All of the VPI/VCI

pairs will generate traffic at the same traffic rate. Since this

test is not a throughput test, the rate should not be greater

than 90% of line rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of cell misinsertion errors at the receiver end

of the test device per VCC.

Reporting Format:

The results of the CMR/Steady Load/Twelve VCCs test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CMR.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CMR for the entire test.

The graph results SHOULD display the Cell misinsertion rate

values. The x-coordinate SHOULD be the test run time in either

seconds, minutes or days depending on the total length of the

test. The x-coordinate time SHOULD be configurable. The y-

coordinate SHOULD be the CMR for each VCC. There should be 12

curves on the graph, on curve indicated and labeled for each VCC.

The integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.4.3. CMR/Steady Load/Maximum VCCs

Objective: To determine the SUT rate of misinserted cells with the

maximum number VCCs supported on the SUT in a transmission in

relation to the total cells sent as defined in RFC2761 "Terminology

for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC's MUST be configured as either a CBR, VBR, or UBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets at a specific constant rate

through the SUT via the defined test VCCs. All of the VPI/VCI

pairs will generate traffic at the same traffic rate. Since this

test is not a throughput test, the rate should not be greater

than 90% of line rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of cell misinsertion errors at the receiver end

of the test device per VCC.

Reporting Format:

The results of the CMR/Steady Load/Maximum VCCs test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CMR.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CMR for the entire test.

The graph results SHOULD display the Cell misinsertion rate

values. There will be (Max number of VCCs/10) graphs, with 10

VCCs indicated on each graph. The x-coordinate SHOULD be the test

run time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the CMR for each VCC. There SHOULD be

no more than 10 curves on each graph, one curve indicated and

labeled for each VCC. The integration time per point MUST be

indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.4.4. CMR/Bursty VBR Load/One VCC

Objective: To determine the SUT rate of misinserted cells on one VCC

in a transmission in relation to the total cells sent as defined in

RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as either a CBR

or VBR connection. The VPI/VCI MUST not be one of the reserved

ATM signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and

MBS must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific rate through the SUT via the

defined test VCC. Since this test is not a throughput test, the

rate should not be greater than 90% of line rate. The IP PDUs

MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the number of cell misinsertion errors at the receiver end

of the test device.

Reporting Format:

The results of the CMR/Bursty VBR Load/One VCC test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CMR.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CMR for the entire test.

The graph results SHOULD display the Cell misinsertion rate

values. The x-coordinate SHOULD be the test run time in either

seconds, minutes or days depending on the total length of the

test. The x-coordinate time SHOULD be configurable. The y-

coordinate SHOULD be the CMR. The integration time per point MUST

be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.4.5. CMR/Bursty VBR Load/Twelve VCCs

Objective: To determine the SUT rate of misinserted cells on twelve

VCCs in a transmission in relation to the total cells sent as defined

in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC's MUST be configured as either a CBR or VBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and MBS

must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific rate through the SUT via the

defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The PCR, SCR, and MBS must be indicated. The IP PDUs MUST

be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of cell misinsertion errors at the receiver end

of the test device per VCC.

Reporting Format:

The results of the CMR/Bursty VBR Load/Twelve VCCs test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CMR.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CMR for the entire test.

The graph results SHOULD display the Cell misinsertion rate

values. The x-coordinate SHOULD be the test run time in either

seconds, minutes or days depending on the total length of the

test. The x-coordinate time SHOULD be configurable. The y-

coordinate SHOULD be the CMR for each VCC. There should be 12

curves on the graph, on curve indicated and labeled for each VCC.

The integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.4.6. CMR/Bursty VBR Load/Maximum VCCs

Objective: To determine the SUT rate of misinserted cells with the

maximum number VCCs supported on the SUT in a transmission in

relation to the total cells sent as defined in RFC2761 "Terminology

for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC's MUST be configured as either a CBR or VBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and MBS

must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific rate through the SUT via the

defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of cell misinsertion errors at the receiver end

of the test device per VCC.

Reporting Format:

The results of the CMR/Bursty VBR Load/Maximum VCCs test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CMR.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, and the

CMR for the entire test.

The graph results SHOULD display the Cell misinsertion rate

values. There will be (Max number of VCCs/10) graphs, with 10

VCCs indicated on each graph. The x-coordinate SHOULD be the test

run time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the CMR for each VCC. There SHOULD be

no more than 10 curves on each graph, one curve indicated and

labeled for each VCC. The integration time per point MUST be

indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.5. CRC Error Ratio (CRC-ER)

3.2.5.1. CRC-ER/Steady Load/One VCC

Objective: To determine the SUT ratio of CRC errors on one VCC in a

transmission in relation to the total cells sent as defined in RFC

2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as either a CBR,

VBR, or UBR connection. The VPI/VCI MUST not be one of the

reserved ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets at a specific constant rate

through the SUT via the defined test VCC. Since this test is not

a throughput test, the rate should not be greater than 90% of

line rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the number of CRC errored cells received on the test

device.

Reporting Format:

The results of the CRC-ER/Steady Load/One VCC test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CRC-

ER. The values given SHOULD include: time period of test in s,

test VPI/VCI value, total number of cells transmitted and received

on the given VPI/VCI during the test in positive integers, and the

CRC-ER for the entire test.

The graph results SHOULD display the CRC Error ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CRC-ER. The integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.5.2. CRC-ER/Steady Load/Twelve VCCs

Objective: To determine the SUT ratio of lost cells on twelve VCCs in

a transmission in relation to the total cells sent as defined in RFC

2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC's MUST be configured as either a CBR, VBR,

or UBR connection. The VPI/VCIs MUST not be one of the reserved

ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets at a specific constant rate

through the SUT via the defined test VCCs. All of the VPI/VCI

pairs will generate traffic at the same traffic rate. Since this

test is not a throughput test, the rate should not be greater

than 90% of line rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of CRC errored cells received per VCC on the

test device.

Reporting Format:

The results of the CRC-ER/Steady Load/Twelve VCCs test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CRC-

ER. The values given SHOULD include: time period of test in s,

test VPI/VCI value, total number of cells transmitted and received

on the given VPI/VCI during the test in positive integers, and the

CRC-ER for the entire test.

The graph results SHOULD display the CRC Error ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CRC-ER for each VCC. There should be 12 curves on the

graph, on curve indicated and labeled for each VCC. The

integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.5.3. CRC-ER/Steady Load/Maximum VCCs

Objective: To determine the SUT ratio of lost cells with the maximum

number VCCs supported on the SUT in a transmission in relation to the

total cells sent as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC's MUST be configured as either a CBR, VBR, or UBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets at a specific constant rate

through the SUT via the defined test VCCs. All of the VPI/VCI

pairs will generate traffic at the same traffic rate. Since this

test is not a throughput test, the rate should not be greater

than 90% of line rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of CRC errored cells received per VCC on the

test device.

Reporting Format:

The results of the CRC-ER/Steady Load/Maximum VCCs test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CRC-

ER. The values given SHOULD include: time period of test in s,

test VPI/VCI value, total number of cells transmitted and received

on the given VPI/VCI during the test in positive integers, and the

CRC-ER for the entire test.

The graph results SHOULD display the CRC Error ratio values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the CRC-ER for each VCC. There SHOULD

be no more than 10 curves on each graph, one curve indicated and

labeled for each VCC. The integration time per point MUST be

indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.5.4. CRC-ER/Bursty VBR Load/One VCC

Objective: To determine the SUT ratio of lost cells on one VCC in a

transmission in relation to the total cells sent as defined in RFC

2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as either a CBR

or VBR connection. The VPI/VCI MUST not be one of the reserved

ATM signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and

MBS must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific rate through the SUT via the

defined test VCC. Since this test is not a throughput test, the

rate should not be greater than 90% of line rate. The IP PDUs

MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the number of CRC errored cells received per VCC on the

test device.

Reporting Format:

The results of the CRC-ER/Bursty VBR Load/One VCC test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CRC-

ER. The values given SHOULD include: time period of test in s,

test VPI/VCI value, total number of cells transmitted and received

on the given VPI/VCI during the test in positive integers, and the

CRC-ER for the entire test.

The graph results SHOULD display the CRC Error ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CRC-ER. The integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.5.5. CRC-ER/Bursty VBR Load/Twelve VCCs

Objective: To determine the SUT ratio of lost cells on twelve VCCs in

a transmission in relation to the total cells sent as defined in RFC

2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC MUST be configured as either a CBR or VBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and MBS

must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific rate through the SUT via the

defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The PCR, SCR, and MBS must be indicated. The IP PDUs MUST

be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of CRC errored cells received per VCC on the

test device for all VCCs.

Reporting Format:

The results of the CRC-ER/Bursty VBR Load/Twelve VCCs test SHOULD

be reported in a form of text and graph.

The text results SHOULD display the numerical values of the CRC-

ER. The values given SHOULD include: time period of test in s,

test VPI/VCI value, total number of cells transmitted and received

on the given VPI/VCI during the test in positive integers, and the

CRC-ER for the entire test.

The graph results SHOULD display the CRC Error ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CRC-ER for each VCC. There should be 12 curves on the

graph, on curve indicated and labeled for each VCC. The

integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.5.6. CRC-ER/Bursty VBR Load/Maximum VCCs

Objective: To determine the SUT ratio of lost cells with the maximum

number VCCs supported on the SUT in a transmission in relation to the

total cells sent as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC MUST be configured as either a CBR or VBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and MBS

must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific rate through the SUT via the

defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of CRC errored cells received per VCC on the

test device for all VCCs.

Reporting Format:

The results of the CRC-ER/Bursty VBR Load/Maximum VCCs test SHOULD

be reported in a form of text and graph.

The text results SHOULD display the numerical values of the CRC-

ER. The values given SHOULD include: time period of test in s,

test VPI/VCI value, total number of cells transmitted and received

on the given VPI/VCI during the test in positive integers, and the

CRC-ER for the entire test.

The graph results SHOULD display the CRC Error ratio values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the CRC-ER for each VCC. There SHOULD

be no more than 10 curves on each graph, one curve indicated and

labeled for each VCC. The integration time per point MUST be

indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.5.7. CRC-ER/Bursty UBR Load/One VCC

Objective: To determine the SUT ratio of lost cells on one VCC in a

transmission in relation to the total cells sent as defined in RFC

2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as a UBR

connection. The VPI/VCI MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and MBS

must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific rate through the SUT via the

defined test VCC. Since this test is not a throughput test, the

rate should not be greater than 90% of line rate. The IP PDUs

MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the number of CRC errored cells received per VCC on the

test device.

Reporting Format:

The results of the CRC-ER/Bursty UBR Load/One VCC test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the CRC-

ER. The values given SHOULD include: time period of test in s,

test VPI/VCI value, total number of cells transmitted and received

on the given VPI/VCI during the test in positive integers, and the

CRC-ER for the entire test.

The graph results SHOULD display the CRC Error ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CRC-ER. The integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.5.8. CRC-ER/Bursty UBR Load/Twelve VCCs

Objective: To determine the SUT ratio of lost cells on twelve VCCs in

a transmission in relation to the total cells sent as defined in RFC

2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC MUST be configured as a UBR connection.

The VPI/VCIs MUST not be one of the reserved ATM signaling

channels (e.g., [0,5], [0,16]). The PCR, SCR, and MBS must be

configured using one of the specified traffic descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific rate through the SUT via the

defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The PCR, SCR, and MBS must be indicated. The IP PDUs MUST

be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of CRC errored cells received per VCC on the

test device for all VCCs.

Reporting Format:

The results of the CRC-ER/Bursty UBR Load/Twelve VCCs test SHOULD

be reported in a form of text and graph.

The text results SHOULD display the numerical values of the CRC-

ER. The values given SHOULD include: time period of test in s,

test VPI/VCI value, total number of cells transmitted and received

on the given VPI/VCI during the test in positive integers, and the

CRC-ER for the entire test.

The graph results SHOULD display the CRC Error ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CRC-ER for each VCC. There should be 12 curves on the

graph, on curve indicated and labeled for each VCC. The

integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.5.9. CRC-ER/Bursty UBR Load/Maximum VCCs

Objective: To determine the SUT ratio of lost cells with the maximum

number VCCs supported on the SUT in a transmission in relation to the

total cells sent as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC MUST be configured as a UBR connection. The

VPI/VCIs MUST not be one of the reserved ATM signaling channels

(e.g., [0,5], [0,16]). The PCR, SCR, and MBS must be configured

using one of the specified traffic descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific rate through the SUT via the

defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of CRC errored cells received per VCC on the

test device for all VCCs.

Reporting Format:

The results of the CRC-ER/Bursty UBR Load/Maximum VCCs test SHOULD

be reported in a form of text and graph.

The text results SHOULD display the numerical values of the CRC-

ER. The values given SHOULD include: time period of test in s,

test VPI/VCI value, total number of cells transmitted and received

on the given VPI/VCI during the test in positive integers, and the

CRC-ER for the entire test.

The graph results SHOULD display the CRC Error ratio values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the CRC-ER for each VCC. There SHOULD

be no more than 10 curves on each graph, one curve indicated and

labeled for each VCC. The integration time per point MUST be

indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.5.10. CRC-ER/Bursty Mixed Load/Three VCC

Objective: To determine the SUT ratio of lost cells on three VCC's in

relation to the total cells sent as defined in RFC2761 "Terminology

for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with three VCC's. Each VCC

MUST be defined as a different Bearer class; one CBR, one UBR and

one VBR. Each VCC SHOULD contain one VPI/VCI. The VPI/VCI MUST

not be one of the reserved ATM signaling channels (e.g., [0,5],

[0,16]). The PCR, SCR, and MBS must be configured using one of

the specified traffic descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns through the SUT via the defined test VCCs.

Each generated VCC stream MUST match the corresponding VCC Bearer

class. All of the VPI/VCI pairs will generate traffic at the

same traffic rate. Since this test is not a throughput test, the

rate should not be greater than 90% of line rate. The IP PDUs

MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the number of CRC errored cells received per VCC on the

test device.

Reporting Format:

The results of the CRC-ER/Bursty Mixed Load/Three VCC test SHOULD

be reported in in a form of text and graph.

The text results SHOULD display the numerical values of the CRC-

ER. The values given SHOULD include: time period of test in s,

test VPI/VCI value, total number of cells transmitted and received

on the given VPI/VCI during the test in positive integers, and the

CRC-ER for the entire test.

The graph results SHOULD display the CRC Error ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CRC-ER for each VCC. There should be 12 curves on the

graph, on curve indicated and labeled for each VCC. The

integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.5.11. CRC-ER/Bursty Mixed Load/Twelve VCCs

Objective: To determine the SUT ratio of lost cells on twelve VCCs in

a transmission in relation to the total cells sent as defined in RFC

2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCC's. Each VCC

MUST be defined as one of the Bearer classes for a total of four

CBR, four UBR and four VBR VCC's. Each VCC SHOULD contain one

VPI/VCI. The VPI/VCI MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing one of the

specified bit patterns through the SUT via the defined test VCCs.

Each generated VCC stream MUST match the corresponding VCC Bearer

class. All of the VPI/VCI pairs will generate traffic at the

same traffic rate. Since this test is not a throughput test, the

rate should not be greater than 90% of line rate. The IP PDUs

MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of CRC errored cells received per VCC on the

test device for all VCCs.

Reporting Format:

The results of the CRC-ER/Bursty Mixed Load/Twelve VCCs test

SHOULD be reported in a form of text and graph.

The text results SHOULD display the numerical values of the CRC-

ER. The values given SHOULD include: time period of test in s,

test VPI/VCI value, total number of cells transmitted and received

on the given VPI/VCI during the test in positive integers, and the

CRC-ER for the entire test.

The graph results SHOULD display the CRC Error ratio values. The

x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the CRC-ER for each VCC. There should be 12 curves on the

graph, on curve indicated and labeled for each VCC. The

integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.5.12. CRC-ER/Bursty Mixed Load/Maximum VCCs

Objective: To determine the SUT ratio of lost cells with the maximum

number VCCs supported on the SUT in a transmission in relation to the

total cells sent as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. Each VCC MUST be defined as one of the Bearer classes for a

total of (max VCC/3) CBR, (max VCC/3) UBR and (max VCC/3) VBR

VCC's. The VPI/VCI MUST not be one of the reserved ATM signaling

channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing one of the

specified bit patterns through the SUT via the defined test VCCs.

Each generated VCC stream MUST match the corresponding VCC Bearer

class. All of the VPI/VCI pairs will generate traffic at the

same traffic rate. Since this test is not a throughput test, the

rate should not be greater than 90% of line rate. The IP PDUs

MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of CRC errored cells received per VCC on the

test device for all VCCs.

Reporting Format:

The results of the CRC-ER/Bursty Mixed Load/Maximum VCCs test

SHOULD be reported in a form of text and graph.

The text results SHOULD display the numerical values of the CRC-

ER. The values given SHOULD include: time period of test in s,

test VPI/VCI value, total number of cells transmitted and received

on the given VPI/VCI during the test in positive integers, and the

CRC-ER for the entire test.

The graph results SHOULD display the CRC Error ratio values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the CRC-ER for each VCC. There SHOULD

be no more than 10 curves on each graph, one curve indicated and

labeled for each VCC. The integration time per point MUST be

indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.6. Cell Transfer Delay (CTD)

3.2.6.1. Test Setup

The cell transfer delay measurements assume that both the transmitter

and receiver timestamp information is synchronized. Synchronization

SHOULD be achieved by supplying a common clock signal (minimum of 100

Mhz or 10 ns resolution) to both the transmitter and receiver. The

maximum timestamp values MUST be recorded to ensure synchronization

in the case of counter rollover. The cell transfer delay

measurements SHOULD utilize the O.191 cell (ITUT-O.191) encapsulated

in a valid IP packet. If the O.191 cell is not available, a test

cell encapsulated in a valid IP packet MAY be used. The test cell

MUST contain a transmit timestamp which can be correlated with a

receive timestamp. A description of the test cell MUST be included

in the test results. The description MUST include the timestamp

length (in bits), counter rollover value, and the timestamp accuracy

(in ns).

3.2.6.2. CTD/Steady Load/One VCC

Objective: To determine the SUT variation in cell transfer delay with

one VCC as defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as either a CBR,

VBR, or UBR connection. The VPI/VCI MUST not be one of the

reserved ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific constant rate through the SUT via the defined test VCC.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device.

Reporting Format:

The results of the CTD/Steady Load/One VCC test SHOULD be reported

in a form of text, graph, and histogram.

The text results SHOULD display the numerical values of the CTD.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, minimum,

maximum, and mean CTD during the test in us.

The graph results SHOULD display the cell transfer delay values.

The x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the cell transfer delay in us. The integration time per point

MUST be indicated.

The histogram results SHOULD display the cell transfer delay. The

x-coordinate SHOULD be the cell transfer delay in us with at least

256 bins. The y-coordinate SHOULD be the number of cells observed

in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

bearer class of the created VCC MUST also be indicated.

3.2.6.3. CTD/Steady Load/Twelve VCCs

Objective: To determine the SUT variation in cell transfer delay with

twelve VCCs as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC's MUST be configured as either a CBR, VBR,

or UBR connection. The VPI/VCIs MUST not be one of the reserved

ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific constant rate through the SUT via the defined test VCCs.

All of the VPI/VCI pairs will generate traffic at the same

traffic rate. Since this test is not a throughput test, the rate

should not be greater than 90% of line rate. The IP PDUs MUST be

encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCCs.

Reporting Format:

The results of the CTD/Steady Load/Twelve VCCs test SHOULD be

reported in a form of text, graph, and histograms.

The text results SHOULD display the numerical values of the CTD.

The values given SHOULD include: time period of test in s, test

VPI/VCI values, total number of cells transmitted and received on

each VCC during the test in positive integers, maximum and minimum

CTD on each VCC during the test in us, and mean CTD on each VCC in

us.

The graph results SHOULD display the cell transfer delay values.

The x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the cell transfer delay for each VCC in ms. There SHOULD be 12

curves on the graph, one curves indicated and labeled for each

VCC. The integration time per point MUST be indicated.

The histograms SHOULD display the cell transfer delay. There will

be one histogram for each VCC. The x-coordinate SHOULD be the

cell transfer delay in us with at least 256 bins. The y-

coordinate SHOULD be the number of cells observed in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

bearer class of the created VCC MUST also be indicated.

3.2.6.4. CTD/Steady Load/Maximum VCCs

Objective: To determine the SUT variation in cell transfer delay with

the maximum number VCCs supported on the SUT as defined in RFC2761

"Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC's MUST be configured as either a CBR, VBR, or UBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific constant rate through the SUT via the defined test VCCs.

All of the VPI/VCI pairs will generate traffic at the same

traffic rate. Since this test is not a throughput test, the rate

should not be greater than 90% of line rate. The IP PDUs MUST be

encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCCs.

Reporting Format:

The results of the CTD/Steady Load/Maximum VCCs test SHOULD be

reported in a form of text, graphs, and histograms.

The text results SHOULD display the numerical values of the CTD.

The values given SHOULD include: time period of test in s, test

VPI/VCI values, total number of cells transmitted and received on

each VCC during the test in positive integers, maximum and minimum

CTD on each VCC during the test in us, and mean CTD on each VCC in

us.

The graph results SHOULD display the cell transfer delay values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the cell transfer delay for each VCC in

us. There SHOULD be no more than 10 curves on each graph, one

curve indicated and labeled for each VCC. The integration time

per point MUST be indicated.

The histograms SHOULD display the cell transfer delay. There will

be one histogram for each VCC. The x-coordinate SHOULD be the

cell transfer delay in us with at least 256 bins. The y-

coordinate SHOULD be the number of cells observed in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

bearer class of the created VCC MUST also be indicated.

3.2.6.5. CTD/Bursty VBR Load/One VCC

Objective: To determine the SUT variation in cell transfer delay with

one VCC as defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as either a CBR

or VBR connection. The VPI/VCI MUST not be one of the reserved

ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific VBR through the SUT via the defined test VCC. Since

this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device.

Reporting Format:

The results of the CTD/Bursty VBR Load/One VCC test SHOULD be

reported in a form of text, graph, and histogram.

The text results SHOULD display the numerical values of the CTD.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, minimum,

maximum, and mean CTD during the test in us.

The graph results SHOULD display the cell transfer delay values.

The x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the cell transfer delay in us. The integration time per point

MUST be indicated.

The histogram results SHOULD display the cell transfer delay. The

x-coordinate SHOULD be the cell transfer delay in us with at least

256 bins. The y-coordinate SHOULD be the number of cells observed

in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.6.6. CTD/Bursty VBR Load/Twelve VCCs

Objective: To determine the SUT variation in cell transfer delay with

twelve VCCs as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC's MUST be configured as either a CBR or VBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific VBR through the SUT via the defined test VCCs. All of

the VPI/VCI pairs will generate traffic at the same traffic rate.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCCs.

Reporting Format:

The results of the CTD/Bursty VBR Load/Twelve VCCs test SHOULD be

reported in a form of text, graph, and histograms.

The text results SHOULD display the numerical values of the CTD.

The values given SHOULD include: time period of test in s, test

VPI/VCI values, total number of cells transmitted and received on

each VCC during the test in positive integers, maximum and minimum

CTD on each VCC during the test in us, and mean CTD on each VCC in

us.

The graph results SHOULD display the cell transfer delay values.

The x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the cell transfer delay for each VCC in ms. There SHOULD be 12

curves on the graph, one curves indicated and labeled for each

VCC. The integration time per point MUST be indicated.

The histograms SHOULD display the cell transfer delay. There will

be one histogram for each VCC. The x-coordinate SHOULD be the

cell transfer delay in us with at least 256 bins. The y-

coordinate SHOULD be the number of cells observed in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.6.7. CTD/Bursty VBR Load/Maximum VCCs

Objective: To determine the SUT variation in cell transfer delay with

the maximum number VCCs supported on the SUT as defined in RFC2761

"Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC's MUST be configured as either a CBR or VBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific VBR through the SUT via the defined test VCCs. All of

the VPI/VCI pairs will generate traffic at the same traffic rate.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCCs.

Reporting Format:

The results of the CTD/Bursty VBR Load/Maximum VCCs test SHOULD be

reported in a form of text, graphs, and histograms.

The text results SHOULD display the numerical values of the CTD.

The values given SHOULD include: time period of test in s, test

VPI/VCI values, total number of cells transmitted and received on

each VCC during the test in positive integers, maximum and minimum

CTD on each VCC during the test in us, and mean CTD on each VCC in

us.

The graph results SHOULD display the cell transfer delay values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the cell transfer delay for each VCC in

us. There SHOULD be no more than 10 curves on each graph, one

curve indicated and labeled for each VCC. The integration time

per point MUST be indicated.

The histograms SHOULD display the cell transfer delay. There will

be one histogram for each VCC. The x-coordinate SHOULD be the

cell transfer delay in us with at least 256 bins. The y-

coordinate SHOULD be the number of cells observed in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.6.8. CTD/Bursty UBR Load/One VCC

Objective: To determine the SUT variation in cell transfer delay with

one VCC as defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as a UBR

connection. The VPI/VCI MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific UBR through the SUT via the defined test VCC. Since

this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device.

Reporting Format:

The results of the CTD/Bursty UBR Load/One VCC test SHOULD be

reported in a form of text, graph, and histogram.

The text results SHOULD display the numerical values of the CTD.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, minimum,

maximum, and mean CTD during the test in us.

The graph results SHOULD display the cell transfer delay values.

The x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the cell transfer delay in us. The integration time per point

MUST be indicated.

The histogram results SHOULD display the cell transfer delay. The

x-coordinate SHOULD be the cell transfer delay in us with at least

256 bins. The y-coordinate SHOULD be the number of cells observed

in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

bearer class of the created VCC MUST also be indicated.

3.2.6.9. CTD/Bursty UBR Load/Twelve VCCs

Objective: To determine the SUT variation in cell transfer delay with

twelve VCCs as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC's MUST be configured as a UBR connection.

The VPI/VCIs MUST not be one of the reserved ATM signaling

channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific UBR through the SUT via the defined test VCCs. All of

the VPI/VCI pairs will generate traffic at the same traffic rate.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCCs.

Reporting Format:

The results of the CTD/Bursty UBR Load/Twelve VCCs test SHOULD be

reported in a form of text, graph, and histograms.

The text results SHOULD display the numerical values of the CTD.

The values given SHOULD include: time period of test in s, test

VPI/VCI values, total number of cells transmitted and received on

each VCC during the test in positive integers, maximum and minimum

CTD on each VCC during the test in us, and mean CTD on each VCC in

us.

The graph results SHOULD display the cell transfer delay values.

The x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the cell transfer delay for each VCC in ms. There SHOULD be 12

curves on the graph, one curves indicated and labeled for each

VCC. The integration time per point MUST be indicated.

The histograms SHOULD display the cell transfer delay. There will

be one histogram for each VCC. The x-coordinate SHOULD be the

cell transfer delay in us with at least 256 bins. The y-

coordinate SHOULD be the number of cells observed in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

bearer class of the created VCC MUST also be indicated.

3.2.6.10. CTD/Bursty UBR Load/Maximum VCCs

Objective: To determine the SUT variation in cell transfer delay with

the maximum number VCCs supported on the SUT as defined in RFC2761

"Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC MUST be configured as a UBR connection. The

VPI/VCIs MUST not be one of the reserved ATM signaling channels

(e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps at a

specific UBR through the SUT via the defined test VCCs. All of

the VPI/VCI pairs will generate traffic at the same traffic rate.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCCs.

Reporting Format:

The results of the CTD/Bursty UBR Load/Maximum VCCs test SHOULD be

reported in a form of text, graphs, and histograms.

The text results SHOULD display the numerical values of the CTD.

The values given SHOULD include: time period of test in s, test

VPI/VCI values, total number of cells transmitted and received on

each VCC during the test in positive integers, maximum and minimum

CTD on each VCC during the test in us, and mean CTD on each VCC in

us.

The graph results SHOULD display the cell transfer delay values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the cell transfer delay for each VCC in

us. There SHOULD be no more than 10 curves on each graph, one

curve indicated and labeled for each VCC. The integration time

per point MUST be indicated.

The histograms SHOULD display the cell transfer delay. There will

be one histogram for each VCC. The x-coordinate SHOULD be the

cell transfer delay in us with at least 256 bins. The y-

coordinate SHOULD be the number of cells observed in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

bearer class of the created VCC MUST also be indicated.

3.2.6.11. CTD/Mixed Load/Three VCC's

Objective: To determine the SUT variation in cell transfer delay with

three VCC's as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with three VCC's. Each VCC

MUST be defined as a different Bearer class: one CBR, one UBR and

one VBR. Each VCC SHOULD contain one VPI/VCI. The VPI/VCI MUST

not be one of the reserved ATM signaling channels (e.g., [0,5],

[0,16]).

3) Send a specific number of IP packets containing timestamps

through the SUT via the defined test VCCs. Each generated VCC

stream MUST match the corresponding VCC Bearer class. All of the

VPI/VCI pairs will generate traffic at the same traffic rate.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCC's.

Reporting Format:

The results of the CTD/Mixed Load/Three VCC test SHOULD be

reported in a form of text, graph, and histogram.

The text results SHOULD display the numerical values of the CTD.

The values given SHOULD include: time period of test in s, test

VPI/VCI value, total number of cells transmitted and received on

the given VPI/VCI during the test in positive integers, minimum,

maximum, and mean CTD during the test in us.

The graph results SHOULD display the cell transfer delay values.

The x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the cell transfer delay in us. The integration time per point

MUST be indicated.

The histogram results SHOULD display the cell transfer delay. The

x-coordinate SHOULD be the cell transfer delay in us with at least

256 bins. The y-coordinate SHOULD be the number of cells observed

in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.6.12. CTD/Mixed Load/Twelve VCCs

Objective: To determine the SUT variation in cell transfer delay with

twelve VCCs as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCC's. Each VCC

MUST be defined as one of the Bearer classes for a total of four

CBR, four UBR and four VBR VCC's. Each VCC SHOULD contain one

VPI/VCI. The VPI/VCI MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps

through the SUT via the defined test VCCs. Each generated VCC

stream MUST match the corresponding VCC Bearer class. All of the

VPI/VCI pairs will generate traffic at the same traffic rate.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCCs.

Reporting Format:

The results of the CTD/Mixed Load/Twelve VCCs test SHOULD be

reported in a form of text, graph, and histograms.

The text results SHOULD display the numerical values of the CTD.

The values given SHOULD include: time period of test in s, test

VPI/VCI values, total number of cells transmitted and received on

each VCC during the test in positive integers, maximum and minimum

CTD on each VCC during the test in us, and mean CTD on each VCC in

us.

The graph results SHOULD display the cell transfer delay values.

The x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the cell transfer delay for each VCC in ms. There SHOULD be 12

curves on the graph, one curves indicated and labeled for each

VCC. The integration time per point MUST be indicated.

The histograms SHOULD display the cell transfer delay. There will

be one histogram for each VCC. The x-coordinate SHOULD be the

cell transfer delay in us with at least 256 bins. The y-

coordinate SHOULD be the number of cells observed in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.2.6.13. CTD/Mixed Load/Maximum VCCs

Objective: To determine the SUT variation in cell transfer delay with

the maximum number VCCs supported on the SUT as defined in RFC2761

"Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. Each VCC MUST be defined as one of the Bearer classes for a

total of (max VCC/3) CBR, (max VCC/3) UBR and (max VCC/3) VBR

VCC's. If the maximum number of VCC's is not divisible by 3, the

total for each bearer class MUST be within 3 VCC's of each other.

The VPI/VCI MUST not be one of the reserved ATM signaling

channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing timestamps

through the SUT via the defined test VCCs. Each generated VCC

stream MUST match the corresponding VCC Bearer class. All of the

VPI/VCI pairs will generate traffic at the same traffic rate.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the packets timestamps at the transmitter and receiver

ends of the test device for all VCCs.

Reporting Format:

The results of the CTD/Mixed Load/Maximum VCCs test SHOULD be

reported in a form of text, graphs, and histograms.

The text results SHOULD display the numerical values of the CTD.

The values given SHOULD include: time period of test in s, test

VPI/VCI values, total number of cells transmitted and received on

each VCC during the test in positive integers, maximum and minimum

CTD on each VCC during the test in us, and mean CTD on each VCC in

us.

The graph results SHOULD display the cell transfer delay values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the cell transfer delay for each VCC in

us. There SHOULD be no more than 10 curves on each graph, one

curve indicated and labeled for each VCC. The integration time

per point MUST be indicated.

The histograms SHOULD display the cell transfer delay. There will

be one histogram for each VCC. The x-coordinate SHOULD be the

cell transfer delay in us with at least 256 bins. The y-

coordinate SHOULD be the number of cells observed in each bin.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST also be indicated.

3.3. ATM Adaptation Layer (AAL) Type 5 (AAL5)

3.3.1. IP Packet Loss due to AAL5 Re-assembly Errors

Objective: To determine if the SUT will drop IP packets due AAL5 Re-

assembly Errors as defined in RFC2761 "Terminology for ATM

Benchmarking".

Procedure:

1) Set up the SUT and test device using the uni-directional

configuration.

2) Send a specific number of cells at a specific rate through the

SUT. Since this test is not a throughput test, the rate should

not be greater than 90% of line rate. The cell payload SHOULD

contain valid IP PDUs. The IP PDUs MUST be encapsulated in AAL5.

3) Count the cells that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

4) Inject one error in the first bit of the AAL5 payload. Verify

that the SUT does not drop any AAL5 PDU's.

5) Discontinue the AAL5 payload error.

6) Inject one error in the first bit of the AAL5 header for 4

consecutive IP PDUs in every 6 IP PDUs. Verify that the SUT does

drop the AAL5 PDU's.

7) Discontinue the AAL5 payload error.

Reporting Format:

The results of the AAL5 PDU Loss due to AAL5 PDU errors test

SHOULD be reported in a form of a table. The rows SHOULD be

labeled single error, one error per second, and four consecutive

errors every 6 IP PDUs. The columns SHOULD be labeled AAL5 PDU

loss and number of PDU's lost. The elements of column 1 SHOULD be

either True or False, indicating whether the particular condition

was observed for each test. The elements of column 2 SHOULD be

non-negative integers.

The table MUST also indicate the traffic rate in IP PDUs per

second as generated by the test device.

3.3.2. AAL5 Reassembly Time.

Objective: To determine the SUT AAL5 Reassembly Time as defined in

RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the uni-directional

configuration.

2) Send a specific number of IP packets at a specific rate through

the SUT. Since this test is not a throughput test, the rate

should not be greater than 90% of line rate. The IP PDUs MUST be

encapsulated in AAL5. The AAL5 PDU size is 65535 octets or 1365

ATM cells.

3) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

4) Given an AAL5 reassembly timer of 'x' seconds, where 'x' is the

actual value of the AAL5 reassembly timer on the SUT, sent

traffic at 1365 cells per 'x' seconds. The expected results are

that no AAL5 PDU's will be dropped.

5) Send traffic at 1360 cells per 'x' seconds. The expected results

are that all AAL5 PDU's will be dropped.

Reporting Format:

The results of the IP packet loss due to AAL5 reassembly timeout

test SHOULD be reported in a form of a table. The rows SHOULD be

labeled 1365 cells per 'x' seconds and 1360 cells per 'x' seconds.

The columns SHOULD be labeled packet loss and number of packets

lost. The elements of column 1 SHOULD be either True or False,

indicating whether the particular condition was observed for each

test. The elements of column 2 SHOULD be non-negative integers.

The table MUST also indicate the packet size in octets and traffic

rate in packets per second as generated by the test device,

including the value of

3.3.3. AAL5 CRC Error Ratio.

3.3.3.1. Test Setup

The AAL5 CRC error ratio measurements assume that both the

transmitter and receiver payload information is synchronized.

Synchronization MUST be achieved by supplying a known bit pattern to

both the transmitter and receiver. If this bit pattern is longer

than the packet size, the receiver MUST synchronize with the

transmitter before tests can be run.

3.3.3.2. AAL5-CRC-ER/Steady Load/One VCC

Objective: To determine the SUT ratio of AAL5 CRC PDU errors on one

VCC in a transmission in relation to the total AAL5 PDU's sent as

defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as either a CBR,

VBR, or UBR connection. The VPI/VCI MUST not be one of the

reserved ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing one of the

specified bit patterns at a constant rate through the SUT via the

defined test VCC. Since this test is not a throughput test, the

rate should not be greater than 90% of line rate. The IP PDUs

MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the number of AAL5 CRC errors at the receiver end of the

test device.

Reporting Format:

The results of the AAL5-CRC-ER/Steady Load/One VCC test SHOULD be

reported in a form of text and graph.

The text results SHOULD display the numerical values of the AAL5-

CRC-ER. The values given SHOULD include: time period of test in

s, test VPI/VCI value, total number of AAL5 PDU's transmitted and

received on the given VPI/VCI during the test in positive

integers, and the AAL5-CRC-ER for the entire test.

The graph results SHOULD display the AAL5 CRC error ratio values.

The x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the AAL5-CRC-ER. The integration time per point MUST be

indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.3.3.3. AAL5-CRC-ER/Steady Load/Twelve VCCs

Objective: To determine the SUT ratio of AAL5 CRC PDU errors on

twelve VCC's in a transmission in relation to the total AAL5 PDU's

sent as defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC's MUST be configured as either a CBR, VBR,

or UBR connection. The VPI/VCIs MUST not be one of the reserved

ATM signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing one of the

specified bit patterns at a constant rate through the SUT via the

defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate.

Since this test is not a throughput test, the rate should not be

greater than 90% of line rate. The IP PDUs MUST be encapsulated

in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of AAL5 CRC errors at the receiver end of the

test device for all VCCs.

Reporting Format:

The results of the AAL5-CRC-ER/Steady Load/Twelve VCCs test SHOULD

be reported in a form of text and graph.

The text results SHOULD display the numerical values of the AAL5-

CRC-ER. The values given SHOULD include: time period of test in

s, test VPI/VCI value, total number of AAL5 PDU's transmitted and

received on the given VPI/VCI during the test in positive

integers, and the AAL5-CRC-ER for the entire test.

The graph results SHOULD display the AAL5 CRC error ratio values.

The x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the AAL5-CRC-ER for each VCC. There should be 12 curves on the

graph, on curve indicated and labeled for each VCC. The

integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.3.3.4. AAL5-CRC-ER/Steady Load/Maximum VCCs

Objective: To determine the SUT ratio of AAL5 CRC PDU errors with the

maximum number VCCs supported on the SUT in a transmission in

relation to the total AAL5 PDU's sent as defined in RFC2761

"Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC's MUST be configured as either a CBR, VBR, or UBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing one of the

specified bit patterns at a constant rate through the SUT via the

defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of AAL5 CRC errors at the receiver end of the

test device for all VCCs.

Reporting Format:

The results of the AAL5-CRC-ER/Steady Load/Maximum VCCs test

SHOULD be reported in a form of text and graph.

The text results SHOULD display the numerical values of the AAL5-

CRC-ER. The values given SHOULD include: time period of test in

s, test VPI/VCI value, total number of AAL5 PDU's transmitted and

received on the given VPI/VCI during the test in positive

integers, and the AAL5-CRC-ER for the entire test.

The graph results SHOULD display the AAL5 CRC error ratio values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the AAL5-CRC-ER for each VCC. There

SHOULD be no more than 10 curves on each graph, one curve

indicated and labeled for each VCC. The integration time per

point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.3.3.5. AAL5-CRC-ER/Bursty VBR Load/One VCC

Objective: To determine the SUT ratio of AAL5 CRC PDU errors on one

VCC in a transmission in relation to the total AAL5 PDU's sent as

defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with one VCC. The VCC SHOULD

contain one VPI/VCI. The VCC MUST be configured as either a CBR

or VBR connection. The VPI/VCI MUST not be one of the reserved

ATM signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and

MBS must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific VBR rate through the SUT via

the defined test VCC. Since this test is not a throughput test,

the rate should not be greater than 90% of line rate. The IP

PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the number of AAL5 CRC errors at the receiver end of the

test device.

Reporting Format:

The results of the AAL5-CRC-ER/Bursty VBR Load/One VCC test SHOULD

be reported in a form of text and graph.

The text results SHOULD display the numerical values of the AAL5-

CRC-ER. The values given SHOULD include: time period of test in

s, test VPI/VCI value, total number of AAL5 PDU's transmitted and

received on the given VPI/VCI during the test in positive

integers, and the AAL5-CRC-ER for the entire test.

The graph results SHOULD display the AAL5 CRC error ratio values.

The x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the AAL5-CRC-ER. The integration time per point MUST be

indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.3.3.6. AAL5-CRC-ER/Bursty VBR Load/Twelve VCCs

Objective: To determine the SUT ratio of AAL5 CRC PDU errors on

twelve VCC's in a transmission in relation to the total AAL5 PDU's

sent as defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCCs, using 1 VPI

and 12 VCIs. The VCC's MUST be configured as either a CBR or VBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and MBS

must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific VBR rate through the SUT via

the defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The PCR, SCR, and MBS must be indicated. The IP PDUs MUST

be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of AAL5 CRC errors at the receiver end of the

test device for all VCCs.

Reporting Format:

The results of the AAL5-CRC-ER/Bursty VBR Load/Twelve VCCs test

SHOULD be reported in a form of text and graph.

The text results SHOULD display the numerical values of the AAL5-

CRC-ER. The values given SHOULD include: time period of test in

s, test VPI/VCI value, total number of AAL5 PDU's transmitted and

received on the given VPI/VCI during the test in positive

integers, and the AAL5-CRC-ER for the entire test.

The graph results SHOULD display the AAL5 CRC error ratio values.

The x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the AAL5-CRC-ER for each VCC. There should be 12 curves on the

graph, on curve indicated and labeled for each VCC. The

integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.3.3.7. AAL5-CRC-ER/Bursty VBR Load/Maximum VCCs

Objective: To determine the SUT ratio of AAL5 CRC PDU errors with the

maximum number VCCs supported on the SUT in a transmission in

relation to the total AAL5 PDU's sent as defined in RFC2761

"Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with the maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. The VCC's MUST be configured as either a CBR or VBR

connection. The VPI/VCIs MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]). The PCR, SCR, and MBS

must be configured using one of the specified traffic

descriptors.

3) Send a specific number of IP packets containing one of the

specified bit patterns at a specific VBR rate through the SUT via

the defined test VCCs. All of the VPI/VCI pairs will generate

traffic at the same traffic rate. Since this test is not a

throughput test, the rate should not be greater than 90% of line

rate. The IP PDUs MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of AAL5 CRC errors at the receiver end of the

test device for all VCCs.

Reporting Format:

The results of the AAL5-CRC-ER/Bursty VBR Load/Maximum VCCs test

SHOULD be reported in a form of text and graph.

The text results SHOULD display the numerical values of the AAL5-

CRC-ER. The values given SHOULD include: time period of test in

s, test VPI/VCI value, total number of AAL5 PDU's transmitted and

received on the given VPI/VCI during the test in positive

integers, and the AAL5-CRC-ER for the entire test.

The graph results SHOULD display the AAL5 CRC error ratio values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the AAL5-CRC-ER for each VCC. There

SHOULD be no more than 10 curves on each graph, one curve

indicated and labeled for each VCC. The integration time per

point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.3.3.8. AAL5-CRC-ER/Mixed Load/Three VCC's

Objective: To determine the SUT ratio of AAL5 CRC PDU errors on three

VCC's in a transmission in relation to the total AAL5 PDU's sent as

defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with three VCC's. Each VCC

MUST be defined as a different Bearer class; one CBR, one UBR and

one VBR. Each VCC SHOULD contain one VPI/VCI. The VPI/VCI MUST

not be one of the reserved ATM signaling channels (e.g., [0,5],

[0,16]).

3) Send a specific number of IP packets containing one of the

specified bit patterns through the SUT via the defined test VCCs.

Each generated VCC stream MUST match the corresponding VCC Bearer

class. All of the VPI/VCI pairs will generate traffic at the

same traffic rate. Since this test is not a throughput test, the

rate should not be greater than 90% of line rate. The IP PDUs

MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT to verify

connectivity and load. If the count on the test device is the

same on the SUT, continue the test; else lower the test device

traffic rate until the counts are the same.

5) Record the number of AAL5 CRC errors at the receiver end of the

test device for all VCCs.

Reporting Format:

The results of the AAL5-CRC-ER/Bursty Mixed Load/Three VCCs test

SHOULD be reported in a form of text and graph.

The text results SHOULD display the numerical values of the AAL5-

CRC-ER. The values given SHOULD include: time period of test in

s, test VPI/VCI value, total number of AAL5 PDU's transmitted and

received on the given VPI/VCI during the test in positive

integers, and the AAL5-CRC-ER for the entire test.

The graph results SHOULD display the AAL5 CRC error ratio values.

The x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the AAL5-CRC-ER for each VCC. There should be 12 curves on the

graph, on curve indicated and labeled for each VCC. The

integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.3.3.9. AAL5-CRC-ER/Mixed Load/Twelve VCCs

Objective: To determine the SUT ratio of AAL5 CRC PDU errors on

twelve VCC's in a transmission in relation to the total AAL5 PDU's

sent as defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with twelve VCC's. Each VCC

MUST be defined as one of the Bearer classes for a total of four

CBR, four UBR and four VBR VCC's. Each VCC SHOULD contain one

VPI/VCI. The VPI/VCI MUST not be one of the reserved ATM

signaling channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing one of the

specified bit patterns through the SUT via the defined test VCCs.

Each generated VCC stream MUST match the corresponding VCC Bearer

class. All of the VPI/VCI pairs will generate traffic at the

same traffic rate. Since this test is not a throughput test, the

rate should not be greater than 90% of line rate. The IP PDUs

MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of AAL5 CRC errors at the receiver end of the

test device for all VCCs.

Reporting Format:

The results of the AAL5-CRC-ER/Bursty Mixed Load/Twelve VCCs test

SHOULD be reported in a form of text and graph.

The text results SHOULD display the numerical values of the AAL5-

CRC-ER. The values given SHOULD include: time period of test in

s, test VPI/VCI value, total number of AAL5 PDU's transmitted and

received on the given VPI/VCI during the test in positive

integers, and the AAL5-CRC-ER for the entire test.

The graph results SHOULD display the AAL5 CRC error ratio values.

The x-coordinate SHOULD be the test run time in either seconds,

minutes or days depending on the total length of the test. The

x-coordinate time SHOULD be configurable. The y-coordinate SHOULD

be the AAL5-CRC-ER for each VCC. There should be 12 curves on the

graph, on curve indicated and labeled for each VCC. The

integration time per point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.3.3.10. AAL5-CRC-ER/Mixed Load/Maximum VCCs

Objective: To determine the SUT ratio of AAL5 CRC PDU errors with the

maximum number VCCs supported on the SUT in a transmission in

relation to the total AAL5 PDU's sent as defined in RFC2761

"Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Configure the SUT and test device with maximum number of VCCs

supported on the SUT. For example, if the maximum number of VCCs

supported on the SUT is 1024, define 256 VPIs with 4 VCIs per

VPI. Each VCC MUST be defined as one of the Bearer classes for a

total of (max VCC/3) CBR, (max VCC/3) UBR and (max VCC/3) VBR

VCC's. The VPI/VCI MUST not be one of the reserved ATM signaling

channels (e.g., [0,5], [0,16]).

3) Send a specific number of IP packets containing one of the

specified bit patterns through the SUT via the defined test VCCs.

Each generated VCC stream MUST match the corresponding VCC Bearer

class. All of the VPI/VCI pairs will generate traffic at the

same traffic rate. Since this test is not a throughput test, the

rate should not be greater than 90% of line rate. The IP PDUs

MUST be encapsulated in AAL5.

4) Count the IP packets that are transmitted by the SUT on all VCCs

to verify connectivity and load. If the count on the test device

is the same on the SUT, continue the test; else lower the test

device traffic rate until the counts are the same.

5) Record the number of AAL5 CRC errors at the receiver end of the

test device for all VCCs.

Reporting Format:

The results of the AAL5-CRC-ER/Bursty Mixed Load/Maximum VCCs test

SHOULD be reported in a form of text and graph.

The text results SHOULD display the numerical values of the AAL5-

CRC-ER. The values given SHOULD include: time period of test in

s, test VPI/VCI value, total number of AAL5 PDU's transmitted and

received on the given VPI/VCI during the test in positive

integers, and the AAL5-CRC-ER for the entire test.

The graph results SHOULD display the AAL5 CRC error ratio values.

There will be (Max number of VCCs/10) graphs, with 10 VCCs

indicated on each graph. The x-coordinate SHOULD be the test run

time in either seconds, minutes or days depending on the total

length of the test. The x-coordinate time SHOULD be configurable.

The y-coordinate SHOULD be the AAL5-CRC-ER for each VCC. There

SHOULD be no more than 10 curves on each graph, one curve

indicated and labeled for each VCC. The integration time per

point MUST be indicated.

The results MUST also indicate the packet size in octets, traffic

rate in packets per second, and bearer class as generated by the

test device. The VCC and VPI/VCI values MUST be indicated. The

PCR, SCR, and MBS MUST be indicated. The bearer class of the

created VCC MUST be indicated. The generated bit pattern MUST

also be indicated.

3.4. ATM Service: Signaling

3.4.1. CAC Denial Time and Connection Establishment Time

Objective: To determine the CAC rejection time and Connection

Establishment Time on the SUT as defined in RFC2761 "Terminology for

ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Create a UNI signaling setup message, as described in Appendix C,

specifying a PCR which will not allow CAC to reject the call.

3) Send the UNI signaling setup message. Note the time the setup

message was sent. Verify that the SVC has been setup with the

correct parameters. Note the time the connect message was

received

4) Create a UNI signaling setup message, as described in Appendix C,

specifying a PCR which will allow CAC to reject the call.

5) Send the UNI signaling setup message. Note the time the setup

message was sent. Verify that the SVC has been rejected with the

correct cause code. Note the time the release complete message

was received.

6) Compute the rejection time as the difference between the time the

release complete message was received and the time setup message

was send.

Reporting Format:

The results of the CAC Denial Time and Connection Establishment

Time tests SHOULD be reported in a form of a table. The rows

SHOULD be labeled call accepted and call rejected. The columns

SHOULD be labeled time setup sent, time response received, and

correct response. The elements of the columns 1 and 2 SHOULD be

in seconds. The elements of column 3 SHOULD be be either True or

False, indicating whether the particular condition was observed

for each test.

The table MUST also indicate the packet size in octets and traffic

rate in packets per second as generated by the test device.

3.4.2. Connection Teardown Time

Objective: To determine the Connection Teardown Time on the SUT as

defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Create a UNI signaling setup message, as described in Appendix C,

specifying a PCR which will not allow CAC to reject the call.

3) Send the UNI signaling setup message. Note the time the setup

message was sent. Verify that the SVC has been setup with the

correct parameters. Note the time the connect message was

received

4) Create a UNI signaling release message, as described in Appendix

C, specifying a cause code of normal call clearing.

5) Send the UNI signaling release message. Note the time the

release message was sent. Verify that the SVC has been

terminated with the correct cause code. Note the time the

release complete message was received.

6) Compute the release time as the difference between the time the

release complete message was received and the time release

message was send.

Reporting Format:

The results of the Connection Teardown Time tests SHOULD be

reported in a form of a table. The rows SHOULD be labeled call

accepted and call released. The columns SHOULD be labeled time

message sent, time response received, and correct response. The

elements of the columns 1 and 2 SHOULD be in seconds. The

elements of column 3 SHOULD be be either True or False, indicating

whether the particular condition was observed for each test.

The table MUST also indicate the packet size in octets and traffic

rate in packets per second as generated by the test device.

3.4.3. Crankback Time

Objective: To determine the Crankback Time on the SUT as defined in

RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the uni-directional

passthrough configuration.

2) Create a PNNI signaling setup message, as described in Appendix

C, specifying a DTL which is not blocked by the far end SUT.

3) Send the PNNI signaling setup message. Note the time the setup

message was sent. Verify that the connect message has been

received by the near-end switch. Note the time the connect

message was received

4) Create a PNNI signaling setup message, as described in Appendix

C, specifying a DTL which is blocked by the far end SUT.

5) Send the PNNI signaling release message. Note the time the

release message was sent. Note the time the release complete

message was received. Note the time the near-end switch sends

it's own PNNI setup message (referred to as the near-end setup

message) specifying the non- blocked DTL.

6) Compute the crankback time as the difference between the time the

near-end setup message was received and the time release message

was send.

Reporting Format:

The results of the Crankback Time tests SHOULD be reported in a

form of a table. The rows SHOULD be labeled DTL call accepted and

call released. The columns SHOULD be labeled time message sent,

time response received, and correct response. The elements of the

columns 1 and 2 SHOULD be in seconds. The elements of column 3

SHOULD be be either True or False, indicating whether the

particular condition was observed for each test.

The table MUST also indicate the packet size in octets and traffic

rate in packets per second as generated by the test device.

3.4.4. Route Update Response Time

Objective: To determine the Route Update Response Time on the SUT as

defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the uni-directional

passthrough configuration.

2) Create a PNNI PTSE as described in Appendix C, specifying a

routing topology. Verify that the routing tables on the far-end

and near-end switches are empty.

3) Send the PTSE message to the far-end switch. Note the time the

PTSE message was sent. Verify that the PTSE message has been

received by the far-end switch. Note the time the PTSE message

was received.

4) Create another PNNI PTSE as described in Appendix C, specifying a

change in the routing topology. Verify that the routing tables

on the far-end and near-end switches contain the previous PTSE

routes.

5) Send the PTSE message to the far-end switch. Note the time the

PTSE message was sent. Verify that the PTSE message has been

received by the far-end switch. Note the time the PTSE message

was received. Note the time the PTSE was sent to the near-end

switch. Note the time the PTSE message was received on the

near-end switch.

6) Compute the Route Update Response time as the difference between

the time the far-end PTSE message was sent and the time far-end

PTSE message was received by the near-end.

Reporting Format:

The results of the Route Update Response Time tests SHOULD be

reported in a form of a table. The rows SHOULD be labeled PTSE

call accepted, far-end PTSE message send, and near-end message

received. The columns SHOULD be labeled time message sent, time

response received, and correct response. The elements of the

columns 1 and 2 SHOULD be in seconds. The elements of column 3

SHOULD be be either True or False, indicating whether the

particular condition was observed for each test.

The table MUST also indicate the packet size in octets and traffic

rate in packets per second as generated by the test device.

3.5. ATM Service: ILMI

3.5.1. MIB Alignment Time

Objective: To determine the MIB Alignment Time on the SUT as defined

in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Send a Cold Start message to the SUT. Note the time the message

was sent to the SUT. Verify that the Cold Start message has been

received by the SUT. Note the time the message was received.

3) Send a Get Request message to the SUT. Note the time the message

was sent to the SUT. Verify that the Get Request message has

been received by the SUT. Note the time the message was

received.

4) After all MIB elements are exchanged, verify that the final Get

Request message has been received by the SUT. Note the time the

message was send and received by the SUT.

5) Compute the MIB Alignment Time as the difference between the time

the Cold Start message was sent and the time the final Get

Request was received by the SUT.

Reporting Format:

The results of the MIB Alignment Time tests SHOULD be reported in

a form of a table. The rows SHOULD be labeled Cold Start Send,

Cold Start accepted, Final Get Request send, and Final Get Request

received. The columns SHOULD be labeled time message sent, time

response received, and correct response. The elements of the

columns 1 and 2 SHOULD be in seconds. The elements of column 3

SHOULD be be either True or False, indicating whether the

particular condition was observed for each test.

The table MUST also indicate the packet size in octets and traffic

rate in packets per second as generated by the test device.

3.5.2. Address Registration Time

Objective: To determine the Address Registration Time on the SUT as

defined in RFC2761 "Terminology for ATM Benchmarking".

Procedure:

1) Set up the SUT and test device using the bi-directional

configuration.

2) Send a Set Request message to the SUT. Note the time the message

was sent to the SUT. Verify that the Set Request message has

been received by the SUT. Note the time the message was

received.

3) Send a Get Request message to the SUT. Note the time the message

was sent to the SUT. Verify that the Get Request message has

been received by the SUT. Note the time the message was

received.

4) After all MIB elements are exchanged, verify that the final Get

Request message has been received by the SUT. Note the time the

message was send and received by the SUT.

5) Compute the Address Registration Time as the difference between

the time the Set Request message was sent and the time the final

Get Request was received by the SUT.

Reporting Format:

The results of the Address Registration Time tests SHOULD be

reported in a form of a table. The rows SHOULD be labeled Set

Request Send, Set Request accepted, Final Get Request send, and

Final Get Request received. The columns SHOULD be labeled time

message sent, time response received, and correct response. The

elements of the columns 1 and 2 SHOULD be in seconds. The

elements of column 3 SHOULD be be either True or False, indicating

whether the particular condition was observed for each test.

The table MUST also indicate the packet size in octets and traffic

rate in packets per second as generated by the test device.

4. Security Considerations

As this document is solely for the purpose of providing methodology

and describes neither a protocol nor an implementation, there are no

security considerations associated with this document.

5. Notices

The IETF takes no position regarding the validity or scope of any

intellectual property or other rights that might be claimed to

pertain to the implementation or use of the technology described in

this document or the extent to which any license under such rights

might or might not be available; neither does it represent that it

has made any effort to identify any such rights. Information on the

IETFs procedures with respect to rights in standards-track and

standards-related documentation can be found in BCP-11. Copies of

claims of rights made available for publication and any assurances of

licenses to be made available, or the result of an attempt made to

oBTain a general license or permission for the use of such

proprietary rights by implementors or users of this specification can

be obtained from the IETF Secretariat.

The IETF invites any interested party to bring to its attention any

copyrights, patents or patent applications, or other proprietary

rights which may cover technology that may be required to practice

this standard. Please address the information to the IETF Executive

Director.

6. References

[RFC2544] Bradner, S. and J. McQuaid, "Benchmarking Methodology

for Network Interconnect Devices", RFC2544, March

1999.

[RFC2225] Laubach, M. and J. Halpern, "Classical IP and ARP over

ATM", RFC2225, April 1998.

[RFC2761] Dunn, J. and C. Martin, "Terminology for ATM

Benchmarking", RFC2761, February 2000.

[AF-ILMI4.0] ATM Forum Integrated Local Management Interface

Version 4.0, af-ilmi-0065.000, September 1996.

[AF-TEST-0022] Introduction to ATM Forum Test Specifications, af-

test-0022.00, December 1994.

[AF-TM4.1] ATM Forum, Traffic Management Specification Version

4.1, af-tm-0121.00, April 1996.

[AF-UNI3.1] ATM Forum, User Network Interface Specification

Version 3.1, September 1994.

[AF-UNI4.0] ATM Forum, User Network Interface Specification

Version 4.0, July 1996.

7. Authors' Addresses

Jeffrey Dunn

Advanced Network Consultants, Inc.

4214 Crest Place

Ellicott City, MD 21043, USA

Phone: +1 (410) 750-1700

EMail: Jeffrey.Dunn@worldnet.att.net

Cynthia Martin

Advanced Network Consultants, Inc.

4214 Crest Place

Ellicott City, MD 21043, USA

Phone: +1 (410) 750-1700

EMail: Cynthia.E.Martin@worldnet.att.net

Appendix A: Ranges

ATM NSAP Network Prefix.

39 0000 0000 0000 0000 0000 0000-39 0000 0000 0000 0000 0000 00FF

39 0000 0000 0000 0000 0001 0000-39 0000 0000 0000 0000 0001 00FF

39 0000 0000 0000 0001 0000 0000

39 0000 0000 0000 0002 0020 0000

39 0000 0000 0300 0002 0030 0000

39 0000 0000 4000 0002 0060 0000

39 0000 0006 0060 0002 0030 0000

39 0000 0006 0050 0002 0030 0000

39 0000 0009 0300 0002 0030 0000

39 0000 00A0 0300 0002 0030 0000

39 0000 0B00 0300 0002 0030 0000

39 0000 C000 0300 0002 0030 0000

ATM NSAP End System Identifier.

1111 1111 1111 00-1111 1111 11FF 00

2222 2222 2000 00-2222 2222 2222 00

9999 999A 0000 00-9999 999C 0000 00

Appendix B: Rates

PNNI Routing Update Size.

1) 1 PNNI routing entry update on non-aggregated addresses

2) 2 PNNI routing entry updates on non-aggregated addresses

3) 5 PNNI routing entry updates on non-aggregated addresses

4) 1 % of total available bandwidth or 1 Mb/s, whichever is less on

non- aggregated addresses

5) 1 % of total available bandwidth or 1 Mb/s, whichever is less on

of non-aggregated addresses and of aggregated addresses

6) 1 % of total available bandwidth or 1 Mb/s, whichever is less on

aggregated addresses

7) 2 % of total available bandwidth or 2 Mb/s, whichever is less on

non- aggregated addresses

8) 2 % of total available bandwidth or 2 Mb/s, whichever is less on

of non-aggregated addresses and of aggregated addresses

9) 2 % of total available bandwidth or 2 Mb/s, whichever is less on

aggregated addresses

PNNI Routing Update Repetition Interval.

Repetition Interval begins after initial PNNI routing table

stabilizes.

1) 1 update every 1 hour, for 24 hours

2) 1 update every 30 minutes, for 24 hours

3) 1 update every 5 minutes, for 1 hour

4) 1 update every 1 minute, for 15 minutes

5) 1 update every 30 seconds, for 5 minutes

6) 1 update every 30 seconds, for 1 minute

7) 1 update every 1 second, for 30 seconds

Maximum WAN Connection rates in packets per second (pps):

25.6 OC-3c OC-12c

IP Packet Size

octets/cells

44/2 30188 176603 706412

64/2 30188 176603 706412

128/3 20125 117735 470940

256/6 10062 58867 235468

1024/22 2744 16054 64216

1518/32 1886 11037 44148

2048/43 1404 8214 32856

4472/94 642 3757 15028

9180/192 314 1839 7356

Maximum LAN Connection rates in packets per second (pps):

DS-1 DS-3 E1 E3

IP Packet Size

octets/cells

44/2 1811 52133 2340 40000

64/2 1811 52133 2340 40000

128/3 1207 34755 1560 26666

256/6 603 17377 780 13333

1024/22 164 4739 212 3636

1518/32 113 3258 146 2500

2048/43 84 2424 108 1860

4472/94 38 1109 49 851

9180/192 18 543 24 416

Notes: 1. PDU size in cells is computed based on ceiling( ( PDU size

in octets + 16) / 48). This assumes an 8 octet LLC/SNAP header and

an 8 octet AAL/5 trailer.

2. Due to the number of possible configurations, IMA pps rates are

not listed, but may be derived from the following formula: floor

(IDCR/cells per packet), where cells per packet is computed as in

note 1.

3. The following cell rates were used: DS-1 = 3622 cps (using ATM TC)

E1 = 4681 cps 25.6 Mb/s = 60377 cps E3 = 80000 cps (using ATM TC)

DS-3 = 104266 cps (using ATM TC) OC-3c = 353207 cps OC-12c = 1412828

cps

Appendix C: PDU's

TCP/IP over ATM Example 1.

LLC: DSAP 0xAA (SNAP-SAP)

SSAP 0xAA (SNAP-SAP)

Control 0x03 (Unnumbered Information)

SNAP: OUI 0x00-00-00 (Ethertype)

PID 0x0800 (Internet Protocol)

IP: Version = 4

Header length = 20

Type of service = 0

000. .... Precedence = Routine(0)

...0 .... Delay = Normal (0)

.... 0... Throughput = Normal (0)

.... .0.. Reliability = Normal (0)

Packet length = 40

Id = 0

Fragmentation Info = 0x0000

.0.. .... .... .... Don't Fragment Bit = FALSE

..0. .... .... .... More Fragments Bit = FALSE

...0 0000 0000 0000 Fragment offset = 0

Time to live = 255

Protocol = TCP (6)

Header checksum = F9CF

Source address = 15.19.209.236

Destination address = 15.19.209.237

TCP: Source port = smtp (25)

Destination port = smtp (25)

Sequence number = 1

Ack number = 0

Data offset = 20

Flags = 0x02

..0. .... URGENT Flag = FALSE

...0 .... ACK Flag = FALSE

.... 0... PUSH Flag = FALSE

.... .0.. RST Flag = FALSE

.... ..1. SYN Flag = TRUE

.... ...0 FIN Flag = FALSE

Window = 0

Checksum = EDAF

Urgent pointer = 00000000

TCP/IP over ATM Example 2.

LLC: DSAP 0xAA (SNAP-SAP)

SSAP 0xAA (SNAP-SAP)

Control 0x03 (Unnumbered Information)

SNAP: OUI 0x00-00-00 (Ethertype)

PID 0x0800 (Internet Protocol)

IP: Version = 4

Header length = 20

Type of service = 0

000. .... Precedence = Routine(0)

...0 .... Delay = Normal (0)

.... 0... Throughput = Normal (0)

.... .0.. Reliability = Normal (0)

Packet length = 40

Id = 0

Fragmentation Info = 0x0000

.0.. .... .... .... Don't Fragment Bit = FALSE

..0. .... .... .... More Fragments Bit = FALSE

...0 0000 0000 0000 Fragment offset = 0

Time to live = 255

Protocol = TCP (6)

Header checksum = F9CF

Source address = 15.19.209.236

Destination address = 15.19.209.237

TCP: Source port = FTP-data (20)

Destination port = 2000

Sequence number = 1

Ack number = 0

Data offset = 20

Flags = 0x02

..0. .... URGENT Flag = FALSE

...0 .... ACK Flag = FALSE

.... 0... PUSH Flag = FALSE

.... .0.. RST Flag = FALSE

.... ..1. SYN Flag = TRUE

.... ...0 FIN Flag = FALSE

Window = 0

Checksum = E5FD

Urgent pointer = 00000000

UDP/IP over ATM Example.

LLC: DSAP 0xAA (SNAP-SAP)

SSAP 0xAA (SNAP-SAP)

Control 0x03 (Unnumbered Information)

SNAP: OUI 0x00-00-00 (Ethertype)

PID 0x0800 (Internet Protocol)

IP: Version = 4

Header length = 20

Type of service = 0

000. .... Precedence = Routine(0)

...0 .... Delay = Normal (0)

.... 0... Throughput = Normal (0)

.... .0.. Reliability = Normal (0)

Packet length = 28

Id = 0

Fragmentation Info = 0x0000

.0.. .... .... .... Don't Fragment Bit = FALSE

..0. .... .... .... More Fragments Bit = FALSE

...0 0000 0000 0000 Fragment offset = 0

Time to live = 255

Protocol = ICMP (1)

Header checksum = F9E0

Source address = 15.19.209.236

Destination address = 15.19.209.237

ICMP: Type = Echo request (8)

Code = 0

Checksum = F7FF

Identifier = 0 (0x0)

Sequence Number = 0 (0x0)

RIP Routing Update over ATM.

-- DATAGRAM HEADER

offset data (hex) description

00 FF FF FF FF FF FF dest MAC address is broadcast

06 xx xx xx xx xx xx source hardware address

12 08 00 type

-- IP HEADER

14 45 IP version - 4, header length (4

byte units) - 5

15 00 service field

16 00 EE total length

18 00 00 ID

20 40 00 flags (3 bits) 4 (do not

fragment),

fragment offset-0

22 0A TTL

23 11 protocol - 17 (UDP)

24 C4 8D header checksum

26 xx xx xx xx source IP address

30 xx xx xx destination IP address

33 FF host part = FF for broadcast

-- UDP HEADER

34 02 08 source port 208 = RIP

36 02 08 destination port 208 = RIP

38 00 DA UDP message length

40 00 00 UDP checksum

-- RIP packet

42 02 command = response

43 01 version = 1

44 00 00 0

-- net 1

46 00 02 family = IP

48 00 00 0

50 xx xx xx net 1 IP address

53 00 net not node

54 00 00 00 00 0

58 00 00 00 00 0

62 00 00 00 07 metric 7

-- net 2

66 00 02 family = IP

68 00 00 0

70 xx xx xx net 2 IP address

73 00 net not node

74 00 00 00 00 0

78 00 00 00 00 0

82 00 00 00 07 metric 7

-- net 3

86 00 02 family = IP

88 00 00 0

90 xx xx xx net 3 IP address

93 00 net not node

94 00 00 00 00 0

98 00 00 00 00 0

102 00 00 00 07 metric 7

-- net 4

106 00 02 family = IP

108 00 00 0

110 xx xx xx net 4 IP address

113 00 net not node

114 00 00 00 00 0

118 00 00 00 00 0

122 00 00 00 07 metric 7

-- net 5

126 00 02 family = IP

128 00 00 0

130 00 net 5 IP address

133 00 net not node

134 00 00 00 00 0

138 00 00 00 00 0

142 00 00 00 07 metric 7

-- net 6

146 00 02 family = IP

148 00 00 0

150 xx xx xx net 6 IP address

153 00 net not node

154 00 00 00 00 0

158 00 00 00 00 0

162 00 00 00 07 metric 7

UNI 3.1 Signaling Setup Message Example. PCR will not allow CAC to

reject the call.

Protocol Discriminator : Q.93B UNI call control

Call Reference Length : 3

Call Reference Flag : orig

Call Reference Value : 0

Message Type : SETUP

Ext : last octet

Action Indicator : clear call

Message Length : 50

Information Element ID : ATM Traffic Descriptor

Ext : last octet

Coding Standard : ITU-T standard

Action Indicator : clear call

IE Length : 9

Cell Rate Subfield ID : forward peak CR(CLP=0+1)

Forward Peak Cell Rate : 1

Cell Rate Subfield ID : backward peak CR(CLP=0+1)

Backward Peak Cell Rate : 1

Cell Rate Subfield ID : best effort indicator

Information Element ID : Broadband Bearer Capability

Ext : last octet

Coding Standard : ITU-T standard

Action Indicator : clear call

IE Length : 2

Ext : last octet

Bearer Class : BCOB-X

Ext : last octet

Clipping Susceptibility : not susceptible to clipping

User Plane Connection CFG : point-to-point

Information Element ID : Called Party Number

Ext : last octet

Coding Standard : ITU-T standard

Action Indicator : clear call

IE Length : 21

Ext : last octet

Addressing/Numbering Plan : ISO NSAP addressing

ISO NSAP Address Octets : 3900000000000000000000000011111111111100

Information Element ID : Quality of Service Parameter

Ext : last octet

Coding Standard : ITU-T standard

Action Indicator : clear call

IE Length : 2

QoS Class Forward : QoS class 0 - unspecified

QoS Class Backward : QoS class 0 - unspecified

UNI 3.1 Signaling Setup Message Reject Example. PCR will allow

CAC to reject the call.

Protocol Discriminator : Q.93B UNI call control

Call Reference Length : 3

Call Reference Flag : orig

Call Reference Value : 0

Message Type : SETUP

Ext : last octet

Action Indicator : clear call

Message Length : 50

Information Element ID : ATM Traffic Descriptor

Ext : last octet

Coding Standard : ITU-T standard

Action Indicator : clear call

IE Length : 8

Cell Rate Subfield ID : forward peak CR(CLP=0+1)

Forward Peak Cell Rate : 300000

Cell Rate Subfield ID : backward peak CR(CLP=0+1)

Backward Peak Cell Rate : 300000

Information Element ID : Broadband Bearer Capability

Ext : last octet

Coding Standard : ITU-T standard

Flag : not significant

Action Indicator : clear call

IE Length : 3

Ext : another octet

Bearer Class : BCOB-X

Ext : last octet

Traffic Type : constant bit rate

Timing Requirements : end-to-end timing required

Ext : last octet

Clipping Susceptibility : not susceptible to clipping

User Plane Connection CFG : point-to-point

Information Element ID : Called Party Number

Ext : last octet

Coding Standard : ITU-T standard

Action Indicator : clear call

IE Length : 21

Ext : last octet

Addressing/Numbering Plan : ISO NSAP addressing

ISO NSAP Address Octets : 3900000000000000000000000011111111111100

Information Element ID : Quality of Service Parameter

Ext : last octet

Coding Standard : ITU-T standard

Action Indicator : clear call

IE Length : 2

QoS Class Forward : QoS class 0 - unspecified

QoS Class Backward : QoS class 0 - unspecified

UNI 3.1 Signaling Release Message, specifying a cause code of normal

call clearing.

Protocol Discriminator : Q.93B UNI call control

Call Reference Length : 3

Call Reference Flag : orig

Call Reference Value : 0

Message Type : RELEASE

Ext : last octet

Action Indicator : clear call

Message Length : 6

Information Element ID : Cause

Ext : last octet

Coding Standard : ITU-T standard

Action Indicator : clear call

IE Length : 2

Ext : last octet

Location : user

Ext : last octet

Cause Value : NE:normal call clearing

PNNI Signaling Setup Message, specifying a DTL which is not blocked

by the far end SUT.

Protocol Discriminator : PNNI signalling

Call Reference Length : 3

Call Reference Flag : from

Message Type : SETUP

Ext : last octet

Pass Along Request : no pass along request

Action Indicator : clear call

Message Length : 56

Information Element ID : ATM Traffic Descriptor

Ext : last octet

Coding Standard : ITU-T standardized

Pass Along Request : no pass along request

Action Indicator : clear call

IE Length : 0

Information Element ID : Broadband Bearer Capability

Ext : last octet

Coding Standard : ITU-T standardized

Pass Along Request : no pass along request

Action Indicator : clear call

IE Length : 3

Ext : another octet

Bearer Class : BCOB-X

Ext : last octet

ATM Transfer Capability : reserved for bwd compatibility

Ext : last octet

Clipping Susceptibility : not susceptible to clipping

User Plane Connection cfg : point-to-point

Information Element ID : Called Party Number

Ext : last octet

Coding Standard : ITU-T standardized

Pass Along Request : no pass along request

Action Indicator : clear call

IE Length : 8

Ext : last octet

Type of Number : unknown

Addressing/Numbering Plan : ATM endsystem address

ATM Endsystem Address Oct : 11111111111101

Information Element ID : Designated Transit List

Ext : last octet

Coding Standard : ATM Forum specific

Pass Along Request : no pass along request

Action Indicator : clear call

IE Length : 29

Current Transit Pointer : 0

Logical Node/Port Indicat : Logical Node/Port Indicator

Logical Node Identifier : 3900000000000000000000000011111111111100

PNNI Signaling Setup Message Reject, specifying a DTL which is

blocked by the far end SUT.

Protocol Discriminator : PNNI signalling

Call Reference Length : 3

Call Reference Flag : from

Call Reference Value : 0

Message Type : SETUP

Ext : last octet

Pass Along Request : no pass along request

Action Indicator : clear call

Message Length : 56

Information Element ID : ATM Traffic Descriptor

Ext : last octet

Coding Standard : ITU-T standardized

Pass Along Request : no pass along request

Action Indicator : clear call

IE Length : 0

Information Element ID : Broadband Bearer Capability

Ext : last octet

Coding Standard : ITU-T standardized

Pass Along Request : no pass along request

Action Indicator : clear call

IE Length : 3

Bearer Class : BCOB-X

Ext : last octet

ATM Transfer Capability : reserved for bwd compatibility

Ext : last octet

Clipping Susceptibility : not susceptible to clipping

User Plane Connection cfg : point-to-point

Information Element ID : Called Party Number

Ext : last octet

Coding Standard : ITU-T standardized

Pass Along Request : no pass along request

Action Indicator : clear call

IE Length : 8

Ext : last octet

Addressing/Numbering Plan : ATM endsystem address

ATM Endsystem Address Oct : 11111111111101

Information Element ID : Designated Transit List

Ext : last octet

Coding Standard : ATM Forum specific

Pass Along Request : no pass along request

Action Indicator : clear call

IE Length : 29

Current Transit Pointer : 0

Logical Node/Port Indicat : Logical Node/Port Indicator

Logical Node Identifier : 3900000000000000000000000011111111111100

PNNI Far End Request Message.

Header: Packet Type 5 (PTSE REQUEST)

Packet Length 40

Protocol Version 1

Newest Version Supported 1

Oldest Version Supported 0

Reserved 0

IG: Information Group Type 513 (Requested PTSE Header)

Information Group Length 32

Originating Node ID

00013900-00000000-00000000-00000011-11111111-1100

PTSE Request Count 1

PTSE Identifier 0

PNNI PTSE, specifying a routing topology.

Header: Packet Type 4 (DATABASE SUMMARY)

Packet Length 76

Protocol Version 1

Newest Version Supported 1

Oldest Version Supported 0

Reserved 0

Initialize (I)Bit 1 (during init. of DB syn

process)

More (M)Bit 1 (PTSEs to summarize)

Master (MS)Bit 1 (both nodes)

Reserved 0

Reserved 0

DS Sequence Number 0

IG: Information Group Type 512 (Nodal PTSE Summaries)

Information Group Length 60

Originating Node ID

00013900-00000000-00000000-00000011-11111111-1100

Originating Node's Peer Group 00000000-00000000-00000000-

0001

Reserved 0

PTSE Summary Count 1

PTSE Type 0

Reserved 0

PTSE Identifier 0

PTSE Sequence Number 0

PTSE Checksum 0

PTSE Remaining Lifetime 0

PNNI PTSE Update, specifying a change in the routing topology.

Header: Packet Type 2 (PTSP)

Packet Length 96

Protocol Version 1

Newest Version Supported 1

Oldest Version Supported 0

Reserved 0

Originating Node ID

00013900-00000000-00000000-00000011-11111111-1100

Originating Node's Peer Group 00000000-00000000-00000000-

0001

IG: Information Group Type 64 (PTSE)

Information Group Length 52

PTSE Type 0

Reserved 0

PTSE Identifier 0

PTSE Sequence Number 0

PTSE Checksum 42252

PTSE Remaining Lifetime 3600

IG: Information Group Type 224 (Internal Reachable ATM

Addresses)

Information Group Length 32

VP Capability Flag 1 (VPCs supported)

Reserved 0

Reserved 0

Port ID 0

Scope of Advertisement 96

Address Information Length 14

Address Information Count 1

Prefix Length 13

Reachable Address Prefix 39000000-00000000-00000000-01

Full Copyright Statement

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This document and translations of it may be copied and furnished to

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or assist in its implementation may be prepared, copied, published

and distributed, in whole or in part, without restriction of any

kind, provided that the above copyright notice and this paragraph are

included on all such copies and derivative works. However, this

document itself may not be modified in any way, such as by removing

the copyright notice or references to the Internet Society or other

Internet organizations, except as needed for the purpose of

developing Internet standards in which case the procedures for

copyrights defined in the Internet Standards process must be

followed, or as required to translate it into languages other than

English.

The limited permissions granted above are perpetual and will not be

revoked by the Internet Society or its successors or assigns.

This document and the information contained herein is provided on an

"AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING

TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING

BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION

HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF

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