IMPORT R:\\ART\\WMF\\ITU.WMF \* mergeformat INTERNATIONAL TELECOMMUNICATION UNION CCITT I.327 THE INTERNATIONAL TELEGRAPH AND TELEPHONE CONSULTATIVE COMMITTEE INTEGRATED SERVICES DIGITAL NETWORK (ISDN) OVERALL NETWORK ASPECTS AND FUNCTIONS, ISDN USER-NETWORK INTERFACES B-ISDN FUNCTIONAL ARCHITECTURE Recommendation I.327 IMPORT R:\\ART\\WMF\\CCITTRUF.WMF \* mergeformat Geneva, 1991 Printed in Switzerland FOREWORD The CCITT (the International Telegraph and Telephone Consultative Committee) is the permanent organ of the International Telecommunication Union (ITU). CCITT is responsible for studying technical, operating and tar- iff questions and issuing Recommendations on them with a view to standard- izing telecommunications on a worldwide basis. The Plenary Assembly of CCITT which meets every four years, establishes the topics for study and approves Recommendations prepared by its Study Groups. The approval of Recommendations by the members of CCITT between Plenary Assemblies is covered by the procedure laid down in CCITT Resolution No. 2 (Melbourne, 1988). Recommendation I.327 was prepared by Study Group XVIII and was approved under the Resolution No. 2 procedure on the 5th of April 1991. ___________________ CCITT NOTES 1) In this Recommendation, the expression _Administration_ is used for con- ciseness to indicate both a telecommunication Administration and a recog- nized private operating agency. 2) A list of abbreviations used in this Recommendation can be found in Annex B. ãITU1991 All rights reserved. No part of this publication may be reproduced or utilized in any form or by any means, electronic or mechanical, including photocopy- ing and microfilm, without permission in writing from the ITU. Preamble to B-ISDN Recommendations In 1990, CCITT SG XVIII approved a first set of Recommendations on B-ISDN. These are: I.113 ù Vocabulary of terms for broadband aspects of ISDN I.121 ù Broadband aspects of ISDN I.150 ù B-ISDN asynchronous transfer mode functional characteristics I.211 ù B-ISDN service aspects I.311 ù B-ISDN general network aspects I.321 ù B-ISDN Protocol Reference Model and its application I.327 ù B-ISDN functional architecture I.361 ù B-ISDN ATM Layer specification I.362 ù B-ISDN ATM Adaptation Layer (AAL) functional description I.363 ù B-ISDN ATM Adaptation Layer (AAL) specification I.413 ù B-ISDN user-network interface I.432 ù B-ISDN user-network interface ù Physical Layer specification I.610 ù Operation and maintenance principles of B-ISDN access These Recommendations address general B-ISDN aspects as well as specific service- and network-oriented issues, the fundamental characteris- tics of the asynchronous transfer mode (ATM), a first set of relevant ATM oriented parameters and their application at the user-network interface as well as impact on operation and maintenance of the B-ISDN access. They are an integral part of the well established I-Series Recommendations. The set of Recommendations are intended to serve as a consolidated basis for ongoing work relative to B-ISDN both within CCITT and in other organizations. They may also be used as a first basis towards the development of network elements. CCITT will continue to further develop and complete these Recom- mendations in areas where there are unresolved issues and develop addi- tional Recommendations on B-ISDN in the I-Series and other series in the future. PAGE BLANCHE Recommendation I.327 Recommendation I.327 B-ISDN FUNCTIONAL ARCHITECTURE 1 Introduction The general functional architecture model for the ISDN is described in RecommendationI.324. The concepts and associated definitions adopted in RecommendationI.324 also apply to the B-ISDN, i.e.reference configura- tions, functional group, reference points. The objective of this Recommendation is to provide a basic functional archi- tecture of the B-ISDN to complement RecommendationI.324. The model is not intended to require or exclude any specific implementation of the B- ISDN but to provide a guide for the specification of B-ISDN capabilities. Recommendation I.310 describes the functions of an ISDN. These functions are by their nature static (i.e.time-independent). The relative dis- tribution and allocation of these functions is the subject of the architecture of the ISDN and is described in this Recommendation. The dynamic aspects of these functions are modelled in RecommendationI.310 as executive pro- cesses. Therefore, the key components in this architecture model are: the functions which are contained in the B-ISDN, where they are located and the relative topology for their distribution in the B-ISDN. 2 General architecture of the B-ISDN In B-ISDN implementations some of the B-ISDN functions will be imple- mented within the same network elements, whereas other specific B-ISDN functions will be dedicated to specialized network elements. Various differ- ent B-ISDN implementations are likely to be realized depending on national conditions. A basic component of the B-ISDN is a network for asynchronous transfer mode (ATM) switching of both constant bit rate (CBR) and variable bit rate (VBR) end-to-end connections. These connections will support 64kbit/s based ISDN services. 3 Architectural aspects of the B-ISDN The basic architectural model defined in Recommendation I.324 is comple- mented as shown in Figure1/I.327. This shows the main information transfer and signalling capabilities of the B-ISDN. The architecture of the B-ISDN includes low Layer capabilities and high Layer capabilities. These capabilities support services within the B- ISDN and within other networks by means of interworking B-ISDN with those other networks. 3.1 Low Layer capabilities From the functional capabilities of the B-ISDN, as shown in Figure1/I.327, the information transfer capabilities require further description. Broadband information transfer is provided by ATM at the B-ISDN user-net- work interface (UNI) and at switching entities inside the network. FIGURE 1/I.327 = 12,5 cm = 489 ATM is a specific packet oriented transfer mode using an asynchro- nous time division multiplexing technique. The multiplexed information flow is organized in fixed size blocks, called cells. A cell consists of an information field and a header: the primary role of the header is to identify cells belonging to the same virtual channel connection. Cells are assigned on demand, depending on the source activity and the available resources. Cell sequence integrity on a virtual channel connection is preserved by the ATM Layer. ATM is a connection oriented technique. A connection within the ATM Layer consists of one or more links, each of which is assigned an iden- tifier. These identifiers remain unchanged for the duration of the connection. It should be noted that signalling information for a given connection is con- veyed using a separate identifier. Although ATM is a connection oriented technique, it does offer a flexible transfer capability common to all services, including connectionless services. Examples of mechanisms supporting connectionless data services are illustrated in AnnexA. The switching and transmission capabilities, as described in Recommenda- tion I.324, are also applicable in B-ISDN. The support of 64kbit/s based ISDN services by a network based on ATM needs further study. 3.2 High Layer capabilities Normally, the high Layer functional capabilities are involved only in the ter- minal equipment. However, for the support of some services, provision of high layer functions could be made via special nodes in the B-ISDN belong- ing to the public network or to centres operated by other organizations and accessed via B-ISDN user-network or network-node interfaces (NNIs). 4 Location of functions in the B-ISDN 4.1 Overall In considering a B-ISDN call (i.e. an instance of a telecommunication ser- vice) two major functional areas are involved: i) the customer equipment (TE and optional customer network), ii) the public B-ISDN. In the case where the customer network is a B-ISPBX based network providing the same B-ISDN connection type as the public B-ISDN, then the overall B-ISDN connection ends at the SB reference point as shown in Figure2/I.327. Note1 ù In the case where the customer network is null then the B- ISDN connection type can be considered to end at the coincidentSB, TB ref- erence point. Note2 ù Other configurations are possible where the call is asym- metrical, or terminates in or involves HLFs. Note3 ù The terms _B-ISPBX/private B-ISDN_ and _public B- ISDN_ do not presuppose a particular regulatory situation in any country and are used purely for technical reasons. FIGURE 2/I.327 = 6,5 cm = 254 4.2 Partitioning of the overall B-ISDN connection The partitioning of functions within the B-ISDN connection type is done by using connection elements, basic connection components and reference points as defined in RecommendationI.324. 4.2.1 Connection elements The first level of partitioning of the overall B-ISDN connection type is the connection element (CE). The partitioning is based on the identification of reference points between connection elements. Figure 3/I.327 identifies five CEs for a mixed private/public B-ISDN overall connection type: the private access CE, the private transit CE, the public access CE, the public national transit CE and the public international transit CE. FIGURE 3/I.327 = 9,5 cm = 371 4.2.2 Functional groups in the B-ISDN connection elements In B-ISDN, the virtual path connection is introduced for routing groups of virtual channels in the network. Therefore two levels of connection handling will exist in the B-ISDN. These levels must be represented by two different switching blocks in the connection elements, one switching according to the virtual path identifier (VPI) and another switching according to the virtual channel identifier (VCI). Each of these switching blocks is under the control of its respective control block. A general connection element model in B-ISDN is thus described using five functional blocks: a switching block for VPI, the SVPI; a control block for VPI, the CVPI; a switching block for VCI, the SVCI, a control block for VCI, the CVCI, and an interconnection link (see Figure4/I.327). The link block incorporates all the functions implementing the physical layer. Different links may be identified, e.g.access links and transit links. In a particular reference configuration for connection types, the con- nection elements can be realized using a subset of the five functional blocks, for example to represent a connection in the network where only VPI han- dling is implemented. FIGURE 4/I.327 = 5,5 cm = 215 4.2.3 B-ISDN connection element generic description The generic B-ISDN connection element is shown in Figure 5/I.327. It repre- sents the logical interrelationship between the functional blocks supporting the B-ISDN connections and the means to control the connections. The B-ISDN connection is supported by the links and the switching blocks SVPI and SVCI. The connections are controlled by the control blocks CVPI and CVCI. These control blocks logically interface to the user-network signal- ling system on the user side of an access connection element and with the internodal signalling network. For the control of semi-permanent connec- tions, the control blocks also interface to the network management function. These management interface definitions will be the subject of further stud- ies. FIGURE 5/I.327 = 11 cm = 430 4.3 Functional architecture models for the B-ISDN Appendix I gives examples of functional architecture models using the prin- ciples established in RecommendationI.324. These principles are basically those of Reference Points and Functional Groups identified in Figure8/ I.324. ANNEX A (to Recommendation I.327) Support of connectionless data services in a B-ISDN Recommendation I.211 identifies the connectionless data service aspects of B-ISDN. Connectionless data services are supported in the B-ISDN using ATM connections between functional groups able to handle connectionless messages. These functional groups may be outside the B-ISDN or may pro- vide a B-ISDN service. Two mechanisms for supporting connectionless data services are described in RecommendationI.211, _ 2.7: 1) indirectly via a B-ISDN Connection Oriented service (Case A), 2) directly via a B-ISDN Connectionless Data service (Case B). The respective functional architecture model for those two methods are represented in Figures A-1/I.327 andA-2/I.327. The direct provision of a B-ISDN Connectionless Data service and the protocol specification are for further study. In order to access a Connectionless Data service, a connection has to be established between the user and the Connectionless service function (CLSF). This connection can be: ù a semi-permanent Virtual Path Connection. All the VC connections in this VP connection are dedicated to the Connectionless Data service; ù a switched or semi-permanent VC connection. CLSF terminates connectionless protocol and routes cells to a desti- nation user according to routing information included in user cells. FIGURE A-1/I.327 = 11, 5 cm = 449 (2 fig. sur la même page) FIGURE A-2/I.327 = 12,5 cm = 489 (sur la même page que fig. prec.) APPENDIX 1 (to Recommendation I.327) Examples for functional architecture models for B-ISDN Functional architecture models aim to identify various possible physical arrangements for the realization of the network when interconnect- ing equipments. Depending on the national situations and on the type of access, a number of different functional architecture models exist for access- ing the B-ISDN: ù a star structure where customers have direct individual links to the local exchange (LE) (see FigureI-1/I.327); ù a multistar structure with a remote unit (RU) between the customer and the main exchange. This is a two stage local network, each stage being star structured (see Figure I-2/I.327); ù a multistar structure, tree-shaped for distributive communication between the local exchange and the remote unit (see FigureI-3/I.327). Other functional architecture models, such as Metropolitan Area Networks, and access technologies such as Passive Optical Network, are for further study. NoteùThe passive optical network concept consists of a shared medium based on a tree topology that allows the connection of several cus- tomers to the local exchange using the same medium. The Metropolitan Area Network logical concept is based on a dis- tributed (not centralized) local CRF. Customers have access to the network using a shared medium based on different topologies. FIGURE I-1/I.327 = 10,5 cm = 410 (sur même page) FIGURE I-2/I.327 = 11 cm = 430 FIGURE I-3/I.327 (page pleine avec les remarques) ANNEX B (to Recommendation I.327) Alphabetical list of abbreviations used in this Recommendation ACE Access connection element AL Access link B-NT1 Network termination 1 for B-ISDN B-ISPBX Private branch exchange for B-ISDN CBR Constant bit rate CE Connection element CLSF Connectionless service function CRF Connection related function DPL Primary link for distribution services IPL Primary link for interactive services IRP Internal reference point LE Local exchange LFC Local function capabilities LT Line termination NNI Network-node interface PLK Primary link RU Remote unit SP Service provider SPL Service provider link TCE Transit connection element TCRF Transit connection related function TE Terminal equipment VBR Variable bit rate VCI Virtual channel identifier VPI Virtual path identifier