Internet Draft
                                     A. Kankkunen 
Internet Draft                                        Integral Access 
Document: <draft-kankkunen-vompls-fw-00.txt>                          
                                                               G. Ash 
                                                                 AT&T 
                                                                      
                                                           J. Hopkins 
                                                              Fujitsu 
                                                                      
                                                             B. Rosen 
                                                              Marconi 
                                                                      
                                                            D. Stacey 
                                                      Nortel Networks 
                                                                      
                                                          A. Yelundur 
                                                                  NEC 
                                                                      
                                                            L. Berger 
                                                      LabN Consulting 
 
 
                      Voice over MPLS Framework 
    
                    draft-kankkunen-vompls-fw-00.txt 
 
 
Status of this Memo 
 
   This document is an Internet-Draft and is in full conformance with 
   all provisions of Section 10 of RFC2026 [1].  
    
   Internet-Drafts are working documents of the Internet Engineering 
   Task Force (IETF), its areas, and its working groups. Note that 
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   Drafts. Internet-Drafts are draft documents valid for a maximum of 
   six months and may be updated, replaced, or obsoleted by other 
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   as reference material or to cite them other than as "work in 
   progress."  
   The list of current Internet-Drafts can be accessed at 
   http://www.ietf.org/ietf/1id-abstracts.txt  
   The list of Internet-Draft Shadow Directories can be accessed at 
   http://www.ietf.org/shadow.html. 
    
    
1. Abstract 
    
   This document provides a Framework for using MPLS as the 
   underlying technology for transporting IP based public voice 
   services. 
    

 
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   The document defines a reference model for Voice over MPLS, 
   defines some specific applications for Voice over MPLS and 
   identifies potential further standardization work that is 
   necessary to support these applications. The annexes of the 
   document discuss the types of requirements that voice services set 
   on the under laying transport infrastructure. 
    
   Editor's Note: 
    
   This document is an initial and incomplete version.  It is being 
   published to facilitate discussion prior to the Adelaide IETF. It 
   is expected that the draft will need to be revised and expanded 
   based on the results of the discussion. 
    
   Discussion related to this document will take place on the  
   vompls@lists.integralaccess.com mailing list.  To subscribe send 
   mail to vompls-request@lists.integralaccess.com with "subscribe" 
   in the message body.  An archive is available at  
   http://sonic.sparklist.com/scripts/lyris.pl?enter=vompls. 
    
    
Table of Contents 
    
1. Abstract 
2. Abbreviations and Acronyms 
3. Introduction 
3.1 Background and motivation 
3.2 Brief Introduction to MPLS 
4. VoMPLS Reference Model 
4.1 Reference Model Components and their roles 
4.1.1 Call Agent 
4.1.1.1 Media Gateway Connection Control 
4.1.1.2 Call processing 
4.1.1.3 Management 
4.1.2 Media Gateways 
4.1.3 Signaling Gateway 
4.1.4 Trunk Gateway 
4.1.5 Access Gateway 
4.1.6 Line Side Gateway 
4.1.7 Integrated Access Device 
4.1.8 Voice Terminals 
4.2 Data Plane 
4.3 Control Plane 
5. VoMPLS Applications 
5.1 Trunking Between Gateways 
5.1.1 Encapsulation Requirements for Efficient Multiplexed Trunk 
5.2 Circuit Emulation over MPLS 
5.3 VoMPLS on Slow Links 
  
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5.4 Voice Traffic Engineering using MPLS 
5.4.1 Off-Line Voice traffic engineering Aspects 
5.4.2 Connection Admission and/or Connection Routing 
5.4.3 Dynamic Traffic Management 
5.5 Providing End-to-end QoS for Voice Using MPLS 
6. Requirements for Call Control Protocols 
6.1 Megaco/H.248 
6.2 MGCP 
6.3 SIP 
6.4 H.323 
6.5 Q.1901 (Bearer-independent call control) 
7. Requirements for MPLS Signaling 
7.1 LDP and CR-LDP 
7.2 RSVP-TE 
8. Requirements for Other Work 
9. Security Considerations 
10. Acknowledgements 
11. References 
12. Author's Addresses 
    
ANNEX A - E-Model analysis of the Voice over MPLS Reference Model 
A.1 Introduction 
A.2 Deployment of VoMPLS within the Core Network 
A.2.1 Scenario 1 - Effect of Multiple MPLS Domains 
A.2.2 Scenario 2 - Analysis of VoMPLS and Typical DCME Practice 
A.2.3 Scenario 3 Analysis of GSM, VoMPLS and Typical DCME Practice 
A.2.4 VoMPLS Core Network Summary 
A.3 Extending VoMPLS into the Access Network 
A.3.1 Scenario 4 - VoMPLS Access on USA to Japan  
A.3.2 Scenario 5 Deployment of GSM and VoMPLS Access  
A.3.3 VoMPLS Access Summary   
A.4 Effects of Voice Codecs in  the access network 
A.4.1 Scenario 6 - Deployment of Codecs in one Access Leg (USA - 
Japan) 
A.4.2 Scenario 7 - Codec Deployment in both Access Legs (USA - Japan) 
A.4.3 Scenario 8 Codec Deployment and Mobile Access (USA - Australia) 
A.4.4 Voice Codec Summary  
A.5 Overall Conclusions 
    
ANNEX B - Service Requirements on VoMPLS 
B.1 Voice Service Requirements 
B.1.1 Voice Encoding 
B.1.2 Control of Echo 
B.1.2.1 Echo Control by Limiting Delay 
B.1.2.2 Echo Control by Deploying Echo Cancellers 
B.1.2.3 Network Architecture implications 
B.1.3 End-to-end Delay and Delay Variation 
B.1.4 Packet Loss Ratio 
  
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B.1.5 Timing Accuracy 
B.1.6 Grade-of-service 
B.1.7 Quality considerations pertaining to Session Management 
B.2 Circuit Emulation Service Requirements 
B.2.1 General Requirements 
B.2.1.1 Signals for circuit emulation 
B.2.1.2 Timing 
B.2.1.3 Applicability of Timing Options 
B.2.2 QoS Requirements for Circuit Emulation 
B.2.2.1 Jitter and Wander 
B.2.2.2 Delay 
B.2.2.3 Error Performance 
    
    
2. Abbreviations and Acronyms 
    
          AG             Access Gateway 
          CA             Call Agent 
          DS1            Digital Signal 1 
          E1             2048kbit/s signal possibly with G.704 
                         framing 
          FIB            Forwarding Information Base 
          IAD            Integrated Access Device 
          ID             Internet Draft 
          IP             Internet Protocol 
          LSG            Line Side Gateway 
          LSP            Label Switched Path 
          MegacoP        Media Gateway Control Protocol (Different 
                         than MGCP) 
          MG             Media Gateway 
          MGC            Media Gateway Controller 
          MGCP           Media Gateway Control Protocol (Different 
                         than MegacoP) 
          MPLS           Multi Protocol Label Switching 
          PABX           Private Automatic Branch Exchange 
          PSTN           Public Switched Telephone Network 
          SG             Signaling Gateway 
          SIP            Session Initiation Protocol 
          SLA            Service Level Agreement 
          SS7            Signaling System 7 
          TBD            To Be Defined 
          TDM            Time Division Multiplexing 
          TG             Trunk Gateway 
          VF             Voice Frequency 
          VoIP           Voice over IP 
          VoMPLS         Voice over MPLS 
    

  
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   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL 
   NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED",  "MAY", and 
   "OPTIONAL" in this document are to be interpreted as described in 
   RFC-2119 [2]. 
    
3.      Introduction 
 
   The purpose of this draft is to provide a common reference point 
   for the operation of voice over MPLS and to identify any needed 
   related standardization work. 
    
   Depending on the application, the voice encapsulation used in 
   VoMPLS can be either voice/RTP/UDP/IP/MPLS or voice/TBD/MPLS, 
   where TBD is a new efficient encapsulation which is to be defined 
   as part of the VoMPLS work. 
    
   The purpose of the TBD encapsulation is to define a way to create 
   LSPs that carry voice efficiently.  The basic format of packets in 
   the LSP should be a compressed header form of IP/UDP/RTP, with 
   trivial conversion to and from real IP/UDP/RTP.  Voice LSPs should  
   optionally support multiplexing within the LSP (multiple channels  
   per LSP), which should be a minor extension to this compressed 
   header.  
    
   LSPs should be able to be created with a constrained delay  
   characteristic.  Finally, LSPs should be able to be created with  
   Circuit Emulation characteristics (Private Line facility 
   emulation). 
    
   One purpose of this effort is to enable Session Switched Services 
   from IP terminals which achieve the same QoS characteristics for 
   real-time media as is currently available on ISDN and B-ISDN 
   networks. The technology should also be usable for growth and 
   retrofit of existing voice, leased-line and other current service 
   networks in order to achieve the multi-service objectives for next 
   generation networks. 
    
   This draft consists of three main sections:  VoMPLS Reference 
   Model, VoMPLS Applications and Definition of the required VoMPLS 
   standardization work. 
    
   Section 4 defines a reference model for VoMPLS. 
    
   Section 5 defines applications where MPLS can be the enabling 
   technology for supporting voice in an IP-infrastructure. 
    


  
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   Sections 6 and 7 define the new VoMPLS related standardization 
   that needs to take place in order to support the applications 
   defined in Section 5 within the reference model of Section 4.  
    
    
   This document identifies new application specific requirements 
     that are not addressed by existing work. These requirements 
     include the following:- Service types for carrying voice 
     services over Packet Networks should be defined. (This is not an 
     MPLS specific issue.) 
   - Explicit quantitative guidelines each service type sets on the 
     parameters described in Annex B should be defined. 
   - Identify how the quantitative guidelines are mapped to MPLS LSPs 
     in both diff-serv and non-diff-serv environments. 
   - Mechanisms for using MPLS for providing GoS required by the 
     various service types need to be defined. 
   - The reduction of header overhead and the support of efficient 
     multiplexing of multiple voice calls over a single LSP. 
   - The reduction of header overhead and the support of multiplexing 
     using link level techniques. 
    
3.1.    Background and motivation 
    
   MPLS is being introduced into IP networks to support Internet 
   Traffic Engineering and other applications. The motivation for 
   Voice over MPLS is to take advantage of this network capability to 
   improve voice-over-packet service by: 
     -  using label-switched-paths as a bearer capability for 
        packetized voice thereby providing more predictable, and even 
        constrained QoS, 
     -  providing a more efficient transport mechanism for 
        packetized-voice possibly using header compression or 
        suppression, 
     -  reducing the complexity of multiple connection-control planes 
        in multi-service networks by converging on the use of MPLS, 
     -  leveraging other advantages of MPLS, e.g. Layer 2 
        independence, integration with IP routing and addressing, 
        etc. 
    
3.2.    Brief Introduction to MPLS 
 
   MPLS (Multi Protocol Label Switching) is an emerging standard, 
   that provides a link layer independent transport framework for IP. 
   MPLS runs over ATM, Frame Relay, Ethernet and point-to-point 
   packet mode links. 
    


  
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   MPLS based networks use existing IP-mechanisms for addressing of 
   elements and for routing of traffic. MPLS adds connection oriented 
   capabilities to the connectionless IP-architecture. 
    
   For more information please see [5], [6], [7], [16], [17] and 
   [18]. 
 
4.      VoMPLS Reference Model 
    
   +--+ +------------+   +--+   +---------------------+ 
   |CA|-|            |<--|TG|-->|                     | 
   +--+ |            |   +--+   |                     | 
        |            |          |                     | 
        |   IP/MPLS  |   +--+   |   Circuit-Switched  | 
   +--+ |   Network  |<--|SG|-->|  Network (e.g. PSTN)| 
   |CA|-|            |   +--+   |                     | 
   +--+ |            |          |                     | 
        +------------+          +---------------------+ 
               ^    ^    +---+              | 
               |    |    |AG/|            +---+ 
               |    +--->|IAD|<---+       |LSG| 
               |         +---+    |       +---+ 
               |                  |         |         MG=AG/IAD or TG 
               |                  |     +-------+ 
               |                  |     |IP/MPLS|  
               |                  |     |Network|              
               |                  |     +-------+ 
               |                  |         | 
               |                  |       +---+ 
               |                  |       |AG/| 
               |                  |       |IAD| 
               |                  |       +---+ 
               |                  |         | 
          IP Terminals          Conventional Terminals 
   (e.g. Workstation-phone,   (e.g. PABX, Analog Phone, Key  
            IP_PBX)           System, ISDN TE, VF modem, FAX) 
    
                   Figure 1 Voice over MPLS Reference Model 
    
4.1.    Reference Model Components and their roles 
    
   The model used for VoMPLS is the "decomposed gateway", which 
   separates call control functions into an entity known as a Call 
   Agent (CA), and a Media Gateway (MG), which has the bearer, or 
   voice/packet stream handling.  Call Agents and a media gateway can 
   be physically realized in a single device, or they may be separate 
   devices that communicate to each other using suitable  protocols 
   (Megaco/H.248 or MGCP for example).  The Media Gateway is a 
  
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   function that converts a voice (or other media stream such as 
   video) into a packet stream. 
    
   There are many types of media gateways (Trunk Gateway, Access 
   Gateway, etc.), differentiated by the number and type of 
   interfaces they have.  There are no "rules" for categorizing a 
   particular media gateway into one type or another, but the 
   following sections define the Call Agent and several different 
   kinds of gateways for expository purposes.  For VoMPLS, each 
   gateway would have at least one MPLS interface.  
  
4.1.1 Call Agent 
    
   Call Agents (CA), sometimes called "Media Gateway Controllers", 
   provide among other things basic call and connection control 
   capabilities for Voice over IP/MPLS networks. These capabilities 
   include media gateway (Trunk Gateway, Access Gateway, etc.) 
   connection control, call processing and related management 
   functions. 
    
4.1.1.1 Media Gateway Connection Control 
    
   Media Gateway Connection control allows a Call Agent to modify the 
   state of a media gateway's resources, e.g. to connect two end-
   points via a label switched path, connect an access line to a tone 
   generator, detect events such as user on-hook/off-hook detection, 
   etc. There is a master-slave relationship between Call Agent and 
   Media Gateway. Megaco/H.248 [9] and MGCP [10] are examples of 
   protocols that enable a Call Agent to control a media gateway. 
    
4.1.1.2 Call processing 
    
   Call processing in a Call Agent provides call control functions 
   and may provide connection control functions. Call control 
   determines how telephony calls are established, modified and 
   released. There is a peer-to-peer relationship between Call 
   processing entities, such as other Call Agents, PSTN switches or 
   IP-telephony appliances. Q.1901 [13], H.323 [11] and SIP [12] are 
   examples of peer call control signaling protocols. Depending on 
   the call control protocol and call model, basic call control may 
   be supplemented by user or service features such as routing based 
   on pre-subscribed carrier identification code, or upon information 
   provided by a service agent, mobility agent or routing & 
   translation server. Work is in progress also to integrate 
   intelligent network (IN) based service logic and call control 
   protocols (see, for example, [14,15]). 
    

  
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   Connection control establishes, modifies and releases logical 
   connections between all reference model components. MPLS LDP [16], 
   RSVP-TE [17] and CR-LDP [18] are examples of connection control 
   protocols in a Voice over MPLS network, in which logical 
   connectivity is provided by label switched paths. Connection 
   control (bearer control in ITU-T terminology) is a subordinate 
   activity, which may result from call control events such as 
   receipt of setup message or on-hook/off-hook detection. 
 
4.1.1.3 Management 
    
   Management functions enable a Call Agent to alter the state of a 
   call in response to network abnormalities such as congestion or 
   failure of a network element (e.g. another Call Agent, Media 
   Gateway or Signaling Gateway) or label switched path payload or 
   signaling transport. It also allows the graceful startup or 
   shutdown of Voice over MPLS network components. 
    
4.1.2 Media Gateways 
    
   A Media Gateway (MG) forms the interface between the IP/MPLS 
   packet network ("packet side"), and circuit-switched PSTN/ISDN/GSM 
   networks or elements ("circuit side"), and adapts between the 
   coding formats for voice, fax and voice-band data in the circuit 
   side and packet side. Depending upon the traffic type, the Media 
   Gateway may also perform signal quality enhancements (e.g. echo 
   cancellation) and silence suppression. A Call Agent has exclusive 
   control over one or more Media Gateways. 
    
   The Voice over MPLS Media Gateway includes the following 
   functions: 
    
   -  Logical Connection Control: The MG receives instructions from 
      the Call Agent to initiate the establishment or release of 
      bearer connections to other media gateways. Optional QoS-
      parameters may be included in this instruction. Bearer 
      connections are usually label switched paths, but fallback to 
      connectionless IP is a requirement in order to handle cases 
      where the peer-gateway is not MPLS-capable, is an IP voice-
      terminal, etc. The instruction to the MG indicates the mapping 
      between circuit side ports and IP address of the peer-GW (or 
      IP-endpoint) to be used for the call. The MPLS Forwarding 
      Information Base e.g. based on MPLS protocol exchanges defines 
      the relationship between that IP address and a label. Two 
      possible modes of operation are foreseen. (a) The MG is an MPLS 
      signaling endpoint and can initiate LSP establishment using 
      LDP, CR-LDP or RSVP-TE as required. (b) An NMS or some other 
      off-line entity provisions a pool of label-switched-path trunks 
  
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      on behalf of the MG and a FIB is downloaded to each Gateway.  
      Multiplexed LSPs may be used to share an LSP with multiple 
      media streams passing between (or through) two VoMPLS gateways. 
    
   -  Call Agent Interface: The MG has an IP-based interface to the 
      Call Agent that is used for the exchange of media gateway 
      control information. This interface may also support the back-
      haul transport of in-band signaling information received from 
      the circuit side, as appropriate.  
    
   -  Packetization/Depacketization: The MG packetizes audio signals 
      from the circuit side for transmission on the packet network 
      and performs the inverse depacketization function for traffic 
      sent to the circuit side. Packetization/Depacketization 
      involves labeling/de-labeling packetized audio samples using 
      the IP address and label indicated for the call by the Call 
      Agent and FIB. The format of labeled voice packets is the 
      subject of a subsequent draft [TBD]. 
    
   Depending upon implementation, the MG may also support other 
   functions, e.g. data detection of fax and modem signals, echo 
   cancellation, transcoding/audio-mixing, silence detection/comfort-
   noise generation, and buffering/traffic shaping for received audio 
   packets. However these functions are beyond the scope of this 
   draft. 
    
4.1.3 Signaling Gateway 
    
   With decomposed gateways, the physical interface for channel 
   controlled signaling (such as SS7 messages and Q.931 messages) may 
   not be in the same device as the logical terminating point for 
   such signaling.  For ISDN, the interface may be in the media 
   gateway.  For SS7, the interface may be in a separate box.  The 
   Signaling Gateway provides a termination point for lower level 
   protocols carrying such signaling channels, and may provide a 
   packet interface to transport the higher layer signaling to the 
   call agent, using, for example, SCTP. For ISDN, the SG might 
   terminate Q.921.  For SS7 networks, the SG might terminate MTP2, 
   or MTP3.  The call agent would terminate Q.931 or Q.761. 
    
   The Signaling Gateway (SG) forms the interface for call/connection 
   control information between the Voice over MPLS network and 
   attached PSTN/ISDN/GSM networks. For example, an SS7 SG receives 
   messages from an SS7-linkset and encapsulates the SS7 application 
   parts (e.g. ISUP, TCAP, MAP, etc.) for delivery to the Call Agent. 
   The SG must terminate and processes MTP2 and MTP3 if an SS7 
   interface is supported, e.g.  to either an STP Pair or SS7 end 
   system (SSP/SCP). There is a master-slave relationship between a 
  
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   Call Agent and a (set of) Signaling Gateways. A SG is responsible 
   for all signaling information relating to a (set of) Media 
   Gateway(s).  
    
   Signaling Gateways in VoMPLS systems are identical to, and use the 
   same mechanisms as similar capability in VoIP systems.  In 
   particular, signaling protocols use IP transport (which may 
   transit MPLS LSPs) such as UDP, TCP or SCTP[19].    
    
4.1.4 Trunk Gateway 
    
   A Trunk Gateway (TG) is a type of Media Gateway, and is generally 
   a large capacity gateway used to connect a PSTN network to a 
   VoMPLS network.  The physical interface in a trunk gateway is a 
   large number of E1/T1s or perhaps concatenated DS3/T3/E3 or OC-n 
   ports intended to be connected to the trunk side of a Central 
   Office.  Signaling for TGs is generally via SS7 through an SG, but 
   in some cases could use ISDN with the SG collocated in the TG. 
    
4.1.5 Access Gateway 
    
   An Access Gateway (AG) is a type of Media Gateway intended to 
   exist on the edge of a public MPLS network, and connect multiple 
   subscriber circuits (such as PBXs) to a VoMPLS network.  The 
   physical interface in an Access Gateway would typically be a 
   number of T1/E1s (possibly PRIs), large number of analog POTS 
   interfaces or ISDN BRI interfaces. 
    
4.1.6 Line Side Gateway 
    
   A Line-Side Gateway (LSG) is a type of media gateway designed to 
   provide "emulated local loop" capability where a VoMPLS network 
   provides voice circuit transport to the line side of a Central 
   Office switch, the CO providing all call control.  In this 
   application, the Call Agent may not exist (the LSPs would be 
   provisioned), or be very simple (providing transport of hook 
   switch and ring for example).  The physical interface for a LSG 
   would be a number of T1/E1s, or possibly an OC-3, using GR-303 or 
   V5.2 signaling, with the SG collocated in the LSG. 
    
4.1.7 Integrated Access Device 
    
   An Integrated Access Device (IAD) is a device that includes the 
   functions of a Media Gateway as well as additional data network 
   capability, with the purpose of coalescing voice/video and data 
   connectivity to a site through a single uplink (communications 
   facility).  For example, an IAD may have an Ethernet interface to 
   the site LAN and a T1/E1 interface to the site PBX, together with 
  
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   an MPLS interface as an uplink to a public MPLS network that 
   carries the voice and data. 
    
4.1.8 Voice Terminals 
    
   Voice terminals form the interface between the human user and the 
   telecommunications infrastructure.  
    
   Traditional voice terminals for the PSTN/ISDN networks include 
   analog phone, PBX, Key System, VF modem, Fax machines and ISDN 
   terminals. 
    
   In addition to being connected directly to an IAD or AG the voice 
   terminals may be connected to a VoMPLS network via: 
   - An conventional PBX through a interworking device such as an 
     H.323 gateway 
   - An IP PBX 
   - A "Phone Hub", which would be a device with multiple analog or 
     digital phone interfaces on one side and an Ethernet on the 
     other side 
   - A single port adapter, which has a single phone port and an 
     Ethernet port 
   - A telephone adapter to another device on the network such as a 
     PC 
   - An "IPPhone" (or "SIPPhone" or H.323 terminal), which is an end 
     device with a native network interface. 
    
   Phone Hubs, Single Port Adapters, IP-Phones and other devices may 
   use external call agents.  H.323 gateway, IP PBXs and similar 
   devices are combined Call Agent/Media Gateways. 
    
 
4.2.    Data Plane 
    
   The data format for VoMPLS is defined in another document [TBD].  
   The requirements for the Data Plane are: 
   -           Provide a transparent path for VoIP bearers (RTP flows). 
   -           Provide efficient transport of voice (header compression) 
   -           Provide an efficient method to implement a multiplexed LSP 
   -           Provide an optional method to specify delay characteristics 
     across the network on a specific LSP, specifically, a way to 
     specify the maximum delay and a bound on delay variation for an 
     LSP. 
   -           Provide an optional method to specify a "Circuit Emulation" 
     LSP, which would provide a method to implement "Private Line" 
     service. 
 
   The data plane may be functionally broken down into -  
  
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   - Voice Encoding [audio signals into digital format - G.711, 
     G.723.1, G.729, etc] 
    
   - Packetization/De-packetization [converting the encoded voice 
     into RTP/UDP/IP/MPLS packets & vice versa] 
    
   - Compression [Compressing the RTP/UDP/IP/MPLS headers to reduce 
     overhead or other alternative approaches such as suppression] 
    
   - Multiplexing [Multiplexing many different voice circuits into 
     one MPLS packet for Voice trunking application] 
    
   - Echo Control [Reduce / cancel the echo generated by legacy PSTN 
     systems] 
    
   - Timing [] 
    
   - Queues / Schedulers [Give priority to voice traffic wrt BE 
     traffic multiplexed on the same output link] 
    
   - Traffic Shapers [To reduce jitter & control burstiness nature of 
     traffic] 
    
   - Tone Generators & Receivers [Generation & detection of DTMF 
     tones, continuity test tones & detection of modem tones] 
    
4.3.    Control Plane 
    
   The control plane may be broken down into two entities - Bearer 
   control & Call control. Bearer control protocols include LDP, CR-
   LDP & RSVP. Call control protocols include H.323, SIP and Q.1901. 
   Joining the two, when Call Agents are physically separated from 
   media gateways are media gateway control protocols such as Megaco 
   and MGCP. 
    
   Call control must arrange for the (bearer) originating media 
   gateway to obtain the address of the (bearer) terminating gateway.  
   It must also determine, through negotiation if necessary, the 
   processing functions the media gateway must apply to the media 
   stream, such as codec choice, echo cancellation application, etc 
   and inform its media gateway function of such treatment. 
    
   Bearer control relies to some extent on the information gathered 
   by call control protocols to set-up LSP between edge routers or 
   Voice gateways / IADs. CR-LDP & RSVP-TE signaling protocols may be 
   used to set-up LSPs based on certain constraints like QoS 
   requirements, traffic class type & resource class type. Voice 
  
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   traffic engineering can also be accomplished by using CR-LDP & 
   RSVP-TE by specifying the actual path to be taken by the LSP 
   between voice gateways / IADs and may be different from the path 
   calculated by routing protocols.  
    
   A capability to signal use of VoMPLS stack (as opposed to ip/mpls  
   stack) is needed, so that LSRs don't try and interpret the stack 
   as IP and drop traffic, try to generate ICMP messages, etc. 
   Similarly a way to signal multiplexing of Voice over MPLS and 
   ip/mpls traffic on a single LSP using some multiplexing scheme is 
   needed. 
    
   The VoMPLS Control plane is IDENTICAL to a VoIP control plane with 
   respect to call control (Call Agent) operation. 
    
   The VoMPLS control plane for bearer control must provide the Call 
   control function the ability to: 
   - create a new LSP for VoMPLS 
   - use an existing multiplexed LSP and create a new subchannel 
   - specify the QoS to be applied to new LSP, or change the QoS on 
     an existing LSP 
   - specify the bandwidth to be allocated to a new LSP, or change 
     the bandwidth on an existing LSP 
    
5.      VoMPLS Applications 
    
5.1.    Trunking Between Gateways 
    
   MPLS LSPs can be used for providing the trunks between the various 
   gateways defined in Section 4. 
    
5.1.1.  Encapsulation Requirements for Efficient Multiplexed Trunk 
    
   Where a label edge router, or a gateway with built-in label edge 
   router functionality can determine that multiple streams must pass 
   on the same LSP to the same far end LER, then the streams can be 
   optimized by using a multiplexing technique.  The VoMPLS 
   multiplexing function shall provide an efficient means for 
   supporting multiple streams on a single LSP which is trivially 
   convertible into multiple individual IP/UDP/RTP streams by the far 
   end LER. 
    
   The multiplexing methods needs to provide an efficient voice 
   encapsulation and a call identification mechanism. 
    
5.2 Circuit Emulation over MPLS 
    

  
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   Circuit emulation is the provision by the packet network of LSPs 
   equivalent to circuits in the PSTN where no call handling 
   functionality is used, i.e. no signaling termination and 
   processing, call routing, or circuit switching. Some circuits in 
   the PSTN may have restricted capabilities, e.g. speech only, but a 
   packet network should emulate an unrestricted capability. 
    
 
5.3.    VoMPLS on Slow Links 
    
   Slow links are being used in the MPLS based access networks. These 
   links are typically based on transmission over copper cables. 
    
   The vast majority of access lines in the world are currently 
   copper-based and this will not change in the near future. 
   Therefore it is important to address the requirements of slow 
   links in the VoMPLS specifications. 
    
   Slow links introduce additional requirements concerning bandwidth 
   efficiency and the control of voice latency. 
    
   In most cases bandwidth in slow links is expensive and needs to be 
   used in the most efficient way possible. Especially it is often 
   desirable to avoid the overhead of carrying full IP, UDP and RTP 
   headers with every voice packet. 
    
   A simple method for compressing IP/UDP/RTP headers shall be 
   specified.  The header compression mechanism and the multiplexing 
   mechanism of section 5.1.1 should be considered the same mechanism 
   (i.e. the IP header compression could yield a short LSP specific 
   channel identifier which permits multiple channels per LSP). 
   Alternatively header compression can be applied at link level 
   using the methods proposed in [8]. Also PPP-muxing can be used for 
   reducing the overhead [3]. 
    
   The control of latency on slow links requires link level 
   fragmentation of large data packets. The fragmentation is 
   specified in RFC 2686 [4]. 
    
5.4 Voice Traffic Engineering using MPLS 
    
   The goal of voice traffic engineering is to ensure that network 
   resources can be efficiently deployed and utilised so that the 
   network is able to support a planned group of users with a 
   controlled/guaranteed (voice) performance. In essence voice 
   traffic engineering may be summed up as providing QoS and GoS to a 
   group of users at a reasonable (network) cost.  
    
  
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   Voice traffic engineering for VoMPLS will encompass forecasting, 
   planning, dimensioning, network control and performance 
   monitoring. It therefore spans both off-line analysis and on-line 
   control, management and measurement. Broadly, voice traffic 
   engineering may be broken down into three distinct layers 
   (characterised by the temporal resolution at which they operate): 
    
        1) Off-line voice traffic engineering.  
    
        2) Connection admission and/or connection routing. 
         
        3) Dynamic Traffic Management. 
    
   The general requirements at each layer will be discussed in more 
   detail below. Clearly in an optimal solution there is interaction 
   between the stages - a fundamental requirement of performance 
   measurement is to provide this necessary feedback.  
    
5.4.1 Off-Line Voice traffic engineering Aspects 
    
   The goal of off-line voice traffic engineering is to ensure that 
   sufficient network resources are engineered together with a given 
   set of policies and procedures such that the network is capable of 
   delivering the GoS and QoS guarantees to the planned group of 
   users.  
    
   In traditional voice network planning the first stage in this 
   process is to perform traffic analysis to determine the capacity 
   requirements for the voice traffic at busy hour. This then enables 
   the network to be dimensioned and configured to support this load 
   with a given blocking probability. Finally a set of policies and 
   procedures should be defined to determine how the allocated 
   network resources should be utilised. The policies should address 
   key requirements including the mechanism whereby the voice GoS is 
   maintained within a multi-service environment, definitions of 
   routing mechanisms that should be applied to ensure efficient 
   network utilisation, behaviour rules for overload and congestion 
   management.  
    
   Some operators may choose to use off line voice traffic 
   engineering tools and techniques in a VoMPLS system, that are 
   radically different from those in the PSTN. As an example, busy 
   hour measurements may have little affect on pre-allocated LSPs in 
   a VoMPLS network, as average rates may determine pre-allocated 
   resources, with dynamically created LSPs absorbing traffic during 
   busy periods. Policy metrics and control points in packet networks 
   are typically very different from those in the PSTN, and thus new 
   mechanisms, specific policies, and enforcement mechanisms will be 
  
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   required. VoMPLS work may motivate some mechanisms but 
   implementing such mechanisms is out of scope of the VoMPLS work. 
    
5.4.2 Connection Admission and/or Connection Routing 
    
   Network performance will be fundamentally affected by the policies 
   and procedures applied when establishing new sessions. At a 
   minimum the following issues need to be addressed within a VoMPLS 
   network:  
    
        (i) New sessions should be routed such that the network 
        resources are used in an efficient manner. This implies that 
        the system needs to be capable of supporting traffic between 
        the same two end points using multiple path alternatives. 
         
        (ii) The QoS guarantees for existing voice connections should 
        be unaffected when new sessions are established - at the 
        limit this implies a requirement that new session requests 
        should be rejected if insufficient network resources are 
        available. 
         
        (iii) The network should be resilient to mass calling events. 
        This implies that call rejection should be performed at the 
        edge of the network to avoid placing undue load onto the core 
        network routers. 
    
   The above requirements imply that VoMPLS systems should be 
   constructed where the Call Agent is aware of LSP usage, and tracks 
   bandwidth consumption, either using admission control to restrict 
   new calls, or signaling MGs to create new LSPs when bandwidth in 
   an existing LSP is committed.  VoMPLS systems where the MG tracks 
   LSP usage is also possible, with the MG determining when new LSPs 
   must be created, and informing the CA when it is unable to do so. 
    
    
 
5.4.3 Dynamic Traffic Management 
    
   Dynamic traffic management refers to the set of procedures and 
   policies that are applied to existing voice sessions to ensure 
   that network congestion is minimised and controlled. The following 
   functions will typically be performed at this layer:  
 
     -  traffic buffering and queue management within MPLS routers to 
        control delay (based on signaled QoS requirements, i.e., is 
        not voice specific) 
     -  traffic policing at key network ingress points to ensure 
        session compliance to traffic contracts/SLAs 
  
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     -  traffic shaping at ingress points to minimise the resource 
        requirements of traffic sources 
     -  loss/late packet interpolation and jitter buffering at egress 
        points to reconstitute the original real-time session stream  
     -  traffic measurement for performance monitoring and congestion 
        detection 
    
   VoMPLS does not differ from other forms of Voice over data 
   networks in its dynamic traffic management capabilities other than 
   the fundamental properties MPLS provides. 
    
    
5.5 Providing End-to-end QoS for Voice Using MPLS 
 
   A key goal of the development of the VoMPLS specification will be 
   to ensure that the reference architecture is capable of supporting 
   end-to-end QoS and GoS. 
    
   Defining new MPLS related signaling protocols is out of the scope 
   of the VoMPLS work. VoMPLS work may motivate some extensions to 
   the existing protocols as required. 
    
   The initial goal is to define an end-to-end QoS architecture for 
   single MPLS domain. This implies that it should be possible to set 
   up LSPs with a bandwidth reservation and a bounded delay. 
   A long term goal is to achieve end-to-end QoS across multiple MPLS 
   domains. However, this will require considerable progress in the 
   area of the generic MPLS specifications. A connectivity model and 
   end-to-end voice over MPLS reference connection is shown in  
   Figure 2 below. The model provides a framework for the control and 
   signaling required to establish QoS capable sessions. The 
   reference model illustrated is scalable to global proportion 
   consisting of access domains and core network domains. In Figure 2 
   two core domains are shown, which might for example represent the 
   two national operators involved in establishing an international 
   session. The connectivity model may be devolved further to support 
   multiple core MPLS domains. The access domains may be provided 
   either by the ISDN (requiring a TDM to packet interworking 
   function at the gateway to the core MPLS domain) or by an MPLS 
   access network enabling full end-to-end voice over MPLS operation. 
    
    
    
    
    
    
    
    
  
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                   Gateway               Gateway 
                   +------+              +------+   
                   |      |              |      |   
   +--+   +------+ | +--+ |              | +--+ |   
   |TE|---| ISDN |---|CC|------------------|CC|-----//--A 
   +--+   |  or  | | +--+ |              | +--+ |   
          | MPLS | |      |              |      |   
          |Access| | +--+ | +--+   +--+  | +--+ |   
          +------+ | |BC|---|BC|---|BC|----|BC|-----//--B 
                   | +--+ | +--+   +--+  | +--+ |   
                   |      |              |      |   
                   +------+              +------+   
      
                   \------------  --------------/ 
                                \/ 
                         MPLS Core Domain 1 
    
    
                     Gateway               Gateway 
                     +------+              +------+   
                     |      |              |      |  
                     | +--+ |              | +--+ |  +------+   +--+ 
             A---------|CC|------------------|CC|----| ISDN |---|TE| 
                     | +--+ |              | +--+ |  |  or  |   +--+ 
                     |      |              |      |  | MPLS |   
                     | +--+ | +--+   +--+  | +--+ |  |Access| 
             B---------|BC|---|BC|---|BC|----|BC|----|      | 
                     | +--+ | +--+   +--+  | +--+ |  +------+    
                     |      |              |      |   
                     +------+              +------+   
    
                                \---------  ---------/ 
                                          \/ 
                                  MPLS Core Domain 2 
    
    
    
   BC = Bearer Control 
   CC = Call Control 
    
               Figure 1 - End-to-End Reference Connection 
 

6.      Requirements for Call Control Protocols 
    
6.1.    Megaco/H.248 
    


  
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   A new bearer definition must be provided for Megaco in the form of 
   an MPLS package, which would define an extension to SDP to 
   describe an MPLS bearer, an addition to Annex C to describe an 
   MPLS bearer, and a set of additional statistics appropriate to 
   LSPs. 
    
6.2.    MGCP 
    
   The extension to SDP defined in section 6.1 would constitute the 
   required additions to MGCP to allow it to specify a VoMPLS bearer. 
    
    
6.3 SIP 
    
    
   The extension to SDP defined in section 6.1 would constitute the 
   required additions to SIP to allow it to specify a VoMPLS bearer.  
   An option tag must be defined and registered with IANA to allow a 
   SIP element to discover the ability of the element to construct an 
   LSP. 
    
6.4 H.323 
    
   H.323 can take advantage of an IP/MPLS network between Media 
   Gateways in two ways.  
   (i)    Establishing label switched paths between media gateways 
          for the transport of media streams, and 
   (ii)   Use of a compressed voice/RTP/MPLS header format to improve 
          transport efficiency. This format avoids the transport of 
          full UDP/IP headers, which tend to be large relative to the 
          size of audio codec samples. 
    
   In a H.323 system, the Gatekeeper is the call control entity. 
   Media streams are established in response to H.225 & H.245 
   signaling, with or without use of the H.323 fast start procedures. 
   In the case of an IP/MPLS network, media stream establishment 
   includes the use or establishment of a label-switched-path as 
   bearer.  
    
    
    
    
    
    
    
    
    
    
  
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               +----+            +-----+             +----+ 
               |GK A|            | GK B|             |GK C| 
               +----+            +-----+             +----+ 
                 |                  |                  | 
              +-----+          +---------+          +-----+ 
    Endpoint  |     |  +----+  |         |  +----+  |     | Endpoint 
         A  --| IP  |--|GW X|--| IP/MPLS |--|GW Y|--| IP  |-- B 
              | Nwk |  +----+  | Network |  +----+  | Nwk | 
              +-----+          +---------+          +-----+ 
    
                   Figure 3 Example H.323 network including MPLS 
    
   LSP establishment without fast start 
    
 
   In a H.323 system without faststart, the H.245 control channel is 
   first established and control messages are explicitly addressed to 
   the gateways. Following Capability Exchange & Master/Slave 
   exchange phases, logical channels can be opened for the transport 
   of media streams. MPLS-enabled gateways can use the information in 
   these messages to establish label-switched-paths in support of 
   media streams. Therefore MPLS capability should be determined 
   during capability exchange. 
    
   Extensions to H.245 Capability Exchange and OpenLogical Channel 
   structures must be defined to allow negotiation and specification 
   of a VoMPLS bearer. In the case of a decomposed H.323 system, the 
   MGCP or H.248/megaco protocol extensions to support label-
   switched-path bearers are also needed. 
 
    
   LSP establishment with fast start 
    
   The H.323 fast connect procedure provides connection setup without 
   waiting for H.245 control channel establishment. The procedure is 
   initiated by inclusion of a fastStart element in the H.225.0 SETUP 
   message, consisting of proposed options for the forward and 
   reverse channels on the respective OpenLogicalChannel elements. An 
   MPLS-capable Gateway may initiate the establishment of label-
   switched-paths in support of media streams.  
    
   Extensions to H.245 Capability Exchange, fastStart elements and 
   OpenLogical Channel structures must be defined to allow 
   negotiation and specification of a VoMPLS bearer. In the case of a 
   decomposed H.323 system, the MGCP or H.248/megaco protocol 
   extensions to support label-switched-path bearers are also needed. 
    
6.5 Q.1901 (Bearer-independent call control) 
  
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   Q.1901 [13](previously known as Q.BICC) is a call control protocol 
   from ITU-T SG11 to support the migration of the full range of 
   public telephony services to a packet-based infrastructure. E.g. 
   POTS, ISDN, mobility, 800/888/877-number toll-free, 900-number 
   information services, CLASS, Centrix, ISDN BRI & PRI, Intelligent 
   Network, Emergency/911, etc. to packet based networks, As such it 
   is primarily of interest to existing operators of those services.  
    
   Q.1901 is a derivation of ISUP [TBD]. Capability Set 1 supports 
   ATM AAL1 & AAL2 as a connection/bearer network. Later versions 
   will  provide support for Internet Protocol bearer networks. 
   In Q.1901 terminology, ISNs (equivalent to a Media Gateway and 
   associated Call Agent) include a bearer control function (BCF-N) 
   that can initiate (or use a pool of) connections/bearers to a peer 
   ISN, possibly traversing intermediate Switching Nodes (SWN). The 
   SWN nodes provide a switching function and may include a Bearer 
   Control Relay Function (BCF-R) that establishes connectivity 
   through the SWN and relays the bearer connection signaling request 
   to the next SWN in order to complete edge-to-edge connection 
   across the backbone. 
    
   Call-control and bearer-control are co-ordinated with the aid of 
   Bearer-Network Connection Identifiers (BNC-ID) and Bearer-
   Interworking Function Addresses (BIWF-Address). This information 
   is carried as parameters in Q.1901 messages, as well as 
   information on the 'Bearer Characteristics'. Q.1901 supports 
   allocation of bearers both using a connection/bearer setup 
   protocol and from a pool of reserved bearers.  
    
   +--------+   +----------+            +----------+   +--------+ 
   | ISDN-A |   | ISN-A    |            | ISN-B    |   | ISDN-B | 
   |        |   |          |            |          |   |        | 
   |        |   | +------+ |            | +------+ |   |        | 
   |        |<->| |CSF-N | |<---CSF-R-->| |CSF-N | |<->|        | 
   |   TDM  |   + +------+ |            | +------+ |   | TDM    | 
   | Switch |   |     |    |   (SWN)    |     |    |   | Switch | 
   |        |   | +------+ |  +------|  + +------+ |   |        | 
   |        |   | |BCF-N | |  |BCF-R |  | |BCF-N | |   |        | 
   |        |   | +------+ |  +------+  | +------+ |   |        | 
   |        |   | |fabric| |  |fabric|  | |fabric| |   |        | 
   |        |   | +------+ |  +------+  | +------+ |   |        | 
   +--------+   +----------+    |   |   +----------+   +--------+ 
        |         |      |      |   |     |       |         | 
        +---------+      +------+   +-----+       +---------+ 
 
            Figure 4 Q.1901 Reference Architecture (abbreviated) 
 
  
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   Q.1901 is readily applicable to IP bearer networks. In this case 
   the ISN consists of Trunk Gateway and associated Call Agent that 
   is capable of instructing the Trunk Gateway of the IP address of 
   the peer ISN. No bearer control protocol is required (IP is 
   connectionless), so the SWN function can be realized by routers. 
    
    
   +--------+   +----------+            +----------+   +--------+ 
   | ISDN-A |   | ISN-A    |            | ISN-B    |   | ISDN-B | 
   |        |   | (=TG+CA) |            | (=TG+CA) |   |        | 
   |        |   | +------+ |   Q.1901   | +------+ |   |        | 
   |        |<->| |CAgent| |<---------->| |CAgent| |<->|        | 
   |   TDM  |   + +------+ |            | +------+ |   | TDM    | 
   | Switch |   |     |    |   (LSR)    |     |    |   | Switch | 
   |        |   | +------+ |  +------|  + +------+ |   |        | 
   |        |   | |MPLS-E| |  |MPLS-C|  | |MPLS-E| |   |        | 
   |        |   | +------+ |  +------+  | +------+ |   |        | 
   |        |   | |fabric| |  |fabric|  | |fabric| |   |        | 
   |        |   | +------+ |  +------+  | +------+ |   |        | 
   +--------+   +----------+    |   |   +----------+   +--------+ 
        |         |      |      |   |     |       |         | 
        +---------+      +------+   +-----+       +---------+ 
    
           Figure 5 Q.1901 Call Control & MPLS bearer network 
    
   Q.1901 is readily applicable to MPLS bearer networks. In this case 
   the ISN consists of Trunk Gateway and an associated Call Agent 
   capable of instructing the Trunk Gateway of the BIWF of the peer 
   ISN, and possibly other parameters that can be used by CR-
   LDP/RSVP-TE. Core label switch routers realize the SWN function. 
   The Trunk Gateway acts as LDP/CR-LDP/RSVP-TE signaling end-point, 
   either to establish a Label-Switched-Path per-call or to establish 
   trunks between Gateways that can support multiple simultaneous 
   calls. In the latter case a multiplexing identifier (similar to 
   AAL2 CID) can be used on the LSP to identify individual 
   multiplexed voice connections within the trunk. 
    
   Extensions to Q.1901 are required to support MPLS Label Switched 
   Paths as bearers. In particular: - 
     -  BNC Characteristics: MPLS LSP should be supported as a bearer 
        type 
     -  BIWF Address: An IPv4 or IPv6 address must be usable to 
        identify the address of the connection control processing 
        function in a peer Call Agent / Media Gateway Controller, 
        i.e. the address for MPLS signaling exchanges.  
     -  Bearer Network Connection Identifier: MPLS Label values (plus 
        Voice over MPLS multiplexing identifiers when appropriate) 

  
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        must be usable as BNC-ID.  Note that BNC-ID is currently 
        restricted to 4-octets. 
    
   (Note: Q.1901 CS1 is designed to use the existing MTP signaling 
   network as transport, or an MTP3b-based ATM-based signaling 
   network. If Q.1901 is to operate over an IP signaling transport 
   e.g. between Call Agents and Signaling Gateways, then an 
   appropriate application-layer framing protocol (signaling 
   transport converter) is required. SCTP is already identified as a 
   candidate signaling transport protocol for use on IP networks (in 
   CS2), as is SSCOP-multi-link.) 
 
7.      Requirements for MPLS Signaling 
    
7.1.    LDP and CR-LDP 
    
   TBD 
    
7.2.    RSVP-TE 
    
   TBD 
 
         
    
8.      Requirements for Other Work 
9.      Security Considerations 
10.     Acknowledgements 
11.     References 
    
    
   1  Bradner, S., "The Internet Standards Process -- Revision 3", 
      BCP 9, RFC 2026, October 1996. 
    
   2  Bradner, S., "Key words for use in RFCs to Indicate Requirement 
   Levels", BCP 14, RFC 2119, March 1997 
    
   3 "PPP Multiplexed Frame Option", R. Pazhyannur et al., work in 
   progress, <draft-ietf-pppext-pppmux-00.txt>, January 2000 
    
   4 "The Multi-Class Extension to Multi-Link PPP", RFC 2686, C. 
   Bormann. September 1999.  
    
   5 "A Framework for Multiprotocol Label Switching", R. Callon et 
   al., work in progress, <draft-ietf-mpls-framework-05.txt>, 
   September 1999 
    
   6 "Multiprotocol Label Switching Architecture", Eric C. Rosen et 
   al., work in progress, draft-ietf-mpls-arch-06.txt, August 1999 
  
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   7 "MPLS Label Stack Encoding", Eric C. Rosen et al., work in 
   progress, draft-ietf-mpls-label-encaps-07.txt, September 1999 
    
   8 "MPLS/IP Header Compression", L. Berger et al., work in 
   progress, draft-berger-mpls-hdr-comp-00.txt, January 2000. 
    
   9 "Megaco Protocol", F. Cuervo et al., work in progress, draft-
   ietf-megaco-protocol-07.txt, February 2000 
    
   10 "Media Gateway Control Protocol (MGCP), Version 1.0", RFC 2705, 
   M. Arango et al., October 1999 
    
   11 "Packet-based multimedia communications systems", ITU-T 
   Recommendation H.323, February 1998 
    
   12 "Session Initiation Protocol (SIP)", RFC 2543, M. Handley et 
   al., March 1999. 
    
   13 "Bearer Independent Call Control", Draft ITU-T Recommendation 
   Q.1901, (to be published) 
    
   14 F. Haerens, "Intelligent Network Application Support of the 
   SIP/SDP Architecture", Internet Draft , November 1999, work in progress. 
    
   15 V. Gurbani, "Accessing IN Services from SIP Networks," Internet 
   Draft , Internet Engineering 
   Task Force, December 1999, work in progress. 
    
   16 "LDP Specification", L. Andersson et al., work in progress, 
   draft-ietf-mpls-ldp-06.txt, October 1999. 
    
   17 "Extensions to RSVP for LSP Tunnels", D. Awduche et al., work 
   in progress, draft-ietf-mpls-rsvp-lsp-tunnel-04.txt, September 
   1999 
    
   18 "Constraint-Based LSP Setup using LDP", B. Jamoussi et al., 
   work in progress, draft-ietf-mpls-cr-ldp-03.txt, September 1999. 
    
   19 "Simple Control Transmission Protocol", R. Stewart et al., work 
   in progress, draft-ietf-sigtran-sctp-06.txt, February 2000 
    
    
    
    
    
    
  
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12.     Author's Addresses 
 
    
    
   Gerald R. (Jerry) Ash 
   AT&T Labs 
   Room MT E3-3C37 
   200 Laurel Avenue 
   Middletown, NJ 07748 
   USA 
    
   John Hopkins 
   Fujitsu 
   2 Longwalk Road, Stockley Park, 
   Uxbridge, Middlesex. UB11 1AB, UK. 
   Email: J.Hopkins@fujitsu.co.uk 
    
   Antti Kankkunen 
   Integral Access 
   6 Omni Way 
   Chelmsford MA, 01824 
   USA 
    
   Brian Rosen 
   Marconi 
   1000 FORE Drive 
   Warrendale, PA 15086 
   USA 
   Email: brosen@fore.com 
    
   Dave Stacey 
   Nortel Networks 
   London Rd, Harlow, Essex, CM17 9NA, UK. 
   Phone: +44 1279 402697 
   Email: dajs@nortelnetworks.com  
    
   Anil Yelundur 
   NEC 
    
   Lou Berger 
   LabN Consulting, LLC 
   Voice: +1 301 468 9228 
   Email: lberger@labn.net 
    
    
    
    
    
  
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   ANNEX A - E-Model analysis of the Voice over MPLS Reference Model 
 
A.1 Introduction 
    
   The ITU-T standards for voice network QoS are defined in relation 
   to a global reference connection, which is intended to represent 
   the worst case international situation. Within this annex we take 
   a PSTN call from Japan to east coast USA and a GSM call from 
   Australia to east-coast USA as being representative of global 
   reference connections having clear commercial significance. 
    
   In this annex several scenarios will be presented to illustrate 
   the requirements on VoMPLS deployments. The scenario analysis is 
   split into three distinct parts. In the first part we analyse 
   scenarios where the VoMPLS deployment is constrained to the core 
   of the network; in the second part of the analysis we extend MPLS 
   into the access network; and in the third part we analyse the 
   impact of deploying differing voice encoding schemes. 
    
   The scenarios are analysed using the ITU-T E-Model transport 
   modelling method [G.107]. The E-Model allows multiple sources of 
   impairment to be quantified and the overall impact assessed. The 
   result is expressed as an R-Value which is a rating of the 
   assessment that real users would express if subjected to the voice 
   impairments. Equations to convert E-model ratings into other 
   metrics e.g. MOS, %GoB, %PoW can be found in Annex B of G.107. 
   Using the R-value the ITU G.109 defines 5 classes of speech 
   transmission quality as illustrated in Table A.1 below. As a rule 
   of thumb, wire-line connections on todays PSTN tend to fall in the 
   'satisified' or 'very 'satisfied categories' - and R-values below 
   50 are 'not recommended'  for any connections. 
 
   +------------------------------------------------------------+ 
   |    R-value range |  Rating | Users Satisfaction            | 
   |------------------|---------|-------------------------------|  
   | 90 <= R < 100    | Best    | Very satisfied                | 
   | 80 <= R < 90     | High    | Satisfied                     | 
   | 70 <= R < 80     | Medium  | Some users dissatisfied       |     
   | 60 <= R < 70     | Low     | Many users dissatisfied       | 
   | 50 <= R < 60     | Poor    | Nearly all users dissatisfied | 
   +------------------------------------------------------------+ 
    
   Table A.1 Definition of Categories of Speech Transmission Quality 
    
   In this analysis we use the term 'intrinsic delay' to define the 
   additional delay introduced by a VoMPLS domain over and above the 
  
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   transmission delay - i.e. typically the intrinsic delay is the sum 
   of any packetisation and buffering delays introduced by a packet 
   network.  
    
   Transmission delay is included within the analysis as a fixed 
   delay based on transmission distance (evaluated based on SONET/SDH 
   transmission rules). 
    
    
    
A.2. Deployment of VoMPLS within the Core Network 
    
    
A.2.1 Scenario 1 - Effect of Multiple MPLS Domains 
    
    
   Figure A.1 illustrates the first reference connections considered. 
   In the PSTN to PSTN connection two core VoMPLS network islands are 
   traversed in both Japan and the USA. In the GSM to PSTN scenario 
   one VoMPLS network island is traversed in Australia and two within 
   the USA. Calls traversing the VoMPLS core networks interwork 
   through the current PSTN. 
    
   The analysis covers a range of intrinsic delays (from 10 ms to 100 
   ms) and Packet Loss Ratios (PLR)(0% to 1%) for each VoMPLS domain. 
   Each VoMPLS domain is assumed to have the same performance. It is 
   assumed that the transmission delay corresponds to 1.5 times the 
   greater circle distance between the two users. 
    
    
                                
                     Japan                    USA                                
               --------/\--------      --------/\--------       
              /                  \    /                  \ 
    
              POTS--|MPLS|--|MPLS|----|MPLS|--|MPLS|--POTS 
                                     / 
                                    / 
                                   / 
            Mobile--|GSM|--|MPLS|-- 
             \                  / 
              --------\/-------       
    
                  Australia 
    
    
   Figure A-1: Scenario 1 - Effect of multiple VoMPLS Core Domains 
    
  
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   A number of further assumptions are made on the basis of best 
   possible practice in order to separate the contribution of 
   multiple networks from other sources of impairment, in particular:  
    
        - DCME on the Japan to USA link is at full rate e.g. 32 kb/s 
        G.726 and VoiceActivity Detection is not included. 
    
       - The Australia to USA link is G.711 i.e. there is no DCME. 
    
        - VoMPLS domains use G.711 with packet loss concealment 
        algorithm employed. 
    
        - GSM domain uses full rate codec and no Voice Activity 
        Detection. 
    
        - Wired PSTN phones are analogue with echo-cancellers 
        employed. 
    
   +--------------------------------------| 
   |          |     | Intrinsic Delay(ms) | 
   |Connection| PLR |  09 | 20 | 50 | 100 | 
   +--------------------------------------| 
   |PSTN-PSTN | 0%  |  79 | 74 | 61 | 48  |  
   |PSTN-PSTN | 0.5%|  67 | 62 | 49 | 36  | 
   |PSTN-PSTN | 1.0%|  59 | 54 | 41 | 29  | 
   |GSM-PSTN  | 0%  |  60 | 56 | 47 | 37  | 
   |GSM-PSTN  | 0.5%|  48 | 44 | 35 | 25  |  
   |GSM-PSTN  | 1.0%|  40 | 36 | 27 | 17  | 
   +--------------------------------------+ 
    
   Table A.2 R-Value Results for Scenario 1 
 
    
   The results are presented in Table A.2. It can be seen that with 
   an intrinsic delay of around 10 msec and 0% packet loss (per 
   VoMPLS domain) then the PSTN case achieves a rating of near 80 
   which is the normal target for PSTN. The equivalent delay and PLR 
   for the GSM case achieves only 60 which is rated as poor quality 
   in the E-Model. It can be seen that any significant relaxation of 
   the intrinsic delay or PLR leads to operations with a rating of 
   less than 50 which is outside recommended planning limits. 
    
A.2.2. Scenario 2 - Analysis of VoMPLS and Typical DCME Practice 
    
   In the second scenario considered the network is simplified to a 
   single VoMPLS core network in both Japan and the USA but the DCME 
   scenario is changed to show the impact of voice activity detection 

  
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   and downspeeding. The deployment scenario is illustrated in figure 
   A-2.  
    
                               
        
                  Japan                       USA                                
               -----/\------               ---/\----       
              /             \             /         \ 
    
              POTS----|MPLS|---|DCME|----|MPLS|---POTS 
                                      
                                                                     
    
   Figure A-2: Scenario 2 - Analysis of Core VoMPLS with DCME  
    
    
   The following voice processing assumptions were used:  
        - DCME on the Japan to USA link uses voice activity detection 
        and includes the downspeeding of the G.728 coding to 12.8 
        kb/s. 
        - VoMPLS domains use G.711 with packet loss concealment. 
        - Wired phones are analogue with echo-cancellers deployed. 
    
    
   +---------------------------------------------------| 
   |                       |     | Intrinsic Delay(ms) | 
   |Connection             | PLR |  09 | 20 | 50 | 100 | 
   +---------------------------------------------------| 
   |DCME G.728 @ 16 kb/s   | 0%  |  82 | 81 | 76 | 64  |  
   |DCME G.728 @ 16 kb/s   | 0.5%|  76 | 75 | 70 | 58  | 
   |DCME G.728 @ 16 kb/s   | 1%  |  72 | 71 | 66 | 54  | 
   |DCME G.728 @ 12.8 kb/s | 0%  |  69 | 68 | 63 | 51  | 
   |DCME G.728 @ 12.8 kb/s | 0.5 |  63 | 62 | 57 | 45  | 
   |DCME G.728 @ 12.8 kb/s | 1%  |  59 | 58 | 53 | 41  |    
   +---------------------------------------------------+ 
    
   Table A.3 R-Value Results for Scenario 2 
    
   The results are presented in table A.3. It can be seen that with 
   DCME downspeeding (12.8 kb/s) an intrinsic delay of 9 ms and 0% 
   packet loss is in the low quality range. Any significant 
   relaxation would lead to poor quality or operation outside of 
   planning limits. 
    
A.2.3 Scenario 3 Analysis of GSM, VoMPLS and Typical DCME Practice 
    
   In this scenario the network is simplified to a single VoMPLS 
   domain in Australia and another in the USA and the analysis covers 
  
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   the impact of typical DCME practice. In this case only 0% packet 
   loss is considered. Three DCME cases are considered, G.711 (i.e. 
   no DCME) G.728 at 16 kb/s and G.728 with downspeeding to 12.8 
   kb/s. The DCME equipment also includes voice activity detection. 
   The deployment configuration for this scenario is shown in figure 
   A.3 and the resultant E-model results shown in figure A.4 
    
    
    
                     Australia                       USA                         
               --------/\--------                -----/\----       
              /                  \              /           \ 
    
             Mobile--|GSM|--|MPLS|-----|DCME|-----|MPLS|--POTS 
    
    
   Figure A-3: Scenario 3 - Deployment of VoMPLS Core Networks 
    
   The voice processing assumptions are as follows:  
        - MSF domains use G.711 with packet loss concealment. 
        - Wired phones are analogue with echo-cancellers deployed. 
         
   +-------------------------------------------------------------| 
   |                                 |     | Intrinsic Delay(ms) | 
   |Connection                       | PLR |  09 | 20 | 50 | 100 | 
   +-------------------------------------------------------------| 
   |G.711 no DCME,GSM User           | 0%  |  65 | 62 | 55 | 45  |  
   |G.711 no DCME,PSTN User          | 0%  |  63 | 59 | 51 | 40  | 
   |G.728 @ 16kb/s DCME, GSM User    | 0%  |  54 | 51 | 45 | 36  | 
   |G.728 @ 16kb/s DCME, PSTN User   | 0%  |  51 | 48 | 40 | 30  | 
   |G.728 @ 12.8kb/s DCME, GSM User  | 0%  |  44 | 38 | 32 | 23  | 
   |G.728 @ 12.8kb/s DCME, PSTN User | 0%  |  38 | 35 | 27 | 17  | 
   +-------------------------------------------------------------+ 
    
   Table A.4 R-Value Results for Scenario 3 
    
    
   The results of the analysis are presented in Table A.4. The GSM 
   listener receives better QoS than the PSTN listener as a result of 
   the asymmetrical operation of echo handling. Echo generated at the 
   2-4 wire conversion in the PSTN side is removed by an echo 
   canceller whereas the GSM side, being 4-wire throughout, relies on 
   the terminal coupling loss achieved by the handset itself to 
   control any acoustic echo. For this calculation a weighted 
   terminal coupling loss of 46 dB is assumed for the terminal. It 
   can be seen by inspection that it is difficult to provide 
   acceptable QoS for GSM calls on Global Reference Connections. DCME 
   is typical practice in this case. 
  
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A.2.4. VoMPLS Core Network Summary 
    
   The deployment of multiple VoMPLS islands interworking via the 
   conventional PSTN will be a natural consequence of switch 
   deployment practice. A carrier wishing to deploy VoMPLS as a PSTN 
   solution would wish to continue normal investment to cope with 
   growth and retiring obsolete equipment. This will lead to multiple 
   VoMPLS islands within a single carriers' network as well as 
   islands which arise due to calls which are routed through multiple 
   operators. It is possible to deploy equipment intelligently and to 
   plan routing to avoid excessive numbers of islands, but if 
   deployment is driven by growth and obsolescence then the 
   transition to a full VoMPLS solution will take 15 to 20 years, 
   during which time multiple islands will be the normal situation. 
   Solutions, which lead to retrofit requirements in order to solve 
   QoS problems, are very unlikely to be cost effective. Therefore to 
   enable operation with such network configurations it will be 
   necessary for each VoMPLS core network domain to be able to 
   achieve an intrinsic delay in the order of 10 ms and negligible 
   packet loss. 
    
    
A.3 Extending VoMPLS into the Access Network 
    
    
   The following scenarios analyse the impact of extending VoMPLS 
   into the access network.  
 
A.3.1 Scenario 4 - VoMPLS Access on USA to Japan  
    
   In this scenario the core network comprises 2 MPLS networks in USA 
   plus 2 MPLS networks in Japan linked by sub cable which may have 
   DCME employed.  The intrinsic delay within each core MPLS network 
   is set to 10 ms delay and zero packet loss is assumed.  The 
   encoding scheme used is G.711 throughout. Figure A.4 illustrates 
   the deployments analysed. Four cases are considered:  
    
       (A) MPLS access network each end,  full echo control, no DCME 
       (B) MPLS access network each end,  no echo control, no DCME 
       (C) MPLS access network one end; analogue PSTN other end, full 
           echo control,  DCME  @32kb/s 
    
       (D) MPLS access network one end; Analogue PSTN other end, full  
           echo control, no DCME  
    
    
  
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                Case A & B: 
    
    TE --|MPLS|---|MPLS|--|MPLS|---------|MPLS|--|MPLS|--|MPLS|--TE 
         
   Dig.  Access    Core    Core SUB-cable Core    Core   Access  Dig    
    
    
    
                Case C & D: 
    
   TE --|CO|---|MPLS|--|MPLS|-----------|MPLS|--|MPLS|--|MPLS|--TE 
    
   An   PSTN   Core    Core   SUB-cable  Core    Core   Access  Dig 
    
    
   Figure A.4 Scenario 4 - Impact of VoMPLS Access Systems 
    
    
   The results for the analysis are shown in Table A.5 which provides 
   results for various access delays (per access domain). For cases A 
   and  B the performance is symmetrical (digital terminals have 
   identical performance) whereas for cases C and D the performance 
   is slightly different at each end due to the different nominal 
   loudness ratings of the analogue and digital terminals. The 
   figures in the table refer to the listener at the analogue PSTN 
   terminal - the performance at the digital terminal is slightly 
   worse by about 5 points. 
    
    
   Table A.5 R-Values for Scenario 4 
    
   Delay - ms  |        10      20      50      100     150 
   ------------|-------------------------------------------- 
   Case (A)    |        92.8    91.9    83.9    73.4    65.9 
   Case (B)    |        80.8    77.9    67.9    54.0    44.3 
   Case (C)    |        84.1    83.0    79.4    73.4    68.3 
   Case (D)    |        93.6    93.0    90.2    84.2    75.8 
    
   The results show that if the MPLS access delay is restricted to 50 
   ms or below generally satisfactory results can be achieved for 
   most scenarios.   
    
    
    
A.3.2 Scenario 5 Deployment of GSM and VoMPLS Access  
    

  
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   In this scenario the core network comprises 2 MPLS networks in USA 
   plus 1 MPLS network and a mobile network in Australia linked by 
   sub cable which does not have DCME employed. Each core MPLS 
   network has 10 ms intrinsic delay and zero packet loss.  Encoding 
   G.711 throughout MPLS domains. Figure A.5 illustrates the 
   deployments analysed. Five cases are considered: 
    
   E - Mobile = GSM FR codec,  full echo control, no DCME 
   F - Mobile = GSM FR codec, no echo control, no DCME 
   G - Mobile = GSM EFR codec,  full echo control, no DCME 
   H - Mobile = GSM EFR codec, no echo control, no DCME 
    
    
   TE --|MPLS|---|MPLS|--|MPLS|-----------|MPLS|--|MPLS|--|GSM|--TE 
    
   Dig   Access   Core    Core  SUB-cable   Core   Core   Access  Dig 
    
   Figure A.5 Scenario 5 - VoMPLS Access with GSM 
    
    
   The results from the E-model analysis are given in Table A.6. 
    
    
   Table A.6 R-Values for Scenario 5 
 
    
   Delay - ms   |       10      20      50      100     150 
   -------------|------------------------------------------- 
   Case (E)     |       73.3    72.7    69.8    63.7    58.1 
   Case (F)     |       61.7    60.5    55.9    47.6    40.1 
   Case (G)     |       88.3    87.7    84.8    78.7    73.1 
   Case (H)     |       76.7    75.5    70.9    62.6    55.1 
    
   Again the results show that MPLS access delays should be 
   restricted to the order of 50 ms or below. The results also 
   highlight the advantage of using the GSM EFR codec over the GSM FR 
   codec and that even when working fully digital full echo control 
   provides a measurable benefit. 
    
A.3.3 VoMPLS Access Summary   
    
   The scenarios show that for VoMPLS access systems the intrinsic 
   delay should be kept to the order of 50 ms per access domain or 
   below to achieve acceptable voice quality for the majority of 
   connections. 
    
A.4 Effects of Voice Codecs in  the access network 
    
  
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   In the final scenarios the impact of deploying voice codecs within 
   the access network is considered. 
    
A.4.1 Scenario 6 - Deployment of Codecs in one Access Leg (USA - 
Japan) 
    
   Again the core network comprises 2 MPLS networks in USA plus 2 
   MPLS networks in Japan linked by sub cable which has no DCME 
   employed.  Each core MPLS network has 10 ms intrinsic delay and 
   zero packet loss.  Encoding is G.711 throughout the core network. 
   A fixed delay of 50ms and zero packet loss is assumed in the 
   access MPLS network. The configuration is illustrated in figure 
   A.6. 
    
   TE --|CO|---|MPLS|--|MPLS|-----------|MPLS|--|MPLS|--|MPLS|--TE 
    
   An   PSTN    Core    Core  SUB-cable  Core    Core   Access  Dig 
        (2ms)  (10ms)  (10ms)           (10ms)  (10ms)  (50ms) (var) 
    
    
   Figure A.6 Scenario 6 - Effects of Codecs in one Access Leg 
    
   The results for various voice codec deployments are presented in 
   Table A.7 which provides the R-values as experienced by the user 
   of the PSTN and the MPLS access system.  
    
    
    
    
    
    
   Table A.7 - R-values for Scenario 6 
    
   Connection                           |PSTN   |MPLS   | 
   ------------------------------------------------------ 
   G.711 to G.711                       | 88.9  | 84.6  | 
   G.711 to G.729A + VAD (8kb/s)        | 73.7  | 69.9  | 
   G.711 to G.723A + VAD (6.3kb/s)      | 62.4  | 58.0  | 
   G.711 to G.723A + VAD (5.3kb/s)      | 58.4  | 54.0  | 
   G.711 to GSM-FR                      | 61.7  | 57.3  | 
   G.711 to GSM-EFR                     | 76.7  | 72.3  | 
    
   The results show asymmetrical performance due to the different 
   nominal loudness ratings of the analogue and digital terminals. 
   Generally acceptable performance is attained although the 
   performance for the low bit rate G.723 coding scheme is marginal. 
   In these examples since VoMPLS access is used for one leg of the 
   connection only transcoding is performed once.   
  
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A.4.2 Scenario 7 - Codec Deployment in both Access Legs (USA - Japan) 
    
   The deployment configuration for this scenario is as scenario 6 
   with the exception that MPLS access systems are used at both ends. 
   The configuration is illustrated in figure A.7. and the resultant 
   R-values provided in Table A.8 
    
   TE --|MPLS|---|MPLS|--|MPLS|---------|MPLS|--|MPLS|--|MPLS|--TE 
    
   Dig   Access    Core    Core SUB-cable Core    Core   Access  Dig 
  (var)  (50ms)   (10ms)  (10ms)         (10ms)  (10ms)  (50ms) (var) 
    
    
   Figure A.7 Scenario 7 - Codec Deployment in Both Access Legs 
    
    
   Table A.8 R-value Results for Scenario 7 
 

   Connection                                   |R-value 
   ------------------------------------------------------ 
   G.711 to G.711                               | 83.9  | 
   G.729A+VAD to G.711 to G.729A+VAD (8.0kb/s)  | 54.2  | 
   G.729A+VAD (8.0kb/s) tandem free operation   | 68.9  | 
   G.723A+VAD to G.711 to G.723A+VAD (6.3kb/s)  | 36.2  | 
   G.723A+VAD (6.3kb/s) tandem free operation   | 58.6  | 
   GSM-FR to G.711 to GSM-FR                    | 31.7  | 
   GSM-FR tandem free operation                 | 57.2  | 
   GSM-EFR to G.711 to GSM-EFR                  | 61.7  | 
   GSM-EFR tandem free operation                | 72.2  | 
    
    
   The benefits of eliminating transcoding - tandem free operation 
   (TFO) - can be clearly seen from these results. Further it can be 
   seen that the performance attained by low bit rate G.723 is 
   extremely poor when transcoding is performed at both access 
   gateways. 
    
A.4.3 Scenario 8 Codec Deployment and Mobile Access (USA - Australia) 
    
   The core network comprises 2 MPLS networks in the USA plus 1 MPLS 
   network and a mobile network in Australia linked by sub cable 
   which does not have DCME employed.  Each core MPLS core network 
   has 10 ms intrinsic delay and zero packet loss. The access network 
   has 50ms delay and zero packet loss. Full echo control is 
   employed. For the UMTS mobile network, a delay of 60ms and an 

  
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   codec impairment factor (Ie) of 5 is assumed based on the 
   predicted performance of the GSM AMR codec. The results are 
   provided in table A.9 
    
    
   TE --|MPLS|--|MPLS|--|MPLS|---------|MPLS|--|MPLS|--|UMTS|--TE 
    
   Dig   Access   Core    Core SUB-cable Core    Core   Mobile  Dig 
  (var)  (50ms)  (10ms)  (10ms)         (10ms)  (10ms)  (60ms) (var) 
    
    
   Figure A.8 Scenario 8 - Codec Deployment and Mobile Access 
    
    
   Table A.9 - Results for Scenario 8 
    
   Connection                   | R-value 
   --------------------------------------- 
   UMTS to G.711                | 78.7 
   UMTS to G.729A via G.711     | 63.9 
   UMTS to G.723A via G.711     | 53.6 
   UMTS to GSM-EFR              | 69.3 
   UMTS to UMTS – TFO           | 76.6 
    
   Again these results highlight the significant benefit arising from 
   the use of tandem free operation. 
    
    
A.4.4 Voice Codec Summary  
    
   The scenarios in this section highlight the critical impact that 
   the voice coding scheme deployed in the access network will have 
   on the overall voice quality. For international reference 
   connections acceptable voice quality may not be attained with some 
   of the very low bit rate codecs. The benefits of avoiding 
   transcoding wherever possible can also clearly be seen. 
    
A.5 Overall Conclusions 
    
   The following key conclusions may be drawn from the study: 
    
        For VoMPLS core networks, per domain the intrinsic delay 
        should not exceed 10 ms and the packet loss should be 
        negligible.  
    
        When MPLS is extended to the access domain (in conjunction 
        with the use of digital terminals) an additional 50 ms per 
        access domain may be tolerated. 
  
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        Wherever possible codec compatibility between the end-
        terminals should be negotiated to avoid the requirement for 
        transcoding. 
    
        Where terminal compatibility cannot be achieved transcoding 
        should be limited to one function per connection. 
    
        Low bit rate G.723 coding should be avoided unless 
        transcoderless operation can be attained. 
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
    
  
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   ANNEX B - Service Requirements on VoMPLS 
 
B.1 Voice Service Requirements 
    
   This section covers generic voice service requirements. These same 
   considerations would apply in any voice network and this section 
   has nothing specific to VoMPLS. 
    
    
   Annex A provides one example of a quantitative approach to voice 
   call quality assessment. This Annex is provided for information 
   purposes only. 
    
   The call quality as perceived by the end user of the VoMPLS 
   service is influenced by a number of key factors including delay, 
   packet loss (and its impact on bit error), voice encoding scheme 
   (and associated compression rates), echo (and its control) and 
   terminal quality. It is the complex interaction of these 
   individual parameters that defines the overall speech quality 
   experienced by the user. 
    
   VoMPLS work should define one or more voice service types, the 
   most obvious ones being a voice service which is comparable to the 
   service provided by the existing PSTN or a voice service which is 
   lower quality than the existing PSTN but could be provided at a 
   lower cost. For each service type quantitative performance 
   objectives for the parameters defined in this section need to be 
   determined. 
    
    
B.1.1 Voice Encoding 
    
   The VoMPLS network should be capable of supporting a variety of 
   voice encoding schemes (and associated voice compression rates) 
   ranging from 64kb/s G.711 down to low-bit rate codecs such as 
   G.723. The applicability of an individual voice encoding algorithm 
   and associated voice compression rate is dependent on the 
   particular network deployment.  
    
   The impact of transcoding between voice encoding schemes must also 
   be considered. Not only does transcoding potentially introduce 
   delay but typically distortion as well - a key voice impairment 
   factor. Whilst transcoding is sometimes an inevitable consequence 
   of complicated networks, wherever possible it should be avoided.  
    
   Specific codec choices are network, service, use, and terminal 
   dependent.  In many cases, no compression will be used (G.711), in 
   other cases (wireless), low bit rate compression may be used.  
  
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   VoMPLS networks shall be capable of transporting traffic with a 
   variety of codecs. 
 
 
B.1.2 Control of Echo 
    
   Echo is one of the most significant impairment factors experienced 
   by the user. In traditional networks echo arises from acoustic 
   coupling in the terminal and impedance mismatches within the 
   hybrid devices that perform the 2 to 4 wire conversion (typically) 
   at the local exchange. The effect that echo has on voice-quality 
   increases non-linearly as the transmission delay increases. The 
   transmission delay consists of the processing delay in network 
   elements and the speed of light delay. 
    
B.1.2.1 Echo Control by Limiting Delay 
 
   Where the one way delay between talker and listener is below 25ms 
   then the effects of echo can be controlled to within acceptable 
   limits if the Talker Echo Loudness Rating (TELR) complies with ITU 
   G.131 Figure 1. At the limiting delay of 25ms this corresponds to 
   a TELR of 33dB, which is not attainable by normal telephone 
   terminals especially on short lines. The telephony network 
   overcomes this limitation by assuming average length subscriber 
   lines and by including 6dB of loss in the four wire path (usually 
   in the receive leg) at the local exchange. In the case of ISDN 
   subscribers using 4 wire terminals it is achieved by specifying 
   terminals with an echo return loss of greater than 40dB. If delay 
   in a VoMPLS network can be controlled, and the delay through the 
   system can be limited to 25 ms, then echo cancellation may not be 
   required in all equipment.  It is desirable, therefore, that MPLS 
   systems be capable of creating an LSP with controlled delay.   
    
B.1.2.2 Echo Control by Deploying Echo Cancellers 
    
   Where either the one way delay between talker and listener exceeds 
   25ms, or, for one way delays below 25ms, the TELR does not meet 
   the requirements of ITU G.131 figure 1, then echo cancellers 
   complying with ITU G.165/G.168 are required. 
    
   The end-to-end delay consists of the processing delays in network 
   elements and the speed of light delay. 
    
   Typically legacy TDM networks are designed so, that when it is 
   known that the origination and termination ends are close enough 
   to each other (less than 25ms delay), no echo cancellation is 
   deployed. This is the case for domestic calls in many small 
   countries and for local calls in larger countries. 
  
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   Echo cancellers are deployed as half cancellers so that each unit 
   only cancels echo in one direction. Each unit should be fitted as 
   close to the point of echo as possible in order to reduce the tail 
   length over which it must operate. The tail length is the round 
   trip delay from the echo canceller to the point of echo plus an 
   allowance for dispersion of the echo; such allowance would 
   typically be 10ms.  
    
   Echo Cancellers will typically be located in Media Gateway devices 
   under the control of a Call Agent. Call processing in the Call 
   Agent may analyze service type and accumulated delay to determine 
   if activation of echo cancellation is appropriate for the call in 
   question.  
    
B.1.2.3 Network Architecture implications 
    
   There are two main mechanisms which introduce echo in the PSTN, 
   namely the 2-wire to 4-wire hybrid at the local exchange, and, 
   with a lesser impact, the users telephone terminal. Where the PSTN 
   extends 4-wire to the users terminal, i.e. ISDN, then echo due to 
   the hybrid is eliminated, and that due to the terminal itself is 
   controlled by specifying such digital terminals to have a TELR 
   better than 40 dB. Where a 4-wire circuit taken to the customers 
   premises is converted to 2-wire so that standard terminals may be 
   used, then the hybrid has been moved from the local exchange to 
   the line terminating equipment on the users premises and the 
   situation as regards echo is essentially the same as for the 
   normal PSTN. 
    
   PSTN networks typically have rules which determine when the 
   network deploys echo cancellation equipment.  Voice over packet 
   networks typically have greater delay (due to packetization and 
   other buffering mechanisms) than the equivalent PSTN equipment.  
   Echo cancellation in packet networks which interface to the PSTN 
   may have to employ additional echo cancellation equipment to 
   compensate.     
    
   The impact of a packetised form of transport to the user would 
   depend upon whether this terminated on a 4-wire ‘audio' unit or 
   was converted to 2-wire and a standard terminal used.  
    
   If a standard terminal is used, then the hybrid in the terminating 
   equipment should be designed to produce a TELR of at least the 33 
   dB encountered in the PSTN, remembering that the 2-wire line will 
   be of very short length and that the 6dB loss which the PSTN 
   introduces to increase the TELR must be accommodated (i.e. it must 

  
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   either be present or the hybrid performance must be further 
   increased by this amount). 
    
   Termination by a 4-wire ‘audio' unit would depend upon the echo 
   performance of this unit. If it is a 4-wire terminal designed for 
   ISDN, then there should be no significant echo. (This arrangement 
   is analogous to GSM mobile networks which do not use any form of 
   echo cancellation device to protect users on the fixed network 
   from echo  even though the mobile network has added 100-150ms 
   additional delay. They do however include half echo cancellers at 
   the point of interconnect to the PSTN to protect the mobile user 
   from echo produced by the PSTN). 
    
   If however the audio unit was a speaker and microphone connected 
   to a personal computer, then the TELR is uncontrollable because 
   there is no control of the special positioning of the speakers and 
   microphone, or the acoustics of the room, and it would become 
   mandatory that provision be made locally for the control of echo 
   (as it is with loudspeaker telephones). 
    
   It should be noted that echo cancellation must be performed at a 
   TDM point, i.e. it cannot be performed within the packetised 
   domain and that there must be no suppression of silent periods in 
   the path to and from the echo canceller to the source of the echo 
   because such an arrangement produces a discontinuous echo function 
   and the echo canceller would be unable to converge. 
    
 
    
B.1.3 End-to-end Delay and Delay Variation 
    
   A key component of the overall voice quality experienced by the 
   user is the end-to-end delay. As a guideline the ITU [G.114] 
   specifies that wherever possible, the one-way transmission delay 
   for an international reference connection should be limited to 150 
   ms.  It is important to stress that the international delay budget 
   is under pressure and that the 150 ms target is already broken if, 
   for example, satellite links or cellular access systems are 
   deployed. 
    
   In a packet based network the end-to-end delay is made up of fixed 
   and variable delays; the fixed delays include packetisation delay 
   and the transmission delay whilst the variable delay is imposed by 
   statistical multiplexing (and hence queuing) at each (MPLS) 
   router. For voice and other real-time media the variable delay 
   must be filtered at the receiving terminal by an appropriate 
   jitter buffer to reconstitute the original constant rate stream. 
   Effectively this process imposes an additional connection delay 
  
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   equal to the maximum packet delay variation (i.e. this fixed delay 
   is set by the 'worst' statistical delay irrespective of its rate 
   of occurrence). 
    
   Thus packet delay variation should be minimised within the VoMPLS 
   network to minimise the overall one way delay as well as reducing 
   costs in the end-equipment by reducing the memory requirements for 
   the jitter buffer. It is desirable that the MPLS network be able 
   to create an LSP with a controlled delay variation. 
    
    
    
B.1.4 Packet Loss Ratio 
    
    
   Packet loss is a key voice impairment factor. 
    
   For voice-band connections ITU-T G.821 specifies overall 
   requirements for error performance in terms of errored seconds and 
   severely errored seconds. Under this definition, for the majority 
   of voice encoding schemes the loss of a single VoMPLS packet will 
   cause at least a single severely errored second. ITU-T G.821 
   specifies an end to end SES requirement of 1 in 10^-3 - this 
   requirement is predominately driven by the demands of voice-band 
   data (fax, modem). Speech impairment in packetized voice networks, 
   on the other hand, can be unnoticeable with fairly high packet 
   loss (as high as 5% in some cases). The relationship between SES 
   and packet loss is not well known. 
 
   In networks where it is important to pass voice, modem and/or fax 
   data without degradation, techniques such as controlling packet 
   loss may be employed. Alternatively demodulation, data pass 
   through and remodulation of fax/modem calls may be employed to 
   achieve such a goal. 
    
B.1.5 Timing Accuracy 
    
   When determining the timing accuracy for VoMPLS domains the 
   following types of traffic must be considered: speech, voice band 
   data, and circuit mode data. 
    
   All speech traffic is obtained by the equivalent of sampling the 
   analogue speech signal at a nominal 8 kHz and generating linear 
   PCM. This can be companded to 64 kbit/s in accordance with ITU-T 
   G.711, or it can be compressed to a lower bit rate either on a 
   sample-by-sample basis (e.g. ADPCM G.726/7) or on a multiple 
   sample basis to produce packets (e.g. various forms of CELP). 
    
  
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   Voice band data traffic is obtained by sampling the analogue modem 
   signal, i.e. low rate data modulated onto defined frequency 
   carrier signals, in the same way as for speech and companding to 
   64 kbit/s using G.711. Except for very low data rates compression 
   is not possible. 
    
   In all cases, provided the traffic could be carried by the VoMPLS 
   packet network directly from encoder to decoder, AND the decoder 
   could work on the sample rate determined from the received 
   traffic, then the encoder would only need to have a frequency 
   tolerance sufficient to achieve the required analogue frequency 
   response and to constrain the traffic data bandwidth; thus the 
   VoMPLS packet network would have no particular frequency tolerance 
   requirements. (Packet jitter including delay variation would still 
   have to be constrained within buffer sizes, and measures such as 
   sequence numbers would still be needed to maintain accurate 
   determination of the transmitter sample rate under circumstances 
   of packet loss.) 
    
   All legacy voice equipment, however, will have been designed 
   assuming a synchronous TDM network; so decoders may typically be 
   designed to use a sample rate derived from the locally available 
   network clock. Furthermore, the packet network will have to 
   interwork for the foreseeable future with the existing synchronous 
   TDM network. The principle characteristic of this existing network 
   is that all basic rate 64 kbit/s signals are timed by the network 
   clock, and thus multiplexing into primary rate signals E1, DS1, or 
   J2 has been defined in ITU-T G.704 to be SYNCHRONOUS. The 
   interface to the interworking equipment will in general be the in-
   station form of these primary rate signals or possibly the primary 
   rate signals multiplexed into PDH or SDH higher order multiplex 
   signals. 
    
   Primary rate signals must be within the tolerances defined in ITU-
   T G.703, e.g. +/-50ppm for E1, to permit them to be carried in the 
   PDH or SDH transport networks. These tolerances allow transport 
   networks to carry primary rate signals from different networks 
   timed by different network clocks, e.g. private networks as well 
   as public networks between which there my be little or no service 
   interworking. The result of interworking between networks at the 
   extremes of these tolerances is frequent slips in which octets of 
   each basic rate 64 kbit/s channel are dropped or alternatively 
   repeated to compensate for the rate difference. 
    
   For example the consequences of 50ppm offset = 1 slip every 2.5 
   seconds are: 
    

  
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        -0- G.711 speech - loss/gain of 1 sample, a barely audible 
        click, 
         
        -0- G.726/727 ADPCM - as for G.711 speech, 
         
        -0- for packet based speech codecs G.723, 728, 729 - packet 
        error, i.e.  multiple sample loss, more annoying click; 
    
        -0- voice band data - a slip produces a 125 us phase shift 
        for modems up to 2.4 kbit/s - probably tolerated without 
        error for modems above 2.4 kbit/s - error burst each slip 
        probably leading to loss of synchronization and resultant 
        retraining: result is intermittent transmission, down 
        speeding if possible, or complete failure; 
    
        -0- circuit mode data - packet loss ratio dependent of client 
        layer packet size, e.g. 1 in 20 for packet size of 1000 
        bytes. 
    
   To permit satisfactory interworking without the above impairments, 
   the slip rate should be constrained within the limits set out in 
   ITU-T G.822. This could be possible by timing the packet network 
   interworking equipment in the same way as existing synchronous TDM 
   network equipment, that is in a synchronization network where 
   timing is traceable to a primary reference clock (PRC) of which 
   the accuracy is in accordance with ITU-T G.811. 
    
   Within the same synchronization domain, where all equipment 
   derives its timing from the same PRC, except under fault 
   conditions the slip rate will be zero. When traversing boundaries 
   between domains of different PRCs the operation will be 
   plesiochronous: the accuracy of 10exp-11 of each PRC will ensure 
   the slip rate is within the normal limit in G.822 of 1 slip per 
   5.8 days over a 27000 km hypothetical reference link consisting of 
   13 nodes. 
    
   Some MPLS networks may not be designed to achieve synchronous 
   timing, and thus slip buffers are required in such networks, and 
   compression choices may be influenced by the lack of 
   synchronization in the network. 
    
B.1.6 Grade-of-service 
    
   In traditional circuit switched networks a clear distinction can 
   be drawn between Grade of Service and Quality of Service. Grade of 
   Service defines blocking probabilities for new connections (and 
   behaviour rules under network overload conditions) so that a 
   network can be dimensioned to achieve an expected behaviour. 
  
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   Quality of Service defines the voice intelligibility requirements 
   for established connections; namely delay (and jitter), error 
   rates, and voice call defects. It is important that both GoS and 
   QoS are addressed equally when determining the architectural 
   framework for VoMPLS networks. 
    
   Much of the work so far undertaken on traffic engineering within 
   IP networks has focussed on the development of QoS mechanisms. 
   Whilst such mechanisms will ensure the intelligibility of 
   established voice connections without an equivalent GoS framework 
   no guarantees can be made to the blocking rate experienced during 
   busy network periods. At the limit this may severely impact users' 
   future willingness to use the network.  
    
   Equally if one merely dimensions the network according to GoS 
   requirements without providing explicit QoS mechanisms then any 
   QoS 'guarantees' are only probabilistic and there remains the 
   possibility of significant packet loss rate at localised 
   congestion points within the network. In a statistically 
   multiplexed network when such congestion occurs it will typically 
   impact other connections traversing the congested routers and is 
   not simply confined to those additional connections that caused 
   the overload condition. 
 
   Generally GoS is defined on a per service basis either through 
   international specification or via peer agreements between network 
   operators.  
    
   Packet networks differ from the PSTN however in that they are 
   designed to support multiple services. It is a requirement that 
   per-service GoS can be provided despite the diverse traffic 
   characteristics of (potentially competing) multiple alternate 
   services. This implies that the network operator may need to be 
   able to isolate (or control the allocation of) key resources 
   within the network on a per-service basis. For example an operator 
   could use multiple LSPs between two points in order to enable 
   trunk provisioning and per-service dimensioning.  
    
B.1.7   Quality considerations pertaining to Session Management 
    
   There are a number of additional quality factors that users take 
   for granted in today's circuit switched network. It is reasonable 
   to anticipate that similar requirements should be placed onto some  
   VoMPLS networks so that from a service perspective equivalent 
   performance is maintained, where that is deemed necessary. These 
   factors include: 
    
     Session Setup Delay (sometimes referred to as "post dial delay") 
  
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     Session Availability - This refers to the ability (or in-
     ability) of the network to establish sessions due to outage 
     events (nodal, sub-network or network). 
    
     Session Defects - This refers to defects that occur to 
     individual (or groups) of sessions. The defects may be caused by 
     transient errors occurring within the network or may be due to 
     architectural defects. Examples of session defects include: 
        - misrouted sessions 
        - dropped sessions 
        - failure to maintain adequate billing records 
        - alerting the end-user prior to establishing a connection 
        and  then not being able to establish a connection  
        - clipping the initial conversation (defined by the post 
        pickup delay) 
        - enabling theft of service by other users  
 
 
B.2 Circuit Emulation Service Requirements 
 
   This section covers generic circuit emulation service 
   requirements. These same considerations would apply in any packet 
   network and this section has nothing specific to VoMPLS. 
    
B.2.1 General Requirements 
 
   The objective of circuit emulation is to carry a constant bit rate 
   traffic signal between originating and destination points without 
   loss or modification whatever the content of the signal. In 
   general nothing would be known about the content other than the 
   bit rate, its timing, and possibly the phase of an 8 kHz frame 
   boundary. This capability shall be optional. 
    
B.2.1.1 Signals for circuit emulation 
    
   Circuits to be emulated consist of those capable of carrying the 
   signals listed below. 
    
     - Basic rate 64 kbit/s with 8 kHz (octet) structure; 
      
     - basic rate 64 kbit/s with 8 kHz (octet) structure plus channel 
     associated signaling (CAS) bit channels ABCD E1 - 4x500 bit/s,  
      
     - DS1 4x333 bit/s, J2 1x1000 bit/s (A only); 
     multiple basic rate  Px64 kbit/s with 8 kHz frame structure,  
     where P=2-30, e.g. P= 2, 6, 24, or 30 in ITU-T I.231 (128 
     kbit/s, H0 - 384 kbit/s, H11 - 1536 kbit/s, H12 - 1920 kbit/s). 
  
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   Primary rate signals, optionally with transmission frequency 
   tolerance: 
    
      - DS1, 1544 kbit/s (+/-32ppm),  
      - E1, 2048 kbit/s (+/-50ppm),  
      - J2, 6312 kbit/s (+/-30ppm), 
    
   Higher order PDH signals, with transmission frequency tolerance: 
    
      - E3, 34368 kbit/s (+/-20ppm),  
      - DS3, 44736 kbit/s (+/-20ppm),  
      - E4, 139264 kbit/s (+/-15ppm)? 
    
   Consideration might be given to SDH signals. 
    
   SDH carriers, with transmission frequency tolerance: 
    
      - STM-0, 51840 kbit/s (+/-20ppm), 
      - STM-1, 155520 kbit/s (+/-20ppm). 
    
   SDH Virtual Containers, with 2 kHz multiframe or 8 kHz frame 
   structure, and frequency offset indicated by associated AU-n or 
   TU-n pointer movements: 
    
      - VC-11, 104 octets per 4-frame multiframe,  
      - VC-12, 140 octets per 4-frame multiframe,  
      - VC-2, 428 octets per 4-frame multiframe,  
      - VC-3, 765 octets per frame,  
      - VC-4, 2349 octets per frame. 
 
B.2.1.2 Timing 
    
   There are two options for timing, asynchronous and synchronous. 
   Since the packet network is intrinsically asynchronous it should 
   always be possible to transmit traffic data from the TDM domain 
   over the packet network at whatever bit rate it arrives at. It is 
   at the destination interworking function that the choice of timing 
   option affects what timing functions are used. 
    
   Synchronous timing assumes that the signal at the originating 
   point is timed by the network clock. At the destination end the 
   clock is not recovered as such: the outgoing signal is timed by 
   the local network clock. Any discrepancy between this and the 
   clock at the originating end is compensated for by introducing 8 
   kHz frame slips, i.e. loss or gain of 125 us of traffic on each 
   channel, as necessary. 
  
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   With asynchronous timing the signals are assumed only to be within 
   the relevant standard transmission frequency tolerance. At the 
   destination end a clock recovery function determines the clock 
   rate from the arriving packet stream. Every bit received is 
   forwarded to the outgoing signal - no slips are introduced. The 
   clock rate may be recovered directly from the information rate in 
   the packet stream (this is typically related to packet rate for 
   constant packet size), termed adaptive clock recovery (ACR). 
   Alternatively, supplementary information may be carried, e.g. time 
   stamps, for use in conjunction with the local network clock. The 
   latter option should provide better control of jitter and wander; 
   however, the overriding principle is that every bit is forwarded 
   (no slips), and so ACR may have to be invoked on occasion in 
   circumstances of plesiochronously operating originating and 
   destination network clocks. 
 
B.2.1.3 Applicability of Timing Options 
    
   For basic rate 64 kbit/s and Px64 kbit/s circuits only synchronous 
   operation is applicable.  
    
   For primary rate signals which carry 64 kbit/s channels in an 8 
   kHz frame structure synchronous or asynchronous operation is 
   possible depending on the source timing.  
    
   Signals at primary rate, however, may alternatively have 
   asynchronous data within the 8 kHz frame structure (e.g. ATM on 
   PDH in G.804) or may be carrying traffic without 8 kHz framing at 
   all. In such applications any slips associated with synchronous 
   operation that were needed to compensate for timing frequency 
   offsets would cause an arbitrary loss or insertion of 125 us of 
   data bits. This would result in a resynchronization procedure 
   downstream; that is to say a much greater disturbance than to a 
   G.711 speech channel.  
    
   In TDM networks such primary rate circuits would be routed only as 
   asynchronous traffic in the transport network (PDH or SDH) and 
   therefore would never be subject to slips. (For paths within the 
   same timing domain slips would not normally occur. However, under 
   fault conditions of the synchronization network the slip rate 
   could be very much greater than that with normal operation between 
   domains with plesiochronous PRCs.) Hence in these applications of 
   primary rate circuits asynchronous clock recovery in the 
   interworking function is preferable to synchronous operation, even 
   if the originating signal timing were known to be network clock 
   derived. The default timing option for primary rate signals in 
   general should therefore be asynchronous operation. 
  
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   For emulation of higher order PDH circuits, these signals contain 
   asynchronously multiplexed data and typically have framing which 
   is not at 8 kHz. Slips that could be necessary with synchronous 
   operation will similarly result in resynchronization downstream 
   but in this case typically at more than one hierarchical level. 
   Hence asynchronous clock recovery in the interworking function is 
   preferable to synchronous operation, even if the originating 
   signal timing were known to be network clock derived. 
    
   Higher order PDH signals are typically timed by free running 
   oscillators: in this case asynchronous operation at the 
   interworking function is essential.  
    
   SDH carriers, while having 8 kHz framing also have data which is 
   effectively asynchronously multiplexed by the use of pointers. 
   Slips could result in pointer errors. Hence asynchronous clock 
   recovery in the interworking function is again preferable. 
    
   Similarly, for SDH virtual containers their timing should be 
   transferred transparently at the destination by regenerating 
   pointer movements in the relevant AU-n or TU-n pointer. 
    
    
B.2.2  QoS Requirements for Circuit Emulation 
    
B.2.2.1 Jitter and Wander 
    
   Timing recovery with asynchronous operation should achieve control 
   of jitter and wander to within the limits for hierarchical 
   interfaces set out in ITU-T G.823 for the ETSI PDH hierarchy 
   signals, Telcordia GR-499/GR-1244/GR-253 for ANSI PDH hierarchy or 
   SONET signals, and G.825 for SDH signals. These limits are set to 
   prevent slips occurring at primary rate interfaces due to jitter 
   and wander.  
    
   NB it unlikely to be possible to meet these limits (for wander) 
   using purely ACR in the presence of likely packet delay variation 
   (PDV). For this reason circuit emulation over a packet network 
   cannot be used to carry a circuit which is itself used to convey 
   network timing. To avoid the problems of pure ACR an asynchronous 
   clock recovery mechanism might be explored for MPLS which would 
   have equivalent performance to the synchronous residual time stamp 
   (SRTS) in ATM. 
    
   In principle the requirements for jitter transfer function set out 
   in the various recommendations for PDH multiplexers and in G.958 
   for SDH regenerators would be applicable across the packet 
  
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   network; in practice, any jitter input from the TDM domain will be 
   swamped by the effect of PDV, and hence the jitter reducers used 
   to filter out PDV to meet G.823/4/5 will certainly be well within 
   such jitter transfer function requirements. 
    
B.2.2.2 Delay 
    
   The delay for the emulated circuit needs be within the budget for 
   overall delay requirement for the service being carried. 
    
B.2.2.3 Error Performance 
    
   For basic rate 64 kbit/s and Px64 kbit/s circuits the 
   specifications in ITU-T G.821 apply. 
    
   For circuits at or above primary rate the specifications in ITU-T 
   G.826 apply. 
    
    
    
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