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14.1.1.1 Enhanced GPRS
EGPRS shall provide a range of bearer capabilities that depend upon the environment and user’s speed. The peak rate shall at least be: EGPRS Indoor/Low range outdoor Urban/Suburban outdoor Rural outdoor EGPRS 384 kbps (48 kbps/timeslot) 384 kbps (48 kbps/timeslot) 144 kbps (18kbps/timeslot) Speed up to 10 km/h up to 100 km/h up to 250 km/h Propagation conditions Indoor, TU3 TU50 HT100 850/900MHz: RA250 1800/1900MHz: RA130 HT100
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14.1.1.2 Enhanced CSD
ECSD shall provide a range of bearer capabilities (per time slot) that depend upon the environment and user’s speed. The peak rates should at least be: ECSD/T Indoor/Low range outdoor Urban/Suburban outdoor Rural outdoor ECSD/T 32 kbps/timeslot *) 32 kbps/timeslot *) - Speed up to 10 km/h up to 100 km/h - Propagation conditions Indoor, TU3 TU50, HT100 - ECSD/NT Indoor/Low range outdoor Urban/Suburban outdoor Rural outdoor ECSD/T 28.8 kbps/timeslot *) 28.8 kbps/timeslot *) - Speed up to 10 km/h up to 100 km/h - Propagation conditions Indoor, TU3 TU50, HT100 - *)The data rates are not defined yet by SMG2/4 and giving a rough indication The maximum transfer delay including channel coding and decoding for ECSD/T shall be the same as for CSD/T. Due to the current limitations of the core network, transmission of circuit switched data shall be limited to 64 kbps per user.
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14.1.2 Bearer service attributes
The same bearer service attributes used for GPRS and CSD should be used for EGPRS and ECSD. Some new bearer service parameters relevant to the radio interface may be needed. For EGPRS the same QoS classes should apply.
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14.1.3 Hand over/cell re-selection
The same hand over/cell re-selection mechanisms as for CSD/GPRS apply. Re-selection methods should allow the operator to optimise the service availability for EDGE users. Seamless transition ECSD-> CSD -> ECSD and EGPRS classic->GPRS -> EGPRS classic. Seamless transition from EGPRS Classic->EGPRS Compact->EGPRS Classic is possible when the Classic and Compact systems are time-synchronised. EGPRS Compact mobile stations shall be able to re-select to a neighboring synchronized EGPRS Classic cell, and vice-versa. Re-selection between EGPRS Classic and EGPRS Compact at different frequency bands is desirable. EDGE shall allow multi-band operation, i.e 850/900/1800/1900 MHz including E- and R-band. Hand over should be supported for GSM850/900/1800/1900 and between GSM850/900/1800/1900. 14.1.4 Mobile Stations EGPRS Compact mobile stations shall support EGPRS Classic. UWCC operators require that EGPRS-Capable handsets shall support operation at both 850 and 1900 MHz, and shall support both EGPRS Classic and EGPRS Compact. 14.1.5 Link adaptation Link adaptation should be provided to adapt the modulation and coding scheme to the radio channel conditions. This includes a reconfiguration of time slots (i.e. transparent 28.8kbps -> 2x14.4kbps) as well as fall-back to GMSK. Measurements should be provided for efficient link adaptation for services and applications provided by EDGE.
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14.2 Operational requirements
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14.2.1 Compatibility with services provided by present core networks
EDGE will enhance the GPRS and CSD service by providing higher data rates. That means, that EDGE will rely on underlying GSM functionality.
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14.2.2 Operating environments
The operational scenario for EDGE includes international operation across various EDGE radio operating environments (850/900/1800/1900 MHz bands). Further, EDGE will support a variety of services with a range of bit rates.
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14.2.3 Radio Access network planning
EDGE should not require a modification of actual frequency/coverage planning defined for GSM air interface when introduced. Frequency/coverage re-planning may be used to maximise the throughput in the system. An EDGE network shall support at least 4/12, 3/9 and 1/3 frequency reuse patterns. EGPRS Compact shall support at least 1/3 frequency re-use.
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14.2.4 Operators
All GSM900/1800/1900 operators should be able to deploy EDGE without licensing problems.
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14.3 Efficient spectrum usage
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14.3.1 Spectral Efficiency
The spectral efficiency of EDGE should be significantly higher than in GSM. The radio interface should be designed to maximise spectral efficiency. EGPRS Compact shall be possible to implement in less than 1 MHz initial spectrum.
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14.3.2 Spectrum utilisation
It should be possible to use EDGE in all GSM bands. It should be possible to mix EDGE and non EDGE timeslots on the same carrier. If simultaneous EDGE and non EDGE operation in the same time slot is required or not is for further investigation. If EDGE is used on the BCCH carrier, it should not have any impact on BCCH power measurements.
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14.3.3 Coverage/capacity
The peak service rates may be provided only in a limited coverage area. Link adaptation shall provide a mechanism to have a smooth degradation of the service rates for the outer cell areas. EDGE should be designed to maximise the area where high data rates can be achieved. SMG2 should define appropriate evaluation criteria. The throughput should be at least 384 kbps over 25% of the cell in both coverage and interference limited systems, with the simulation assumptions as described in the EDGE Feasibility Study”. EDGE should be flexible to support a variety of initial coverage/capacity configurations, e.g. cell by cell deployment, and facilitate coverage/capacity evolution. EGPRS Compact shall support more than one carrier in a given sector. EGPRS Compact shall be able to grow non-uniformly, such that sectors may have a different number of EGPRS Compact carriers.
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14.3.4 Evolution requirements
With EDGE several 3rd generation services can be provided in GSM. The technical parameters for EDGE should allow an evolution for coverage and capacity, as well as provisioning of future 3rd generation services.
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14.3.4.1 Coverage evolution
The radio coverage for the EDGE may be: - contiguous coverage; - island coverage; - spot coverage. EDGE should be sufficiently flexible to support a variety of initial coverage configurations and facilitate coverage evolution. Coverage can be increased by deploying cell planning parameters optimised for EDGE usage and/or techniques like e.g. adaptive antennas, advanced power control, efficient resource allocation etc.
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14.3.4.2 Capacity evolution
EDGE should facilitate the implementation and use of appropriate capacity improvement techniques, if applicable, in the various radio operating environments. EDGE should not prevent capacity improvements, e.g. adaptive antennas, advanced power control, efficient resource allocation etc. It is desirable that the EDGE does not depend on the implementation of these techniques, but that they are capacity improvement options. It is desirable that they do not significantly add complexity or cost to the infrastructure or MSs.
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14.4 Complexity / Cost
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14.4.1 Mobile complexity and cost
Hand portable and PCMCIA card sized EDGE terminals should be optimised in terms of size, weight, operating time, range, effective radiated power and cost/performance ratio.
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14.4.2 Network complexity and cost
The cost/performance ratio of development and equipment should be kept at a reasonable level.
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14.4.3 Mobile Station / Base Station types
The EDGE standard should support multislot operation for ECSD and EGPRS. It should be possible to provide a variety of Mobile Station as well as Base Station types of varying complexity, cost and capabilities in order to satisfy the needs of different types of users. The number of mobile classes should though be minimised. (The number and classes are for further study).
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14.5 Requirements from bodies outside SMG
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14.5.1 Electromagnetic compatibility
The modulation characteristics have to be such that the degree of interference caused to other equipment is not higher than in today's systems.
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14.5.2 RF Radiation effects
EDGE shall be operative at RF emission power levels which are in line with the recommendations related to electromagnetic radiation.
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14.5.3 Security
The EDGE radio interface should be able to accommodate at least the same level of security as the GSM radio interface does.
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14.6 Co-existence with other systems
A GSM system with EDGE should be capable to co-exist with a GSM system without EDGE deployment within the same or neighbouring band as well on neighbouring time slots. Furthermore should the performance of GSM channels without EDGE not be worsened by the fact that the neighbouring channel is a GSM channel with EDGE and vice versa. A GSM or ANSI-136 system with EGPRS Compact should be able to co-exist with a GSM or ANSI-136 system without EGPRS Compact deployed within the same or neighbouring band.
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14.7 Further Work Areas
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14.7.1 Services coordination
Possibility to have same or similar services in EDGE as in UMTS needs to be investigated. Investigation of hand-over between GSM and UMTS is necessary.
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14.7.3 Measurements in existing GSM
It should be studied if there is a need to modify existing measurements for EDGE or other work items. History Document history 16th February 1998 First draft 20th February 1998 Update after Joint SMG1,2,3 & 4 EDGE workshop in Helsinki 27th April 1998 Update after SMG1 and SMG2 WPB#4 25th May 1998 Update after SMG4 and EDGE SMG2 working session 27th May 1998 Update after smg2 #26 decision, V1.0.0 3rd July 1998 Update after SMG4 workshop , V1.1.0 7th August 1998 Update after SMG1 plenary, V1.2.0 28th August 1998 Update after SMG2 EDGE workshop and SMG3WPA, V1.3.0, removal of open questions. expanded concept section 12th of October 1998 Update after SMG2WPA and SMG2 WPB, V1.4.0 2nd of November 1998 Update after EDGE WS, V1.5.0 2nd of December 1998 Update for EDGE WS #6, V1.6.0 14th December 1998 Update for SMG 7, V1.7.0 7th of January 1999 Update for SMG2 WPB, V1.8.0 25th of January 1999 Update for SMG2 plenary, V1.9.0 4th February 1999 Update for SMG plenary, V1.10.0 2nd March 1999 Update for SMG2 EDGE WS #7, V1.11.0 12th March 1999 Update for SMG2 #30, V1.12.0 31st May 1999 Updated for SMG2 #31, V1.13.0 18th June 1999 Updated for SMG EDGE WS #9, V1.14.0 24th August 1999 Updated for SMG EDGE WS #10, V1.15.0 19th September 1999 CR list for EDGE compact included, updated for SMG2 #32, V1.16.0 22th September 1999 COMPACT requirements included, V1.17.0 14th October 1999 Update with results from SMG2#32, V1.18.0 22th November 1999 Updated with results from workshop and other STCs, V1.19.0 10th January 2000 Updated with results from workshop and SMG #30bis, V1.20.0 23rd February 2000 Updated with the results from SMG2 and SMG#31, V1.21.0 2nd April 2000 Updated with results from EDGE WS #13, V1.22.0 22nd May 2000 Updated with results from SMG #31bis, V1.23.0 June 2000 Approved at SMG#32 Plenary Rapporteur EDGE BSS: Frank Mueller, Ericsson Email: Frank.Muller@era.ericsson.se Tel: +46-8-7570287 Fax:+46-8-7575550 Rapporteur EDGE NSS: Tommi Kokkola, Nokia Email: tommi.kokkola@ntc.nokia.com Tel: +358-9-511 38358 Fax:+358-40-504 0734 Rapporteur GPRS 136 HS EDGE: Tommi Ljunggren, AT&T Email: tommy.ljunggren@northstream.se Tel: +46 8 754 0001 Fax: +46 8 754 0002
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1 Scope
The purpose of this Technical Report is to study the feasibility of a core network CAMEL server controlling voice services carried by VoIP within a GPRS PDP Context using: 1) An architecture based on ITU-T, H.323 family of recommendations. 2) An architecture based on IETF SIP specifications.
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2 References
The following documents contain provisions, which through reference in this text, constitute provisions of the present document. - References are either specific (identified by date of publication, edition number, version number, etc.) or non‑specific. - For a specific reference, subsequent revisions do not apply. - For a non-specific reference, the latest version applies. - A non-specific reference to an ETS shall also be taken to refer to later versions published as an EN with the same number. [1] IETF RFC 1889, A Transport Protocol for Real-Time Applications. [2] ITU-T Q.931, Digital Subscriber Signalling System No. 1 (DSS 1) – ISDN User-Network Interface Layer 3 Specification For Basic Call Control. [3] GSM 04.08 [4] IETF RFC 2543, SIP: Session Initiation Protocol. [5] N2-99826, “Feasibility Technical Report on CAMEL control of VoIP Services”, 19th-23rd July 1999, Visby, Sweden. [6] “Location of the SSF entity in GPRS network supporting real-time applications”, Contribution from Lucent Technologies circulated to supporters of CAMEL control over VOIP on 26th July 1999. [7] S2-99528, “The inclusion of a ‘Service Switching Function’ in the reference multimedia architecture for the support IN based service features”, 26th – 20th July 1999, New Jersey, USA [8] Tdoc65, “Comments to DTR 02004, concerning IP, fixed wireless and cellular mobile roaming scenarios and the conceptual IP cellular network model”, Motorola, ETSI TIPHON Tel Aviv 26-30th October 1998. [9] TS 101 441 Vx.4.0 Draft A, GSM 03.78, CAMEL Phase 3, stage 2 [10] N2-99826, “Feasibility Technical Report on CAMEL control over VoIP Services”, 19th-23rd July 1999, Visby, Sweden. [11] TS 101 441 Vx.4.0 Draft A, GSM 03.78, CAMEL Phase 3, stage 2. [12] ETSI TIPHON 10, Temporary Document 65, Tel Aviv, 26-30 Oct.1998
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3 Introduction
The GSM CAMEL feature for control of operator specific services when roaming has evolved over a number of years and work on the latest Phase (Phase 3) is planned for completion as part of Release '99. Work in other 3GPP groups, particularly S2, is focused on developing a reference architecture for an all IP PLMN. One of the many requirements for 3G is to support roaming between 2G and 3G networks. Another requirement is to support a minimum set of 2G standardised supplementary services for roamers, such as call forwarding. The all IP PLMN is based on an evolved GPRS that supports voice over IP (VoIP). VoIP calls may be established between 3G terminals or between a 3G terminal and legacy network terminal, such as 2G mobile, ISDN or PSTN. In the IP world there are currently two solutions that support VoIP; the H.323 family of recommendations defined by the ITU, and the Session Initiation Protocol (SIP) defined by the Internet Engineering Task Force (IETF). This Technical Report introduces these solutions and examines the feasibility of CAMEL controlling VoIP services in an all IP network with a view to supporting some 2G Supplementary Services and operator specific services or similar. Thus it is envisaged that CAMEL service control may be employed across 2G and 3G networks providing consistent services when roaming. The information in the report is introduced below: Section 5: briefly describes the proposal and functional model. Section 6: addresses services that may be employed across 2G and 3G. Section 7: describes the H.323 solution, architecture, message flows, state models, impact on standards, impact on services, multimedia evolution, advantages and disadvantages. Section 8: describes the SIP solution, message flows, state models, impact on standards, impact on services, multimedia evolution, advantages and disadvantages. Section 9: introduces work in other standards groups covering similar or related issues. Section 10: records questions and answers from CN2a meeting presentations of earlier drafts Section 11: describes conclusions and recommendations.
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4 Definitions and Abbreviations
BCSM Basic Call State Model CAMEL Customised Application for Mobile networks Enhanced Logic CAP CAMEL Application Protocol CSI CAMEL Subscriber Information GGSN Gateway GPRS Support Node GPRS General Packet Radio Service HLR Home Location Register IPSSF Internet Protocol Service Switching Function MAP Mobile Application Part MSC Mobile Switching Centre MO Mobile Originating MS Mobile Station MT Mobile Terminating O-CSI Originating CSI PDP Packet Data Protocol SGSN Serving GPRS Support Node SIP Session Initiation Protocol SS-CSI Supplementary Service CSI T-CSI Terminating CSI VLR Visitor Location Register
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5 Proposition
An overall objective for this feasibility study is to demonstrate that CAMEL control of VoIP services in 3G networks can be readily specified and implemented by adapting standards and software used in 2G networks. This approach leads to services that function the same when a user roams between 2G and 3G networks, simplifies service evolution from 2G to 3G, and leads to more rapid implementation. Figure 1: Functional Model for CAMEL Control of VoIP Services Figure 1 illustrates the proposed functional model of the core network. It is derived from existing CAMEL specifications and 3GPP 23.121. In the latter technical specification, the Gatekeeper/SIP Proxy Server has been placed on the Gi interface to allow the Internet call control signalling to be transparent to the GPRS nodes, (SGSN and GGSN). Furthermore, if the signalling were to be non-transparent, and the SGSN were to handle the VoIP call control, the existing GPRS procedures, including the current CAMEL Phase 3 work would require changes. The reason is that if a subscriber roams outside the area served by the SGSN, the relationship between the gsmSCF and the SGSN in the old location is terminated and a new dialogue between the SGSN in the new location area and the gsmSCF is established. Such an approach would not allow existing CAMEL services to be re-used without substantial changes, unless techniques such as anchoring original SGSN are introduced. The functions represented in the model are: HLR: Release ’99 or later HLR gsmSCF: Release ’99 or later CAMEL Service Control Function (gsmSCF) gsmSSF: Release ’99 or later Service Switching Function MSC Emulator and VLR: Modified Release ’99 GMSC, VMSC and VLR functions. Many processes, such as call control, database and billing are retained or enhanced. Circuit switching and ancillary processes are removed. H.323 or SIP server inter-working functions are added. This combination of functionality is referred to in this report as the 'IPSSF'. The interface between the H.323 Gatekeeper/SIP Server and the 'IPSSF' call control processes must: 1 Carry sufficient call data for the gsmSSF to function correctly and to deliver the necessary information to the gsmSCF so that service logic decisions can be made. 2 Allow the gsmSCF (in combination with gsmSSF and MSC Emulator) to control VoIP calls (e.g. change ‘B’ party address) and manipulate call information (such as presentation number) similar to a GSM Release ’99 GMSC or VMSC. H.323 Gatekeeper/SIP Proxy Server: – Either a H.323 Gatekeeper or a SIP Proxy server. Gateway: - Provides interworking between packet network and external circuit switched networks such as PSTN or ISDN. GGSN: – Release '99 or later Gateway GPRS Support Node Notes: Mobile Terminated (MT) Speech Calls: MT VoIP call states are modelled using a CAMEL Phase 3 or later T_BCSM as used for circuit switched MT calls. Mobile Originated (MT) Speech Calls: MO VoIP call states are modelled using a CAMEL Phase 3 or later O_BCSM as for circuit switched MO calls. Physical Location: The H.323 Gatekeeper/SIP Server and 'IPSSF' may be located in a home network or a visited network as both MAP signalling and CAP signalling are standardised for international use. Physical Realisation: From the control of VoIP viewpoint the IPSSF and the H.323 Gatekeeper/SIP Server may be combined in one network entity or may be separate in separate network entities. If they are separate, standardisation of the interface may be required. IP PDU Routing: Routing of IP call control packets to/from the H.323 Gatekeeper/SIP Proxy Server is not fully addressed in this work. It is simply assumed that appropriate addressing and routing takes place.
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5.1 Relationship with Architecture work in S2
Ongoing architecture work in S2 for 3G is documented in TS 23.121 and in the Technical Report on 'Architecture for an all IP network' (TR 23.922 V1.0.0). The work in this CAMEL control of VoIP services FTR is intended to aid/complement S2 work by analysing feasibility at a somewhat lower level of abstraction, focusing on functional/protocol capabilities. The IPSSF in the functional model described above may form part of a Service Capability Server (SCS) in the Multimedia architecture PS Domain' described in TS 23.121. Similarly, it may form part of the Call State Control Function (CSCF) described in the all IP TR. The exact mapping between the Functional Model used in this report and the architectures developed by S2 requires further study and is work probably most appropriate to S2.
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6 Service Requirements
In 3GPP, SA1 has responsibility for the definition of service requirements. Requirements for Release '00 are at a very early stage of development. When considering feasibility it is very useful to have in mind the services that a 3G network may be required to support. This section lists many example 2G network voice services that may be required by 3G VoIP customers, including some new 3G network possibilities, such as ‘high quality audio’. Other services are being considered but not included here because the focus of this report is mainly on how existing 2G services may be support on an IP only network. Many of the services listed below are not supported by H.323 or SIP. They may be supported in the future. Services that early implementations may be required to support are show in italics. Detailed study is necessary to identify the services that require CAMEL control as it may be possible to re-use the VLR and MSC Emulator capabilities for some services without the need for CAMEL control, such as Operator Determined Barring. Some services may be more appropriate to implementation in the Terminal not the network, such as Call Hold.
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6.1 Basic Services
Example basic services that may require CAMEL control in a 3G network: - Speech - Emergency calls - Low bit rate data - Medium bit rate data - High bit rate data - High quality audio - Low bandwidth video - High bandwidth video
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6.2 Supplementary Services
Example 2G supplementary services that may require CAMEL control in a 3G network: - Operator determined barring - User defined barring - Call screening - Call deflection - Call forwarding unconditional - Call forwarding on busy, no reply and not reachable - Call waiting - Call hold - Call transfer - Calling number identification presentation/restriction - Connected number identification presentation/restriction - Multiple Subscriber Profile - Multi-party - Call Completion Services (e.g. CCBS) - Closed user group - Advise of charge - Calling name presentation
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6.3 Operator Specific Services
Example 2G operator specific services that may require CAMEL control in a 3G network: - Short number dialling - Prepay - VPN
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6.4 Other Services
Example services not listed in the ‘Basic Services’, ‘Supplementary Services’ or ‘Operator Specific Services categories that may require CAMEL control in a 3G network: - Lawful interception - Voice group-call service - Voice broadcast service - SMS - Fax - ASCI - MExE - Location Services - SoLSA
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7 H.323 Solution
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7.1 Description
ITU-T defines a family of recommendations known as H.323 for multimedia communications over packet based networks. The majority of VoIP products available today support H.323. Figure 2: H.323 Environment The H.323 environment is illustrated in Figure 2. A 'terminal' is a network endpoint that provides real-time, voice or multimedia communications with another Terminal or a Gateway. A Gateway is a network endpoint that provides the necessary translation services to allow H.323 terminals to communicate with terminals on other networks, such as the ISDN. A Gatekeeper is a network entity that provides address translation and access control. It may also provide bandwidth management. Gatekeepers are optional. A Multipoint Control Unit (MCU) is a network endpoint that provides the capability for VoIP conference calls. All terminals participating in a conference establish a connection with the MCU. It manages resources and negotiates between terminals to determine which video and audio codec to use. Figure 3: H.323 Protocol Architecture Figure 4: H.323 Protocol Summary Figure 5: Simple Example H.225 Gatekeeper Routed Call Setup Addressing: It is common for Internet addresses to be assigned dynamically which means that an IP addresses cannot be used to identify a user. One way of overcoming this problem is for users to register with a Gatekeeper . Once registered, other users can reach them by sending a location request message to the Gatekeeper. To accomplish roaming and IN service convergence a temporary ETSI TIPHON document reference[12] identifies a special type of Gatekeeper called a 'Mediation Gatekeeper' or 'MGK'. The user is assigned a unique ID (or 'alias') in the MGK, such as an MSISDN or an IP address. However, there are other methods that can be used. In this TR, H.323 roaming users are assumed to register with a Gatekeeper in a visited network and the alias is registered in the HLR. H.225, GSM and IN Integration: H.225 messages are based on Q.931. GSM (04.08) call control processes are similar to Q.931. ITU-T IN Capability Sets (e.g. IN CS-1) are based around ISDN call control. Q.931 is the ISDN user-network interface layer 3 specification for basic call control. This common ancestry in ISDN and Q.931 especially, leads to a view that integration based on a common call control model may be feasible. H.323 supports an architecture where all call control signalling messages between terminals are routed via a Gatekeeper. A Gatekeeper seems to be an obvious choice when attempting to integrate H.225, GSM and IN (i.e. CAMEL).
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7.2 Architecture
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7.2.1 Introduction
This section of the report provides information flows that illustrate simple MO and MT calls with CAMEL interactions. It is based upon an architecture that proposed in references [6] and [7]. The objective is to provide further understanding of the proposed architecture and to further progress the work in the feasibility study.
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7.2.2 Assumptions
a. The call flows presented are based on using the ITU-T H.323 protocol between the Mobile Station (MS) and the Gatekeeper. b. The gatekeeper and the IPSSF have been co-located in order to avoid any showing information flows between the two entities. Standardisation of the information flows between these entities is for further study. c. The attach/detach and establishment of (MS initiated or network initiated) PDP context is based on existing GPRS procedures as defined in UMTS 24.008 and UMTS 29.060. No changes are assumed. d. The information flows make no consideration for interworking with other networks such as the PSTN/ISDN and no media gateways or signalling gateways are shown. This is considered to be outside the scope of the feasibility study. e. For this work, it is assumed that roaming users register with a gatekeeper in the visited network. It is acknowledged that there are several proposals in other standard bodies investigating other alternatives involving for example registration with home gatekeeper whilst roaming. f. The addressing mechanism used to identify called parties provides a means to identify the home GPRS network. An incoming call request can be forwarded to the mediation gatekeeper in the home network of the called user. The mediation gatekeeper can query the HLR to identify the gatekeeper that the called used is registered with. It is acknowledged that there are other alternatives being investigated by the various standards groups.
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7.2.3 Functional Architecture
The proposed functional architecture is discussed in [6] and is shown in Figure 6. The main idea behind this functional architecture is to be able to reuse existing (circuit switched) CAMEL services for VoIP. Figure 6: Proposed functional architecture
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7.3 Message Flows
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7.3.1 Registration
It is not within the scope of this feasibility study to investigate or select the registration and location update process that must exist within a multimedia service network. However this section outlines a possible registration process that allows CAMEL Subscriber Information (CSI) to be stored in the Gatekeeper/IPSSF. Two distinct levels of registration exist; one at the PDP transport capability (Attach/Detach and PDP context establishment) and another level at the VoIP/multimedia level. Within H.323, this latter registration takes places with a Gatekeeper and roaming users register with a gatekeeper in the visited network. Gatekeeper discovery can be achieved via H.323 gatekeeper discovery procedure or via the resolution of ras://gk via DNS. Figure 7 outlines a proposed registration process. MS is a mobile station in a visited network. {1} The MS attaches to the network via existing GPRS procedures. This involves an attach request to the SGSN and a location update sequence from the SGSN to the HLR. {2} The MS activates a PDP context to establish an IP session with the gatekeeper. {3} The MS checks that it can register with that particular gatekeeper using a RAS GatekeeperRQ message. Assuming that the request is accepted, the gatekeeper confirms that registration can take place. {4} Upon confirmation that the MS is allowed to register with the gatekeeper, a RAS Registration Request is sent. {5} At this point, the gatekeeper sends a location update to the HLR in the user’s home network to register the alias address. The HLR responds with an InsertSubscriberData message that contains the CAMEL subscription Information (CSI). At this stage it is assumed that the Originating CSI (O-CSI) and the Terminating CSI (T-CSI) is sent to the gatekeeper. Supplementary Service CSI (SS-CSI) applicability is for further study. The HLR keeps a record of the address of the gatekeeper that the MS is registered with. {6} Once the registration process is complete, the PDP session with the gatekeeper may be terminated. Figure 7: MS registration with gatekeeper
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7.3.2 MO call requiring CAMEL interaction
The call flows for a mobile originated (MO) calls are shown in Figure 8 and are further explained below: {1} The MS wishes to place a VoIP call. A PDP context must be established to allow an IP session to be set up. {2} The MS checks that it is allowed to place a call via RAS Admission Request message. {3} If the MS is allowed to place the call (gatekeeper routed) an H.225 Setup message is sent to the gatekeeper. {4} When the Setup message is received at the gatekeeper, if the O-CSI for the calling user is present, it would be possible to analyse its contents and if necessary invoke the IPSSF. The IPSSF is now assumed capable of implementing the CAMEL O-BCSM. Later sections in this report cover the mapping of the O-BCSM points in call and H.323 call state model. The IPSSF starts a dialogue with the gsmSCF. The gsmSCF address and service key to invoke are obtained from the triggering criteria in the O-CSI. {5} The gsmSCF sends the instructions to the IPSSF according to the service logic invoked {6} The gatekeeper forwards the call according to the instructions received from the gsmSCF. H.225 Setup message is sent to the destination address. {7} Dialogue between the gsmSCF and the IPSSF may continue according to the service logic. The remainder of the information flows will vary according to the service logic and are not shown. Figure 8: MO call with CAMEL interaction
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7.3.3 MT call requiring CAMEL interaction
The call flows for mobile terminated (MT) calls are shown in Figure 9 and are further explained below: {1} An incoming H225 Setup message is received by the mediation gatekeeper in the home network of the called subscriber. (The incoming call could be from an other H.323 gatekeeper or H.323 signalling gateway representing a call originating from external networks such as the PSTN). {2} The mediation gatekeeper queries the HLR to discover the IP address of the gatekeeper that the called user is registered with. SendRoutingInformation/Ack messages can be used for this purpose. {3} The mediation gatekeeper forwards the call to the required gatekeeper by sending a Setup message. {4} The gatekeeper receives the H225 Setup message and checks the T-CSI of the called user to determine whether any CAMEL services should be invoked. {5} If analysis of the T-CSI shows that the triggering criteria are met, the IPSSF is invoked to create a T-BCSM and the IPSSF initiates a dialogue with the gsmSCF in the home network of the called user. Instructions are received from the gsmSCF on how the call is to proceed. {6} The gatekeeper will route the call according to the instructions received from the gsmSCF and will send an H225 Setup message to the destination party {7} Dialogue between the gsmSCF and the IPSSF may continue according to the service logic. The remainder of the information flows will vary according tot he service logic and are not shown. Figure 9: MT Call with CAMEL interaction
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7.4 State Models
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7.4.1 H.323 and CAMEL O-BCSM
Figures 10, 11 and 12 show the relationship between the H.323 protocol state model and the points in call (PICs) defined in the CAMEL phase 3 Originating Basic Call State Model (O-BCSM) for successful and unsuccessful call attempts. The O-BCSM represented is based on CAMEL phase 3 state models as described in reference [9]. For the sake of simplicity, the information flows between the GPRS network nodes (GGSN and SGSN), the gsmSCF and Gatekeeper/SSF are not shown in any of the Figures. The sequence of messages flows relating to the SGSN, GGSN and the gsmSCF are as covered in section 7.3.2 and Figure 8. An O-BCSM object can be created upon receipt of an H.225 Setup message and the analysis of the O-CSI. The figures assume that the MS has previously registered with a gatekeeper in the network. The destination entity shown can be an other MS, gatekeeper, mediation gatekeeper or H.323 signalling gateway. As the call control protocol, H225 used in an H.323 environment is based on Q931, the mapping between the messages and the PICs are similar to existing GSM mechanisms.
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7.4.2 Successful call establishment
Figure 10 shows the PICs and relationship to H.323 messages for a successful call establishment of MO call with CAMEL interaction. {1} The H.225 Setup message indicates that a dialled number is received from the MS and detects that an O-CSI exists for this subscriber. {2} Analysis of the O-CSI takes place and gsmSCF is invoked. {3} Instructions are received from the gsmSCF to route the call to the destination address. {4} Upon receipt of the Connect message from the called party, a transition to the PIC O_Active takes place. O_Answer DP can be reported. {5} Either called or calling party can release the call with a ReleaseComplete message, upon which a transition to the PIC O_Null&Authorise_Origination_Attempt_Collect_Info takes place and the DP O_Disconnect may be reported. Figure 10: H.323 message flows and corresponding CAMEL O-BCSM for successful call establishment
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7.4.3 Unsuccessful call establishment due to gatekeeper admission reject
Figure 11 shows the PICs and relationship to H.323 messages for the situation where the destination is refused permission to accept the incoming call by the gatekeeper. An AdmissionReject message may be sent by the gatekeeper to the destination is registered with for reasons specified in RAS procedures. In order to keep the Figures relatively simple, the PICs O_Null&Authorise.. and Analyse_Info and corresponding message flows are not shown. {1} Instructions received from the gsmSCF on routing of the call and an H.225 Setup message is sent to the destination. {2} The destination is not given permission by the gatekeeper to accept the incoming call. A number of reasons could exist, such as insufficient bandwidth, permission expired etc. This information is carried in the rejection reason of the AdmissionReject and transported into the ReleaseComplete message back to the gatekeeper. {3} ReleaseComplete message arrives at gatekeeper indicating that the call could not be completed. DPs Route_Select_Failure or O_Routing_and_Alerting_Failure may be reported according to the rejection reason provided in the RelaseComplete message. Figure 11: H.323 messages flows and corresponding CAMEL O-BCSM for the case where the destination is refused permission to accept the call by the gatekeeper
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7.4.4 Unsuccessful call establishment due to refusal by destination party
Figure 12 shows the PICs and relationship to H.323 messages for the situation where the destination does not accept the incoming call request. Once again, in order to keep the Figures relatively simple, the PICs O_Null&Authorise.. and Analyse_Info and corresponding message flows are not shown. {1} Instructions received from the gsmSCF on routing of call and an H225 Setup message is sent to the destination. {2} The gatekeeper receives a ReleaseComplete message with a release reason. Potentially, depending on the release reason, the DPs O_No_Answer, O_Busy, O_Abandon, O_Routing_and_Alerting_Failure or Route_Select_Failure may be reported. Figure 12: H.323 messages flows and corresponding CAMEL O-BCSM for the unsuccessful establishment (other than admission refusal)
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7.4.5 H.323 and CAMEL T-BCSM
Figures 13 and 14 show the relationship between the H.323 protocol state model and the points in call (PICs) defined in the CAMEL phase 3 Terminating Basic Call State Model (T-BCSM) for successful and unsuccessful MT call attempts. The T-BCSM represented is based on CAMEL phase 3 state models as described in reference [9]. Once again, for the sake of simplicity, the information flows between the GPRS network nodes (GGSN and SGSN), the gsmSCF and Gatekeeper/SSF are not shown in any of the Figures. The sequence of messages flows relating to the SGSN, GGSN and the gsmSCF are as covered in section 7.3.3 and Figure 9. A T-BCSM object can be created upon receipt of an H.225 Setup message and the analysis of the T-CSI.
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7.4.6 Successful MT call delivery
Figure 13 shows the PICS and relationship to the H.323 protocol state model for a successfully established MT call requiring CAMEL interaction. {1} The H.225 Setup message arrives at the gatekeeper the destination MS is register with. If a T-CSI exists for the subscriber, a T-BCSM instance is created. {2} Analysis of the T-CSI takes place and gsmSCF is invoked {3} Instructions from the gsmSCF are received and upon receipt of the Connect message from the called MS a transition to T_Answer takes place. The DP T_Answer may be reported. {4} Either calling or called party can release the call with a ReleaseComplete message, upon which a transition to PIC T_Null takes place with potentially the DP T_Disconnect being reported. Figure 13: H.323 message flows and corresponding CAMEL T-BCSM for successful call establishment
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7.4.7 Unsuccessful MT call delivery
Figure 14 shows the PICs and relationship to H.323 message for the situation where the terminating MS does not accept the incoming call. {1} The H.225 Setup message arrives at the gatekeeper the destination MS is register with. If a T-CSI exists for the subscriber, a T-BCSM instance is created. {2} Analysis of the T-CSI takes place and gsmSCF is invoked {3} The called party refuses to accept the call and sends a ReleaseComplete message to the gatekeeper. The ReleaseComplete message may contain release reason. Potentially, depending on the release reason, the DPs T_No_Answer, T_Busy, T_Abandon or T_call_handling_Failure may be reported. Figure 14: H.323 message flows and corresponding CAMEL T-BCSM for unsuccessful call establishment
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7.5 CAMEL Integration
Integration of CAMEL functions with H.323 Gatekeeper functions may require enhancements to H.323 standards or CAMEL standards. Some initial work has been done to identify the standards that may need to be enhanced and to assess the extent of the changes required.
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7.5.1 Impact on H.323 Standards
Section 7.4 describes and illustrates how H.225 messages may be mapped to O_BCSM and T_BCSM Detection Points (DPs) at the Gatekeeper/SSF. When studying the Figures it can be seen that some CAMEL Phase 3 DPs (such as O_Active) have good correspondence with H.225 messages at the Gatekeeper, while other DPs require more detailed analysis. At this level of analysis it seems likely that changes to H.323 may not be needed. As the H.323 standards are already well established it seems likely that changes would be unwelcome in and it seems more likely that, if necessary, some reduction in CAMEL functionality may be a more acceptable compromise.
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7.5.2 Impact on CAMEL and other UMTS Standards
It is likely the some functional modelling additions and some CAP message information element additions will be needed. It is also likely that some HLR/VLR data and MAP protocol additions may be needed. It is of course very difficult to assess and describe exactly how much effort and meeting time is required to effect these changes. In comparison to previous CAMEL work on Phase 1, Phase 2 and Phase 3, in the author's opinion the effort required is probably more than was necessary to complete GPRS inter-working in CAMEL Phase 3, but probably less than the work necessary to complete CAMEL Phase 1. The major impact of these changes concerns documents 22.078, 23.018, 23.078, 29.078 and 29.002.
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7.6 Service Impacts
The combination of CAMEL and H.323 (as described in this report) may support some GSM supplementary services, such as unconditional call forwarding (subject to some re-engineering) and perhaps most operator specific services (depends on the extent of any reduced functionality necessary for integration). Every service needs to be studied in detail to determine exactly what can be supported. Interworking with H.323 based supplementary services is another aspect. Again every service needs to be studied in detail, however, it seems likely that a comparable level of inter-working may be possible to that achieved with a combination of an MSC and ISDN, i.e. low-level services like CLI probably are feasible but more complex services may not be feasible.
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7.7 Multimedia Evolution
The proposal in this report is focused on voice not multimedia. Control of multimedia services requires further study. However, the proposal does not in any way preclude CAMEL evolution to control multimedia services supported by the H.323 family of recommendations. It is likely that further enhancements to the protocols and functions listed in section 7.5.2 (e.g.. MAP, CAP, HLR, VLR, CSE) may be necessary, depending on the nature of the multimedia service control required.
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7.8 Advantages
The following advantages have been identified:  Maximises the re-use of existing functional entities, protocols and services. Such reuse decreases the development and ownership costs allowing existing familiar 2G services to be provided to 3G subscribers at an early stage.  Minimum changes to the CSE for the support of legacy services. There are several IN/CAMEL services already deployed such as PrePaid, VPN, Mobile Number Portability etc., which may be required in a voice over IP network.  This approach is in line with the work currently underway in ETSI SPAN 3 (Services and Protocols), in particular a work item addressing IN support for voice over IP in the H.323 architecture and associated protocols in association with the TIPHON project. The study will investigate how an H.323 gatekeeper can act as a virtual Service Switching Point (SSP). It is worth noting that ETSI plan to harmonise the fixed line IN protocol (ETSI Core INAP CS3.1) and mobile equivalent (CAP Phase 3) into a common protocol targeted for ETSI Core INAP CS4.
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7.9 Disadvantages
The following disadvantages have been identified:  Introduces new functional entity ‘IPSSF’, which provides the necessary mapping between the Gatekeeper and the CSE. However, this functional entity is based on the functions already provided by a VMSC/GMSC, where already standardised process such as the gsmSSF can be reused. The interface between the SCS/CSCF and the IPSSF requires further study.
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8 SIP Solution
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8.1 Description
The IETF Multiparty Multimedia Session Control (MMUSIC) working group specifies an IP telephony architecture (Figure 15). The architecture is seen as an alternative to ITU-T H.323 family of recommendations that is simpler to implement. It allows for the possibility of interworking with H.323 terminals. However, H.323 currently has the greatest industry backing. The Session Description Protocol (SDP) can be likened to H.245 (channel open/close and terminal capability handling). Session descriptions have a list format containing information about the session (see RFC 2327). The Session Initiation Protocol (SIP), reference [4], can be likened to H.225 (Registration, Admission, Status (RAS), and Q.931 messages). Message headers are in plain text and look similar to Email headers. SIP uses a client server model similar to the Hypertext Transfer Protocol (HTTP) and many others (Figure 16 (a)). It is used in conjunction with other protocols such as SDP, RTP and RSVP. SIP can establish connections via TCP or UDP (Figure 16 (b)). Figure 15: IETF IP Telephony Architecture Figure 16: (a) Client/Server Model using TCP, (b) Protocol Stack using UDP/TCP SIP Messages: To initiate a session a client sends an INVITE message to a server. An INVITE message typically contains a session description in SDP sufficient to establish communication. SIP Request and Response messages are listed below. SIP Request Messages SIP Response Messages INVITE ACK BYE CANCEL OPTIONS REGISTER 1xx Informational 2xx Success 3xx Redirection 4xx Client Error 5xx Server Error 6xx Global Failure INVITE - Invites client or server to establish a session. ACK - Confirmation reception of a final response to an INVITE message. BYE - The sender wishes to close the session. CANCEL - Cancels pending requests. OPTIONS - Asks for information about capabilities before establishing a session. REGISTER - Informs a Location Server of the client's IP address. SIP response messages use a 3 digit number, e.g. 1xx. The first digit defines the category. The next two digits allow up to 100 variations, e.g. 200 OK (successful invitation). Session Establishment: Sessions may be established using direct point-to-point communication or by using a SIP Server for personal mobility. A SIP server may be a Redirection Server or a Proxy Server. To establish a session using a SIP server the originator sends an INVITE message to the server. The server communicates with a Location Server to retrieve the IP address of the terminating party. When a Redirection Server is employed (Figure 17) the IP address is passed to the originator. The originator sends a new INVITE message and a session is established with the terminating party. When a Proxy Server is employed (Figure 18) the address of the terminating party is not passed to the originator. A Session is established between the originator and terminating party via the Proxy Server. One or more intermediate Proxy Servers may take part in the session. It is envisaged that a Proxy Server may be a network entity where CAMEL service control could be applied. This possibility is investigated further in this report. Figure 17: Session Establishment Using a Redirection Server Figure 18: Session Establishment Using a Proxy Server Interworking with H.323: RFC 2543 states (reference [4]) that SIP could be used to determine that a party can be reached via H.323, obtain the H.245 gateway and user address and then use H.225.0 to establish the call.
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8.2 Architecture
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8.2.1 Introduction
This section of the report provides information flows that illustrate the possible interaction of CAMEL and SIP. In particular it provides a proposal for the triggering of CAMEL services as well as a mapping between the CAMEL call states and the call states of the Session Initiation Protocol (SIP). An overall objective for the feasibility study is to demonstrate that CAMEL control of VoIP services in 3G networks can be readily specified and implemented by adapting standards and software used in 2G networks. This approach leads to services that function the same when a user roams between 2G and 3G networks, simplifies service evolution from 2G to 3G, and leads to more rapid implementation. This section of the report investigates the possibility of CAMEL service control based on the SIP proxy Server approach, as described in companion contributions (or sections that will form part of the technical report). This means that a locally configured proxy server is required for outgoing calls that require legacy service support based on existing CAMEL services. The section of the report is organised as follows: Section 8.2.2 outlines the proposed functional architecture for the support of CAMEL/SIP interaction. Section 8.2.3 briefly describes the concepts for IN service triggering based on CAMEL Subscription Information. Section 8.3.1 describes a registration process, section 8.3.2 deals with the detail of triggering services for Mobile Originated Calls, section 8.3.3 deals with the details for triggering Mobile Terminated calls. Section 8.4 describes the mapping of the SIP protocol state to the CAMEL basic call state model for the Originating and the Terminating sides.
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8.2.2 Functional Architecture
The proposed functional architecture is derived from various companion contributions relating to the technical report. It is provided here for completeness. The concept of the ‘IPSSF’ is introduced which acts as an overlay between the IP telephony call control and the Intelligent Network layer provided by the CAMEL Service Environment (CSE) or the GSM Service Control Function (gsmSCF). This ‘IPSSF’ provides the necessary mapping between the SIP protocol state machine and the CAMEL Basic Call State Model (BCSM). Figure 19 outlines the proposed functional architecture at the network level. Figure 19: Proposed functional Architecture to support CAMEL control of VoIP based on SIP call control
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8.2.3 Basic concept of the proposal
Subscribers may register in the visited SIP network allowing the subscriber to receive incoming calls. A subscriber may use the MSISDN as an additional identifier in the registration process. Upon registration with the server, the CAMEL subscription information for the subscriber is sent to the IPSSF by the HLR in the subscriber’s home network. As incoming calls made to the subscriber terminate at the server the subscriber is registered with, the Terminating CAMEL Subscription Information (T-CSI) may be examined and if necessary the gsmSCF may be invoked on a per incoming call basis. Similarly, calls made by a subscriber already registered with a proxy server allow the Originating CAMEL (O-CSI) subscription information to be examined and potentially allow the gsmSCF to be invoked. Callers not registered will not have any O-CSI information in the proxy server they are using to place the call. The proposal here is as follows: when the initial call request message (or the INVITE method) is received by the SIP proxy server, the IPSSF/VLR establishes a dialogue with the HLR of the home subscribers network to allow the CAMEL subscription information to sent. The O-CSI may then be examined and if necessary the gsmSCF may be invoked.
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8.2.4 Assumptions
a. All the call flows show that the SIP Proxy Server and the IPSSF have been co-located in order to avoid showing an information flows between the two entities. Standardisation of the messages for this interface is for further study. b. The attach/detach and establishment of the Packet Data Protocol (PDP) session are based on existing GPRS procedures found in UMTS 24.080 and UMTS 29.060. c. When a subscriber registers or places a call via a SIP Proxy server, the home network of the subscriber can be identified. d. A subscriber may use the MSISDN as an additional identifier in the registration process. e. Originating and terminating SIP Proxy servers must operate in a call-state aware mode. f. As registration with a SIP Proxy server is not mandatory, it shall be possible to determine whether a registration exists for that particular subscriber when an incoming call is placed by a subscriber. This allows the CSI information to be fetched from the HLR is the subscriber is not registered. (Note: Absence of the O-CSI does not necessarily mean that the user is not registered, merely that the O-CSI may not exist for that subscriber). g. The information flows make no consideration for interworking with other networks (e.g. PSTN via gateways as this is considered to be outside to scope of the technical report.
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8.3 Message Flows
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8.3.1 Proposed Registration process
This section outlines a possible registration process based on the SIP REGISTER method, which allows CAMEL subscription information to be stored in the SIP Proxy Server/IPSSF. IETF RFC 2543 [4] defines the term Registrar for registration purposes and it is the SIP registrar that accepts the REGISTER method. In this section it has been assumed that the SIP Proxy Server and the SIP registrar are co-located. This registration process is in addition to the PDP transport layer registration (GPRS Attach/Detach and PDP context establishment as found in UMTS 24.080 and UMTS 29.060). With the SIP REGISTER method, it is assumed that registration with a location server takes place. As this is outside the scope of SIP to specify, the information flows for this procedure are not shown, but are assumed to take place. Unlike H.323, registration with a server is not mandatory. Only users that wish to receive incoming calls need to register with a SIP Proxy server and a location server. Callers placing calls are not required to register. The information flows for the registration procedure are shown in Figure 21 and elaborated in the following text: {1} The MS attaches to the network using existing GPRS procedures. This involves an attach request to the SGSN and a location update sequence between the SGSN and the HLR. {2} The MS activates a PDP context to establish an IP session with the local proxy SIP server in the visited network. Mechanisms for the discovery of the SIP Proxy server are for further study. {3} The MS sends a REGISTER method to the SIP Proxy server. {4} The SIP Proxy server notifies the IPSSF/VLR of the registration attempt. The IPSSF in turn notifies the HLR. The HLR responds with an InsertSubscriberData message which contains the CAMEL Subscription Information (CSI) which includes the Originating CSI (O-CSI) and Terminating CSI (T-CSI). The applicability of the Supplementary Service CSI (SS-CSI) is for further study. {5} The SIP Proxy server acknowledges that the registration process has been completed by a 200 OK response message. {6} Once the registration process is complete, the PDP session with the SIP Proxy Server may be terminated. Figure 21: Proposed registration procedure
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8.3.2 Mobile Originating Call with CAMEL interaction
This section deals with the mobile originating calls that require interaction with CAMEL. The call flows are shown in Figure 22 and are further explained below: {1} The MS wishes to place a VoIP call. A PDP context is established to allow an IP session to be established over the GPRS network. {2} The User Agent Server in the MS initiates a SIP request by issuing an INVITE method to the SIP Proxy server. {3} The VLR functionality in the IPSSF is checked to determine if the calling party has previously registered. If no registration found, then step {4} is followed. If the IPSSF determines that the calling user has a valid registration then step {5} is followed. {4} The IPSSF establishes a dialogue with the HLR of the subscriber’s network. An UpdateLocation message is sent to the HLR. The HLR responds by sending an InsertSubscribersData message, which may contain the CAMEL Subscription Information, including O-CSI, T-CSI and the SS-CSI. {5} The O-CSI data is analysed and if the necessary triggering criteria are met, the gsmSCF is invoked via an InitialDP message. {6} The SIP Proxy server will route the call based on the instructions received by the service logic in the gsmSCF. The remainder of the information flows will vary according to the service logic and are not shown. Figure 22: MO Call with CAMEL interaction
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8.3.3 Mobile Terminating Call with CAMEL interaction
This section deals with the CAMEL interaction for mobile terminated calls. A CAMEL service is triggered if the triggering criteria held in the called subscriber’s T-CSI matches the characteristics of the incoming call. The information flows are shown in Figure 23 and further explained below: {1} The terminating SIP Proxy server receives an INVITE method. {2} The T-CSI is analysed and the triggering criteria are check against the particulars of the incoming call. A terminal must register with a server to be able to accept incoming call and has been assumed that since this registration has taken place; the T-CSI is available at the server. {3} If the necessary triggering criteria are met, the gsmSCF is invoked and a CAP dialogue established between the IPSSF and the gsmSCF. {4} Instructions are received from the gsmSCF on how the call is to be routed. {5} The SIP Proxy server will route the call based on the instructions received by the service logic in the gsmSCF. A network initiated PDP context is established in order to deliver the INVITE method to the User agent server. As the rest of the information flows will vary according to the service logic, the remained of the information flows are not shown. Figure 23: MT Call with CAMEL interaction
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8.4 State Models
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8.4.1 Mapping SIP message to CAMEL Basic Call State Models
This section deals with how the Originating Basic Call State Model (O-BCSM) Points in Call (PICs) and Detection Points (DPs) or ‘triggers’ are mapped to the appropriate SIP messages. Although a mapping is possible, there is not always the same analogy between the circuit switched environment that the CAMEL BCSM were designed for and the packet environment, and as a result a direct mapping is not always possible. The state models for the CAMEL O-BCSM and the T-BCSM are based on the emerging CAMEL Phase 3 draft specifications as identified in reference[11]. For simplicity, the information flows in the Figures of the following subsections do not show the flows between the GPRS network nodes (SGSN and GGSN) and between the gsmSCF and IPSSF.
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8.4.2 Mapping to Originating BCSM for MO calls
The mapping between the SIP methods and responses for O-BCSM relating to Mobile Originating Calls are shown in Figure 24. Only the successful case is described. Further work is necessary to describe all other scenarios. The information flows are further described below : {1} INVITE method arrives at the proxy server, indicating that the MS has requested to set up a call. SIP Proxy server determines if O-CSI exists for this user. {2} Analysis of the O-CSI takes places and if necessary triggering criteria are met, gsmSCF is invoked. DP CollectedInfo may be reported. {3} Instructions received from the gsmSCF on how the call is to be routed, together with which EDPs are armed. State Routing_And_Alerting entered. INVITE method forwarded to destination. {4} A response ‘200 OK’ indicates that the destination has accepted in session invitation, indicating that a session has been established. State O_Active is entered, DP O_Active may be reported to the gsmSCF and an ACK is sent to the originating party. {5} Either party may release the call with a BYE method. On receipt of the BYE, transition to the PIC O_Null&Authorise_Oriigination_Attempt_Collect takes place and the DP O_Disconnect may be reported to the gsmSCF. Figure 24: Message flows and corresponding CAMEL O-BCSM for successful call establishment
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8.4.3 Terminating BCSM for MT Calls
The mapping between the SIP methods and responses for T-BCSM and Mobile Terminating Call is shown in Figure 25. The information flows further described below : {1} INVITE method arrives at the destination SIP Proxy server. Server/IPSSF determines if a T-CSI exists for the called user {2} T-CSI is analysed and if necessary triggering criteria are met, gsmSCF is invoked. Transition to state TerminatingCallHandling and DP Terminating_Atttempt_Authorised may be reported. {3} Call accepted by the terminating party. DP T_Answer may be reported to the gsmSCF, state T_Active entered. {4} Either party may terminate the call by sending a BYE and transition to PIC T_Null takes place and the DP T_Disconnect may be reported. Figure 25: Message flows and corresponding PIC in the CAMEL T-BCSM for successful call delivery
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8.4.4 Unsuccessful MT Call Delivery
This subsection explores the mapping and the reporting of the DPs that may be encountered when the call is not successfully established. The information flows are shown in Figure 26 and further explained below: {1} INVITE method arrives at the destination SIP proxy server. Server/IPSSF determines is a T-CSI exists for the called user {2} T-CSI is analysed and if necessary triggering criteria are met, gsmSCF is invoked. Transition to state TerminatingCallHandling and DP Terminating_Atttempt_Authorised may be reported. {3} The destination does not accept the incoming call – reason response may be any value in 4xx response range. The mapping of client error codes (4xx) to the possible Detection Points in PIC Terminating_Call_Handling is not all that straight forward. For example, the DP T_CallHandlingFailure can capture most of the 4xx error codes, and T_Busy can be mapped on to 486 Busy Here, it is not clear how T_Abandon and T_No_Answer can be mapped on to the error codes. Although further work is required, the problem is not unique to GSM and CAMEL. Work in other standards organisations needs to be investigated to determine similar issues. Figure 26: Message flows and corresponding PIC in the CAMEL T-BCSM for unsuccessful call establishment.
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8.5 CAMEL Integration
Integration of CAMEL functions with SIP Proxy Server functions may require enhancements to SIP standards or CAMEL standards. Some initial work has been done to identify the standards that may need to be enhanced and to assess the extent of the changes required.
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8.5.1 Impact on SIP Standards
Section 8.4 describes and illustrates how SIP messages may be mapped to O_BCSM and T_BCSM Detection Points (DPs) at the SIP Proxy Server/SSF. When studying the Figures it can be seen that some CAMEL Phase 3 DPs (such as O_Active) have good correspondence with SIP messages at the SIP Proxy Server, while other DPs require more detailed analysis. At this level of analysis it seems likely that changes to SIP may not be needed.
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8.5.2 Impact on CAMEL and other UMTS Standards
It is likely that some functional modelling additions and some CAP message information element additions will be needed. It is also likely that some HLR/VLR data and MAP protocol additions may be needed. It is of course very difficult to assess and describe exactly how much effort and meeting time is required to effect these changes. In comparison to previous CAMEL work on Phase 1, Phase 2 and Phase 3, in the author's opinion the effort required is probably more than was necessary to complete GPRS inter-working in CAMEL Phase 3, but probably less than the work necessary to complete CAMEL Phase 1. The major impact of these changes concerns documents 22.078, 23.018, 23.078, 29.078 and 29.002
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8.6 Service Impacts
The combination of CAMEL and SIP (as described in this report) may support some GSM supplementary services, such as unconditional call forwarding (subject to some re-engineering) and perhaps most operator specific services (depends on the extent of any reduced functionality necessary for integration). Every service needs to be studied in detail to determine exactly what can be supported. Interworking with SIP extensions for call control services is another aspect. Again every service needs to be studied in detail.
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8.7 Multimedia Evolution
The proposal in this report is focused on voice not multimedia. Control of multimedia services requires further study. However, the proposal does not in any way preclude CAMEL evolution to control multimedia services supported by SIP. It is likely that further enhancements to the protocols and functions listed in section 8.5.2 (e.g.. MAP, CAP, HLR, VLR, CSE) may be necessary, depending on the nature of the multimedia service support required.
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8.8 Advantages
The following advantages have been identified:  Maximises the re-use of existing functional entities, protocols and services. Such reuse decreases the development and ownership costs allowing existing familiar 2G services to be provided to 3G subscribers at an early stage. Minimum changes to the CSE for the support of legacy services. There are several IN/CAMEL services already deployed such as PrePaid, VPN, Mobile Number Portability, etc which may be used in a voice over IP network.
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8.9 Disadvantages
The following disadvantages have been identified:  This approach is not in line with the work currently underway in ETSI SPAN 3 (Services and Protocols), in particular a work item addressing IN support for voice over IP on the H.323 architecture and associated protocols in association with the TIPHON project.  Introduces new functional entity ‘IPSSF’, which provides the necessary mapping between the SIP Proxy Server and the CSE. However, this functional entity is based on the functions already provided by a VMSC/GMSC, where already standardised process such as the gsmSSF can be reused. The interface between the SCS/CSCF and the IPSSF requires further study.
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9 Work in other Standards Groups
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9.1 3GPP
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9.1.1 System Architecture Working Group 2 (S2)
The 3GPP S2 group has overall system architecture responsibility for the GSM/GPRS evolved system within the 3GPP organisation and also has close linkage with the ETSI SMG12 (GSM/GPRS) system architecture group. The S2 group is investigating the architectural impacts and linkages involved with providing IN (CAMEL) based features into the mobile environment including the impacts of aspects such as roaming, Mobile Originated and Terminating calls, interactions with GSM standardised supplementary services and distributed service control/SSF issues across network boundaries. Items currently under study include the addition of CAMEL features for GPRS (beyond CAMEL Phase 3) and the opportunities to include further location based capabilities. CAMEL is also continuing into the UMTS area to include the Open Service Architecture (OSA) aspects. 3GPP document 23.121 specifies architectural requirements.
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9.2 ETSI
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9.2.1 TIPHON
TIPHON Working Group 7 is studying the implementation of TIPHON networks in a mobile environment, and has been in existence since the beginning of 1999. TIPHON mobility is user and service mobility in the context of the VoIP application. The group has an understanding with 3GPP S2 to liase over IP activities. It is currently planning on producing 3 main documents: 07.001 Analysis of existing roaming techniques applicable to TIPHON mobility services 07.002 Investigation of synergies and common requirements between TIPHON networks and wireless systems as they are currently being developed by other bodies. 07.003 Mobility and Access to Wireless Systems: Extensions to Requirements, Architectures and Protocols However, at the present moment only 07.001 has any significant text associated with it. The document is a review of existing mobile networks and specifically lists supplementary services as an open issue. In section 5.1 the GSM network is described, and CAMEL identified as the Intelligent Network service within GSM used to provide service mobility where the end user should not see any difference in the services provided by the IN nodes irrespective of the user’s location and terminal used. Similarly section 5.7 describes the GPRS network, section 5.9.4 introduces Session Initiation Protocol, and section 5.10 details the mobile extension to H.323. At the July 1999 TIPHON 14 meeting, working group 7 discussed a document (14TD054) received from ITU-T SG16 for information concerning new work recently approved on mobility for H.323. The contribution stirred discussion, as the solution was seen as conflicting with the general attempt within TIPHON to work towards a layered architecture.
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9.2.2 SPAN3
ETSI SPAN (Services and Protocol for Advanced Networks) is ETSI’s core competence centre for fixed networks standardisation including IP based networks. SPAN3 (formerly SPS3) is the competence centre for IN Activities, including generic operations for INAP mobility. SPS3 work on Core INAP CS-3 has been split into two streams. CS-3.1 comprises CS2 and CAMEL Phase 3, while CS-3.2 looks at fixed network requirements and will be based on the ITU CS3 output. Both are due for completion by the end of 1999 and will be merged in Core INAP CS4, due for completion at the end of 2000. CS-3.2 contains a work item addressing IN support for voice over IP based on the H.323 architecture and associated protocols in conjunction with the TIPHON project. A liaison statement from SPS3 to TIPHON entitled “Using Intelligent Networks in a Tiphon Architecture” was written in June 1999, giving the following proposals - The IN infrastructure shall be independent of the IP telephony signalling protocol (SIP, H.323,…). - The call control and consequently IN control shall be at least at the edge of the network i.e. nearest to the user in a Local Exchange and between two operators in an Inter-operator Gateway.
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9.3 IETF
The Routing area contains the IP Routing for Wireless/Mobile Hosts (mobileIP) Working Group. It has developed routing support to permit IP nodes (hosts and routers) using either IPv4 or IPv6 to seamlessly roam among IP sub-networks and media types. The group has produced an Internet draft entitled “Requirements on Mobile IP from a Cellular Perspective” which considers MobileIP as a macro-mobility solution for cellular networks. This document does not address the issues surrounding the provision of supplementary services. The Transport area contains the IP Telephony (iptel) working group and the Media Gateway Control (MEGACO) working group. The Internet draft “SIP Call Control Services” describes a set of extensions to SIP which allow for various call control services. Example services include blind transfer, transfer with consultation, multi-party calls, bridged conferences, and ad-hoc conferencing. The Internet draft “Accessing IN services from SIP networks” proposes a mapping from the states of the IN call model to the states of SIP, an Internet call signalling protocol.
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9.4 ITU-T
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9.4.1 SG11
Study Group SG11 is responsible for studies relating to signalling requirements and protocols for telephone, N-ISDN, B-ISGN, UPT, mobile and multimedia communications. SG11 is responsible for most of the Q-Series standards, including Q.931. Questions under study by the group include: 5/11 Intelligent network capability sets 6/11 New signalling capabilities and requirements for advanced broadband multimedia services 7/11 Signalling, call handling and management requirements for universal personal telecommunications and for user mobility in future public land mobile systems 13/11 Network signalling for the support of broadband services and third generation land mobile networks (FPLMTS) 22/11 Intelligent Network Application Protocol (INAP) 24/11 Signalling requirements for emerging land mobile and satellite mobile - Network and Inter-network Signalling Requirements
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9.4.2 SG16
Study Group16 is responsible for studies relating to multimedia service definition and multimedia systems, including the associated terminals, modems, protocols and signal processing. SG16 is responsible for the H-Series standards, including H.323, as well as parts of the T-, G-, and F-Series. Questions under study by the group include: 13/16 Packet switched multimedia systems and terminals This question covers the H.323 standard, of which Annex H studies H.323 Mobility. The annex has the following objectives:  Define functional requirements for H.323 mobility at the application level in a transport independent way.  Examine whether any new messages or message elements need to be created in H.323 for supporting mobility  Facilitate interoperability for implementation of H.323 mobility over any specific networking environment such as wireless/PSTN
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10 Questions & Answers
Early drafts of this FTR were presented to 3GPP CN WG2a and a small number of questions were raised. The questions and answers are recorded here. Q. In our work, are we considering IN control of RAS signalling or for call control or both? A. Control of RAS signalling is out of scope. Q. How does the architecture support the playing of tones and announcements? A. This is a problem not unique to CAMEL and is one of many issues that we have not addressed. We felt that it is appropriate to address this aspect as part of a more detailed study. Q. Are we only considering CAP over SS7? A. We have not excluded the possibility of CAP over IP, this possibility depends on the outcome of SIGTRAN work and the MAP over IP work in CN2B. CAMEL control of VoIP services is independent of whether SS7 or IP is used for the lower layer signalling transport. Q. What considerations are there for 'fast start' and what impact does this have? A. Requires further study. Q. How are we incorporating the work output from MEGACO? A. As far as we are aware MEGACO work does not directly impact CAMEL control of VoIP services but further study is required.
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11 Conclusions & Recommendations
This report has demonstrated how CAMEL can be used to control VoIP services in an all IP network using H.323 or SIP. The analysis has been carried out at a high level sufficient to identify that further detailed design and specification work should lead to a viable solution provided the architectural assumptions used in this report are correct. At this level of analysis no preference for H.323 or SIP was evident. Based on this evidence, either H.323, SIP or both could be successfully employed. Use of CAMEL is one service creation approach for H.323/SIP-based services. There are also alternative H.323/SIP and IN interworking options identified in the report. Finally use of “next generation” architectures may enable other types of service creation which are not based on IN. The overall options need to be reviewed to select which of them will be most appropriate for R00 considering service and technical aspects. Based on this analysis the use of CAMEL is technically feasible and would provide a service evolution path from R99, but detailed comparison with other options has not been included. Finalisation of the architecture and service creation principles for R00 is urgently needed so that work on the selected option(s) can start. It is also necessary to decide what standardised service(s) are required for H.323/SIP and which service(s) will be implemented using tool-kits. Annex A: Change history Change history Date TSG # TSG Doc. CR Rev Subject/Comment Old New Jun 2000 CN#08 NP-000252 Approved by TSG CN 2.1.1 3.0.0
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1 Scope
The present document describes the statistical theory and concepts applied in the conformance test of the user equipment (UE) so as to improve test speed.