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IP Multimedia Subsystem IMS

IP Multimedia Subsystem IMS. Rajkiran Velluri Rahul Allawadhi Rahul Parey Santosh Kandukuri. History of IMS.

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IP Multimedia Subsystem IMS

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  1. IP Multimedia Subsystem IMS Rajkiran Velluri Rahul Allawadhi Rahul Parey Santosh Kandukuri

  2. History of IMS • IMS first appeared in release 5 of the evolution from 2G to 3G networks for W-CDMA networks (UMTS), when SIP-based multimedia domain was added to NGN networks. Support for older GSM and GPRS networks is also provided. • In 3GPP release 6, interworking with WLAN was added. • 3GPP release 7 adds support for fixed networks, together with TISPAN which allowed adopted a more generalized model able to address a wider variety of network and service requirements. This overall architecture is based upon the concept of cooperating subsystems sharing common components. This subsystem-oriented architecture enables the addition of new subsystems over the time to cover new demands and service classes. . • "Early IMS" was defined for IPv4 networks, and provides a migration path to IPv6

  3. Cellular Networks • 1G • Used analog transmission and provided only circuit switched voice telephony • 2G • Fully digital. Offered both voice & CS data services • 2.5G • Addition of Packet Switched Data services to 2G Networks. • 3G • Provide (or try to) all services over PS (including voice telephony)

  4. IP Multimedia Subsystem (IMS) • The IP Multimedia subsystem standard defines a generic architecture for offering VoIP and multimedia services. • Internationally recognized standard first specified by the 3GPP ( 3rd generation Partnership Project) • Supports multiple access types: GSM, WCDMA, CDMA2000, Wireline broadband access and WLAN. • Established with the aim of allowing UMTS network to provide all of its services over IP on an end-to-end basis.

  5. Concept of the IP Multimedia Subsystem (IMS) The IP Multimedia Subsystemis an open, standardized, NGN multi-media architecture for mobile and fixed IP-based services. It's a VoIP implementation based on a 3GPP variant of SIP (Session Initiation Protocol), and runs over the standard Internet protocol. It's used by Telcos in NGN networks (which combine voice and data in a single packet switched network),to offer network controlled multimedia services. The aim of IMS is not only to provide new services but to provide all the services, current and future, that the Internet provides. In addition, users have to be able to execute all their services when roaming as well as from their home networks. To achieve these goals the IMS uses open standard IP protocols, defined by the IETF.

  6. Concept of the IP Multimedia Subsystem (IMS) So, a multi-media session between 2 IMS users, between an IMS user and a user on the Internet, and between 2 users on the Internet is established using exactly the same protocol. Moreover, the interfaces for service developers are also based in IP protocols. This is why the IMS truly merges the Internet with the cellular world; it uses cellular technologies to provide ubiquitous access and Internet technologies to provide appealing services.

  7. IMS concept The IMS concept was introduced to address the following network and user requirements: • Deliver person-to-person real-time IP-based multimedia communications (e.g. voice or video telephony) as well as person-to-machine communications (e.g. gaming service). • Fully integrate real-time with non-real-time multimedia communications (e.g. live streaming and chat). • Enable different services and applications to interact (e.g. combined use of presence and instant messaging). • Easy user setup of multiple services in a single session or multiple simultaneous synchronized sessions.

  8. IMS solution overview Source: Alcatel

  9. IMS Standards • 3GPP and 3GPP2 - 3rd Generation Partnership Project 3rd Generation Partnership Project 2 • Have both defined the IP Multimedia Subsystem (IMS) • The harmonization effort has kept the definitions as similar as possible. • IETF - Internet Engineering Task Force • Provide the definitions for SIP, SDP and other protocols underlying IMS • IMS is driving some of the work in IETF • OMA - Open Mobile Alliance • Defining services for IMS architecture, e.g. Instant Messaging, Push-to-Talk • ITU - International Telecommunication Union • Provides protocol definitions used by IMS • H.248 for media control • Q.1912.SIP for SIP – ISUP interworking (in conjunction with IETF) • ETSI - European Telecommunications Standards Institute • TISPAN - TISPAN is merger of TIPHON (VoIP) and SPAN (fixed networks) • Agreement on reuse of 3GPP/3GPP2 IMS in comprehensive NGN plans • ANSI - American National Standards Institute • Provides protocol definitions used by IMS • ATIS - Alliance for Telecommunications Industry Solutions • Addressing end-to-end solutions over wireline and wireless • Nearing agreement to use 3GPP/3GPP2 IMS

  10. IMS GOALS • Support of real-time IP- based multimedia communication services (VoIP, Video Conferencing e.t.c). This implies that IMS will replace the CS domain of a UMTS network, providing all the traditional CS services over IP, in PS domain • Provide ability of interactions between services, so that users may combine different services in one session, e.g. group conferencing.

  11. Characteristics of IMS • Takes the concept of horizontal architecture a step further where service enablers and common functions can be reused for multiple applications • Well integrated with existing voice and data networks adopting many of the key benefits of the IT domain • Horizontal architecture specifies interoperability and roaming, and provides bearer control, charging and security • IMS enables services to be delivered in a standardized, well structured manner • The horizontal architecture enables operators to avoid the problems associated with charging, presence, group and list management, routing and provisioning.

  12. Advantages of IMS • Advantages over other existing systems: • The core network is independent of a particular access technology • Integrated mobility for all network applications • Easier migration of applications from fixed to mobile users • Faster deployment of new services based on standardized architecture • An end to unique or customized applications • New applications such as presence information, videoconferencing, Push to talk over cellular (POC), multiparty gaming, community services and content sharing. • Evolution to combinational services, for example by combining instant messaging and voice • User profiles are stored in a central location

  13. Advantages of IMS • Advantages over free VoIP: • It's possible to run free VoIP applications over the regular Internet. Then why do we need IMS, if all the power of the Internet is already available for 3G users? • Quality of Service : The network offers no guarantees about the amount of bandwidth a user gets for a particular connection or about the delay the packets experience. Consequently, the quality of a VoIP conversation can vary dramatically throughout its duration. • Charging of multimedia services : Videoconferences can transfer a large amount of information, but the telecom operator can't charge separately for this data. Some business models might be more beneficial for the user (for instance: a fixed price per message, not per byte); others might charge extra for better QoS. • Integration of different services : an operator can use services developed by third parties, combine them, integrate them with services they already have, and provide the user with a completely new service. For example: if voicemail and text-to-speech is combined, a voice version of incoming text messages can be provided for blind users.

  14. IMS SERVICES & ARCHITECTURE • These basic services can be controlled by external Application Servers (AS) so as to provide various applications. • For example, IMS does not offer a conferencing or chat room service! • It provides - point-to-point and point to multipoint transmission facilities. - Group management facilities - The ability for an external AS to control the group communication

  15. IMS SERVICES & ARCHITECTURE • To maximize flexibility IMS organizes ITS functionality in three layers.

  16. IMS SERVICES & ARCHITECTURE • Transport & Endpoint Layer Initiates & terminates the signaling needed to setup & control sessions, provides bearer services between the endpoints. Media gateways are provided to convert from/to analog/digital voice telephony formats to/from IP packets using RTP. IMS signaling is based on SIP on top of IPv6 • The session control layer provides functionality that allows endpoints to be registered with the network and sessions to be setup between them. It also contains the functions that control the media gateways and servers so as to provide the requested services • The application server layer allows sessions to interact with various AS entities. In this layer multiple sessions may be coordinated to provide single application.

  17. IMS SERVICES & ARCHITECTURE • Supporta wide range of services, both telephony & non-telephony oriented. All these services are provided over IP, end-to-end. Some of them are the followings: • Voice & video telephony • Instant Messaging • Chat Rooms • Video Conferencing • Multiparty Gaming

  18. BROADVIEW OF IMS ARCHITECTURE

  19. BROADVIEW OF IMS ARCHITECTURE • The IP Multimedia Core Network Subsystem is a collection of different functions, linked by standardized interfaces. A function is not a node (hardware box) : an implementer is free to combine 2 functions in 1 node, or to split a single function into 2 or more nodes. Each node can also be present multiple times in a network, for load balancing or organizational issues.

  20. BROADVIEW OF IMS ARCHITECTURE • Access Network • The user can connect to an IMS network using various methods, all of which are using the standard Internet Protocol (IP). • Direct IMS terminals can register directly into an IMS network. • Fixed access, mobile access and wireless access are all supported.

  21. BROADVIEW OF IMS ARCHITECTURE USER DATABASE Access Network Access Network

  22. BROADVIEW OF IMS ARCHITECTURE • User Database • The HSS (Home Subscriber Server) is the master user database that supports the IMS network entities that are actually handling the calls/sessions. • It contains the subscription-related information, performs authentication and authorization of the user, and can provide information about the physical location of user. • A SLF (Subscriber Location Function) is needed when multiple HSSs are used.

  23. BROADVIEW OF IMS ARCHITECTURE Call/Session Control

  24. BROADVIEW OF IMS ARCHITECTURE • Call/Session Control Several types of SIP servers, collectively known as CSCF, they are used to process SIP signaling packets in the IMS. • P-CSCF (Proxy-CSCF) • I-CSCF (Interrogating-CSCF) • S-CSCF (Serving-CSCF)

  25. BROADVIEW OF IMS ARCHITECTURE • Call/Session Control 1) A P-CSCF (Proxy-CSCF) • It is a SIP proxy that is the first point of contact for the IMS terminal. • It can be located either in the visited network or in the home network. • It has terminal which will discover its P-CSCF with either DHCP, or it's assigned in the PDP Context (in GPRS).

  26. BROADVIEW OF IMS ARCHITECTURE • Call/Session Control 2) I-CSCF (Interrogating-CSCF) • It is a SIP proxy located at the edge of an administrative domain. • Its IP address is published in the DNS records of the domain, so that remote servers can find it, and use it as an entry point for all SIP packets to this domain. • The I-CSCF queries the HSS using the DIAMETER Cx and Dx interfaces to retrieve the user location, and then route the SIP request to its assigned S-CSCF. • It can also be used to hide the internal network from the outside world, in which case it's called a THIG (Topology Hiding Interface Gateway).

  27. BROADVIEW OF IMS ARCHITECTURE • Call/Session Control 3) S-CSCF (Serving-CSCF) • It is the central node of the signaling plane. • It's a SIP server, but performs session control as well. • It's always located in the home network. The S-CSCF uses DIAMETER Cx and Dx interfaces to the HSS to download and upload user profiles. • It has no local storage of the user.

  28. BROADVIEW OF IMS ARCHITECTURE Application Server

  29. BROADVIEW OF IMS ARCHITECTURE • Application Servers • Application servers (AS) host and execute services, and interfaces with the S-CSCF using SIP. • Depending on the actual service, the AS can operated in SIP proxy mode, SIP US mode or SIP B2BUA mode. • An AS can be located in the home network or in an external third-party network.

  30. BROADVIEW OF IMS ARCHITECTURE Media Servers

  31. BROADVIEW OF IMS ARCHITECTURE • Media Servers • A MRF (Media Resource Function) provides a source of media in the home network. • It's used for Playing of announcements, Multimedia conferencing, Text-to-speech conversation (TTS) and speech recognition, Real time transcoding of multimedia data. • Each MRF is further divided into : 1) A MRFC (Media Resource Function Controller) is a signalling plane node that acts as a SIP User Agent to the S-CSCF, and which controls the MRFP with a H.248 interface 2) A MRFP (Media Resource Function Processor) is a media plane node that implements all media-related functions.

  32. BROADVIEW OF IMS ARCHITECTURE Breakout Gateways

  33. BROADVIEW OF IMS ARCHITECTURE • Breakout Gateway • A BGCF (Breakout Gateway Control Function) is a SIP server that includes routing functionality based on telephone numbers. • It's only used when calling from the IMS to a phone in a circuit switched network, such as the PSTN or the PLMN.

  34. BROADVIEW OF IMS ARCHITECTURE PSTN gateways

  35. BROADVIEW OF IMS ARCHITECTURE • PSTN Gateways • A PSTN/CS gateway interfaces with PSTN circuit switched (CS) networks. • A SGW (Signalling Gateway) interfaces with the signalling plane of the CS. It transforms lower layer protocols as SCTP into MTP, to pass ISUP from the MGCF to the CS network. • A MGCF (Media Gateway Controller Function) does call control protocol conversion between SIP and ISUP, and interfaces with the SGW over SCTP. • A MGW (Media Gateway) interfaces with the media plane of the CS network, by converting between RTP and PCM.

  36. BROADVIEW OF IMS ARCHITECTURE • Charging • Definitions: Offline charging is applied to users who pay for their services periodically whereas Online charging is applied to usera who pay credit-based charging which is used for prepaid services. • Offline Charging : All the SIP network entities involved in the session use the DIAMETER Rf interface to send accounting information to a CCF (Charging Collector Function) located in the same domain. CCF collects all this information, and build a CDR (Charging Data Record), which is send to the billing system (BS) of the domain. • Online charging : The S-CSCF talks to a SCF (Session Charging Function), which looks like a regular SIP application server. The SCF can signal the S-CSCF to terminate the session when the user runs out of credits during a session. The AS and MRFC use the DIAMETER Ro interface towards a ECF (Event Charging Function), that also communicates with the SCF.

  37. BROADVIEW OF IMS ARCHITECTURE • Advantages: Advantages over existing systems • The core network is independent of a particular access technology • Integrated mobility for all network applications • Easier migration of applications from fixed to mobile users • Faster deployment of new services based on standardized architecture • New applications such as presence information, videoconferencing, Push to talk over cellular (POC), multiparty gaming, community services and content sharing. • User profiles are stored in a central location

  38. BROADVIEW OF IMS ARCHITECTURE • Advantages: Advantages over free VoIP • Quality of Service : The network offers no guarantees about the amount of bandwidth a user gets for a particular connection or about the delay the packets experience. • Charging of multimedia services : Videoconferences can transfer a large amount of information. Some business models might be more beneficial for the user, others might charge extra for better QoS. • Integration of different services : an operator can use services developed by third parties, combine them, integrate them with services they already have, and provide the user with a completely new service.

  39. BROADVIEW OF IMS ARCHITECTURE • Issues • Benefits need to be further articulated in terms of actual savings. • IMS is "operator friendly" which means that it provides the operator with comprehensive control of content at the expense of the consumer. • IMS uses the 3GPP variant of SIP, which needs to interoperate with the IETF SIP. • IMS is an optimization of the network, and investments for such optimization are questionable.

  40. BROADVIEW OF IMS ARCHITECTURE • Associated Protocols • RFC 1889 Real-time Transport Protocol (RTP) • RFC 2327 Session Description Protocol (SDP) • RFC 2748 Common Open Policy Server protocol (COPS) • RFC 2782 a DNS RR for specifying the location of services (SRV) • RFC 2806 URLs for telephone calls (TEL) • RFC 2915 the naming authority pointer DNS resource record (NAPTR) • RFC 2916 E.164 number and DNS • RFC 3261 Session Initiation Protocol (SIP) • RFC 3262 reliability of provisional responses (PRACK) • RFC 3263 locating SIP servers • RFC 3264 an offer/answer model with the Session Description Protocol • RFC 3310 HTTP Digest Authentication using Authentication and Key Agreement (AKA) • RFC 3311 update method • RFC 3312 integration of resource management and SIP • RFC 3319 DHCPv6 options for SIP servers • RFC 3320 signalling compression (SIGCOMP) • RFC 3323 a privacy mechanism for SIP • RFC 3324 short term requirements for network asserted identity • RFC 3325 private extensions to SIP for asserted identity within trusted networks • RFC 3326 the reason header field • RFC 3327 extension header field for registering non-adjacent contacts (path header) • RFC 3329 security mechanism agreement • RFC 3455 private header extensions for SIP • RFC 3485 SIP and SDP static dictionary for signaling compression • RFC 3574 Transition Scenarios for 3GPP Networks • RFC 3588 DIAMETER base protocol • RFC 3589 DIAMETER command codes for 3GPP release 5 (informational) • RFC 3608 extension header field for service route discovery during registration • RFC 3680 SIP event package for registrations • RFC 3824 using E164 numbers with SIP

  41. Session Initiation Protocol -SIP • SIP is the core protocol for initiating, managing and terminating sessions in the Internet • These sessions may be text, voice, video or a combination of these • SIP sessions involve one or more participants and can use unicast or multicast communication.

  42. Session Initiation Protocol - SIP • Provides call control for multi-media services • initiation, modification, and termination of sessions • terminal-type negotiation and selections • call holding, forwarding, forking, transfer • media type negotiation (also mid-call changes) using Session Description Protocol (SDP) • Provides personal mobility support • Independent of transport protocols (TCP, UDP, SCTP,…) • ASCII format SIP headers • Separation of call signalling and data stream Application types/examples: • Interactive Voice over IP (VoIP) • Multimedia conferences (multi-party, e.g. voice & video) • Instant messaging • Presence service • Support of location-based services

  43. SIP in IMS • Mandatory existence of P-CSCF as first point of contact • Network initiated call release (e.g. due to missing coverage or administrative reasons) • Proxies are able to send BYE • Network Control of Media Types • P/S-CSCF checks the SDP in the SIP body • If SDP contains invalid parameters (e.g. not supported codecs), P/S-CSCF rejects the SIP request by sending a 488 (“not acceptable here”) response that contains a SDP body indicating parameters that would be acceptable by the network • Network Hiding (Encryption of Route and Via Headers)

  44. SIP in IMS • Additional Signaling Information • For example Cell-ID, Mobile Network/Country Code, Charging-IDs • Information transported P-header based solution • Compression • SIP Compression is mandatory as radio interface is a scarce resource • Compression / decompression of SIP will be performed by the UE and the P-CSCF • Authentication & Integrity protection • S-CSCF performs the Authentication using AKA • P-CSCF checks the integrity of messages received via the air interface via IPsec ESP

  45. SIP based session management

  46. Redirect Server Registrar Server Location Server SIP Architecture User Agent User Agent Proxy Server Proxy Server

  47. SIP Entities • User Agent User Agent Client User Agent Server • Proxy Server • Redirect Server • Registrar Server

  48. SIP Message Types Requests – Sent from client to server • INVITE • ACK • REFER • OPTIONS • BYE • CANCEL • REGISTER • SUBSCRIBE • NOTIFY • MESSAGE

  49. SIP Message Types (Contd.) Responses – Sent from server to the client • Success • Redirection • Forwarding • Request failure • Server failure • Global failure

  50. SIP Session Establishment and Call Termination

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