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Gprs Welcome to the world of internet. Unit – 3 Vipul joshi. Contents of Presentation. A) GPRS and packet data network, B) GPRS network architecture, C) GPRS network operation, D) Data services in GPRS, E) Applications of GPRS, F) Billing and charging in GPRS. “ GPRS “.
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GprsWelcome to the world of internet Unit – 3 Vipul joshi
Contents of Presentation A) GPRS and packet data network, B) GPRS network architecture, C) GPRS network operation, D) Data services in GPRS, E) Applications of GPRS, F) Billing and charging in GPRS
“ GPRS “ • GPRS- General Packet Radio Serviceprovides a direct link into the Internet from a GSM phone
INTRODUCTION TO GPRS • GPRS will undoubtedly speed up a handset's Internet connection - but it remains to be seen exactly how much speed can be achieved out of the system • GPRS works by aggregating a number of separate data channels. This is possible because data is being broken down into small 'packets' which are re-assembled by the receiving handset back into their original format.
INTRODUCTION (cont…) • GPRS stands for General Packet Radio Service , and is a relatively low cost technology that offers packet-based radio service and allows data or information to be sent and received across mobile telephone networks. • GPRS provides a permanent connection where information can be sent or received immediately as the need arises, subject to radio coverage.
Constraints with existing network • Data Rates too slow – about 9.6 kbps • Connection setup time too long • Inefficient resource utilization for bursty traffic • Proves expensive for bursty traffic utilization • No efficient method for packet transfers
GPRS in INDIA • BPL Mobile • Bharti Cellular • Hutchison Max • Hutchison Essar • Idea Cellular
a) GPRS and Packet Data N/W • Capacity and other end user aspects : It has ability to offer data speeds of 14.1 Kbps to 171.2 Kbps, which allow easy Internet access. • QoS (Quality of Service) : • Service precedence : is the priority of a service in relation to another service. High , normal and low • Reliability : loss, duplication and mis- sequencing • Delay : end to end transfer time • Throughput : Maximum bit rate • Integral Part of the future 3G Systems : the use of GPRS in GSM n/w is known as 2.5G with limited Internet accessibility speed.
B) GPRS ARCHITECTURE & n/w enhancement • GPRS Subscriber Terminals • GPRS BSS • GPRS Networks Node • GPRS Mobility Management
GPRS SYSTEM ARCHITECTURE Other GPRS PLMN Gd SMS-GMSC SMS-INMSC SGSN Gp GGSN Gb Gn GGSN Gf BTS BSC Gr Gs PDN Gi Gc BTS EIR HLR+GPRS Register MS D MSC/VLR
Interfaces • Gb – Connects BSC with SGSN • Gn – SGSN – SGSN/GGSN (in the same network) • Gp – SGSN –GGSN (in different networks) • Gf – For equipment querying at registering time • Gi – Connects PLMN with external Packet Data Networks (PDNs) • Gr – To exchange User profile between HLR & SGSN • Gs – To exchange Database between SGSN & MSC • Gd – Interface between SMS & GPRS
GPRS NETWORKS NODE • In the core network, the existing MSCs are based upon circuit-switched central-office technology, and they cannot handle packet traffic. • Thus two new components, called GPRS Support Nodes, are added: • Serving GPRS Support Node (SGSN) • Gateway GPRS Support Node (GGSN)
1) Gateway GPRS support node (GGSN): • The Gateway GPRS Support Node acts as an interface and a router to external networks. • The GGSN contains routing information for GPRS mobiles, which is used to tunnel packets through the IP based internal backbone to the correct Serving GPRS Support Node. • The GGSN also collects charging information connected to the use of the external data networks and can act as a packet filter for incoming traffic.
2) Serving GPRS support node (SGSN): • The Serving GPRS Support Node is responsible for authentication of GPRS mobiles, registration of mobiles in the network, mobility management, and collecting information for charging for the use of the air interface.
GPRS BSS • Each BSC will require the installation of one or more PCUs and a software upgrade. The PCU provides a physical and logical data interface out of the base station system (BSS) for packet data traffic. • The BTS may also require a software upgrade, but typically will not require hardware enhancement.
Transmission Plane & Protocol Architecture SNDCPSubnetwork Dependent Convergence Protocol RFL Physical RF Layer BSSGP Base Station System GPRS Protocol
IP / X.25 SNDCP GTP GTP UDP/ TCP UDP/ TCP LLC LLC LLC RLC RLC BSSGP BSSGP IP IP Frame Relay Frame Relay MAC MAC L2 L2 GSM RF L1bis L1bis L1 L1 MS BSS (PCU) SGSN GGSN Gi Transmission Plane & Protocol Architecture Protocol Stack Application IP / X.25 SNDCP GSM RF Gb Gn Um
Information transfer control procedures (e.g., flow control, error detection, error correction and error recovery), see Figure . The needed protocols are • SNDCPSubnetwork Dependent Convergence Protocol • LLC Logical Link Control • RLC Radio Link Control • MAC Medium Access Control • PLL Physical Link Layer • RFL Physical RF Layer • BSSGP Base Station System GPRS Protocol • IP Internet Protocol • TCP Transmission Control Protocol • UDP User Datagram Protocol • GTP GPRS Tunneling Protocol
1) SNDCP - Sub Network Dependent Convergence Protocol • Used to transfer data packets between SGSN and MS • Multiplexing of several connections of network layer onto one logical connection of underlying LLC layer • Compression and decompression of user data and header information
2) BSSGP-(BSS GPRS Application Protocol) • Delivers routing & Quality of Service related information between BSS and SGSN • LLC • N/W Service.
3) Data Link layer • Divided into two sub layers : • LLC layer (between MS-SGSN) • RLC/MAC (between MS-BSS)
LLC-Logical Link Control • Establishes highly reliable logical link between MS & its assigned SGSN • Works either in acknowledged or unacknowledged modes • Data confidentiality is ensured by ciphering functions
RLC/MAC Layer • Radio Link Control(RLC) • Establish a reliable link between MS & BSS • Segmentation and reassembly of LLC frames into RLC data blocks • Medium Access Control(MAC) • Controls access attempts of an MS on radio channels shared by several MSs • Employs algos. for contention resolution, multiuser multiplexing on PDTCH • Both ack and unack. Modes of operation are supported in RLC/MAC layer
4) Physical Layer • Divided into two sub layers : • Physical Link Layer (PLL) • Physical RF Layer (RFL) • PLL – Provides a physical channel between MS and BSS • Channel coding, interleaving, detection of physical link congestion • RFL - Operates below PLL
c) GPRS Network Operations • Attachment and De-attachment procedure • APN- Access Point Name • Mobility Management • Routing • Communicating with IP N/W
Attachment & Detachment Procedure • GPRS attach • User is registered in SGSN, after authentication check from HLR • SGSN assigns P-TMSI to MS • GPRS detach • Disconnection of MS from GPRS network is called GPRS detach • It can be initiated by MS or by network(SGSN or HLR)
2. Access Point Name • Access Point Name (APN) is a configurable network identifier used by a mobile device when connecting to a GSM carrier. • The carrier will then examine this identifier to determine what type of network connection should be created. • for example: what IP addresses should be assigned to the wireless device, what security methods should be used, and how or if, it should be connected to some private customer network.
Structure of APN • Network Identifier: Defines the external network to which the Gateway GPRS Support Node (GGSN) is connected. Optionally, it may also include the service requested by the user. This part of the APN is mandatory • Operator Identifier: Defines the specific operator’s packet domain network in which the GGSN is located. This part of the APN is optional. The MCC is the Mobile Country Code and the MNC is the Mobile Network Code which together uniquely identify a mobile network operator.
3. Mobility Management • GPRS Mobility Management (GMM) is a GPRS signaling protocol that handles mobility issues such as roaming, authentication, and selection of encryption algorithms. • GPRS Mobility Management, together with Session Management (GMM/SM) protocol support the mobility of user terminal so that the SGSN can know the location of a mobile station (MS) at any time and to activate, modify and deactivate the PDP sessions required by the MS for the user data transfer.
If the MS moves to a new Location Area, it also moves to a new Routing Area. Each RA is identified by a routing area identifier (RAI). This is made up of a location area identifier (LAI) and a routing area code (RAC).
4.Routing There are three important routing schemes: • Mobile-originated message: This path begins at the GPRS mobile and ends at the host • Network-initiated message when the MS is in its home network: This path begins at the host and ends at the GPRS mobile. • Network-initiated message when the MS roams to another GPRS network: This path begins at the host of visited network and ends at the GPRS mobile
D) Data services in gprs 1. Application Mode • Delivers routing & Quality of Service related information between BSS and SGSN
2.GTP – GPRS Tunneling Protocol • GTP tunnels user data packets and related signaling information between GSNs • Signaling is used to create, modify and delete tunnels • Defined both at Gn and Gpinterface • Below GTP, TCP or UDP are employed to transport the GTP Packets within backbone network
Inter working with IP networks • GPRS n/w can be interconnected with an IP-based packet data network • GPRS supports both IPv4 and IPv6 • GPRS n/w looks like IP sub network and GGSN looks like a IP router • DHCP, DNS servers are installed
WORKING OF GPRS • Each voice circuit in GSM transmits the speech on a secure 14kbps digital radio link between the mobile phone and a nearby GSM transceiver station. • The GPRS service joins together multiple speech channels to provide higher bandwidth data connections for GPRS data users. The radio bandwidth remains the same, it is just shared between the voice users and the data users.
GPRS handsets • The key use for GPRS is to send and receive data to a computer application such as Email, web browsing or even telemetry. • To use GPRS the service is 'dialed' in a similar manner to a standard data call at which point the user is 'attached' and an IP address is allocated.
GPRS MOBILE DEVICES(cont…) • The three standard methods to connect your computer to GPRS mobile phone are: 1… Infrared 2… Data-cable 3… Bluetooth
Bearers in gprs • GPRS supports following types of data services: • SMS • WAP • MMS
GPRS Roaming • In the short term don't expect to be able to roam to many countries with GPRS, many networks are still negotiating to set up roaming agreements. Technically there are two type of GPRS Roaming 1… Home Network Roaming 2… Local Network Roaming
GPRS SECURITY • The radio interface is considered to be relatively secure being controlled by the GSM network's security - (SIM card + HLR). Security issues arise when data needs to leave the GPRS network to be delivered to either the Internet or a company LAN. • Internet connectivity is the cheapest and most common - and here you can take charge of security by encrypting sensitive data.
E) GENERAL APPLICATIONS OF GPRS • Communications—E-mail and fax; • Intranet/Internet access • Value-added services (VAS)—Information services; games • E-commerce—Retail; ticket purchasing; banking; financial trading • Location-based applications—Navigation; traffic conditions; airline/rail schedules; location finder • Vertical applications—Freight delivery; fleet management; sales-force automation • Advertising
Applications of GPRS • Web browsing • Corporate & Internet Email • Vehicle Positioning • Remote LAN Access • Home Automation • Document Sharing/Collaborative working • E-Commerce • Banking • Financial Trading • Unified Messaging
LIMITATIONS OF GPRS • Limited Cell Capacity for All Users • Speeds Much Lower in Reality • Support of GPRS Mobile Terminate by Terminals is Not Ensured • Suboptimal Modulation • Transit Delays • No Store and Forward
ADVANTAGES OF GPRS • GPRS will enable a variety of new and unique services to the mobile wireless subscriber. These mobile applications contain several unique characteristics that enhance the value to the customers. • First among them is mobility—the ability to maintain constant voice and data communications while on the move. • Second is immediacy, which allows subscribers to obtain connectivity when needed, regardless of location and without a lengthy login session. • Finally, localization allows subscribers to obtain information relevant to their current location