General Packet Radio Service

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General Packet Radio Service (GPRS) is a packet oriented mobile data service on the 2G and 3G cellular communication system's global system for mobile communications (GSM). GPRS was originally standardized by European Telecommunications Standards Institute (ETSI) in response to the earlier CDPD and i-mode packet-switched cellular technologies. It is now maintained by the 3rd Generation Partnership Project (3GPP).[1][2]

GPRS usage is typically charged based on volume of data transferred, contrasting with circuit switched data, which is usually billed per minute of connection time. Sometimes billing time is broken down to every third of a minute. Usage above the bundle cap is charged per megabyte, speed limited, or disallowed.

GPRS is a best-effort service, implying variable throughput and latency that depend on the number of other users sharing the service concurrently, as opposed to circuit switching, where a certain quality of service (QoS) is guaranteed during the connection. In 2G systems, GPRS provides data rates of 56–114 kbit/second.[3] 2G cellular technology combined with GPRS is sometimes described as 2.5G, that is, a technology between the second (2G) and third (3G) generations of mobile telephony.[4] It provides moderate-speed data transfer, by using unused time division multiple access (TDMA) channels in, for example, the GSM system. GPRS is integrated into GSM Release 97 and newer releases.

Technical overview[edit]

The GPRS core network allows 2G, 3G and WCDMA mobile networks to transmit IP packets to external networks such as the Internet. The GPRS system is an integrated part of the GSM network switching subsystem.

Services offered[edit]

GPRS extends the GSM Packet circuit switched data capabilities and makes the following services possible:

If SMS over GPRS is used, an SMS transmission speed of about 30 SMS messages per minute may be achieved. This is much faster than using the ordinary SMS over GSM, whose SMS transmission speed is about 6 to 10 SMS messages per minute.

Protocols supported[edit]

GPRS supports the following protocols:

  • Internet Protocol (IP). In practice, built-in mobile browsers use IPv4 since IPv6 was not yet popular.
  • Point-to-Point Protocol (PPP). In this mode PPP is often not supported by the mobile phone operator but if the mobile is used as a modem to the connected computer, PPP is used to tunnel IP to the phone. This allows an IP address to be assigned dynamically (IPCP not DHCP) to the mobile equipment.
  • X.25 connections. This is typically used for applications like wireless payment terminals, although it has been removed from the standard. X.25 can still be supported over PPP, or even over IP, but doing this requires either a network-based router to perform encapsulation or intelligence built into the end-device/terminal; e.g., user equipment (UE).

When TCP/IP is used, each phone can have one or more IP addresses allocated. GPRS will store and forward the IP packets to the phone even during handover. The TCP handles any packet loss (e.g. due to a radio noise induced pause).


Devices supporting GPRS are divided into three classes:

Class A
Can be connected to GPRS service and GSM service (voice, SMS), using both at the same time. Such devices are known to be available today.
Class B
Can be connected to GPRS service and GSM service (voice, SMS), but using only one or the other at a given time. During GSM service (voice call or SMS), GPRS service is suspended, and then resumed automatically after the GSM service (voice call or SMS) has concluded. Most GPRS mobile devices are Class B.
Class C
Are connected to either GPRS service or GSM service (voice, SMS). Must be switched manually between one or the other service.

A true Class A device may be required to transmit on two different frequencies at the same time, and thus will need two radios. To get around this expensive requirement, a GPRS mobile may implement the dual transfer mode (DTM) feature. A DTM-capable mobile may use simultaneous voice and packet data, with the network coordinating to ensure that it is not required to transmit on two different frequencies at the same time. Such mobiles are considered pseudo-Class A, sometimes referred to as "simple class A". Some networks support DTM since 2007.

Huawei E220 3G/GPRS Modem

USB 3G/GPRS modems use a terminal-like interface over USB 1.1, 2.0 and later, data formats V.42bis, and RFC 1144 and some models have connector for external antenna. Modems can be added as cards (for laptops) or external USB devices which are similar in shape and size to a computer mouse, or nowadays more like a pendrive.


A GPRS connection is established by reference to its access point name (APN). The APN defines the services such as wireless application protocol (WAP) access, short message service (SMS), multimedia messaging service (MMS), and for Internet communication services such as email and World Wide Web access.

In order to set up a GPRS connection for a wireless modem, a user must specify an APN, optionally a user name and password, and very rarely an IP address, provided by the network operator.

GPRS modems and modules[edit]

GSM module or GPRS modules are similar to modems, but there’s one difference: the modem is an external piece of equipment, whereas the GSM module or GPRS module can be integrated within an electrical or electronic equipment. It is an embedded piece of hardware. A GSM mobile, on the other hand, is a complete embedded system in itself. It comes with embedded processors dedicated to provide a functional interface between the user and the mobile network.

Coding schemes and speeds[edit]

The upload and download speeds that can be achieved in GPRS depend on a number of factors such as:

  • the number of BTS TDMA time slots assigned by the operator
  • the channel encoding is used.
  • the maximum capability of the mobile device expressed as a GPRS multislot class

Multiple access schemes[edit]

The multiple access methods used in GSM with GPRS are based on frequency division duplex (FDD) and TDMA. During a session, a user is assigned to one pair of up-link and down-link frequency channels. This is combined with time domain statistical multiplexing which makes it possible for several users to share the same frequency channel. The packets have constant length, corresponding to a GSM time slot. The down-link uses first-come first-served packet scheduling, while the up-link uses a scheme very similar to reservation ALOHA (R-ALOHA). This means that slotted ALOHA (S-ALOHA) is used for reservation inquiries during a contention phase, and then the actual data is transferred using dynamic TDMA with first-come first-served.

Channel encoding[edit]

The channel encoding process in GPRS consists of two steps: first, a cyclic code is used to add parity bits, which are also referred to as the Block Check Sequence, followed by coding with a possibly punctured convolutional code.[5] The Coding Schemes CS-1 to CS-4 specify the number of parity bits generated by the cyclic code and the puncturing rate of the convolutional code.[5] In Coding Schemes CS-1 through CS-3, the convolutional code is of rate 1/2, i.e. each input bit is converted into two coded bits.[5] In Coding Schemes CS-2 and CS-3, the output of the convolutional code is punctured to achieve the desired code rate.[5] In Coding Scheme CS-4, no convolutional coding is applied.[5] The following table summarises the options.

Coding scheme
Bitrate including RLC/MAC overhead[a][b]
Bitrate excluding RLC/MAC overhead[c]
Modulation Code rate
CS-1 9.20 8.00 GMSK 1/2
CS-2 13.55 12.00 GMSK ≈2/3
CS-3 15.75 14.40 GMSK ≈3/4
CS-4 21.55 20.00 GMSK 1
  1. ^ This is rate at which the RLC/MAC layer protocol data unit (PDU) (called a radio block) is transmitted. As shown in TS 44.060 section 10.0a.1,[6] a radio block consists of MAC header, RLC header, RLC data unit and spare bits. The RLC data unit represents the payload, the rest is overhead. The radio block is coded by the convolutional code specified for a particular Coding Scheme, which yields the same PHY layer data rate for all Coding Schemes.
  2. ^ Cited in various sources, e.g. in TS 45.001 table 1.[5] is the bitrate including the RLC/MAC headers, but excluding the uplink state flag (USF), which is part of the MAC header,[7] yielding a bitrate that is 0.15 kbit/s lower.
  3. ^ The net bitrate here is the rate at which the RLC/MAC layer payload (the RLC data unit) is transmitted. As such, this bit rate excludes the header overhead from the RLC/MAC layers.

The least robust, but fastest, coding scheme (CS-4) is available near a base transceiver station (BTS), while the most robust coding scheme (CS-1) is used when the mobile station (MS) is further away from a BTS.

Using the CS-4 it is possible to achieve a user speed of 20.0 kbit/s per time slot. However, using this scheme the cell coverage is 25% of normal. CS-1 can achieve a user speed of only 8.0 kbit/s per time slot, but has 98% of normal coverage. Newer network equipment can adapt the transfer speed automatically depending on the mobile location.

In addition to GPRS, there are two other GSM technologies which deliver data services: circuit-switched data (CSD) and high-speed circuit-switched data (HSCSD). In contrast to the shared nature of GPRS, these instead establish a dedicated circuit (usually billed per minute). Some applications such as video calling may prefer HSCSD, especially when there is a continuous flow of data between the endpoints.

The following table summarises some possible configurations of GPRS and circuit switched data services.

Technology Download (kbit/s) Upload (kbit/s) TDMA timeslots allocated (DL+UL)
CSD 9.6 9.6 1+1
HSCSD 28.8 14.4 2+1
HSCSD 43.2 14.4 3+1
GPRS 85.6 21.4 (Class 8 & 10 and CS-4) 4+1
GPRS 64.2 42.8 (Class 10 and CS-4) 3+2
EGPRS (EDGE) 236.8 59.2 (Class 8, 10 and MCS-9) 4+1
EGPRS (EDGE) 177.6 118.4 (Class 10 and MCS-9) 3+2

Multislot Class[edit]

The multislot class determines the speed of data transfer available in the Uplink and Downlink directions. It is a value between 1 and 45 which the network uses to allocate radio channels in the uplink and downlink direction. Multislot class with values greater than 31 are referred to as high multislot classes.

A multislot allocation is represented as, for example, 5+2. The first number is the number of downlink timeslots and the second is the number of uplink timeslots allocated for use by the mobile station. A commonly used value is class 10 for many GPRS/EGPRS mobiles which uses a maximum of 4 timeslots in downlink direction and 2 timeslots in uplink direction. However simultaneously a maximum number of 5 simultaneous timeslots can be used in both uplink and downlink. The network will automatically configure for either 3+2 or 4+1 operation depending on the nature of data transfer.

Some high end mobiles, usually also supporting UMTS, also support GPRS/EDGE multislot class 32. According to 3GPP TS 45.002 (Release 12), Table B.1,[8] mobile stations of this class support 5 timeslots in downlink and 3 timeslots in uplink with a maximum number of 6 simultaneously used timeslots. If data traffic is concentrated in downlink direction the network will configure the connection for 5+1 operation. When more data is transferred in the uplink the network can at any time change the constellation to 4+2 or 3+3. Under the best reception conditions, i.e. when the best EDGE modulation and coding scheme can be used, 5 timeslots can carry a bandwidth of 5*59.2 kbit/s = 296 kbit/s. In uplink direction, 3 timeslots can carry a bandwidth of 3*59.2 kbit/s = 177.6 kbit/s.[9]

Multislot Classes for GPRS/EGPRS[edit]

Multislot Class Downlink TS Uplink TS Active TS
1 1 1 2
2 2 1 3
3 2 2 3
4 3 1 4
5 2 2 4
6 3 2 4
7 3 3 4
8 4 1 5
9 3 2 5
10 4 2 5
11 4 3 5
12 4 4 5
30 5 1 6
31 5 2 6
32 5 3 6
33 5 4 6
34 5 5 6

Attributes of a multislot class[edit]

Each multislot class identifies the following:

  • the maximum number of Timeslots that can be allocated on uplink
  • the maximum number of Timeslots that can be allocated on downlink
  • the total number of timeslots which can be allocated by the network to the mobile
  • the time needed for the MS to perform adjacent cell signal level measurement and get ready to transmit
  • the time needed for the MS to get ready to transmit
  • the time needed for the MS to perform adjacent cell signal level measurement and get ready to receive
  • the time needed for the MS to get ready to receive.

The different multislot class specification is detailed in the Annex B of the 3GPP Technical Specification 45.002 (Multiplexing and multiple access on the radio path)


The maximum speed of a GPRS connection offered in 2003 was similar to a modem connection in an analog wire telephone network, about 32–40 kbit/s, depending on the phone used. Latency is very high; round-trip time (RTT) is typically about 600–700 ms and often reaches 1s. GPRS is typically prioritized lower than speech, and thus the quality of connection varies greatly.

Devices with latency/RTT improvements (via, for example, the extended UL TBF mode feature) are generally available. Also, network upgrades of features are available with certain operators. With these enhancements the active round-trip time can be reduced, resulting in significant increase in application-level throughput speeds.

History of GPRS[edit]

GPRS opened in 2000 as a packet-switched data service embedded to the channel-switched cellular radio network GSM. GPRS extends the reach of the fixed Internet by connecting mobile terminals worldwide.

The CELLPAC[10] protocol developed 1991-1993 was the trigger point for starting in 1993 specification of standard GPRS by ETSI SMG. Especially, the CELLPAC Voice & Data functions introduced in a 1993 ETSI Workshop contribution[11] anticipate what was later known to be the roots of GPRS. This workshop contribution is referenced in 22 GPRS related US-Patents.[12] Successor systems to GSM/GPRS like W-CDMA (UMTS) and LTE rely on key GPRS functions for mobile Internet access as introduced by CELLPAC.

According to a study on history of GPRS development[13] Bernhard Walke and his student Peter Decker are the inventors of GPRS – the first system providing worldwide mobile Internet access.

See also[edit]


  1. ^ ETSI
  2. ^ 3GPP
  3. ^ General packet radio service from Qkport
  4. ^ Mobile Phone Generations from Archived June 11, 2010, at the Wayback Machine.
  5. ^ a b c d e f 3rd Generation Partnership Project (November 2014). "3GGP TS45.001: Technical Specification Group GSM/EDGE Radio Access Network; Physical layer on the radio path; General description". 12.1.0. Retrieved 2015-12-05. 
  6. ^ 3rd Generation Partnership Project (June 2015). "3GGP TS45.001: Technical Specification Group GSM/EDGE Radio Access Network; Mobile Station (MS) - Base Station System (BSS) interface; Radio Link Control / Medium Access Control (RLC/MAC) protocol; section 10.0a.1 - GPRS RLC/MAC block for data transfer". 12.5.0. Retrieved 2015-12-05. 
  7. ^ 3rd Generation Partnership Project (June 2015). "3GGP TS45.001: Technical Specification Group GSM/EDGE Radio Access Network; Mobile Station (MS) - Base Station System (BSS) interface; Radio Link Control / Medium Access Control (RLC/MAC) protocol; section 10.2.1 - Downlink RLC data block". 12.5.0. Retrieved 2015-12-05. 
  8. ^ 3rd Generation Partnership Project (March 2015). "3GGP TS45.002: Technical Specification Group GSM/EDGE Radio Access Network; Multiplexing and multiple access on the radio path (Release 12)". 12.4.0. Retrieved 2015-12-05. 
  9. ^ GPRS and EDGE Multislot Classes
  10. ^ Bernhard Walke, Wolf Mende, Georgios Hatziliadis: “CELLPAC: A packet radio protocol applied to the cellular GSM mobile radio network”, Proceedings of 41st IEEE Vehicular Technology Conference, May 1991, 408-413.
  11. ^ Peter Decker, Bernhard Walke: “A General Packet Radio Service proposed for GSM”, ETSI SMG Workshop “GSM in a Future Competitive Environment”, Helsinki, Finland, Oct. 13, 1993, pp. 1-20.
  12. ^ Program “Publish or Perish”, see [1] returns to a search for P. Decker, B. Walke their most cited paper that (after double click) unveils US patents referencing that paper
  13. ^ Bernhard Walke: „The Roots of GPRS: The First System for Mobile Packet-Based Global Internet Access“, IEEE Wireless Communications, Oct. 2013, 12-23.

External links[edit]