THIRD GENERATION (3G) WIRELESS SYSTEM

HISTORY

The first pre-commercial 3G network was launched by NTT DoCoMo in Japan on 1998^[8], branded as FOMA. It was first available in May 2001 as a pre-release (test) of W-CDMA technology.^[9] The first commercial launch of 3G was also by NTT DoCoMo in Japan on 1 October 2001, although it was initially somewhat limited in scope;^[10][11] broader availability of the system was delayed by apparent concerns over its reliability.^[12]

The first European pre-commercial network was an UMTS network on the Isle of Man by Manx Telecom, the operator then owned by British Telecom, and the first commercial network (also UMTS based W-CDMA) in Europe was opened for business by Telenor in December 2001 with no commercial handsets and thus no paying customers.

The first network to go commercially live was by SK Telecom in South Korea on the CDMA-based 1xEV-DO technology in January 2002. By May 2002 the second South Korean 3G network was by KT on EV-DO and thus the Koreans were the first to see competition among 3G operators.

The first commercial United States 3G network was by Monet Mobile Networks, on CDMA2000 1x EV-DO technology, but this network provider later shut down operations. The second 3G network operator in the USA was Verizon Wireless in July 2002 also on CDMA2000 1x EV-DO. AT&T Mobility is also a true 3G UMTS network, having completed its upgrade of the 3G network to HSUPA.

3G refers to the third generation of mobile telephony (that is, cellular) technology. The third generation, as the name suggests, follows two earlier generations.

DEFINITION

The first generation (1G) began in the early 80's with commercial deployment of Advanced Mobile Phone Service (AMPS) cellular networks. Early AMPS networks used Frequency Division Multiplexing Access (FDMA) to carry analog voice over channels in the 800 MHz frequency band.

The second generation (2G) emerged in the 90's when mobile operators deployed two competing digital voice standards. In North America, some operators adopted IS-95, which used Code Division Multiple Access (CDMA) to multiplex up to 64 calls per channel in the 800 MHz band. Across the world, many operators adopted the Global System for Mobile communication (GSM) standard, which used Time Division Multiple Access (TDMA) to multiplex up to 8 calls per channel in the 900 and 1800 MHz bands.

The International Telecommunications Union (ITU) defined the third generation (3G) of mobile telephony standards IMT-2000 to facilitate growth, increase bandwidth, and support more diverse applications. For example, GSM could deliver not only voice, but also circuit-switched data at speeds up to 14.4 Kbps. But to support mobile multimedia applications, Wireless Networks, WiMAX, 3G and Wireless Broadband, Basics.

3G had to deliver packet-switched data with better spectral efficiency, at far greater speeds.

However, to get from 2G to 3G, mobile operators had make "evolutionary" upgrades to existing networks while simultaneously planning their "revolutionary" new mobile broadband networks. This lead to the establishment of two distinct 3G families: 3GPP and 3GPP2.

The 3rd Generation Partnership Project (3GPP) was formed in 1998 to foster deployment of 3G networks that descended from GSM. 3GPP technologies evolved as follows.

• General Packet Radio Service (GPRS) offered speeds up to 114 Kbps.

• Enhanced Data Rates for Global Evolution (EDGE) reached up to 384 Kbps.

• UMTS Wideband CDMA (WCDMA) offered downlink speeds up to 1.92 Mbps.

• High Speed Downlink Packet Access (HSDPA) boosted the downlink to 14Mbps.

• LTE Evolved UMTS Terrestrial Radio Access (E-UTRA) is aiming for 100 Mbps.

ADVANTAGES OF 3G

             The Advantage that 3G tends to have when compared to all earlier forms of next generation mobile communications systems is an improvement in bit rate.  The higher bit rate capabilities have brought about a move in service providers to indulge into producing  many bandwidth intensive applications that would not have been conceived of otherwise.  There are 2 forces bringing about the improvement of these 3G systems.  The first being the need for higher data rate services, such as high-speed wireless Internet access.  The second being more efficient use of the available radio frequency (RF) spectrum.  The second is a consequence of the projected expansion in worldwide usage of wireless services.

Benefits also include packet-based data offers a number of advantages over the existing circuit-switched methods used for transporting mobile voice.  It allows increased call volumes and support for multimedia data applications, such as video and photography.

Consumers will be charged on the quantity of data they transmit, not on how much time they are connected to the network, while with 3G you are constantly online and basically pay for the information you receive.

While third-generation packet based networks will allow users to be online all the time the capability for new applications is huge.




References:
http://home.wlv.ac.uk/~a9814003/advantages_of_3g.htm
http://www.answers.com/topic/3g
http://searchtelecom.techtarget.com/definition/3G

GENERAL PACKET RADIO SERVICE (GPRS)

General Packet Radio Services (GPRS) is a packet-based wireless communication service that promises data rates from 56 up to 114 Kbps and continuous connection to the Internet for mobile phone and computer users. The higher data rates allow users to take part in video conferences and interact with multimedia Web sites and similar applications using mobile handheld devices as well as notebook computers. GPRS is based on Global System for Mobile (GSM) communication and complements existing services such circuit-switched cellular phone connections and the Short Message Service (SMS).

In theory, GPRS packet-based services cost users less than circuit-switched services since communication channels are being used on a shared-use, as-packets-are-needed basis rather than dedicated to only one user at a time. It is also easier to make applications available to mobile users because the faster data rate means that middleware currently needed to adapt applications to the slower speed of wireless systems are no longer be needed. As GPRS has become more widely available, along with other 2.5G and 3G services, mobile users of virtual private networks (VPNs) have been able to access the private network continuously over wireless rather than through a rooted dial-up connection.

The key drivers for operators to evolve to GPRS networks are to:

Ø  Increase revenues by moving into the mobile data market, especially since the voice market has had profit margins squeezed with the commoditization of voice services.

Ø  Gain new subscribers who require mobile data services or do not want to invest in a PC to gain internet access.

Ø  Retain current subscribers by offering new services.

Ø  Reduce costs due to the efficient use of network resources.

Ø  Ease of adapting applications for mobile users because high data speeds mean that middleware is no longer required to convert fixed applications for mobile use.

GPRS also complements Bluetooth, a standard for replacing wired connections between devices with wireless radio connections. In addition to the Internet Protocol (IP), GPRS supports X.25, a packet-based protocol that is used mainly in Europe. GPRS is an evolutionary step toward Enhanced Data GSM Environment (EDGE) and Universal Mobile Telephone Service (UMTS).

Advantages of GPRS

GPRS brought mobile phone users out from the world of WAP, and into a world where Internet was finally available on mobiles. This in itself was a monumental feat, and hence GPRS took off with quite a bang. With GPRS, large amounts of data can be transferred to and from the mobile device over the Internet.

Applications for GPRS

Ø  Chat

Ø  Textual and Visual Information

Ø  Moving Images

Ø  Web Browsing

Ø  Document Sharing/Collaborative Working

Ø  Audio

Ø  Job Dispatch

Ø  Corporate E−mail

Ø  Internet E−mail

Ø  Vehicle Positioning

Ø  Remote LAN Access

Ø  File Transfer

Ø  Home Automation

Disadvantages:

Ø  GPRS packet loss phenomena occur. As the packet 
switching connection is worse than the number of circuit-switched connection, 
therefore, use the GPRS packet loss phenomena will occur. 

Ø   The actual rate lower than the theoretical value, GPRS 
data transfer rate to achieve the theoretical maximum 172.2kbps, must be only 
one user occupy all eight time slots, and no protection against mistakes. 

Ø   Termination of the Terminal does not 
support wireless functions, the absence of any declared a major handset 
manufacturer to support its GPRS wireless terminal to receive calls termination 
functions, this would be whether the market can successfully GPRS from other 
non-voice services market, grab the user's core problem.

Ø   Modulation is not optimal, GPRS-based GMSK (Gaussian 
Minimum-Shift Keying) modulation technique, compared to, EDGE modulation method 
based on a new 8PSK (eight-phase-shift keying), which allows wireless interface 
to support higher rates.

Ø  There is switching delay, GPRS packet data sent by different 
directions and eventually reach the same destination, then the data is 
transmitted via wireless link may occur during one or several packet loss or 
error situation.

References:


http://searchmobilecomputing.techtarget.com/definition/GPRS
http://www.mobilein.com/GPRS.pdf
http://www.brighthub.com/mobile/symbian-platform/articles/16995.aspx
http://www.blurtit.com/q3456268.html