4G

From Wikipedia, the free encyclopedia

In telecommunications, 4G is the fourth generation of cellular wireless standards. It is a successor to the 3G and 2G families of standards. In 2008, the ITU-R organization specified the IMT-Advanced (International Mobile Telecommunications Advanced) requirements for 4G standards, setting peak speed requirements for 4G service at 100 Mbit/s for high mobility communication (such as from trains and cars) and 1 Gbit/s for low mobility communication (such as pedestrians and stationary users).^[1]
A 4G system is expected to provide a comprehensive and secure all-IP based mobile broadband solution to laptop computer wireless modems, smartphones, and other mobile devices. Facilities such as ultra-broadband Internet access, IP telephony, gaming services, and streamed multimedia may be provided to users.
Pre-4G technologies such as mobile WiMAX and Long term evolution (LTE) have been on the market since 2006^[2] and 2009^[3][4][5] respectively, and are often branded as 4G. The current versions of these technologies did not fulfill the original ITU-R requirements of data rates approximately up to 1 Gbit/s for 4G systems. Marketing materials use 4G as a description for LTE and Mobile-WiMAX in their current forms.
IMT-Advanced compliant versions of the above two standards are under development and called “LTE Advanced” and “WirelessMAN-Advanced” respectively. ITU has decided that “LTE Advanced” and “WirelessMAN-Advanced” should be accorded the official designation of IMT-Advanced. On December 6, 2010, ITU announced that current versions of LTE, WiMax and other evolved 3G technologies that do not fulfill "IMT-Advanced" requirements could be considered "4G", provided they represent forerunners to IMT-Advanced and "a substantial level of improvement in performance and capabilities with respect to the initial third generation systems now deployed."^[6]
In all suggestions for 4G, the CDMA spread spectrum radio technology used in 3G systems and IS-95 is abandoned and replaced by OFDMA and other frequency-domain equalization schemes.^{[citation needed]} This is combined with MIMO (Multiple In Multiple Out), e.g., multiple antennas, dynamic channel allocation and channel-dependent scheduling.^{[citation needed]}

Contents 1 Background 2 ITU Requirements and 4G wireless standards 3 4G Predecessors and candidate systems 3.1 4G candidate systems 3.1.1 LTE Advanced 3.1.2 IEEE 802.16m or WirelessMAN-Advanced 3.2 4G predecessors and discontinued candidate systems 3.2.1 3GPP Long Term Evolution (LTE) 3.2.2 Mobile WiMAX (IEEE 802.16e) 3.2.3 UMB (formerly EV-DO Rev. C) 3.2.4 Flash-OFDM 3.2.5 iBurst and MBWA (IEEE 802.20) systems 4 Data rate comparison 5 Objective and approach 5.1 Objectives assumed in the literature 5.2 Approaches 5.2.1 Principal technologies 6 4G features assumed in early literature 7 Components 7.1 Access schemes 7.2 IPv6 support 7.3 Advanced antenna systems 7.4 Software-defined radio (SDR) 8 History of 4G and pre-4G technologies 8.1 Deployment plans 9 Beyond 4G research 10 References 11 External links

[edit] Background

The nomenclature of the generations generally refers to a change in the fundamental nature of the service, non-backwards compatible transmission technology, and new frequency bands. New generations have appeared about every ten years since the first move from 1981 analog (1G) to digital (2G) transmission in 1992. This was followed, in 2001, by 3G multi-media support, spread spectrum transmission and at least 200 kbit/s, in 2011 expected to be followed by 4G, which refers to all-IP packet-switched networks, mobile ultra-broadband (gigabit speed) access and multi-carrier transmission.^{[citation needed]}
The fastest 3G based standard in the WCDMA family is the HSPA+ standard, which was commercially available in 2009 and offers 28 Mbit/s downstreams without MIMO, i.e. only with one antenna (it would offer 56 Mbit/s with 2x2 MIMO), and 22 Mbit/s upstreams. The fastest 3G based standard in the CDMA2000 family is the EV-DO Rev. B, which was available in 2010 and offers 15.67 Mbit/s downstreams.^{[citation needed]}
In mid 1990s, the ITU-R organization specified the IMT-2000 specifications for what standards that should be considered 3G systems. However, the cell phone market only brands some of the IMT-2000 standards as 3G (e.g. WCDMA and CDMA2000), but not all (3GPP EDGE, DECT and mobile-WiMAX all fulfil the IMT-2000 requirements and are formally accepted as 3G standards, but are typically not branded as 3G). In 2008, ITU-R specified the IMT-Advanced (International Mobile Telecommunications Advanced) requirements for 4G systems.

[edit] ITU Requirements and 4G wireless standards

This article uses 4G to refer to IMT-Advanced (International Mobile Telecommunications Advanced), as defined by ITU-R. An IMT-Advanced cellular system must fulfil the following requirements:^[7]

• Based on an all-IP packet switched network.
• Peak data rates of up to approximately 100 Mbit/s for high mobility such as mobile access and up to approximately 1 Gbit/s for low mobility such as nomadic/local wireless access, according to the ITU requirements.
• Dynamically share and utilize the network resources to support more simultaneous users per cell.
• Scalable channel bandwidth, between 5 and 20 MHz, optionally up to 40 MHz.^[8][8][9]
• Peak link spectral efficiency of 15 bit/s/Hz in the downlink, and 6.75 bit/s/Hz in the uplink (meaning that 1 Gbit/s in the downlink should be possible over less than 67 MHz bandwidth).
• System spectral efficiency of up to 3 bit/s/Hz/cell in the downlink and 2.25 bit/s/Hz/cell for indoor usage.^[8]
• Smooth handovers across heterogeneous networks.
• Ability to offer high quality of service for next generation multimedia support.

In September 2009, the technology proposals were submitted to the International Telecommunication Union (ITU) as 4G candidates.^[10] Basically all proposals are based on two technologies:

• LTE Advanced standardized by the 3GPP
• 802.16m standardized by the IEEE (i.e. WiMAX)

Present implementations of WiMAX and LTE are largely considered a stopgap solution that will offer a considerable boost while WiMAX 2 (based on the 802.16m spec) and LTE Advanced are finalized. Both technologies aim to reach the objectives traced by the ITU, but are still far from being implemented.^[7]
The first set of 3GPP requirements on LTE Advanced was approved in June 2008.^[11] LTE Advanced will be standardized in 2010 as part of the Release 10 of the 3GPP specification. LTE Advanced will be fully built on the existing LTE specification Release 10 and not be defined as a new specification series. A summary of the technologies that have been studied as the basis for LTE Advanced is included in a technical report.^[12]
Current LTE and WiMAX implementations are considered pre-4G, as they don't fully comply with the planned requirements of 1 Gbit/s for stationary reception and 100 Mbit/s for mobile.
Confusion has been caused by some mobile carriers who have launched products advertised as 4G but which are actually current technologies, commonly referred to as '3.9G', which do not follow the ITU-R defined principles for 4G standards. A common argument for branding 3.9G systems as new-generation is that they use different frequency bands to 3G technologies; that they are based on a new radio-interface paradigm; and that the standards are not backwards compatible with 3G, whilst some of the standards are expected to be forwards compatible with "real" 4G technologies.
While the ITU has adopted recommendations for technologies that would be used for future global communications, they do not actually perform the standardization or development work themselves, instead relying on the work of other standards bodies such as IEEE, The WiMAX Forum and 3GPP. Recently, ITU-R Working Party 5D approved two industry-developed technologies (LTE Advanced and WirelessMAN-Advanced)^[13] for inclusion in the ITU’s International Mobile Telecommunications Advanced (IMT-Advanced program), which is focused on global communication systems that would be available several years from now.^{[citation needed]} This working party’s objective was not to comment on today’s 4G being rolled out in the United States and in fact, the Working Party itself purposely agreed not to tie their IMT-Advanced work to the term 4G, recognizing its common use in industry already; however, the ITU’s PR department ignored that agreement and used term 4G anyway when issuing their press release.^{[citation needed]}
The ITU’s purpose is to foster the global use of communications.^{[citation needed]} The ITU is relied upon by developing countries,^{[citation needed]} for example, who want to be assured a technology is standardised and likely to be widely deployed. While the ITU has developed recommendations on IMT-Advanced, those recommendations are not binding on ITU member countries.^{[citation needed]}

4G Predecessors and candidate systems

The wireless telecommunications industry as a whole has early assumed the term 4G as a short hand way to describe those advanced cellular technologies that, among other things, are based on or employ wide channel OFDMA and SC-FDE technologies, MIMO transmission and an all-IP based architecture.^{[citation needed]} Mobile-WiMAX, first release LTE, IEEE 802.20 as well as Flash-OFDM meets these early assumptions, and have been considered as 4G candidate systems, but do not yet meet the more recent ITU-R IMT-Advanced requirements.

4G candidate systems

LTE Advanced

See also: 3GPP Long Term Evolution (LTE) below

LTE Advanced (Long-term-evolution Advanced) is a candidate for IMT-Advanced standard, formally submitted by the 3GPP organization to ITU-T in the fall 2009, and expected to be released in 2012. The target of 3GPP LTE Advanced is to reach and surpass the ITU requirements.^[14] LTE Advanced is essentially an enhancement to LTE. It is not a new technology but rather an improvement on the existing LTE network. This upgrade path makes it more cost effective for vendors to offer LTE and then upgrade to LTE Advanced which is similar to the upgrade from WCDMA to HSPA. LTE and LTE Advanced will also make use of additional spectrum and multiplexing to allow it to achieve higher data speeds. Coordinated Multi-point Transmission will also allow more system capacity to help handle the enhanced data speeds. Release 10 of LTE is expected to achieve the LTE Advanced speeds. Release 8 currently supports up to 300 Mbit/s download speeds which is still short of the IMT-Advanced standards.^[15]

Data speeds of LTE Advanced

	LTE Advanced
Peak Download	1 Gbit/s
Peak Upload	500 Mbit/s

IEEE 802.16m or WirelessMAN-Advanced

The IEEE 802.16m or WirelessMAN-Advanced evolution of 802.16e is under development, with the objective to fulfill the IMT-Advanced criteria of 1 Gbit/s for stationary reception and 100 Mbit/s for mobile reception.^[16]

4G predecessors and discontinued candidate systems

3GPP Long Term Evolution (LTE)

See also: LTE Advanced above

Telia-branded Samsung LTE modem

The pre-4G technology 3GPP Long Term Evolution (LTE) is often branded "4G", but the first LTE release does not fully comply with the IMT-Advanced requirements. LTE has a theoretical net bit rate capacity of up to 100 Mbit/s in the downlink and 50 Mbit/s in the uplink if a 20 MHz channel is used — and more if multiple-input multiple-output (MIMO), i.e. antenna arrays, are used.
The physical radio interface was at an early stage named High Speed OFDM Packet Access (HSOPA), now named Evolved UMTS Terrestrial Radio Access (E-UTRA). The first LTE USB dongles do not support any other radio interface.
The world's first publicly available LTE service was opened in the two Scandinavian capitals Stockholm (Ericsson system) and Oslo (a Huawei system) on 14 December 2009, and branded 4G. The user terminals were manufactured by Samsung.^[3] Currently, the two publicly available LTE services in the United States are provided by Metro PCS,^[17] and Verizon Wireless.^[18] AT&T also has an LTE service in planned for deployment between mid-2011 and end of 2013.^[18]

Mobile WiMAX (IEEE 802.16e)

The Mobile WiMAX (IEEE 802.16e-2005) mobile wireless broadband access (MWBA) standard (also known as WiBro in South Korea) is sometimes branded 4G, and offers peak data rates of 128 Mbit/s downlink and 56 Mbit/s uplink over 20 MHz wide channels^{[citation needed]}.
The world's first commercial mobile WiMAX service was opened by KT in Seoul, South Korea on 30 June 2006.^[2]
Sprint Nextel has begun using Mobile WiMAX, as of September 29, 2008 branded as a "4G" network even though the current version does not fulfil the IMT Advanced requirements on 4G systems.^[19]
In Russia, Belarus and Nicaragua WiMax broadband internet access is offered by a Russian company Scartel, and is also branded 4G, Yota.

UMB (formerly EV-DO Rev. C)

Main article: Ultra Mobile Broadband

UMB (Ultra Mobile Broadband) was the brand name for a discontinued 4G project within the 3GPP2 standardization group to improve the CDMA2000 mobile phone standard for next generation applications and requirements. In November 2008, Qualcomm, UMB's lead sponsor, announced it was ending development of the technology, favouring LTE instead.^[20] The objective was to achieve data speeds over 275 Mbit/s downstream and over 75 Mbit/s upstream.

[edit] Flash-OFDM

At an early stage the Flash-OFDM system was expected to be further developed into a 4G standard.

[edit] iBurst and MBWA (IEEE 802.20) systems

The iBurst system ( or HC-SDMA, High Capacity Spatial Division Multiple Access) was at an early stage considered as a 4G predecessor. It was later further developed into the Mobile Broadband Wireless Access (MBWA) system, also known as IEEE 802.20.

[edit] Data rate comparison

The following table shows a comparison of 4G candidate systems as well as other competing technologies.

Comparison of Mobile Internet Access methods (This box: view · talk · edit)

Standard	Family	Primary Use	Radio Tech	Downlink (Mbit/s)	Uplink (Mbit/s)	Notes
WiMAX	802.16	Mobile Internet	MIMO-SOFDMA	128 (in 20MHz bandwidth)	56 (in 20MHz bandwidth)	WiMAX update IEEE 802.16m expected to offer peak rates of at least 1 Gbit/s fixed speeds and 100Mbit/s to mobile users.
LTE	UMTS/4GSM	General 4G	OFDMA/MIMO/SC-FDMA	100 (in 20MHz bandwidth)	50 (in 20 MHz bandwidth)	LTE-Advanced update expected to offer peak rates up to 1 Gbit/s fixed speeds and 100 Mb/s to mobile users.
Flash-OFDM	Flash-OFDM	Mobile Internet mobility up to 200mph (350km/h)	Flash-OFDM	5.3 10.6 15.9	1.8 3.6 5.4	Mobile range 30km (18 miles) extended range 55 km (34 miles)
HIPERMAN	HIPERMAN	Mobile Internet	OFDM	56.9
Wi-Fi	802.11 (11n)	Mobile Internet	OFDM/MIMO	300 (using 4x4 configuration in 20MHz bandwidth) or 600 (using 4x4 configuration in 40MHz bandwidth)		Antenna, RF front end enhancements and minor protocol timer tweaks have helped deploy long range P2P networks compromising on radial coverage, throughput and/or spectra efficiency (310km & 382km)
iBurst	802.20	Mobile Internet	HC-SDMA/TDD/MIMO	95	36	Cell Radius: 3–12 km Speed: 250km/h Spectral Efficiency: 13 bits/s/Hz/cell Spectrum Reuse Factor: "1"
EDGE Evolution	GSM	Mobile Internet	TDMA/FDD	1.6	0.5	3GPP Release 7
UMTS W-CDMA HSDPA+HSUPA HSPA+	UMTS/3GSM	General 3G	CDMA/FDD CDMA/FDD/MIMO	0.384 14.4 56	0.384 5.76 22	HSDPA widely deployed. Typical downlink rates today 2 Mbit/s, ~200 kbit/s uplink; HSPA+ downlink up to 56 Mbit/s.
UMTS-TDD	UMTS/3GSM	Mobile Internet	CDMA/TDD	16		Reported speeds according to IPWireless using 16QAM modulation similar to HSDPA+HSUPA
1xRTT	CDMA2000	Mobile phone	CDMA	0.144		Succeeded by EV-DO for data use, but still is used for voice and as a failover for EV-DO
EV-DO 1x Rev. 0 EV-DO 1x Rev.A EV-DO Rev.B	CDMA2000	Mobile Internet	CDMA/FDD	2.45 3.1 4.9xN	0.15 1.8 1.8xN	Rev B note: N is the number of 1.25 MHz chunks of spectrum used. EV-DO is not designed for voice, and requires a fallback to 1xRTT when a voice call is placed or received.

Notes: All speeds are theoretical maximums and will vary by a number of factors, including the use of external antennae, distance from the tower and the ground speed (e.g. communications on a train may be poorer than when standing still). Usually the bandwidth is shared between several terminals. The performance of each technology is determined by a number of constraints, including the spectral efficiency of the technology, the cell sizes used, and the amount of spectrum available. For more information, see Comparison of wireless data standards.
For more comparison tables, see bit rate progress trends, comparison of mobile phone standards, spectral efficiency comparison table and OFDM system comparison table.

[edit] Objective and approach

Objectives assumed in the literature

4G is being developed to accommodate the quality of service (QoS) and rate requirements set by further development of existing 3G applications like mobile broadband access, Multimedia Messaging Service (MMS), video chat, mobile TV, but also new services like HDTV. 4G may allow roaming with wireless local area networks, and may interact with digital video broadcasting systems.
In the literature, the assumed or expected 4G requirements have changed during the years before IMT-Advanced was specified by the ITU-R. These are examples of objectives stated in various sources:

• A nominal data rate of 100 Mbit/s while the client physically moves at high speeds relative to the station, and 1 Gbit/s while client and station are in relatively fixed positions as defined by the ITU-R^[21]
• A data rate of at least 100 Mbit/s between any two points in the world^[21]
• Smooth handoff across heterogeneous networks^[22]
• Seamless connectivity and global roaming across multiple networks^[23]
• High quality of service for next generation multimedia support (real time audio, high speed data, HDTV video content, mobile TV, etc.)^[23]
• Interoperability with existing wireless standards^[24]
• An all IP, packet switched network^[23]
• IP-based femtocells (home nodes connected to fixed Internet broadband infrastructure)

Approaches

Principal technologies

• Physical layer transmission techniques are as follows:^[25]
  • MIMO: To attain ultra high spectral efficiency by means of spatial processing including multi-antenna and multi-user MIMO
  • Frequency-domain-equalization, for example Multi-carrier modulation (OFDM) in the downlink or single-carrier frequency-domain-equalization (SC-FDE) in the uplink: To exploit the frequency selective channel property without complex equalization.
  • Frequency-domain statistical multiplexing, for example (OFDMA) or (Single-carrier FDMA) (SC-FDMA, a.k.a. Linearly precoded OFDMA, LP-OFDMA) in the uplink: Variable bit rate by assigning different sub-channels to different users based on the channel conditions
  • Turbo principle error-correcting codes: To minimize the required SNR at the reception side
• Channel-dependent scheduling: To utilize the time-varying channel.
• Link adaptation: Adaptive modulation and error-correcting codes
• Relaying, including fixed relay networks (FRNs), and the cooperative relaying concept, known as multi-mode protocol

4G features assumed in early literature

The 4G system was originally envisioned by the Defense Advanced Research Projects Agency (DARPA).^{[citation needed]} The DARPA selected the distributed architecture, end-to-end Internet protocol (IP), and believed at an early stage in peer-to-peer networking in which every mobile device would be both a transceiver and a router for other devices in the network eliminating the spoke-and-hub weakness of 2G and 3G cellular systems.^[26] Since the 2.5G GPRS system, cellular systems have provided dual infrastructures: packet switched nodes for data services, and circuit switched nodes for voice calls. In 4G systems, the circuit-switched infrastructure is abandoned, and only a packet-switched network is provided, while 2.5G and 3G systems require both packet-switched and circuit-switched network nodes, i.e. two infrastructures in parallel. This means that in 4G, traditional voice calls are replaced by IP telephony.
Cellular systems such as 4G allow seamless mobility; thus a file transfer is not interrupted in case a terminal moves from one cell (one base station coverage area) to another, but handover is carried out. The terminal also keeps the same IP address while moving, meaning that a mobile server is reachable as long as it is within the coverage area of any server. In 4G systems this mobility is provided by the mobile IP protocol, part of IP version 6, while in earlier cellular generations it was only provided by physical layer and datalink layer protocols. In addition to seamless mobility, 4G provides flexible interoperability of the various kinds of existing wireless networks, such as satellite, cellular wirelss, WLAN, PAN and systems for accessing fixed wireless networks.^[27]
While maintaining seamless mobility, 4G will offer very high data rates with expectations of 100 Mbit/s wireless service. The increased bandwidth and higher data transmission rates will allow 4G users the ability to utilize high definition video and the video conferencing features of mobile devices attached to a 4G network. The 4G wireless system is expected to provide a comprehensive IP solution where multimedia applications and services can be delivered to the user on an 'Anytime, Anywhere' basis with a satisfactory high data rate, premium quality and high security.^[28]
4G is described as MAGIC: mobile multimedia, any-time anywhere, global mobility support, integrated wireless solution, and customized personal service.^{[citation needed]} Some key features (primarily from users' points of view) of 4G mobile networks are:^{[citation needed]}

• High usability: anytime, anywhere, and with any technology
• Support for multimedia services at low transmission cost
• Personalization
• Integrated services

Components

Access schemes

This section contains information which may be of unclear or questionable importance or relevance to the article's subject matter. Please help improve this article by clarifying or removing superfluous information. (May 2010)

As the wireless standards evolved, the access techniques used also exhibited increase in efficiency, capacity and scalability. The first generation wireless standards used plain TDMA and FDMA. In the wireless channels, TDMA proved to be less efficient in handling the high data rate channels as it requires large guard periods to alleviate the multipath impact. Similarly, FDMA consumed more bandwidth for guard to avoid inter carrier interference. So in second generation systems, one set of standard used the combination of FDMA and TDMA and the other set introduced an access scheme called CDMA. Usage of CDMA increased the system capacity, but as a theoretical drawback placed a soft limit on it rather than the hard limit (i.e. a CDMA network setup does not inherently reject new clients when it approaches its limits, resulting in a denial of service to all clients when the network overloads; though this outcome is avoided in practical implementations by admission control of circuit switched or fixed bitrate communication services). Data rate is also increased as this access scheme (providing the network is not reaching its capacity) is efficient enough to handle the multipath channel. This enabled the third generation systems, such as IS-2000, UMTS, HSXPA, 1xEV-DO, TD-CDMA and TD-SCDMA, to use CDMA as the access scheme. However, the issue with CDMA is that it suffers from poor spectral flexibility and computationally intensive time-domain equalization (high number of multiplications per second) for wideband channels.
Recently, new access schemes like Orthogonal FDMA (OFDMA), Single Carrier FDMA (SC-FDMA), Interleaved FDMA and Multi-carrier CDMA (MC-CDMA) are gaining more importance for the next generation systems. These are based on efficient FFT algorithms and frequency domain equalization, resulting in a lower number of multiplications per second. They also make it possible to control the bandwidth and form the spectrum in a flexible way. However, they require advanced dynamic channel allocation and traffic adaptive scheduling.
WiMax is using OFDMA in the downlink and in the uplink. For the next generation UMTS, OFDMA is used for the downlink. By contrast, IFDMA is being considered for the uplink since OFDMA contributes more to the PAPR related issues and results in nonlinear operation of amplifiers. IFDMA provides less power fluctuation and thus avoids amplifier issues. Similarly, MC-CDMA is in the proposal for the IEEE 802.20 standard. These access schemes offer the same efficiencies as older technologies like CDMA. Apart from this, scalability and higher data rates can be achieved.
The other important advantage of the above mentioned access techniques is that they require less complexity for equalization at the receiver. This is an added advantage especially in the MIMO environments since the spatial multiplexing transmission of MIMO systems inherently requires high complexity equalization at the receiver.
In addition to improvements in these multiplexing systems, improved modulation techniques are being used. Whereas earlier standards largely used Phase-shift keying, more efficient systems such as 64QAM are being proposed for use with the 3GPP Long Term Evolution standards.

IPv6 support

Main articles: Network layer, Internet protocol, and IPv6

Unlike 3G, which is based on two parallel infrastructures consisting of circuit switched and packet switched network nodes respectively, 4G will be based on packet switching only. This will require low-latency data transmission.
By the time that 4G was deployed, the process of IPv4 address exhaustion was expected to be in its final stages. Therefore, in the context of 4G, IPv6 support is essential in order to support a large number of wireless-enabled devices. By increasing the number of IP addresses, IPv6 removes the need for network address translation (NAT), a method of sharing a limited number of addresses among a larger group of devices, although NAT will still be required to communicate with devices that are on existing IPv4 networks.
As of June 2009^[update], Verizon has posted specifications that require any 4G devices on its network to support IPv6.^[29]

Advanced antenna systems

Main articles: MIMO and MU-MIMO

The performance of radio communications depends on an antenna system, termed smart or intelligent antenna. Recently, multiple antenna technologies are emerging to achieve the goal of 4G systems such as high rate, high reliability, and long range communications. In the early 1990s, to cater for the growing data rate needs of data communication, many transmission schemes were proposed. One technology, spatial multiplexing, gained importance for its bandwidth conservation and power efficiency. Spatial multiplexing involves deploying multiple antennas at the transmitter and at the receiver. Independent streams can then be transmitted simultaneously from all the antennas. This technology, called MIMO (as a branch of intelligent antenna), multiplies the base data rate by (the smaller of) the number of transmit antennas or the number of receive antennas. Apart from this, the reliability in transmitting high speed data in the fading channel can be improved by using more antennas at the transmitter or at the receiver. This is called transmit or receive diversity. Both transmit/receive diversity and transmit spatial multiplexing are categorized into the space-time coding techniques, which does not necessarily require the channel knowledge at the transmitter. The other category is closed-loop multiple antenna technologies, which require channel knowledge at the transmitter.

[edit] Software-defined radio (SDR)

SDR is one form of open wireless architecture (OWA). Since 4G is a collection of wireless standards, the final form of a 4G device will constitute various standards. This can be efficiently realized using SDR technology, which is categorized to the area of the radio convergence.

History of 4G and pre-4G technologies

• In 2002, the strategic vision for 4G—which ITU designated as IMT-Advanced—was laid out.
• In 2005, OFDMA transmission technology is chosen as candidate for the HSOPA downlink, later renamed 3GPP Long Term Evolution (LTE) air interface E-UTRA.
• In November 2005, KT demonstrated mobile WiMAX service in Busan, South Korea.^[30]
• In June 2006, KT started the world's first commercial mobile WiMAX service in Seoul, South Korea.^[2]
• In mid-2006, Sprint Nextel announced that it would invest about US$5 billion in a WiMAX technology buildout over the next few years^[31] ($5.45 billion in real terms^[32]). Since that time Sprint has faced many setbacks, that have resulted in steep quarterly losses. On May 7, 2008, Sprint, Imagine, Google, Intel, Comcast, Bright House, and Time Warner announced a pooling of an average of 120 MHz of spectrum; Sprint merged its Xohm WiMAX division with Clearwire to form a company which will take the name "Clear".
• In February 2007, the Japanese company NTT DoCoMo tested a 4G communication system prototype with 4x4 MIMO called VSF-OFCDM at 100 Mbit/s while moving, and 1 Gbit/s while stationary. NTT DoCoMo completed a trial in which they reached a maximum packet transmission rate of approximately 5 Gbit/s in the downlink with 12x12 MIMO using a 100 MHz frequency bandwidth while moving at 10 km/h,^[33] and is planning on releasing the first commercial network in 2010.
• In September 2007, NTT Docomo demonstrated e-UTRA data rates of 200 Mbit/s with power consumption below 100 mW during the test.^[34]
• In January 2008, a U.S. Federal Communications Commission (FCC) spectrum auction for the 700 MHz former analog TV frequencies began. As a result, the biggest share of the spectrum went to Verizon Wireless and the next biggest to AT&T.^[35] Both of these companies have stated their intention of supporting LTE.
• In January 2008, EU commissioner Viviane Reding suggested re-allocation of 500–800 MHz spectrum for wireless communication, including WiMAX.^[36]
• On 15 February 2008 - Skyworks Solutions released a front-end module for e-UTRAN.^[37][38][39]
• In 2008, ITU-R established the detailed performance requirements of IMT-Advanced, by issuing a Circular Letter calling for candidate Radio Access Technologies (RATs) for IMT-Advanced.^[40]
• In April 2008, just after receiving the circular letter, the 3GPP organized a workshop on IMT-Advanced where it was decided that LTE Advanced, an evolution of current LTE standard, will meet or even exceed IMT-Advanced requirements following the ITU-R agenda.
• In April 2008, LG and Nortel demonstrated e-UTRA data rates of 50 Mbit/s while travelling at 110 km/h.^[41]
• On 12 November 2008, HTC announced the first WiMAX-enabled mobile phone, the Max 4G^[42]
• In December 2008, San Miguel Corporation, Asia's largest food and beverage conglomerate, has signed a memorandum of understanding with Qatar Telecom QSC (Qtel) to build wireless broadband and mobile communications projects in the Philippines. The joint-venture formed wi-tribe Philippines, which offers 4G in the country.^[43] Around the same time Globe Telecom rolled out the first WiMAX service in the Philippines.
• On 3 March 2009, Lithuania's LRTC announcing the first operational "4G" mobile WiMAX network in Baltic states.^[44]
• In December 2009, Sprint began advertising "4G" service in selected cities in the United States, despite average download speeds of only 3–6 Mbit/s with peak speeds of 10 Mbit/s (not available in all markets).^[45]
• On 14 December 2009, the first commercial LTE deployment was in the Scandinavian capitals Stockholm and Oslo by the Swedish-Finnish network operator TeliaSonera and its Norwegian brandname NetCom (Norway). TeliaSonera branded the network "4G". The modem devices on offer were manufactured by Samsung (dongle GT-B3710), and the network infrastructure created by Huawei (in Oslo) and Ericsson (in Stockholm). TeliaSonera plans to roll out nationwide LTE across Sweden, Norway and Finland.^[4][46] TeliaSonera used spectral bandwidth of 10 MHz, and single-in-single-out, which should provide physical layer net bitrates of up to 50 Mbit/s downlink and 25 Mbit/s in the uplink. Introductory tests showed a TCP throughput of 42.8 Mbit/s downlink and 5.3 Mbit/s uplink in Stockholm.^[5]
• On 25 February 2010, Estonia's EMT opened LTE "4G" network working in test regime.^[47]
• On 4 June 2010, Sprint Nextel released the first WiMAX smartphone in the US, the HTC Evo 4G.^[48]
• In July 2010, Uzbekistan's MTS deployed LTE in Tashkent.^[49]
• On 25 August 2010, Latvia's LMT opened LTE "4G" network working in test regime 50% of territory.
• On 6 December 2010, at the ITU World Radiocommunication Seminar 2010, the ITU stated that LTE, WiMax and similar "evolved 3G technologies" could be considered "4G".^[6]
• On 12 December 2010, VivaCell-MTS launches in Armenia 4G/LTE commercial test network with a live demo conducted in Yerevan.^[50]
• On 28 April 2011, Lithuania's Omnitel opened LTE "4G" network working in 5 biggest cities.^[51]

[edit] Deployment plans

In May 2005, Digiweb, an Irish fixed and wireless broadband company, announced that they had received a mobile communications license from the Irish Telecoms regulator, ComReg. This service will be issued the mobile code 088 in Ireland and will be used for the provision of 4G Mobile communications.^[52][53] Digiweb launched a mobile broadband network using FLASH-OFDM technology at 872 MHz.
On September 20, 2007, Verizon Wireless announced plans for a joint effort with the Vodafone Group to transition its networks to the 4G standard LTE. On December 9, 2008, Verizon Wireless announced their intentions to build and begin to roll out an LTE network by the end of 2009. Since then, Verizon Wireless has said that they will start their rollout by the end of 2010.
On July 7, 2008, South Korea announced plans to spend 60 billion won, or US$58,000,000, on developing 4G and even 5G technologies, with the goal of having the highest mobile phone market share by 2012, and the hope of an international standard.^[54]
Telus and Bell Canada, the major Canadian cdmaOne and EV-DO carriers, have announced that they will be cooperating towards building a fourth generation (4G) LTE wireless broadband network in Canada. As a transitional measure, they are implementing 3G UMTS that went live in November 2009.^[55]
Sprint offers a 3G/4G connection plan, currently available in select cities in the United States.^[45] It delivers rates up to 10 Mbit/s.
In the United Kingdom, Telefónica O₂ is to use Slough as a guinea pig in testing the 4G network and has called upon Huawei to install LTE technology in six masts across the town to allow people to talk to each other via HD video conferencing and play PlayStation games while on the move.^[56]
Verizon Wireless has announced that it plans to augment its CDMA2000-based EV-DO 3G network in the United States with LTE. AT&T, along with Verizon Wireless, has chosen to migrate toward LTE from 2G/GSM and 3G/HSPA by 2011.^[57]
Sprint Nextel has deployed WiMAX technology which it has labeled 4G as of October 2008. It is currently deploying to additional markets and is the first US carrier to offer a WiMAX phone.^[58]
The U.S. FCC is exploring the possibility of deployment and operation of a nationwide 4G public safety network which would allow first responders to seamlessly communicate between agencies and across geographies, regardless of devices. In June 2010 the FCC released a comprehensive white paper which indicates that the 10 MHz of dedicated spectrum currently allocated from the 700 MHz spectrum for public safety will provide adequate capacity and performance necessary for normal communications as well as serious emergency situations.^[59]
TeliaSonera started deploying LTE (branded "4G") in Stockholm and Oslo November 2009 (as seen above), and in several Swedish, Norwegian, and Finnish cities during 2010. In June 2010, Swedish television companies used 4G to broadcast live television from the Swedish Crown Princess' Royal Wedding.^[60]
Safaricom, a telecommunication company in East& Central Africa, began its setup of a 4G network in October 2010 after the now retired& Kenya Tourist Board Chairman, Michael Joseph, regarded their 3G network as a white elephant i.e. it failed to perform to expectations. Huawei was given the contract the network is set to go fully commercial by the end of Q1 of 2011
Telstra announced on 15 February 2011, that it intents to upgrade its current Next G network to 4G with Long Term Evolution (LTE) technology in the central business districts of all Australian capital cities and selected regional centres by the end of 2011.^[61]

[edit] Beyond 4G research

Main article: 5G

A major issue in 4G systems is to make the high bit rates available in a larger portion of the cell, especially to users in an exposed position in between several base stations. In current research, this issue is addressed by macro-diversity techniques, also known as group cooperative relay, and also by beam-division multiple access.^[62]
Pervasive networks are an amorphous and at present entirely hypothetical concept where the user can be simultaneously connected to several wireless access technologies and can seamlessly move between them (See vertical handoff, IEEE 802.21). These access technologies can be Wi-Fi, UMTS, EDGE, or any other future access technology. Included in this concept is also smart-radio (also known as cognitive radio) technology to efficiently manage spectrum use and transmission power as well as the use of mesh routing protocols to create a pervasive network.

[edit] References

1. ^ http://www.itu.int/ITU-R/index.asp?category=information&rlink=imt-advanced&lang=en
2. ^ ^{a b c} "South Korea launches WiBro service". EE Times. 2006-06-30. http://www.eetimes.com/news/latest/showArticle.jhtml?articleID=189800030. Retrieved 2010-06-23. 
3. ^ ^{a b} "Light Reading Mobile - 4G/LTE — Ericsson, Samsung Make LTE Connection — Telecom News Analysis". Unstrung.com. http://www.unstrung.com/document.asp?doc_id=183528&. Retrieved 2010-03-24. 
4. ^ ^{a b} "Teliasonera First To Offer 4G Mobile Services". The Wall Street Journal. 2009-12-14. http://online.wsj.com/article/BT-CO-20091214-707449.html. ^{[dead link]}
5. ^ ^{a b} Daily Mobile Blog
6. ^ ^{a b} "ITU World Radiocommunication Seminar highlights future communication technologies". http://www.itu.int/net/pressoffice/press_releases/2010/48.aspx. 
7. ^ ^{a b} Vilches, J. (2010, April 29). Everything you need to know about 4G Wireless Technology. TechSpot.
8. ^ ^{a b c} ITU-R, Report M.2134, Requirements related to technical performance for IMT-Advanced radio interface(s), Approved in Nov 2008
9. ^ Moray Rumney, "IMT-Advanced: 4G Wireless Takes Shape in an Olympic Year", Agilent Measurement Journal, September 2008
10. ^ Nomor Research Newsletter: The way of LTE towards 4G
11. ^ 3GPP specification: Requirements for further advancements for E-UTRA (LTE Advanced)
12. ^ 3GPP Technical Report: Feasibility study for Further Advancements for E-UTRA (LTE Advanced)
13. ^ , "ITU paves way for next-generation 4G mobile technologies", ITU Press Release, 21 October 2010
14. ^ Parkvall, Stefan; Dahlman, Erik; Furuskär, Anders; Jading, Ylva; Olsson, Magnus; Wänstedt, Stefan; Zangi, Kambiz (21–24 September 2008). "LTE Advanced – Evolving LTE towards IMT-Advanced" (PDF). Vehicular Technology Conference Fall 2008. Stockholm: Ericsson Research. http://www.ericsson.com/res/thecompany/docs/journal_conference_papers/wireless_access/VTC08F_jading.pdf. Retrieved 26 November 2010. 
15. ^ Parkvall, Stefan; Astely, David (April 2009). "The evolution of LTE toward LTE Advanced". Journal of Communications 4 (3): 146–154. http://ojs.academypublisher.com/index.php/jcm/article/view/0403146154/49. 
16. ^ [1] The Draft IEEE 802.16m System Description Document, 2008-04-20
17. ^ "MetroPCS Launches First 4G LTE Services in the United States and Unveils World’s First Commercially Available 4G LTE Phone". MetroPCS IR. 21 Sept 2010. http://www.metropcs.com/presscenter/articles/mpcs-news-20100921.aspx. Retrieved 2011-04-08. 
18. ^ ^{a b} Jason Hiner (12 January 2011). "How AT&T and T-Mobile conjured 4G networks out of thin air". TechRepublic. http://www.techrepublic.com/blog/hiner/how-at-t-and-t-mobile-conjured-4g-networks-out-of-thin-air/7361. Retrieved 2011-04-05. 
19. ^ "Sprint announces seven new WiMAX markets, says 'Let AT&T and Verizon yak about maps and 3G coverage'". Engadget. 2010-03-23. http://www.engadget.com/2010/03/23/sprint-announces-seven-new-wimax-markets-says-let-atandt-and-ver/. Retrieved 2010-04-08. 
20. ^ Qualcomm halts UMB project, Reuters, November 13th, 2008
21. ^ ^{a b} Young Kyun, Kim; Prasad, Ramjee (2006). 4G Roadmap and Emerging Communication Technologies. Artech House 2006. pp. 12–13. ISBN 1-58053-931-9. 
22. ^ Sadia Hussain, Zara Hamid and Naveed S. Khattak (May 30–31, 2006). "Mobility Management Challenges and Issues in 4G Heterogeneous Networks". ACM Proceedings of the first international conference on Integrated internet ad hoc and sensor networks. http://delivery.acm.org/10.1145/1150000/1142698/a14-hussain.pdf?key1=1142698&key2=8898704611&coll=GUIDE&dl=&CFID=15151515&CFTOKEN=6184618. Retrieved 2007-03-26. 
23. ^ ^{a b c} Werner Mohr (2002). "Mobile Communications Beyond 3G in the Global Context" (PDF). Siemens mobile. http://www.cu.ipv6tf.org/pdf/werner_mohr.pdf. Retrieved 2007-03-26. 
24. ^ Noah Schmitz (March 2005). "The Path To 4G Will Take Many Turns". Wireless Systems Design. http://www.wsdmag.com/Articles/ArticleID/10001/10001.html. Retrieved 2007-03-26. 
25. ^ G. Fettweis, E. Zimmermann, H. Bonneville, W. Schott, K. Gosse, M. de Courville (2004). "High Throughput WLAN/WPAN" (PDF). WWRF. http://www.wireless-world-research.org/fileadmin/sites/default/files/about_the_forum/WG/WG5/Briefings/WG5-br2-High_Throughput_WLAN_WPAN-V2004.pdf. 
26. ^ Zheng, P., Peterson, L., Davie, B., & Farrel, A. (2009). Wireless Networking Complete. Morgan Kaufmann
27. ^ Nicopolitidis, P. (2003). WIRELESS NETWORKS (p. 190). Chichester, England ; Hoboken, NJ : John Wiley & Sons, Ltd. (UK), 2003
28. ^ Mishra, A. R. (2007). In Advanced Cellular Network Planning and Optimisation: 2G/2.5G/3G...Evolution to 4G. The Atrium, Southern Gate, Chichester, West Sussex PO19 8SQ, England: John Wiley & Sons.
29. ^ Morr, Derek (2009-06-09). "Verizon mandates IPv6 support for next-gen cell phones". http://www.personal.psu.edu/dvm105/blogs/ipv6/2009/06/verizon-mandates-ipv6-support.html. Retrieved 2009-06-10. 
30. ^ "KT Launches Commercial WiBro Services in Korea". WiMAX Forum. 2005-11-15. http://www.wimaxforum.org/news/831. Retrieved 2010-06-23. 
31. ^ "4G Mobile Broadband". sprint.com. http://www2.sprint.com/mr/cda_pkDetail.do?id=1260. Retrieved 2008-03-12. 
32. ^ Consumer Price Index (estimate) 1800–2008. Federal Reserve Bank of Minneapolis. Retrieved December 7, 2010.
33. ^ "DoCoMo Achieves 5 Gbit/s Data Speed". NTT DoCoMo Press. 2007-02-09. http://www.nttdocomo.com/pr/2007/001319.html. 
34. ^ Reynolds, Melanie (2007-09-14). "NTT DoCoMo develops low power chip for 3G LTE handsets". Electronics Weekly. http://www.electronicsweekly.com/Articles/2007/09/14/42179/ntt-docomo-develops-low-power-chip-for-3g-lte-handsets.htm. Retrieved 2010-04-08. 
35. ^ "Auctions Schedule". FCC. http://wireless.fcc.gov/auctions/default.htm?job=auctions_sched. Retrieved 2008-01-08. 
36. ^ "European Commission proposes TV spectrum for WiMax". zdnetasia.com. http://www.zdnetasia.com/news/communications/0,39044192,62021021,00.htm. Retrieved 2008-01-08. 
37. ^ "Skyworks Rolls Out Front-End Module for 3.9G Wireless Applications. (Skyworks Solutions Inc.)". Wireless News. February 14, 2008. http://www.accessmylibrary.com/coms2/summary_0286-33896688_ITM. Retrieved 2008-09-14. 
38. ^ "Wireless News Briefs — February 15, 2008". WirelessWeek. February 15, 2008. http://www.wirelessweek.com/News_Briefs021508.aspx. Retrieved 2008-09-14. 
39. ^ "Skyworks Introduces Industry's First Front-End Module for 3.9G Wireless Applications.". Skyworks press release (Free with registration). 11 FEB 2008. http://www.accessmylibrary.com/coms2/summary_0286-33869434_ITM. Retrieved 2008-09-14. 
40. ^ ITU-R Report M.2134, “Requirements related to technical performance for IMT-Advanced radio interface(s),” November 2008.
41. ^ Nortel and LG Electronics Demo LTE at CTIA and with High Vehicle Speeds :: Wireless-Watch Community
42. ^ HTC Corporation (12 November 2008). "Scartel and HTC Launch World's First Integrated GSM/WiMAX Handset". Press release. http://www.htc.com/www/press.aspx?id=76204&lang=1033. Retrieved 1 March 2011. 
43. ^ http://www.sanmiguel.com.ph/Articles.aspx?ID=1&a_id=748
44. ^ WiMAX Forum (3 March 2009). "LRTC to Launch Lithuania’s First Mobile WiMAX 4G Internet Service". Press release. http://www.wimaxforum.org/news/837. Retrieved 26 November 2010. 
45. ^ ^{a b} "4G Coverage and Speeds". Sprint. http://nextelonline.nextel.com/en/stores/popups/4G_coverage_popup.shtml. Retrieved 26 November 2010. 
46. ^ NetCom.no - NetCom 4G (in English)
47. ^ Neudorf, Raigo (25 February 2010). "EMT avas 4G testvõrgu" (in Estonian). E24.ee. http://www.e24.ee/?id=229584. Retrieved 26 November 2010. 
48. ^ Anand Lal Shimpi (June 28, 2010). "The Sprint HTC EVO 4G Review". AnandTech. http://www.anandtech.com/show/3791/the-sprint-htc-evo-4g-review. Retrieved 2011-03-19. 
49. ^ МТS kompaniyasi O’zbekistonda 4G tarmog’i ishga tushirilishini e’lon qiladi (in Uzbek)
50. ^ VivaCell-MTS launches in Armenia 4G/LTE
51. ^ "„Omnitel“ skelbia pirmoji Lietuvoje pradėjusi tiekti 4G LTE ryšio paslaugas" (in Lithuanian). delfi.lt. 2011-04-28. http://mokslas.delfi.lt/technology/omnitel-skelbia-pirmoji-lietuvoje-pradejusi-tiekti-4g-lte-rysio-paslaugas.d?id=44866433. Retrieved 2011-04-28. 
52. ^ Press Release: Digiweb Mobile Takes 088
53. ^ RTÉ News article: Ireland gets new mobile phone provider
54. ^ "Korea to Begin Developing 5G". unwiredview.com. 2008-07-08. http://www.unwiredview.com/2008/07/08/korea-to-start-working-on-5g/. Retrieved 2010-04-08. 
55. ^ TELUS (2008-10-10). "Next Generation Network Evolution". TELUS. http://www.telusmobility.com/network/. 
56. ^ Neate, Rupert (2009-12-12). "Slough accepts the call to be 4G mobile phone trailblazer". The Daily Telegraph (London). http://www.telegraph.co.uk/finance/newsbysector/mediatechnologyandtelecoms/6797198/Slough-accepts-the-call-to-be-4G-mobile-phone-trailblazer.html. Retrieved 2010-04-08. 
57. ^ "AT&T, Verizon, Vodafone to share same 4G network". Electronista. 2007-09-21. http://www.electronista.com/articles/07/09/21/verizon.and.vodafone.4g/. Retrieved 2010-04-08. 
58. ^ Sprint (23 March 2010). "World's First 3G/4G Android Phone, HTC EVO™ 4G, Coming this Summer Exclusively from Sprint". Press release. http://newsroom.sprint.com/article_display.cfm?article_id=1414. Retrieved 26 November 2010. 
59. ^ FCC White Paper. "The Public Safety Nationwide Interoperable Broadband Network, A New Model For Capacity, Performance and Cost", June 2010.
60. ^ TeliaSonera website
61. ^ http://www.telstra.com.au/abouttelstra/media-centre/announcements/telstra-to-launch-4g-mobile-broadband-network-by-end-2011.xml
62. ^ IT R&D program of MKE/IITA: 2008-F-004-01 “5G mobile communication systems based on beam-division multiple access and relays with group cooperation”.

[edit] External links

• 3GPP LTE Encyclopedia
• Alcatel-Lucent chair on Flexible Radio, working on the concept of small cells
• Nomor Research: White Paper on LTE Advance the new 4G standard
• Brian Woerner (June 20–22, 2001). "Research Directions for Fourth Generation Wireless" (PDF). Proceedings of the 10th International Workshops on Enabling Technologies: Infrastructure for Collaborative Enterprises (WET ICE ’01). Massachusetts Institute of Technology, Cambridge, MA, USA. http://csdl2.computer.org/comp/proceedings/wetice/2001/1269/00/12690060.pdf.  (118kb)
• Sajal Kumar Das, John Wiley & Sons (April 2010): "Mobile Handset Design", ISBN 978-0-470-82467-2
• Suk Yu Hui; Kai Hau Yeung (December 2003). "Challenges in the migration to 4G mobile systems". Communications Magazine, IEEE (City Univ. of Hong Kong, China) 41: 54. doi:10.1109/MCOM.2003.1252799. http://ieeexplore.ieee.org/xpls/abs_all.jsp?arnumber=1252799&isnumber=28028. 
• "4G Mobile". Alcatel-Lucent. 2005-06-13. http://www.alcatel.com/publications/abstract.jhtml?repositoryItem=tcm%3A172-262211635. 
• Will Knight (2005-09-02). "4G prototype testing". New Scientist. http://www.newscientist.com/article.ns?id=dn7943. 
• "Caribbean telecoms to invest in 4G wireless networks". Caribbean Net News. 2006-06-27. http://www.caribbeannetnews.com/cgi-script/csArticles/articles/000021/002142.htm. 
• "High speed mobile network to launch in Jersey". BBC News. 2010-03-19. http://news.bbc.co.uk/local/jersey/hi/people_and_places/arts_and_culture/newsid_8574000/8574436.stm. 
• "Future use of 4G Femtocells". 2010-03-10. http://www.ict-befemto.eu/. 
• "Date set for 4G airwaves auction". 2010-11-17. http://www.bbc.co.uk/news/technology-11776901. 

Preceded by 3rd Generation (3G)

Mobile Telephony Generations

Succeeded by 5th Generation (5G)

[hide]v · d · eMobile telephony standards 0G (radio telephones) MTS · MTA · MTB · MTC · IMTS · MTD · AMTS · OLT · Autoradiopuhelin 1G AMPS family AMPS · TACS · ETACS Other NMT · Hicap · Mobitex · DataTAC 2G GSM/3GPP family GSM · CSD 3GPP2 family cdmaOne (IS-95) AMPS family D-AMPS (IS-54 and IS-136) Other CDPD · iDEN · PDC · PHS 2G transitional (2.5G, 2.75G) GSM/3GPP family HSCSD · GPRS · EDGE/EGPRS 3GPP2 family CDMA2000 1xRTT (IS-2000) Other WiDEN 3G (IMT-2000) 3GPP family UMTS (UTRAN) · WCDMA-FDD · WCDMA-TDD · UTRA-TDD LCR (TD-SCDMA) 3GPP2 family CDMA2000 1xEV-DO (IS-856) 3G transitional (3.5G, 3.75G, 3.9G) 3GPP family HSPA · HSPA+ · LTE (E-UTRA) 3GPP2 family EV-DO Rev. A · EV-DO Rev. B IEEE family Mobile WiMAX (IEEE 802.16e-2005) · Flash-OFDM · IEEE 802.20 4G (IMT-Advanced) 3GPP family LTE Advanced IEEE family IEEE 802.16m 5G unconfirmed unconfirmed Related articles History · Cellular network theory · List of standards · Comparison of standards · Channel access methods · Spectral efficiency comparison table · Cellular frequencies · GSM frequency bands · UMTS frequency bands · Mobile broadband

Retrieved from "http://en.wikipedia.org/wiki/4G"

Categories: Software-defined radio | Emerging standards

Hidden categories: All articles with dead external links | Articles with dead external links from September 2010 | Articles with obsolete information from March 2011 | All articles with unsourced statements | Articles with unsourced statements from December 2010 | Articles with unsourced statements from June 2010 | Articles with unsourced statements from January 2011 | Articles with unsourced statements from March 2011 | Articles with unsourced statements from October 2010 | Articles containing potentially dated statements from June 2009 | All articles containing potentially dated statements