Huge Application Potential for Smart Antenna Technologies.DUBLIN, Ireland -- Research and Markets (http://www.researchandmarkets.com/reports/c50883) has announced the addition of Frost & Sullivan's new report: Smart Antennas for Future Wireless Systems (Technical Insights) to their offering. This Technical Insights research service entitled Smart Antennas for Future Wireless Systems provides an overview of the key technologies and latest developments in the smart antenna industry along with a complete analysis of major technology drivers, restraints, and trends. It reviews the advancements in the field of smart antenna technologies and assesses their enormous potential to impact wireless communications in terms of high performance benefits. In this research service, Technical Insights' expert analysts thoroughly examine the following technologies: beamforming, spatial multiplexing, diversity antennas, and multiple input multiple output (MIMO (Multiple Input/Multiple Output) Pronounced "my-mo," it is the use of multiple transmitters and receivers (multiple antennas) on wireless devices for improved performance. ). The following technologies are covered in this research: -Beamforming: Beamforming is an advanced signal processing technique which, when employed along with an array of transmitters or receivers, is capable of controlling the 'directionality of' or 'sensitivity to' a particular radiation pattern. This method creates the radiation pattern of the antenna array by adding the phases of the signals in the desired direction and by nulling the pattern in the unwanted direction. -Spatial Multiplexing: The basic concept behind spatial multiplexing is the division (multiplex) of a specific data stream into different branches and subject to transmission in various independent channels in space. Similar to time-division multiplexing (TDM (Time Division Multiplexing) A technology that transmits multiple signals simultaneously over a single transmission path. Each lower-speed signal is time sliced into one high-speed transmission. ) or frequency-division multiplexing (FDM (1) (Fused Deposition Modeling) See 3D printing. (2) (Frequency Division Multiplexing) Transmitting multiple data signals simultaneously over a single wire by using multiple carriers, each having a unique center frequency. ) which uses the medium of transmission as time and frequency respectively, space-division multiplexing (SDM SDM - Schematic Data Model ) or spatial multiplexing uses the transmission medium as space. Some characteristics of spatial multiplexing include no bandwidth expansion, necessity of space-time equalization in the receiver, and capability of separating data streams from the equalizer in the presence of independent fading processes of the spatial channels. -Multiple Input Multiple Output (MIMO): MIMO is the technique in which multiple antennas (multiple transmitters and receivers) are used in wireless systems resulting in a significant increase in the wireless performance. Usage of multiple antennas typically means increased data rates as numerous streams of data can be transferred. Rather than focusing on eradicating effects of multipath, MIMO takes advantage of the multipath phenomena, resulting in high throughput and low bit error rates. MIMO can be used in alignment with orthogonal frequency-division multiplexing Orthogonal Frequency-Division Multiplexing (OFDM) — essentially identical to Coded OFDM (COFDM) — is a digital multi-carrier modulation scheme, which uses a large number of closely-spaced orthogonal sub-carriers. (OFDM (Orthogonal Frequency Division Multiplexing) A digital transmission technique that uses a large number of carriers spaced apart at slightly different frequencies. ) and is expected to be a part of the 802.11.n standard. -Diversity Antennas: Antenna diversity is a technique by which two or more antennas are used on a wireless device in order to null multipath signal distortion. Ideally the signal from the antenna with least noise is chosen and the other antenna is neglected. This method uses transmission of the information carrying signal along various propagation paths. Even in the case of the antennas being not more than a quarter of wavelength apart, significant gains can be realized by using this technique. Market Overview The 'Smart' Way to Achieve Highly Efficient Wireless Networks Smart antenna technologies are set to revolutionize the wireless communications industry with their enormous potential to enable the development of more powerful, cost-effective, and efficient wireless systems. While alternative techniques such as lower noise amplifiers and wider bandwidths can be used to improve the performance of wireless systems, they cannot compare with smart antenna technologies - which essentially merge an antenna array with a digital signal processing See DSP. Digital Signal Processing - (DSP) Computer manipulation of analog signals (commonly sound or image) which have been converted to digital form (sampled). (DSP (1) (Digital Signal Processor) A special-purpose CPU used for digital signal processing applications (see definition #2 below). It provides ultra-fast instruction sequences, such as shift and add, and multiply and add, which are commonly used in math-intensive ) capability - in terms of enhancing their range, speed, and capacity. "One of the strongest drivers for smart antenna technologies is their performance-enhancing benefits in terms of capacity, coverage, and range," notes the analyst of this research service. "The growing necessity for higher data rates in emerging communication systems with applications such as mobile Internet, high-speed downlink packet access High-Speed Downlink Packet Access (HSDPA) is a 3G (third generation) mobile telephony communications protocol in the High-Speed Packet Access (HSPA) family, which allows networks based on Universal Mobile Telecommunications System (UMTS) to have higher data (HSDPA (High Speed Downlink Packet Access) See HSPA. ), and evolution-data optimized (EV-DO (EVolution-Data Only) A 3G high-speed digital data service provided by cellular carriers worldwide that use the CDMA technology, including Verizon and Sprint in the U.S. EV-DO works on EV-DO cellphones as well as laptops and portable devices that have EV-DO modems. ) has increased the need to improve the range as well as speed of wireless links and promoted interest in the deployment of these technologies." Although smart antenna technologies have been used in defense systems for several years, they are yet to make an appearance in commercial systems due to prohibitive costs. However, this is set to change with the development of low-cost DSPs that will allow smart antenna technologies to be used in a wide range of wireless applications such as worldwide interoperability for microwave access (WiMax) and voice over wireless fidelity (VoWi-Fi). Huge Application Potential for Smart Antenna Technologies Research into smart antenna technologies has increased tremendously to keep pace with the constantly expanding needs of the wireless communications industry. Emerging application areas such as ultra wideband (UWB (Ultra-WideBand) A wireless technology that uses less power and provides higher speed than 802.11 Wi-Fi networks or first-generation Bluetooth products. UWB is expected to provide wireless video transmission for home theater systems, cable TV, auto safety and ), radio frequency identification See RFID. (RFID (Radio Frequency IDentification) A data collection technology that uses electronic tags for storing data. The tag, also known as an "electronic label," "transponder" or "code plate," is made up of an RFID chip attached to an antenna. ), and mobile direct broadcast satellite (DBS (Direct Broadcast Satellite) A one-way TV broadcast service from a communications satellite to a small round or oval dish antenna no larger than 20" in diameter. ) are expected to see extensive adoption of these technologies in the next few years. For instance, smart antennas can greatly improve the performance of mobile DBS in increasingly popular automotive accessories such as back-seat video systems. Innovative applications based on the benefits of these technologies, such as providing location information during emergencies, are also emerging in the market. "The best near-term application opportunities for smart antennas are wireless local area networks (WLANs), mobile DBS, WiMax, and cellular areas," says the analyst. "By 2007, they are expected to become a common feature in these application areas and with the confirmation of 802.11n standards, the number of smart antenna products entering the market is likely to increase considerably." For more information visit http://www.researchandmarkets.com/reports/c50883 |
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