San Diego, CA (PRWEB) January 20, 2005
AValonRF presents its Wearable Computer solutions and Wearable computers with integrated digital wireless links at AFCEA WEST 2005, San Diego, California, February 1-3, 2005, San Diego, California, Booth 1451.
Leapfrog advances in communications, sensors, and materials technologies have transformed the equipment inventory carried by todayÂs soldier beyond the realm of the well-oiled weapon. Included are far-flung items like video cameras, microphones, and global positioning systems (GPS) - tools that let leaders and soldiers exchange video, audio and data. The Future Combat System (FCS) contents of the new-age kitbag provide soldiers with accurate target location capabilities, enabling operation in harsh weather or close to zero light conditions, and even allowing shots to be taken around corners without exposure to enemy fire. Above all else, todayÂs tools of the battlefield are aimed at helping soldiers survive.
In the urban combat theater, Âland warriors,Â like police, fire fighters, medics and security guards, can also benefit from these lightweight, wireless video/audio tools. While the uses may differ, wireless systems like these must be compact, energy efficient, easy to produce, and affordable, if they are to become successfully applied in military and commercial/industrial contexts.
AValon RF, located in El Cajon, CA, develops and manufacturers such wireless products. The companyÂs original products were based on true diversity wireless technology that allows fast video, audio, data, and telemetry communications over dial-up phone lines and wireless media (Âin air,Â or under water).
A pioneer and innovator dedicated to the delivery of state-of-the-art wireless products at affordable prices, AValon RF set out to develop its next-generation of products based on the latest space-time wireless technology. For this, AValon RF turned to Analog Devices, Inc. (ADI) for its BlackfinÂ® processor. Blackfin embodies a new breed of embedded processor that combines high performance and low power. Blackfin was designed specifically to meet the computational demands and power constraints of today's embedded audio, video, and communications applications.
A Stronger Signal
AValon RF products target high mobility applications for military, government, private industry, and consumers. The companyÂs products can be used for unmanned air, ground and sea vehicles, mine sweeping, long-range video links for border patrol, covert surveillance, maintenance of nuclear power plants, electronic newsgathering, wireless TV viewing, and many other applications. To accommodate these applications, AValon RF products carry one-way video, alarm, and telemetry, two-way audio and data, and cover frequencies from 56 MHz to 2.5 GHz.
Developers of high mobility products must take care to manage signal fading, which can result when multiple signals from different paths cancel each other out at the receiver antenna, or when large objects obstruct the line of sight between the antenna/transmitter. It can also happen as a result of humidity, fog, or rain, or from an overcrowded spectrum. Signal fading is often managed by capturing the strongest signal from an array of multiple antennas (a technique called antenna diversity). There are numerous types of diversity technologies and numerous types of diversity receivers.
The most commonly used method for mobile applications is space diversity, which ensures that at least one antenna at any given time will not be subject to distortion. With multiple antennas placed at a site, one can control the proximity of the transmitter antenna to one of the receiving antennas. Signal fading is further complicated in a mobile environment in that the ÂnullsÂ are not fixed in space, but vary in time; the user is moving and so is the environment. ÂDeveloping wireless products that deliver reliable audio/video is tough,Â said Eli Weinstein, President of AValon RF. ÂThe likelihood of unwanted interference is high when youÂre transferring audio/video back and forth between two moving objects.Â
One of the newest and best solutions to signal-fading issues in mobile environments is space-time diversity, whereby signal processing is performed on a receiver that comprises several antennas, exploiting both the spatial (space) and temporal (time) dimensions of a radio channel. AValon RF planned to update its entire product lineÂ¾transmitters, lapel cameras, diversity receivers, boom cameras, and wireless digital microphonesÂ¾to cutting-edge space-time diversity technology.
High Performance, Low Power, Low Cost
AValon RFÂs space-time diversity receiver is essentially a software-defined radio (SDR), which requires a processor to handle SDR functions and space-time diversity processing for the receiver. Said Weinstein, ÂWe needed a high-performance processor that could handle the complex mathematical algorithms this application requires. It had to be low power so that we can use smaller batteries for lighter, more comfortable products our customers can wear. And it had to be cost-effective so that we can manufacture products our customers can afford to buy in volume.Â
ÂBlackfin was the best choice for us. It is the smallest chip on the market. It doesnÂt waste battery power,Â he continued. ÂItÂs very powerful. And itÂs affordable.Â
Blackfin processors combine a 32-bit RISC-like instruction set and dual 16-bit multiply-accumulate signal-processing functionality with the ease-of-use attributes found in general-purpose microcontrollers. For power savings, Blackfin processors are based on a gated clock core design that selectively powers down functional units on an instruction-by-instruction basis. Blackfin supports multiple power-down modes for periods where little or no CPU activity is required. Blackfin also features a dynamic power-management scheme whereby the operating frequency and voltage can be tailored to meet the performance requirements of the algorithm currently being executed. As such, Blackfin processors are particularly well suited for portable applications requiring extended battery life.
Weinstein says another benefit of working with ADI is that he was able to purchase a whole suite of products from the company in addition to the Blackfin processors. ÂADI is one of the very few companies where you can get everything you need to build a radio under one roof.Â
Thanks to Blackfin, AValon RFÂs space-time diversity receivers offer the best possible signal-to-noise ratio, using signals from all antennas to create an output. That translates to a 6dB gain in a four-antenna system. The receivers clean up most, if not all, multi-path distortion and compensate for receiver/transmitter motion by measuring the Doppler shift and spread, and by shifting the spectrum. AValon RFÂs space-time receivers convert line-of-sight systems into non-line-of-sight systems by tuning in to the multi-path signals in the absence of a direct signal. And they eliminate jamming signals from unwanted directions. This adds up to high-mobility solutions that deliver audio/video data without fail, which, on the battlefield, can mean the difference between life and death.
A conventional digital radio system comprises three main sections: a radio frequency (RF) front-end section, an intermediate frequency (IF) section, and a baseband section. The RF section, also called the RF front-end, comprises analog hardware modules, while the IF and baseband blocks comprise digital hardware modules.
The RF front-end transmits/receives the RF signal from an antenna, converts the signal to an IF signal, and performs RF amplification as well as analog down and analog up conversions. The IF block comprises A-D and D-A conversion blocks for analog-to-digital conversions and vice versa, and digital-down conversion (DDC) and digital-up conversion (DUC) blocks to perform signal modulation (signal generation) on the transmit path and demodulation (also called digital tuning) on the receive path. The baseband section performs numerous operations such as connection setup, equalization, hopping, and timing, and implements the link layer protocol.
Software-defined radio (SDR) technology comprises software modules that implement IF and baseband radio functions and various waveform requirements over a broad frequency range. Used for military, commercial, and civilian radio applications, SDR technology enables a system to implement differing link-layer protocols and modulation / demodulation techniques.
This kind of flexibility helps manufacturers deal with multiple standards as well as issues surrounding the deployment of new services and features. SDR dramatically reduces the hardware costs that would otherwise be necessary to accommodate multiple standards and upgrades.
AValon RF digital module lineup includes:
Â·RF UHF Encrypted Transceivers
TR430-3G - 1.53Mbaud/1W UHF transceiver with GPS
TR423-1 - 76Kbaud/0.25W UHF transceiver
TR430-2G - 200Kbaud/1W UHF transceiver with GPS
TR430-2+G - 325Kbaud/1W UHF transceiver with GPS
TR430-3+G - 3.06Mbaud/1W UHF transceiver with GPS
Module F - CPU, running Windows XP at 1.5GHz, 512MB DRAM, AGP - display controller with resolution of 800x600 to 1280x1024, 4GB HDD, 802.11g, 802.15 and GSM/GPRS for Wearable Computers
Module A - NTSC/PAL to MJPEG/MPEG1/MPEG2/MPEG4 Encoder based on the WISchip GO7007SB Encoder and Includes a smart video pre-processor DSP, RTC and VITC
Module B - Same as Module A with camera on board
Module C - Power PC with TCP/IP + USB 2.0 + IDE/ATA interface
Module D - MPEG4 to NTSC/PAL decoder (software dependent)
MPEG4 low latency CODEC or MPEG4 video conferencing controller.
Â·Modules: General & Mechanical
Power - 5V-10V unregulated
Size - 60mm x 33mm x 9mm
Weight - approximately 14 grams
For more information about AValon RF products, visit http://www.avalonrf.com.
For more information about Analog Devices Blackfin processors, visit http://www.analog.com/processors
Vice President, Business Development
San Diego, CA
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