http://www.compoundsemiconductor.net/csc/news-details.php?cat=news&id=19737503
The assets needed for long-range, high-bandwidth communications capabilities are often unavailable to lower echelons due to theatre-wide mission priorities.
DARPA’s Mobile Hotspots program aims to help overcome this challenge by developing a reliable, on-demand capability for establishing long-range, high-capacity reachback that is organic to tactical units.
The program is building and demonstrating a scalable, mobile millimetre-wave communications backhaul network mounted on small unmanned aerial vehicles (UAVs) and providing a 1 Gb/s capacity. DARPA performers recently completed the first of three phases in which they developed and tested key technologies to be integrated into a complete system and flight tested in subsequent phases.
“We’re pleased with the technical achievements we’ve seen so far in steerable millimetre-wave antennas and millimetre-wave amplifier technology,” says Dick Ridgway, DARPA program manager. “These successes -and the novel networking approaches needed to maintain these high-capacity links - are key to providing forward deployed units with the same high-capacity connectivity we all enjoy over our 4G cell-phone networks.”
Phase 1 accomplishments include:
Smaller, steerable millimetre-wave antennas: During field testing, the program successfully demonstrated steerable, compact millimetre-wave antennas that rapidly acquire, track, and establish a communications link between moving platforms. Steerable millimetre-wave antennas will enable the formation of a high-capacity backhaul network between aerial and ground platforms
Low-noise amplifiers: Performers also demonstrated an advanced low-noise amplifier (LNA), which boosts the desired communications signal while minimising unwanted noise. The prototype achieved the record for one of the world’s lowest noise millimetre-wave LNAs at about half the noise figure of a typical LNA.
More efficient and capable power amplifiers:Efficient millimetre-wave amplification is required to achieve the long ranges (> 50 km) desired in the Mobile Hotspots programme. During Phase 1, performers demonstrated output power exceeding 1 watt and 20 percent power added efficiency (PAE) from a single GaN chip operating at E-Band frequencies (71 GHz to 86 GHz). Output powers exceeding 20 watts and approaching 20 percent PAE were also achieved using power-combining techniques.
New approaches for robust airborne networking: Mobile ad-hoc networking approaches were developed to maintain the high-capacity backhaul network among mobile air and ground platforms. Phase 1 performers developed unique solutions to overcome connectivity and network topology challenges associated with mobility and signal blockages due to terrain and platform shadowing.
Low-Size, Weight, and Power (SWAP) pod design to carry it all: Performers created engineering designs for small, lightweight pods to be mounted on an RQ-7 Shadow UAV. The pods, with all of the Mobile Hotspots components inside, are designed to meet the challenging program goals of widths no more than 8 inches, weight less than 20 pounds, and power consumption less than 150 watts.
Phase 2 of the program began in March 2014. Two performers, L-3 Communications and FIRST RF, were chosen to lead teams comprising several Phase 1 performers. Phase 2 goals include the integration of the selected Phase 1 technologies into Shadow-compatible aerial pods and ground vehicles.
Phase 2 will conclude with a ground demonstration of at least four Shadow-compatible pods, two ground vehicles and a fixed ground node. A planned third phase will encompass field testing of the Mobile Hotspot systems on networks of multiple SRQ-7 Shadow UAVs and mobile ground vehicles.
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