High-Speed Weapon Radomes

Award Information
Agency:
Department of Defense
Branch
n/a
Amount:
$149,760.00
Award Year:
2012
Program:
SBIR
Phase:
Phase I
Contract:
FA8651-12-M-0221
Award Id:
n/a
Agency Tracking Number:
F121-092-0375
Solicitation Year:
2012
Solicitation Topic Code:
AF121-092
Solicitation Number:
2012.1
Small Business Information
5340 Airport Blvd., Boulder, CO, -
Hubzone Owned:
N
Minority Owned:
N
Woman Owned:
Y
Duns:
125961123
Principal Investigator:
Anthony Jensen
Senior RF Engineer
(303) 449-5211
ajensen@firstrf.com
Business Contact:
Theresa Boone
President
(303) 449-5211
tboone@firstrf.com
Research Institution:
Stub




Abstract
ABSTRACT: In high-speed weapon applications, typical forward-looking RF antenna sensors must reside near the nose. Unfortunately, this is the location that experiences the greatest amount of atmospheric ram pressure and thus thermal loading. As more and more advanced hypersonic weapons are developed, the amount of atmospheric ram and thus thermal loading only stands to increase. Expected temperatures are up to 1250 degrees K (977 degrees C). This usually requires the antenna sensors to reside under a protective radome, as it provides an ablative heat shield. FIRST RF proposes a significantly different approach to the challenge of High-Speed Weapon Radomes by relocating the antenna sensors to alternate lower temperature regions of the weapons. The antenna element design then makes use of unique forward-looking, endfire antennas that may be constructed from conformal, more common high-temperature dielectric materials. Essentially, the radome becomes the antenna. The overall antenna design is implemented with low-cost manufacturing techniques that minimize scrap and unit failure because it allows the individual components to be manufactured and tested separately, before integration. The part count is low and the construction method is very simple and robust. This approach significantly lowers the overall cost, thermal, mechanical and performance risk of both IR and RF sensor systems. BENEFIT: Thermal management is the greatest challenge to this particular application. FIRST RF believes that we offer the most practical, lowest risk approach to solving the antenna design. It leverages proven radiator technology and minimizes thermal impact on the antenna. It also allows for use of more common, lower-temp, less-exotic construction materials, allowing for a quicker path-to-field. The specific benefits are: 1) Thermal impact on the antennas is lessened, while improving, or maintaining, overall platform capability and performance. 2) The antenna design is such that the radiation pattern is optimized and efficiency is maximized, while ensuring environmental operation.

* information listed above is at the time of submission.

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