SBIR-STTR Award

Rydberg-atom RF Sensors for Direction Finding and Geolocation (RADARS)
Award last edited on: 9/28/2020

Sponsored Program
STTR
Awarding Agency
DOD : AF
Total Award Amount
$899,924
Award Phase
2
Solicitation Topic Code
AF17A-T028
Principal Investigator
Evan Salim

Company Information

ColdQuanta Inc (AKA: Cold Quanta Inc)

3030 Sterling Circle
Boulder, CO 80301
   (303) 440-1284
   info@coldquanta.com
   www.coldquanta.com

Research Institution

University of Colorado - Boulder

Phase I

Contract Number: FA8650-18-P-1123
Start Date: 10/26/2017    Completed: 6/30/2018
Phase I year
2018
Phase I Amount
$149,935
ColdQuanta is partnering with Dr. Zoya Popovic at the University of Colorado, Boulder, to develop a three-dimensional quantum-enhanced radio-frequency (RF) signal sensor and direction finder. Our approach combine Rydberg-atom-based RF electrometry and discrete lens arrays (DLAs) of planar antennas. The DLA will serve as a Fourier optic for an incident wave, and a Rydberg-atom RF electrometer will measure the Fourier transform at the focal plane. The precision with which the direction of arrival can be determined depends foremost upon the spatial resolution with which the Fourier transform can be measured. In this regard, Rydberg-atom RF electrometry offers significant benefits over receivers based on antennas, including improved sensitivity and signal-to-noise ratio, sub-wavelength resolution, and accuracy that is determined by atomic structure.

Phase II

Contract Number: FA8650-19-C-1736
Start Date: 6/4/2019    Completed: 9/28/2020
Phase II year
2019
Phase II Amount
$749,989
ColdQuanta, in partnership with Dr. Zoya Popovic at the University of Colorado at Boulder, proposes to develop a three-dimensional quantum-enhanced radio-frequency (RF) signal sensor and direction finder. Our approach combines Rydberg-atom-based RF electrometry and discrete lens arrays (DLAs) of planar antennas. The DLA will serve as a Fourier optic for an incident wave, and a Rydberg-atom RF electrometer will measure the Fourier transform at the focal plane. The precision with which the direction of arrival can be determined depends foremost upon the spatial resolution with which the Fourier transform can be measured. In this regard, Rydberg-atom RF electrometry offers significant benefits over receivers based on antennas, including improved sensitivity and signal-to-noise ratio, sub-wavelength resolution, and accuracy that is determined by atomic structure.