SBIR-STTR Award

Development of Co-Mingled E and B Field Antennas
Award last edited on: 11/7/2018

Sponsored Program
STTR
Awarding Agency
DOD : Navy
Total Award Amount
$832,867
Award Phase
2
Solicitation Topic Code
N10A-T015
Principal Investigator
Mengqing Yuan

Company Information

Wave Computation Technologies Inc

1800 Martin Luther King Jr Parkway Suite 204
Durham, NC 27707
   (919) 360-6475
   tianxiao@wavenology.com
   www.wavenology.com

Research Institution

Duke University

Phase I

Contract Number: N00014-10-M-0261
Start Date: 6/28/2010    Completed: 7/18/2011
Phase I year
2010
Phase I Amount
$100,000
Wave Computation Technologies and Duke University will develop minimally coupled, co-mingled E and B field antennas through numerical and experimental investigations based on both phenomenological and first-principle theories. The project objectives are to (a) develop the simulation capability for modeling superconducting quantum interference filter devices and the related B field antennas, (b) make appropriate designs of co-mingled E and B antennas, and (c) experimentally verify and improve these designs. The numerical simulation will also include the superconducting and quantum mechanic effects in the B field antennas; thus, this project will provide a new tool to determine the optimal configurations of individual E and B field antennas and the arrays formed by such antennas. In Phase 1, we will develop an initial simulation capability for both electric and magnetic field antennas in the near field based on our enhanced new commercial electromagnetic field software package Wavenology EM. With this tool we will determine the mutual coupling and isolation levels from a variety of combinations of E field and B field transmitters/receivers, and the dependence on scanning parameters such as the scan angle. By the end of Phase 1, we will have several candidates for the co-mingled E and B field antennas.

Keywords:
Mutual Coupling, Mutual Coupling, Sqif, T/R Isolation, Superconducting Quantum Antennas., Interferometer Array, Magnetic Antennas, Near Field Antenna Patterns, Antenna Phased

Phase II

Contract Number: N00014-11-C-0471
Start Date: 7/27/2011    Completed: 1/27/2013
Phase II year
2011
Phase II Amount
$732,867
Wave Computation Technologies and Duke University will develop minimally coupled, co-mingled E and B field antennas through numerical and experimental investigations based on first-principle theories. The project objectives are to (a) develop the simulation capability for modeling superconducting quantum interference filter devices and the related B field antennas, (b) make appropriate designs of co-mingled E and B antennas, and (c) experimentally verify and improve these designs. The numerical simulation will also include the superconducting and quantum mechanic effects in the B field antennas; thus, this project will provide a new tool to determine the optimal configurations of individual E and B field antennas and the arrays formed by such antennas. Based on the successful development of 1D and simple 2D SQIF array modeling capabilities, in Phase 2, we will develop sophisticated 2D SQIF array simulation capabilities for magnetic field antennas, as well as multiscale simulation capabilities for electric field antennas in the near field based on our enhanced new commercial electromagnetic field software package Wavenology EM. With this tool we will determine the mutual coupling and isolation levels from a variety of combinations of E field and B field transmitters/receivers, and the dependence on scanning parameters such as the scan angle. We will also experimentally verify the designed co-mingled E and B field antennas.

Keywords:
Superconducting Quantum Antenna, Superconducting Quantum Antenna, Antenna Array, Interferometer Arra