Title :
Simulator for Velocity Gate Pull-Off electronic countermeasure techniques
Author :
Townsend, James D. ; Saville, Michael A. ; Hong, Seng M. ; Martin, Richard K.
Author_Institution :
Air Force Inst. of Technol./Electr. Eng., Wright-Patterson AFB, OH
Abstract :
This paper explores the use of implementing deception waveforms in the space-time adaptive processing (STAP) model for efficient waveform optimization in hardware-in-the-loop simulation. By understanding range gate pull-off (RGPO) techniques developed in a generic form, velocity gate pull-off (VGPO) technique models can be explored in a similar manner. The VGPO mathematical models are developed using a STAP framework to simplify the optimization cost function. The STAP model, implemented in MATLAB, is solely used to represent a series of electronic countermeasure signals. Using the proposed implementation, the ECM waveform can be injected in the HILS architecture via simulation or hardware. Initial results reveal that the pulse-indexed STAP representation is M times better than a time-indexed signal representation while naturally including coordinated RGPO/VGPO.
Keywords :
electronic countermeasures; mathematical analysis; space-time adaptive processing; HILS architecture; MATLAB; deception waveforms; electronic countermeasure signals; hardware-in-the-loop simulation; optimization cost function; pulse-indexed STAP representation; range gate pull-off techniques; space-time adaptive processing model; velocity gate pull-off electronic countermeasure techniques; velocity gate pull-off technique; waveform optimization; Doppler radar; Electronic countermeasures; Frequency; Jamming; MATLAB; Mathematical model; Radar cross section; Radar tracking; Space vector pulse width modulation; Target tracking; Space-Time Adaptive Processing (STAP); countermeasures; deception jamming;
Conference_Titel :
Radar Conference, 2008. RADAR '08. IEEE
Conference_Location :
Rome
Print_ISBN :
978-1-4244-1538-0
Electronic_ISBN :
1097-5659
DOI :
10.1109/RADAR.2008.4720888
