Browsing by Author "Randeny, T"

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item: Conference-Full-text
Aperture-Array Directional Sensing using 2-D Beam Digital Filters with Doppler-Radar Front-Ends
(2015-08-03) Randeny, T; Madanayake, A; Sengupta, A; Li, Y; Li, C
A directional sensing algorithm is proposed employing doppler radar and low-complexity 2-D IIR spatially bandpass filters. The speed of the scatterer is determined by the frequency shift of the received signal following down-conversion. The downconversion is done by mixing it with the instantaneous transmitted signal. The direction of the scatterer is determined by the means of 2-D plane-wave spectral characteristics, using 2-D IIR beam filters. The proposed architecture was simulated for three scatterers at 10,o 30,o 60o from array broadside, traveling at speeds of 31 ms,−1 18 ms−1 and 27 ms−1, respectively. A doppler radar module was used to transmit and receive reflected signals, that has a carrier frequency of 2.4 GHz. Simulations show both direction and doppler information being enhanced.
item: Conference-Abstract
Aperture-array directional Sensing using 2-D Beam Digital Filters with Doppler-Radar Front-Ends
Randeny, T; Madanayake, A; Sengupta, A; Li, Y; Li, C
A directional sensing algorithm is proposed employing doppler radar and low-complexity 2-D IIR spatially bandpass filters. The speed of the scatterer is determined by the frequency shift of the received signal following down-conversion. The downconversion is done by mixing it with the instantaneous transmitted signal. The direction of the scatterer is determined by the means of 2-D plane-wave spectral characteristics, using 2-D IIR beam filters. The proposed architecture was simulated for three scatterers at 10,o 30,o 60o from array broadside, traveling at speeds of 31 ms,−1 18 ms−1 and 27 ms−1, respectively. A doppler radar module was used to transmit and receive reflected signals, that has a carrier frequency of 2.4 GHz. Simulations show both direction and doppler information being enhanced.