Author :
Bliss, D.W. ; Forsythe, K.W. ; Davis, S.K. ; Fawcett, G.S. ; Rabideau, D.J. ; Horowitz, L.L. ; Kraut, S.
Author_Institution :
MIT Lincoln Lab., Lexington, MA
Abstract :
Multiple-input multiple-output (MIMO) extensions to radar systems enable a number of advantages compared to traditional approaches. These advantages include improved angle estimation and target detection. In this paper, MIMO ground moving target indication (GMTI) radar is addressed. The concept of coherent MIMO radar is introduced. Comparisons are presented comparing MIMO GMTI and traditional radar performance. Simulations and theoretical bounds for MIMO GMTI angle estimation and minimum detectable velocity are presented. The simulations are evaluated in the time domain, enabling waveform design studies. For some applications, these results indicate significant potential improvements in clutter-mitigation SINR loss and reduction in angle-estimation error for slow-moving targets.
Keywords :
MIMO communication; estimation theory; radar clutter; radar tracking; target tracking; GMTI MIMO radar; angle estimation; angle-estimation error reduction; clutter-mitigation SINR loss; ground moving target indication; minimum detectable velocity; multiple-input multiple-output radar; radar performance; radar system; slow-moving target; target detection; waveform design; Adaptive arrays; Covariance matrix; Linear antenna arrays; MIMO; Polynomials; Radar antennas; Radar clutter; Space technology; Spaceborne radar; Upper bound;
Conference_Titel :
Waveform Diversity and Design Conference, 2009 International
Conference_Location :
Kissimmee, FL
Print_ISBN :
978-1-4244-2970-7
Electronic_ISBN :
978-1-4244-2971-4
DOI :
10.1109/WDDC.2009.4800327
