This paper considers two different models for coherent radar data in which a single target is observed by an array of antennas in the presence of noise, clutter, and jamming. One model is parameterized in terms of the target signal's amplitude and direction of arrival (DOA), while the other uses an unstructured "spatial signature" instead. The maximum likelihood (ML) estimator and generalized likelihood ratio detection test for the unstructured model are derived, and compared with the standard solutions for the structured DOA-based model. Using the extended invariance principle, it is further shown how asymptotically optimal estimates of the target signal's amplitude, DOA, and Doppler can be obtained from the unstructured ML parameter estimates. Several advantages of the two-step unstructured approach are noted, including reduced computational cost and greater robustness to calibration errors.
[1]
G. G. Stokes.
"J."
,
1890,
The New Yale Book of Quotations.
[2]
Bjorn Ottersten,et al.
A Comparison of Model-Based Detection and Adaptive Sidelobe Cancelling for Radar Array Processing
,
1994
.
[3]
E. Cowley,et al.
Adaptive Radar Detection and Estimation
,
1993
.
[4]
P. Stoica,et al.
Maximum likelihood methods in radar array signal processing
,
1998,
Proc. IEEE.
[5]
James Ward,et al.
Space-time adaptive processing for airborne radar
,
1998
.
[6]
Simon Haykin,et al.
Adaptive radar detection and estimation
,
1992
.
[7]
J. Litva,et al.
Radar Array Processing
,
1993
.
[8]
T. Söderström,et al.
On reparametrization of loss functions used in estimation and the invariance principle
,
1989
.