Stochastic Cramer-Rao Bound for DOA Estimation With a Mixture of Circular and Noncircular Signals

Abstract: The Cramer-Rao bound (CRB) offers insights into the inherent performance benchmark of any unbiased estimator developed for a specific parametric model, which is an important tool to evaluate the performance of direction-of-arrival (DOA) estimation algorithms. In this paper, a closed-form stochastic CRB for a mixture of circular and noncircular uncorrelated Gaussian signals is derived. As a general one, it can be transformed into some existing representative results. The existence condition of the CRB is also a… Show more

“…As a special case, for the situation with circular signals only, the DM-MUSIC algorithm is developed as in our earlier published conference paper [26]. As the Cramer-Rao bound (CRB) provides an important benchmark for assessing the performance of various 2D DOA estimation algorithms [27], [28], the CRB for 2D DOA estimation for a mixture of circular and noncircular signals is derived following the approach in [29], which can handle the general underdetermined problem. As demonstrated by computer simulations, the DB-MUSIC-M and DB-MUSIC algorithms have outperformed some existing corresponding L-shaped array based 2D DOA estimation algorithms.…”

“…Moreover, significantly reduced computation time was achieved by the proposed solution in comparison with a direct 2D search method based on I-MUSIC.APPENDIX AIn order to assess the performance of the proposed algorithms, the CRB for 2D DOA estimation for a mixture of circular and noncircular signals is derived in this part. According to the result of 1D CRB in[29], the 2D CRB result is CRB e (α, β)r e = vec (R e ) ,(44)where S nap is the number of snapshots, ⊗ is the Kronecker product operator, and vec(•) is the vectorization operation.The matrices C and D in the proposed CRB e (α, β) can be further represented asdif = E[z(t)z H (t)], R sum = E[z(t)z T (t)], r d = vec (R dif ) = T d (α, β) η + σ 2 vec (I N +M ) , r s = vec (R sum ) = T s (α nc , β nc ) diag{η nc } diag{ρ}ψ e , T d (α, β) = A * (α, β) ⊙ A (α, β) , T s (α nc , β nc ) = A (α nc , β nc ) ⊙ A (α nc , β nc ) , ψ e = [ e jψ1 , e jψ2 , . .…”

A low-complexity two-dimensional DOA estimation algorithm based on an L-shaped sensor array

“…As a special case, for the situation with circular signals only, the DM-MUSIC algorithm is developed as in our earlier published conference paper [26]. As the Cramer-Rao bound (CRB) provides an important benchmark for assessing the performance of various 2D DOA estimation algorithms [27], [28], the CRB for 2D DOA estimation for a mixture of circular and noncircular signals is derived following the approach in [29], which can handle the general underdetermined problem. As demonstrated by computer simulations, the DB-MUSIC-M and DB-MUSIC algorithms have outperformed some existing corresponding L-shaped array based 2D DOA estimation algorithms.…”

“…Moreover, significantly reduced computation time was achieved by the proposed solution in comparison with a direct 2D search method based on I-MUSIC.APPENDIX AIn order to assess the performance of the proposed algorithms, the CRB for 2D DOA estimation for a mixture of circular and noncircular signals is derived in this part. According to the result of 1D CRB in[29], the 2D CRB result is CRB e (α, β)r e = vec (R e ) ,(44)where S nap is the number of snapshots, ⊗ is the Kronecker product operator, and vec(•) is the vectorization operation.The matrices C and D in the proposed CRB e (α, β) can be further represented asdif = E[z(t)z H (t)], R sum = E[z(t)z T (t)], r d = vec (R dif ) = T d (α, β) η + σ 2 vec (I N +M ) , r s = vec (R sum ) = T s (α nc , β nc ) diag{η nc } diag{ρ}ψ e , T d (α, β) = A * (α, β) ⊙ A (α, β) , T s (α nc , β nc ) = A (α nc , β nc ) ⊙ A (α nc , β nc ) , ψ e = [ e jψ1 , e jψ2 , . .…”

A low-complexity two-dimensional DOA estimation algorithm based on an L-shaped sensor array

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