Edge Illumination and Imaging of Extended Reflectors

Abstract: Abstract. We use the singular value decomposition of the array response matrix, frequency by frequency, to image selectively the edges of extended reflectors in a homogeneous medium. We show with numerical simulations in an ultrasound regime, and analytically in the Fraunhofer diffraction regime, that information about the edges is contained in the singular vectors for singular values that are intermediate between the large ones and zero. These transition singular vectors beamform selectively from the array on… Show more

“…and is called subspace migration functional [12]. Similarly by replacing Π(ω) by D[ Π(ω); ω] in (3) we obtain the subspace coherent interferometric functional.…”

“…Similarly by replacing Π(ω) by D[ Π(ω); ω] in (3) we obtain the subspace coherent interferometric functional. Such filtered versions of the data were used for example in [10,12] and they are based on the singular value decomposition (SVD) of the response matrix,…”

“…To focus on the edges of an extended object we follow the approach in [12] and define the filter weights so that the normalized singular values…”

“…This can be done with higher accuracy if we recover information about the edges of the reflector, which are usually masked by the direct or specular reflections from the bulk of the object. A solution to this problem based on the singular value decomposition (SVD) of the response matrix frequency by frequency was proposed in [12]. In particular, it was shown that information about the edges is contained in the singular vectors for singular values that are intermediate between the large ones and zero.…”

“…In [12], the extended reflector was embedded in a homogeneous medium. We focus our attention here on imaging extended reflectors in cluttered media.…”

Subspace projection filters for imaging in random media

“…and is called subspace migration functional [12]. Similarly by replacing Π(ω) by D[ Π(ω); ω] in (3) we obtain the subspace coherent interferometric functional.…”

“…Similarly by replacing Π(ω) by D[ Π(ω); ω] in (3) we obtain the subspace coherent interferometric functional. Such filtered versions of the data were used for example in [10,12] and they are based on the singular value decomposition (SVD) of the response matrix,…”

“…To focus on the edges of an extended object we follow the approach in [12] and define the filter weights so that the normalized singular values…”

“…This can be done with higher accuracy if we recover information about the edges of the reflector, which are usually masked by the direct or specular reflections from the bulk of the object. A solution to this problem based on the singular value decomposition (SVD) of the response matrix frequency by frequency was proposed in [12]. In particular, it was shown that information about the edges is contained in the singular vectors for singular values that are intermediate between the large ones and zero.…”

“…In [12], the extended reflector was embedded in a homogeneous medium. We focus our attention here on imaging extended reflectors in cluttered media.…”

Subspace projection filters for imaging in random media

Numerical implementation for reconstruction of inhomogeneous conductivities via generalized polarization tensors

Spatiospectral concentration in the Cartesian plane