OSCAR achieves high-ratio lossy compression of wave fields by exploiting on-shell Fourier confinement in weakly scattering media, preserving second-order statistics for direct computation in compressed space.
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Develops a microscopic theory for optical sensitivity under coherent illumination in turbid media, demonstrating that phase conjugation maximizes local sensitivity while remission eigenchannels provide global enhancement compatible with existing DOT algorithms.
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Universal compression of wave fields in weakly scattering media
OSCAR achieves high-ratio lossy compression of wave fields by exploiting on-shell Fourier confinement in weakly scattering media, preserving second-order statistics for direct computation in compressed space.
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Harnessing coherent-wave control for sensing applications
Develops a microscopic theory for optical sensitivity under coherent illumination in turbid media, demonstrating that phase conjugation maximizes local sensitivity while remission eigenchannels provide global enhancement compatible with existing DOT algorithms.