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Universal bounds for imaging in scattering media<sup>*</sup>

Niall Byrnes, Matthew R Foreman

2020New Journal of Physics11 citationsDOIOpen Access PDF

Abstract

Abstract In this work we establish universal ensemble independent bounds on the mean and variance of the mutual information and channel capacity for imaging through a complex medium. Both upper and lower bounds are derived and are solely dependent on the mean transmittance of the medium and the number of degrees of freedom N . In the asymptotic limit of large N , upper bounds on the channel capacity are shown to be well approximated by that of a bimodal channel with independent identically Bernoulli distributed transmission eigenvalues. Reflection based imaging modalities are also considered and permitted regions in the transmission-reflection information plane defined. Numerical examples drawn from the circular and DMPK random matrix ensembles are used to illustrate the validity of the derived bounds. Finally, although the mutual information and channel capacity are shown to be non-linear statistics of the transmission eigenvalues, the existence of central limit theorems is demonstrated and discussed.

Topics & Concepts

PhysicsIndependent and identically distributed random variablesLimit (mathematics)Degrees of freedom (physics and chemistry)Mutual informationBernoulli's principleChannel (broadcasting)Upper and lower boundsTransmission (telecommunications)Reflection (computer programming)ScatteringRandom matrixStatistical physicsChannel capacityRandom variableWork (physics)Information theoryTransmittanceMatrix (chemical analysis)Plane (geometry)Variance (accounting)Ghost imagingMathematical analysisFisher informationCentral limit theoremMeasure (data warehouse)Core (optical fiber)Topology (electrical circuits)Microwave Imaging and Scattering AnalysisNumerical methods in inverse problemsRandom lasers and scattering media
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