This paper derives bounds on the performance of statistical object recognition systems, wherein an image of a target is observed by a remote sensor. Detection and recognition problems are modeled as composite hypothesis testing problems involving nuisance parameters. We develop information-theoretic performance bounds on target recognition based on statistical models for sensors and data, and examine conditions under which these bounds are tight. In particular, we examine the validity of asymptotic approximations to probability of error in such imaging problems. Problems involving Gaussian, Poisson, and multiplicative noise, and random pixel deletions are considered, as well as least-favorable Gaussian clutter. A sixth application involving...
The implementation of computational systems to perform intensive operations often involves balancing...
Many investigators are currently developing models to predict human performance in detecting a signa...
AbstractÐWe present a method for predicting fundamental performance of object recognition. We assume...
This work conducted within the Army's Center for Imaging Science (CIS) focuses on quantifying p...
Limiting capabilities of practical recognition systems are de-termined by a variety of factors that ...
The problem of recognizing objects imaged in complex real-world scenes is examined from a parametric...
In this paper, we consider the theoretical bound of the probability of error in compressed sensing (...
In this paper we derive information theoretic performance bounds to sensing and reconstruction of sp...
We present a novel method for predicting the performance of an object recognition approach in the pr...
Most of the recent compressive sensing (CS) literature has focused on sparse signal recovery based o...
International audienceAssume that a N-dimensional noisy measurement vector is available via a N × R ...
Compressed sensing (CS) enables the recovery of sparse or compressible signals from relatively a sm...
Abstract—This correspondence investigates the asymptotic performance of Bayesian target recognition ...
Performance prediction is a crucial step for transforming the field of object recognition from an ar...
International Telemetering Conference Proceedings / October 14-16, 1975 / Sheraton Inn, Silver Sprin...
The implementation of computational systems to perform intensive operations often involves balancing...
Many investigators are currently developing models to predict human performance in detecting a signa...
AbstractÐWe present a method for predicting fundamental performance of object recognition. We assume...
This work conducted within the Army's Center for Imaging Science (CIS) focuses on quantifying p...
Limiting capabilities of practical recognition systems are de-termined by a variety of factors that ...
The problem of recognizing objects imaged in complex real-world scenes is examined from a parametric...
In this paper, we consider the theoretical bound of the probability of error in compressed sensing (...
In this paper we derive information theoretic performance bounds to sensing and reconstruction of sp...
We present a novel method for predicting the performance of an object recognition approach in the pr...
Most of the recent compressive sensing (CS) literature has focused on sparse signal recovery based o...
International audienceAssume that a N-dimensional noisy measurement vector is available via a N × R ...
Compressed sensing (CS) enables the recovery of sparse or compressible signals from relatively a sm...
Abstract—This correspondence investigates the asymptotic performance of Bayesian target recognition ...
Performance prediction is a crucial step for transforming the field of object recognition from an ar...
International Telemetering Conference Proceedings / October 14-16, 1975 / Sheraton Inn, Silver Sprin...
The implementation of computational systems to perform intensive operations often involves balancing...
Many investigators are currently developing models to predict human performance in detecting a signa...
AbstractÐWe present a method for predicting fundamental performance of object recognition. We assume...