Contextual performance prediction for low-level image analysis algorithms

Bernard Chalmond; Christine Graffigne; Michel Prenat; M. Roux

doi:10.1109/83.931098

Contextual performance prediction for low-level image analysis algorithms

Bernard Chalmond
, Christine Graffigne
, Michel Prenat
, M. Roux

Research output: Contribution to journal › Article › peer-review

Abstract

This paper explores a generic approach to predict the output accuracy of an algorithm without running it, by a careful examination of the local context. Such a performance prediction will allow to qualify the appropriateness of an algorithm to treat images with given properties (contrast, resolution, noise, richness in details, contours or textures, etc.) resulting either from experimental acquisition conditions or from a specific type of scene. We have to answer the following question: a context c being given at any site, what will be the performance? In our experiments, c is described by three contextual variables: Gabor components, entropy and signal/noise ratio. As initially proposed in the related work [8], the prediction function is determined from training using a logistic regression model. This technique is illustrated on aerial infrared images for two types of algorithm: edge detection and displacement estimation.

Original language	English
Pages (from-to)	1039-1046
Number of pages	8
Journal	IEEE Transactions on Image Processing
Volume	10
Issue number	7
DOIs	https://doi.org/10.1109/83.931098
Publication status	Published - 1 Jul 2001

Keywords

Arial infrared image
Contextual measurement
Logistic regression model
Performance prediction
Reliability

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title = "Contextual performance prediction for low-level image analysis algorithms",

abstract = "This paper explores a generic approach to predict the output accuracy of an algorithm without running it, by a careful examination of the local context. Such a performance prediction will allow to qualify the appropriateness of an algorithm to treat images with given properties (contrast, resolution, noise, richness in details, contours or textures, etc.) resulting either from experimental acquisition conditions or from a specific type of scene. We have to answer the following question: a context c being given at any site, what will be the performance? In our experiments, c is described by three contextual variables: Gabor components, entropy and signal/noise ratio. As initially proposed in the related work [8], the prediction function is determined from training using a logistic regression model. This technique is illustrated on aerial infrared images for two types of algorithm: edge detection and displacement estimation.",

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N2 - This paper explores a generic approach to predict the output accuracy of an algorithm without running it, by a careful examination of the local context. Such a performance prediction will allow to qualify the appropriateness of an algorithm to treat images with given properties (contrast, resolution, noise, richness in details, contours or textures, etc.) resulting either from experimental acquisition conditions or from a specific type of scene. We have to answer the following question: a context c being given at any site, what will be the performance? In our experiments, c is described by three contextual variables: Gabor components, entropy and signal/noise ratio. As initially proposed in the related work [8], the prediction function is determined from training using a logistic regression model. This technique is illustrated on aerial infrared images for two types of algorithm: edge detection and displacement estimation.

AB - This paper explores a generic approach to predict the output accuracy of an algorithm without running it, by a careful examination of the local context. Such a performance prediction will allow to qualify the appropriateness of an algorithm to treat images with given properties (contrast, resolution, noise, richness in details, contours or textures, etc.) resulting either from experimental acquisition conditions or from a specific type of scene. We have to answer the following question: a context c being given at any site, what will be the performance? In our experiments, c is described by three contextual variables: Gabor components, entropy and signal/noise ratio. As initially proposed in the related work [8], the prediction function is determined from training using a logistic regression model. This technique is illustrated on aerial infrared images for two types of algorithm: edge detection and displacement estimation.

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KW - Contextual measurement

KW - Logistic regression model

KW - Performance prediction

KW - Reliability

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JF - IEEE Transactions on Image Processing

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Contextual performance prediction for low-level image analysis algorithms

Abstract

Keywords

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