Nonlinear Scale-Space

Luc Florack; Alfons H. Salden; Bart M. ter Haar Romeny; Jan J. Koenderink; Max A. Viergever

doi:10.1016/0262-8856(95)99716-E

Nonlinear Scale-Space

Luc Florack, Alfons H. Salden, Bart M. ter Haar Romeny, Jan J. Koenderink, Max A. Viergever

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Abstract

A generalization of linear Gaussian scale-space theory for scalar images is proposed, based on a particular type of metric transform preserving the intrinsic properties of the spatial domain. The existence of such a transformation defines an equivalence class. As such, a generalized scale-space can be considered as a conventional scale-space ‘in disguise’, representing the scale-space data in a format that is more convenient for specific applications. Conventional, linear scale-space is a convenient representative of the equivalence class for general purposes. The equivalence constraint is shown to yield a particular class of (linear or nonlinear) diffusion equations. The emphasis is on nonlinear scale-spaces, although the principle of equivalence can be used within the linear context as well. Examples are included to illustrate the theory both in the linear as well as in the nonlinear sector.

Original language	English
Pages (from-to)	279-294
Number of pages	16
Journal	Image and Vision Computing
Volume	13
Issue number	4
DOIs	https://doi.org/10.1016/0262-8856(95)99716-E
Publication status	Published - 1995

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title = "Nonlinear Scale-Space",

abstract = "A generalization of linear Gaussian scale-space theory for scalar images is proposed, based on a particular type of metric transform preserving the intrinsic properties of the spatial domain. The existence of such a transformation defines an equivalence class. As such, a generalized scale-space can be considered as a conventional scale-space {\textquoteleft}in disguise{\textquoteright}, representing the scale-space data in a format that is more convenient for specific applications. Conventional, linear scale-space is a convenient representative of the equivalence class for general purposes. The equivalence constraint is shown to yield a particular class of (linear or nonlinear) diffusion equations. The emphasis is on nonlinear scale-spaces, although the principle of equivalence can be used within the linear context as well. Examples are included to illustrate the theory both in the linear as well as in the nonlinear sector.",

author = "Luc Florack and Salden, {Alfons H.} and Romeny, {Bart M. ter Haar} and Koenderink, {Jan J.} and Viergever, {Max A.}",

year = "1995",

doi = "10.1016/0262-8856(95)99716-E",

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pages = "279--294",

journal = "Image and Vision Computing",

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T1 - Nonlinear Scale-Space

AU - Florack, Luc

AU - Salden, Alfons H.

AU - Romeny, Bart M. ter Haar

AU - Koenderink, Jan J.

AU - Viergever, Max A.

PY - 1995

Y1 - 1995

N2 - A generalization of linear Gaussian scale-space theory for scalar images is proposed, based on a particular type of metric transform preserving the intrinsic properties of the spatial domain. The existence of such a transformation defines an equivalence class. As such, a generalized scale-space can be considered as a conventional scale-space ‘in disguise’, representing the scale-space data in a format that is more convenient for specific applications. Conventional, linear scale-space is a convenient representative of the equivalence class for general purposes. The equivalence constraint is shown to yield a particular class of (linear or nonlinear) diffusion equations. The emphasis is on nonlinear scale-spaces, although the principle of equivalence can be used within the linear context as well. Examples are included to illustrate the theory both in the linear as well as in the nonlinear sector.

AB - A generalization of linear Gaussian scale-space theory for scalar images is proposed, based on a particular type of metric transform preserving the intrinsic properties of the spatial domain. The existence of such a transformation defines an equivalence class. As such, a generalized scale-space can be considered as a conventional scale-space ‘in disguise’, representing the scale-space data in a format that is more convenient for specific applications. Conventional, linear scale-space is a convenient representative of the equivalence class for general purposes. The equivalence constraint is shown to yield a particular class of (linear or nonlinear) diffusion equations. The emphasis is on nonlinear scale-spaces, although the principle of equivalence can be used within the linear context as well. Examples are included to illustrate the theory both in the linear as well as in the nonlinear sector.

U2 - 10.1016/0262-8856(95)99716-E

DO - 10.1016/0262-8856(95)99716-E

M3 - Article

VL - 13

SP - 279

EP - 294

JO - Image and Vision Computing

JF - Image and Vision Computing

SN - 0262-8856

IS - 4

ER -

Nonlinear Scale-Space

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