Embedding Blake–Zisserman Regularization in Unfolded Proximal Neural Networks for Enhanced Edge Detection

Hoang Trieu Vy Le; Marion Foare; Audrey Repetti; Nelly Pustelnik

doi:10.1109/lsp.2025.3547671

Embedding Blake–Zisserman Regularization in Unfolded Proximal Neural Networks for Enhanced Edge Detection

Hoang Trieu Vy Le, Marion Foare, Audrey Repetti, Nelly Pustelnik

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Abstract

In this paper, we present a new edge detection model based on proximal unfolded neural networks. The architecture relies on unfolding proximal Blake–Zisserman iterations, leading to a composition of two blocks: a smoothing block and an edge detection block. We show through simulations that the proposed approach efficiently eliminates irrelevant details while retaining key edges and significantly improves performance with respect to state-of-the-art strategies. Additionally, our architecture is significantly lighter than recent learning models designed for edge detection in terms of number of learnable parameters and inference time.

Original language	English
Pages (from-to)	1271-1275
Number of pages	5
Journal	IEEE Signal Processing Letters
Volume	32
Early online date	3 Mar 2025
DOIs	https://doi.org/10.1109/lsp.2025.3547671
Publication status	Published - 2025

Keywords

Blake-Zisserman functional
Mumford-Shah functional
edge detection
optimization
proximal neural networks

ASJC Scopus subject areas

Signal Processing
Electrical and Electronic Engineering
Applied Mathematics

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title = "Embedding Blake–Zisserman Regularization in Unfolded Proximal Neural Networks for Enhanced Edge Detection",

abstract = "In this paper, we present a new edge detection model based on proximal unfolded neural networks. The architecture relies on unfolding proximal Blake–Zisserman iterations, leading to a composition of two blocks: a smoothing block and an edge detection block. We show through simulations that the proposed approach efficiently eliminates irrelevant details while retaining key edges and significantly improves performance with respect to state-of-the-art strategies. Additionally, our architecture is significantly lighter than recent learning models designed for edge detection in terms of number of learnable parameters and inference time.",

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AU - Pustelnik, Nelly

PY - 2025

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AB - In this paper, we present a new edge detection model based on proximal unfolded neural networks. The architecture relies on unfolding proximal Blake–Zisserman iterations, leading to a composition of two blocks: a smoothing block and an edge detection block. We show through simulations that the proposed approach efficiently eliminates irrelevant details while retaining key edges and significantly improves performance with respect to state-of-the-art strategies. Additionally, our architecture is significantly lighter than recent learning models designed for edge detection in terms of number of learnable parameters and inference time.

KW - Blake-Zisserman functional

KW - Mumford-Shah functional

KW - edge detection

KW - optimization

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JO - IEEE Signal Processing Letters

JF - IEEE Signal Processing Letters

ER -

Embedding Blake–Zisserman Regularization in Unfolded Proximal Neural Networks for Enhanced Edge Detection

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Keywords

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