Reduced Dilation-Erosion Perceptron for Binary Classification

Valle, Marcos Eduardo

doi:10.3390/math8040512

Cited by 19 publications

(21 citation statements)

References 60 publications

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“…Valle proposes a greedy algorithm where the dilation and the erosion perceptrons are trained separately and combined later by minimizing the average hinge loss [31]. This method allows the inclusion of a regularization term C u − r 1 in the objective function, where u = w or u = m and r is a reference term.…”

Section: Training Morphological Network Via Convex-concave Proceduresmentioning

confidence: 99%

“…The Dilation-Erosion Perceptron suffers from a major flaw as a lattice-based model, it presupposes a partial ordering both on the features and the classes. By simply inverting the classes N P, the performance of the classifier might severely drop [31]. A way to counteract this behavior lies on the use of reduced morphological operators based on a reduced ordering: Definition 2.…”

Section: Training Morphological Network Via Convex-concave Proceduresmentioning

confidence: 99%

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Advances in Morphological Neural Networks: Training, Pruning and Enforcing Shape Constraints

Dimitriadis

Maragos

2021

ICASSP 2021 - 2021 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP)

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In this paper, we study an emerging class of neural networks, the Morphological Neural networks, from some modern perspectives. Our approach utilizes ideas from tropical geometry and mathematical morphology. First, we state the training of a binary morphological classifier as a Difference-of-Convex optimization problem and extend this method to multiclass tasks. We then focus on general morphological networks trained with gradient descent variants and show, quantitatively via pruning schemes as well as qualitatively, the sparsity of the resulted representations compared to FeedForward networks with ReLU activations as well as the effect the training optimizer has on such compression techniques. Finally, we show how morphological networks can be employed to guarantee monotonicity and present a softened version of a known architecture, based on Maslov Dequantization, which alleviates issues of gradient propagation associated with its "hard" counterparts and moderately improves performance.

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Section: Training Morphological Network Via Convex-concave Proceduresmentioning

confidence: 99%

Section: Training Morphological Network Via Convex-concave Proceduresmentioning

confidence: 99%

Advances in Morphological Neural Networks: Training, Pruning and Enforcing Shape Constraints

Dimitriadis

Maragos

2021

ICASSP 2021 - 2021 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP)

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“…Neural networks can be divided into feedforward neural networks (perceptron, back propagation neural network (BPNN), and convolutional neural network (CNN)), feedback neural networks (Elman and Hopfield neural networks), and self-organizing map (SOM) neural networks according to the interconnection of neurons in the network. The perceptron neural network can only handle linear problems [54]. BP neural network adds the number of layers and BP algorithm on the basis of the perceptron, and has strong nonlinear mapping and optimization computing ability [55].…”

Section: Introductionmentioning

confidence: 99%

Motion Recognition Based on Sum of the Squared Errors Distribution

Yang

Cui

et al. 2021

IEEE Access

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Human motion recognition is playing an increasingly important role in modern society. Direct recognition of complex motions has great limitations, so we usually study basic motions first. The key to the establishment of the basic motion set is how to determine the number of basic motions. Sum of the Squared Errors Distribution (SSED) is therefore proposed to determine the number of clustering classes of Self Organizing Maps (SOM). Secondly, the Weighted Tangent Segmentation (WTS) is also proposed to segment complex motions into simple ones, and the sequence with the time stamp is generated. Finally, Back Propagation with the time stamp (BPTS) is proposed to classify the simple motions according to the basic motion set, and the complex motion is recognized according to the time stamp. The motions of human upper limbs are used to verify the effectiveness of this method. SSED determines that the number of clusters of human upper limb motion is 10. The experimental results show that the correct segmentation rate (CSR) is 98.13%. The recognition rate of basic motions is 98.67% and 99.33% in user independent (UI) and user dependent (UD) experiments, respectively. The recognition rate of complex motions is 96.37%. Experiments on UI and UD recognitions verified the effectiveness of our algorithm. Compared with other recognition algorithms, the complex motion recognition method proposed in this paper has better recognition performance.

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“…Hence, we take advantage of the recent advances in deep, sparse and non-negative auto-encoders to design a new framework able to learn part-based representations of an image database, compatible with morphological processing. To that extent, this work is part of the resurgent research line investigating interactions between deep learning and mathematical morphology [9,22,23,27,32]. However with respect to these studies, focusing mainly on introducing morphological operators in neural networks, the present paper addresses a different question.…”

Section: Introductionmentioning

confidence: 99%

Approximating morphological operators with part-based representations learned by asymmetric auto-encoders

Blusseau

Ponchon

Velasco-Forero

et al. 2020

Mathematical Morphology - Theory and Applications

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This paper addresses the issue of building a part-based representation of a dataset of images. More precisely, we look for a non-negative, sparse decomposition of the images on a reduced set of atoms, in order to unveil a morphological and explainable structure of the data. Additionally, we want this decomposition to be computed online for any new sample that is not part of the initial dataset. Therefore, our solution relies on a sparse, non-negative auto-encoder, where the encoder is deep (for accuracy) and the decoder shallow (for explainability). This method compares favorably to the state-of-the-art online methods on two benchmark datasets (MNIST and Fashion MNIST) and on a hyperspectral image, according to classical evaluation measures and to a new one we introduce, based on the equivariance of the representation to morphological operators.

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Reduced Dilation-Erosion Perceptron for Binary Classification

Cited by 19 publications

References 60 publications

Advances in Morphological Neural Networks: Training, Pruning and Enforcing Shape Constraints

Advances in Morphological Neural Networks: Training, Pruning and Enforcing Shape Constraints

Motion Recognition Based on Sum of the Squared Errors Distribution

Approximating morphological operators with part-based representations learned by asymmetric auto-encoders

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