Related papers: Embed Me If You Can: A Geometric Perceptron

Embed Me If You Can: A Geometric Perceptron

URL: http://arxiv.org/abs/2006.06507v4
Date: Wed, 18 Aug 2021 12:13:57 GMT
Title: Embed Me If You Can: A Geometric Perceptron
Authors: Pavlo Melnyk, Michael Felsberg, M{\aa}rten Wadenb\"ack
Abstract summary: We introduce an extension of the multilayer hypersphere perceptron (MLHP) Our model is superior to the vanilla multilayer perceptron when classifying 3D Tetris shapes.
Score: 14.274582421372308
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Solving geometric tasks involving point clouds by using machine learning is a challenging problem. Standard feed-forward neural networks combine linear or, if the bias parameter is included, affine layers and activation functions. Their geometric modeling is limited, which motivated the prior work introducing the multilayer hypersphere perceptron (MLHP). Its constituent part, i.e., the hypersphere neuron, is obtained by applying a conformal embedding of Euclidean space. By virtue of Clifford algebra, it can be implemented as the Cartesian dot product of inputs and weights. If the embedding is applied in a manner consistent with the dimensionality of the input space geometry, the decision surfaces of the model units become combinations of hyperspheres and make the decision-making process geometrically interpretable for humans. Our extension of the MLHP model, the multilayer geometric perceptron (MLGP), and its respective layer units, i.e., geometric neurons, are consistent with the 3D geometry and provide a geometric handle of the learned coefficients. In particular, the geometric neuron activations are isometric in 3D, which is necessary for rotation and translation equivariance. When classifying the 3D Tetris shapes, we quantitatively show that our model requires no activation function in the hidden layers other than the embedding to outperform the vanilla multilayer perceptron. In the presence of noise in the data, our model is also superior to the MLHP.

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