Deep Differentiable Logic Gate Networks

Felix Petersen; Christian Borgelt; Hilde Kühne; Oliver Deussen

Deep Differentiable Logic Gate Networks

Felix Petersen
, Christian Borgelt
, Hilde Kühne
, Oliver Deussen

Artificial Intelligence and Human Interfaces

Research output: Chapter in Book/Report/Conference proceeding/Legal commentary › Conference contribution › peer-review

Abstract

Recently, research has increasingly focused on developing efficient neural network architectures. In this work, we explore logic gate networks for machine learning tasks by learning combinations of logic gates. These networks comprise logic gates such as "AND" and "XOR", which allow for very fast execution. The difficulty in learning logic gate networks is that they are conventionally non-differentiable and therefore do not allow training with gradient descent. Thus, to allow for effective training, we propose differentiable logic gate networks, an architecture that combines real-valued logics and a continuously parameterized relaxation of the network. The resulting discretized logic gate networks achieve fast inference speeds, e.g., beyond a million images of MNIST per second on a single CPU core.

Original language	English
Title of host publication	Proceedings of the 36th Conference on Neural Information Processing Systems (NeurIPS 2022)
Publication status	Published - 28 Nov 2022

Fields of Science and Technology Classification 2012

102 Computer Sciences

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Cite this

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title = "Deep Differentiable Logic Gate Networks",

abstract = "Recently, research has increasingly focused on developing efficient neural network architectures. In this work, we explore logic gate networks for machine learning tasks by learning combinations of logic gates. These networks comprise logic gates such as {"}AND{"} and {"}XOR{"}, which allow for very fast execution. The difficulty in learning logic gate networks is that they are conventionally non-differentiable and therefore do not allow training with gradient descent. Thus, to allow for effective training, we propose differentiable logic gate networks, an architecture that combines real-valued logics and a continuously parameterized relaxation of the network. The resulting discretized logic gate networks achieve fast inference speeds, e.g., beyond a million images of MNIST per second on a single CPU core.",

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T1 - Deep Differentiable Logic Gate Networks

AU - Petersen, Felix

AU - Borgelt, Christian

AU - Kühne, Hilde

AU - Deussen, Oliver

PY - 2022/11/28

Y1 - 2022/11/28

N2 - Recently, research has increasingly focused on developing efficient neural network architectures. In this work, we explore logic gate networks for machine learning tasks by learning combinations of logic gates. These networks comprise logic gates such as "AND" and "XOR", which allow for very fast execution. The difficulty in learning logic gate networks is that they are conventionally non-differentiable and therefore do not allow training with gradient descent. Thus, to allow for effective training, we propose differentiable logic gate networks, an architecture that combines real-valued logics and a continuously parameterized relaxation of the network. The resulting discretized logic gate networks achieve fast inference speeds, e.g., beyond a million images of MNIST per second on a single CPU core.

AB - Recently, research has increasingly focused on developing efficient neural network architectures. In this work, we explore logic gate networks for machine learning tasks by learning combinations of logic gates. These networks comprise logic gates such as "AND" and "XOR", which allow for very fast execution. The difficulty in learning logic gate networks is that they are conventionally non-differentiable and therefore do not allow training with gradient descent. Thus, to allow for effective training, we propose differentiable logic gate networks, an architecture that combines real-valued logics and a continuously parameterized relaxation of the network. The resulting discretized logic gate networks achieve fast inference speeds, e.g., beyond a million images of MNIST per second on a single CPU core.

M3 - Conference contribution

BT - Proceedings of the 36th Conference on Neural Information Processing Systems (NeurIPS 2022)

ER -