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Main Authors: Liao, Zhanfeng, Zheng, Qian, Liu, Yan, Pan, Gang
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2311.09077
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author Liao, Zhanfeng
Zheng, Qian
Liu, Yan
Pan, Gang
author_facet Liao, Zhanfeng
Zheng, Qian
Liu, Yan
Pan, Gang
contents A crucial reason for the success of existing NeRF-based methods is to build a neural density field for the geometry representation via multiple perceptron layers (MLPs). MLPs are continuous functions, however, real geometry or density field is frequently discontinuous at the interface between the air and the surface. Such a contrary brings the problem of unfaithful geometry representation. To this end, this paper proposes spiking NeRF, which leverages spiking neurons and a hybrid Artificial Neural Network (ANN)-Spiking Neural Network (SNN) framework to build a discontinuous density field for faithful geometry representation. Specifically, we first demonstrate the reason why continuous density fields will bring inaccuracy. Then, we propose to use the spiking neurons to build a discontinuous density field. We conduct a comprehensive analysis for the problem of existing spiking neuron models and then provide the numerical relationship between the parameter of the spiking neuron and the theoretical accuracy of geometry. Based on this, we propose a bounded spiking neuron to build the discontinuous density field. Our method achieves SOTA performance. The source code and the supplementary material are available at https://github.com/liaozhanfeng/Spiking-NeRF.
format Preprint
id arxiv_https___arxiv_org_abs_2311_09077
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Spiking NeRF: Representing the Real-World Geometry by a Discontinuous Representation
Liao, Zhanfeng
Zheng, Qian
Liu, Yan
Pan, Gang
Computer Vision and Pattern Recognition
A crucial reason for the success of existing NeRF-based methods is to build a neural density field for the geometry representation via multiple perceptron layers (MLPs). MLPs are continuous functions, however, real geometry or density field is frequently discontinuous at the interface between the air and the surface. Such a contrary brings the problem of unfaithful geometry representation. To this end, this paper proposes spiking NeRF, which leverages spiking neurons and a hybrid Artificial Neural Network (ANN)-Spiking Neural Network (SNN) framework to build a discontinuous density field for faithful geometry representation. Specifically, we first demonstrate the reason why continuous density fields will bring inaccuracy. Then, we propose to use the spiking neurons to build a discontinuous density field. We conduct a comprehensive analysis for the problem of existing spiking neuron models and then provide the numerical relationship between the parameter of the spiking neuron and the theoretical accuracy of geometry. Based on this, we propose a bounded spiking neuron to build the discontinuous density field. Our method achieves SOTA performance. The source code and the supplementary material are available at https://github.com/liaozhanfeng/Spiking-NeRF.
title Spiking NeRF: Representing the Real-World Geometry by a Discontinuous Representation
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2311.09077