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Main Authors: Lin, Guying, Yang, Lei, Liu, Yuan, Zhang, Congyi, Hou, Junhui, Jin, Xiaogang, Komura, Taku, Keyser, John, Wang, Wenping
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2401.01391
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author Lin, Guying
Yang, Lei
Liu, Yuan
Zhang, Congyi
Hou, Junhui
Jin, Xiaogang
Komura, Taku
Keyser, John
Wang, Wenping
author_facet Lin, Guying
Yang, Lei
Liu, Yuan
Zhang, Congyi
Hou, Junhui
Jin, Xiaogang
Komura, Taku
Keyser, John
Wang, Wenping
contents Neural implicit fields, such as the neural signed distance field (SDF) of a shape, have emerged as a powerful representation for many applications, e.g., encoding a 3D shape and performing collision detection. Typically, implicit fields are encoded by Multi-layer Perceptrons (MLP) with positional encoding (PE) to capture high-frequency geometric details. However, a notable side effect of such PE-equipped MLPs is the noisy artifacts present in the learned implicit fields. While increasing the sampling rate could in general mitigate these artifacts, in this paper we aim to explain this adverse phenomenon through the lens of Fourier analysis. We devise a tool to determine the appropriate sampling rate for learning an accurate neural implicit field without undesirable side effects. Specifically, we propose a simple yet effective method to estimate the intrinsic frequency of a given network with randomized weights based on the Fourier analysis of the network's responses. It is observed that a PE-equipped MLP has an intrinsic frequency much higher than the highest frequency component in the PE layer. Sampling against this intrinsic frequency following the Nyquist-Sannon sampling theorem allows us to determine an appropriate training sampling rate. We empirically show in the setting of SDF fitting that this recommended sampling rate is sufficient to secure accurate fitting results, while further increasing the sampling rate would not further noticeably reduce the fitting error. Training PE-equipped MLPs simply with our sampling strategy leads to performances superior to the existing methods.
format Preprint
id arxiv_https___arxiv_org_abs_2401_01391
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle On Optimal Sampling for Learning SDF Using MLPs Equipped with Positional Encoding
Lin, Guying
Yang, Lei
Liu, Yuan
Zhang, Congyi
Hou, Junhui
Jin, Xiaogang
Komura, Taku
Keyser, John
Wang, Wenping
Computer Vision and Pattern Recognition
Graphics
Machine Learning
Neural implicit fields, such as the neural signed distance field (SDF) of a shape, have emerged as a powerful representation for many applications, e.g., encoding a 3D shape and performing collision detection. Typically, implicit fields are encoded by Multi-layer Perceptrons (MLP) with positional encoding (PE) to capture high-frequency geometric details. However, a notable side effect of such PE-equipped MLPs is the noisy artifacts present in the learned implicit fields. While increasing the sampling rate could in general mitigate these artifacts, in this paper we aim to explain this adverse phenomenon through the lens of Fourier analysis. We devise a tool to determine the appropriate sampling rate for learning an accurate neural implicit field without undesirable side effects. Specifically, we propose a simple yet effective method to estimate the intrinsic frequency of a given network with randomized weights based on the Fourier analysis of the network's responses. It is observed that a PE-equipped MLP has an intrinsic frequency much higher than the highest frequency component in the PE layer. Sampling against this intrinsic frequency following the Nyquist-Sannon sampling theorem allows us to determine an appropriate training sampling rate. We empirically show in the setting of SDF fitting that this recommended sampling rate is sufficient to secure accurate fitting results, while further increasing the sampling rate would not further noticeably reduce the fitting error. Training PE-equipped MLPs simply with our sampling strategy leads to performances superior to the existing methods.
title On Optimal Sampling for Learning SDF Using MLPs Equipped with Positional Encoding
topic Computer Vision and Pattern Recognition
Graphics
Machine Learning
url https://arxiv.org/abs/2401.01391