Litcius/Paper detail

Fourier Features Let Networks Learn High Frequency Functions in Low Dimensional Domains

Matthew Tancik, Pratul P. Srinivasan, Ben Mildenhall, Sara Fridovich-Keil, Nithin Raghavan, Utkarsh Singhal, Ravi Ramamoorthi, Jonathan T. Barron, Ren Ng

2020Neural Information Processing Systems137 citations

Abstract

We show that passing input points through a simple Fourier feature mapping enables a multilayer perceptron (MLP) to learn high-frequency functions in low-dimensional problem domains. These results shed light on recent advances in computer vision and graphics that achieve state-of-the-art results by using MLPs to represent complex 3D objects and scenes. Using tools from the neural tangent kernel (NTK) literature, we show that a standard MLP fails to learn high frequencies both in theory and in practice. To overcome this spectral bias, we use a Fourier feature mapping to transform the effective NTK into a stationary kernel with a tunable bandwidth. We suggest an approach for selecting problem-specific Fourier features that greatly improves the performance of MLPs for low-dimensional regression tasks relevant to the computer vision and graphics communities.

Topics & Concepts

Computer scienceFourier transformArtificial intelligenceKernel (algebra)GraphicsPattern recognition (psychology)Artificial neural networkFeature (linguistics)Bandwidth (computing)AlgorithmComputer visionMathematicsComputer graphics (images)Mathematical analysisLinguisticsComputer networkCombinatoricsPhilosophyNeural Networks and ApplicationsModel Reduction and Neural NetworksIndustrial Vision Systems and Defect Detection
Fourier Features Let Networks Learn High Frequency Functions in Low Dimensional Domains | Litcius