Stephan J. Garbin scite author profile

Translating or rotating an input image should not affect the results of many computer vision tasks. Convolutional neural networks (CNNs) are already translation equivariant: input image translations produce proportionate feature map translations. This is not the case for rotations. Global rotation equivariance is typically sought through data augmentation, but patch-wise equivariance is more difficult. We present Harmonic Networks or H-Nets, a CNN exhibiting equivariance to patch-wise translation and 360-rotation. We achieve this by replacing regular CNN filters with circular harmonics, returning a maximal response and orientation for every receptive field patch.H-Nets use a rich, parameter-efficient and fixed computational complexity representation, and we show that deep feature maps within the network encode complicated rotational invariants. We demonstrate that our layers are general enough to be used in conjunction with the latest architectures and techniques, such as deep supervision and batch normalization. We also achieve state-of-the-art classification on rotated-MNIST, and competitive results on other benchmark challenges.

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FastNeRF: High-Fidelity Neural Rendering at 200FPS

Garbin

et al. 2021

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Interpretable Transformations with Encoder-Decoder Networks

Worrall

Garbin

Turmukhambetov

et al. 2017

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Deep feature spaces have the capacity to encode complex transformations of their input data. However, understanding the relative feature-space relationship between two transformed encoded images is difficult. For instance, what is the relative feature space relationship between two rotated images? What is decoded when we interpolate in feature space? Ideally, we want to disentangle confounding factors, such as pose, appearance, and illumination, from object identity. Disentangling these is difficult because they interact in very nonlinear ways. We propose a simple method to construct a deep feature space, with explicitly disentangled representations of several known transformations. A person or algorithm can then manipulate the disentangled representation, for example, to re-render an image with explicit control over parameterized degrees of freedom. The feature space is constructed using a transforming encoder-decoder network with a custom feature transform layer, acting on the hidden representations. We demonstrate the advantages of explicit disentangling on a variety of datasets and transformations, and as an aid for traditional tasks, such as classification. *

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CONFIG: Controllable Neural Face Image Generation

Kowalski

Garbin

Estellers

et al. 2020

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3D Face Reconstruction with Dense Landmarks

Wood¹,

Baltrušaitis²,

Hewitt³

et al. 2022

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Stephan J. Garbin

Harmonic Networks: Deep Translation and Rotation Equivariance

FastNeRF: High-Fidelity Neural Rendering at 200FPS

Interpretable Transformations with Encoder-Decoder Networks

CONFIG: Controllable Neural Face Image Generation

3D Face Reconstruction with Dense Landmarks

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