HIGHER-ORDER FUNCTION NETWORKS FOR LEARNING COMPOSABLE 3D OBJECT REPRESENTATIONS

Eric Mitchell; Selim Engin; Volkan Isler; Daniel D. Lee

HIGHER-ORDER FUNCTION NETWORKS FOR LEARNING COMPOSABLE 3D OBJECT REPRESENTATIONS

Eric Mitchell, Selim Engin, Volkan Isler, Daniel D. Lee

Research output: Contribution to conference › Paper › peer-review

Abstract

We present a new approach to 3D object representation where a neural network encodes the geometry of an object directly into the weights and biases of a second 'mapping' network. This mapping network can be used to reconstruct an object by applying its encoded transformation to points randomly sampled from a simple geometric space, such as the unit sphere. We study the effectiveness of our method through various experiments on subsets of the ShapeNet dataset. We find that the proposed approach can reconstruct encoded objects with accuracy equal to or exceeding state-of-the-art methods with orders of magnitude fewer parameters. Our smallest mapping network has only about 7000 parameters and shows reconstruction quality on par with state-of-the-art object decoder architectures with millions of parameters. Further experiments on feature mixing through the composition of learned functions show that the encoding captures a meaningful subspace of objects.

Original language	English (US)
State	Published - 2020
Externally published	Yes
Event	8th International Conference on Learning Representations, ICLR 2020 - Addis Ababa, Ethiopia Duration: Apr 30 2020 → …

Conference

Conference	8th International Conference on Learning Representations, ICLR 2020
Country/Territory	Ethiopia
City	Addis Ababa
Period	4/30/20 → …

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© 2020 8th International Conference on Learning Representations, ICLR 2020. All rights reserved.

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author = "Eric Mitchell and Selim Engin and Volkan Isler and Lee, {Daniel D.}",

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T1 - HIGHER-ORDER FUNCTION NETWORKS FOR LEARNING COMPOSABLE 3D OBJECT REPRESENTATIONS

AU - Mitchell, Eric

AU - Engin, Selim

AU - Isler, Volkan

AU - Lee, Daniel D.

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AB - We present a new approach to 3D object representation where a neural network encodes the geometry of an object directly into the weights and biases of a second 'mapping' network. This mapping network can be used to reconstruct an object by applying its encoded transformation to points randomly sampled from a simple geometric space, such as the unit sphere. We study the effectiveness of our method through various experiments on subsets of the ShapeNet dataset. We find that the proposed approach can reconstruct encoded objects with accuracy equal to or exceeding state-of-the-art methods with orders of magnitude fewer parameters. Our smallest mapping network has only about 7000 parameters and shows reconstruction quality on par with state-of-the-art object decoder architectures with millions of parameters. Further experiments on feature mixing through the composition of learned functions show that the encoding captures a meaningful subspace of objects.

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HIGHER-ORDER FUNCTION NETWORKS FOR LEARNING COMPOSABLE 3D OBJECT REPRESENTATIONS

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