Silvan Weder scite author profile

We present a novel online depth map fusion approach that learns depth map aggregation in a latent feature space. While previous fusion methods use an explicit scene representation like signed distance functions (SDFs), we propose a learned feature representation for the fusion. The key idea is a separation between the scene representation used for the fusion and the output scene representation, via an additional translator network. Our neural network architecture consists of two main parts: a depth and feature fusion sub-network, which is followed by a translator sub-network to produce the final surface representation (e.g. TSDF) for visualization or other tasks. Our approach is real-time capable, handles high noise levels, and is particularly able to deal with gross outliers common for photometric stereo-based depth maps. Experiments on real and synthetic data demonstrate improved results compared to the state of the art, especially in challenging scenarios with large amounts of noise and outliers.

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Learning Online Multi-sensor Depth Fusion

Sandström

Oswald

Kumar

et al. 2022

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DeepSurfels: Learning Online Appearance Fusion

Mihajlovic

Weder

Pollefeys

et al. 2021

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RoutedFusion: Learning Real-time Depth Map Fusion

Weder¹,

Schönberger²,

Pollefeys³

et al. 2020

Preprint

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The efficient fusion of depth maps is a key part of most state-of-the-art 3D reconstruction methods. Besides requiring high accuracy, these depth fusion methods need to be scalable and real-time capable. To this end, we present a novel real-time capable machine learning-based method for depth map fusion. Similar to the seminal depth map fusion approach by Curless and Levoy, we only update a local group of voxels to ensure real-time capability. Instead of a simple linear fusion of depth information, we propose a neural network that predicts non-linear updates to better account for typical fusion errors. Our network is composed of a 2D depth routing network and a 3D depth fusion network which efficiently handle sensor-specific noise and outliers. This is especially useful for surface edges and thin objects for which the original approach suffers from thickening artifacts. Our method outperforms the traditional fusion approach and related learned approaches on both synthetic and real data. We demonstrate the performance of our method in reconstructing fine geometric details from noise and outlier contaminated data on various scenes.

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Silvan Weder

RoutedFusion: Learning Real-Time Depth Map Fusion

NeuralFusion: Online Depth Fusion in Latent Space

Learning Online Multi-sensor Depth Fusion

DeepSurfels: Learning Online Appearance Fusion

RoutedFusion: Learning Real-time Depth Map Fusion

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