Edoardo Remelli scite author profile

We present a new algorithm for real-time hand tracking on commodity depth-sensing devices. Our method does not require a user-specific calibration session, but rather learns the geometry as the user performs live in front of the camera, thus enabling seamless virtual interaction at the consumer level. The key novelty in our approach is an online optimization algorithm that jointly estimates pose and shape in each frame, and determines the uncertainty in such estimates. This knowledge allows the algorithm to integrate per-frame estimates over time, and build a personalized geometric model of the captured user. Our approach can easily be integrated in state-of-the-art continuous generative motion tracking software. We provide a detailed evaluation that shows how our approach achieves accurate motion tracking for real-time applications, while significantly simplifying the workflow of accurate hand performance capture. We also provide quantitative evaluation datasets at http://gfx.uvic.ca/datasets/handy

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Voxel2Mesh: 3D Mesh Model Generation from Volumetric Data

Wickramasinghe

Remelli

Knott

et al. 2020

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Lightweight Multi-View 3D Pose Estimation Through Camera-Disentangled Representation

et al. 2020

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Sketch2Mesh: Reconstructing and Editing 3D Shapes from Sketches

Guillard¹,

Remelli²,

Yvernay³

et al. 2021

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Low-Dimensionality Calibration through Local Anisotropic Scaling for Robust Hand Model Personalization

Remelli

Tkach

Tagliasacchi

et al. 2017

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We present a robust algorithm for personalizing a spheremesh tracking model to a user from a collection of depth measurements. Our core contribution is to demonstrate how simple geometric reasoning can be exploited to build a shape-space, and how its performance is comparable to shape-spaces constructed from datasets of carefully calibrated models. We achieve this goal by first reparameterizing the geometry of the tracking template, and introducing a multi-stage calibration optimization. Our novel parameterization decouples the degrees of freedom for pose and shape, resulting in improved convergence properties. Our analytically differentiable multi-stage calibration pipeline optimizes for the model in the natural low-dimensional space of local anisotropic scalings, leading to an effective solution that can be easily embedded in other tracking/calibration algorithms. Compared to existing sphere-mesh calibration algorithms, quantitative experiments assess our algorithm possesses a larger convergence basin, and our personalized models allows to perform motion tracking with superior accuracy.

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Edoardo Remelli

Online generative model personalization for hand tracking

Voxel2Mesh: 3D Mesh Model Generation from Volumetric Data

Lightweight Multi-View 3D Pose Estimation Through Camera-Disentangled Representation

Sketch2Mesh: Reconstructing and Editing 3D Shapes from Sketches

Low-Dimensionality Calibration through Local Anisotropic Scaling for Robust Hand Model Personalization

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