Neural Mesh Flow: 3D Manifold Mesh Generation via Diffeomorphic Flows

Gupta, Kunal; Chandraker, Manmohan

doi:10.48550/arxiv.2007.10973

Cited by 7 publications

(14 citation statements)

References 39 publications

(101 reference statements)

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“…Therefore, by sampling a large number of points in the physical space, these methods can also achieve high-resolution reconstruction that are not constrained by the voxel resolution of the input image or GPU memory. However, the inference process for such methods is computationally expensive (Gupta and Chandraker, 2020) as it requires prediction on a large number of points. In contrast, our method represents the mesh as a graph (i.e., a sparse matrix) and takes less than a second to predict a high resolution whole heart mesh.…”

Section: Discussionmentioning

confidence: 99%

A Deep-Learning Approach For Direct Whole-Heart Mesh Reconstruction

Kong,

Wilson,

Shadden

2021

Preprint

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Automated construction of surface geometries of cardiac structures from volumetric medical images is important for a number of clinical applications. While deep-learning based approaches have demonstrated promising reconstruction precision, these approaches have mostly focused on voxel-wise segmentation followed by surface reconstruction and post-processing techniques. However, such approaches suffer from a number of limitations including disconnected regions or incorrect surface topology due to erroneous segmentation and stair-case artifacts due to limited segmentation resolution. We propose a novel deep-learning-based approach that directly predicts whole heart surface meshes from volumetric CT and MR image data. Our approach leverages a graph convolutional neural network to predict deformation on mesh vertices from a pre-defined mesh template to reconstruct multiple anatomical structures in a 3D image volume. Our method demonstrated promising performance of generating high-resolution and high-quality whole heart reconstructions and outperformed prior deep-learning based methods on both CT and MR data in terms of precision and surface quality. Furthermore, our method can more efficiently produce temporally-consistent and feature-corresponding surface mesh predictions for heart motion from CT or MR cine sequences, and therefore can potentially be applied for efficiently constructing 4D whole heart dynamics.

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Section: Discussionmentioning

confidence: 99%

A Deep-Learning Approach For Direct Whole-Heart Mesh Reconstruction

Kong,

Wilson,

Shadden

2021

Preprint

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“…Training a deep learning model requires extensive use of sampling, and faster methods are needed. Indeed for a large number of applications [45,17,14], this sampling is performed online and at each training step when a new mesh is predicted by the neural network.…”

Section: Related Workmentioning

confidence: 99%

“…Recently, computer vision researchers have demonstrated an increasing interest in developing deep learning models for 3D data understanding [42,5]. As successful applications of those models, we can mention single view object shape reconstruction [45,14], shape and pose estimation [22], point cloud completion and approximation [16], and brain cortical surface reconstruction [38].…”

Section: Introductionmentioning

confidence: 99%

“…In essence, the mainstream approach relies on sampling point clouds from any given meshes to be able to compute point-based distances such as the Chamfer distance [3] or earth mover's distance [37]. While there exist in-depth discussions about these distance metrics in the literature [13,27], the mesh sampling technique itself remains uncharted, where the uniform sampling approach is widely adopted by most of the 3D deep learning models [45,31,14]. This approach is computationally efficient and is the only mesh sampling method available in existing 3D deep learning libraries like PyTorch3D [35] and Kaolin [19].…”

Section: Introductionmentioning

confidence: 99%

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MongeNet: Efficient Sampler for Geometric Deep Learning

Lebrat¹,

Cruz²,

Fookes³

et al. 2021

Preprint

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“…As point clouds and meshes become the most popular representations for several vision and graphics applications, different approaches have been proposed to compress and reconstruct 3D models. Current shape processing approaches [10,52,51,12] often adopt an autoencoder architecture, where the encoder projects the input family into a lower-dimensional latent space and the decoder reconstructs the data from the latent embedding.…”

Section: Towards 3d Style Transfermentioning

confidence: 99%

3DSNet: Unsupervised Shape-to-Shape 3D Style Transfer

Segù¹,

Grinvald²,

Siegwart³

et al. 2020

Preprint

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Transferring the style from one image onto another is a popular and widely studied task in computer vision. Yet, learning-based style transfer in the 3D setting remains a largely unexplored problem. To our knowledge, we propose the first learning-based generative approach for style transfer between 3D objects. Our method allows to combine the content and style of a source and target 3D model to generate a novel shape that resembles in style the target while retaining the source content. The proposed framework can synthesize new 3D shapes both in the form of point clouds and meshes. Furthermore, we extend our technique to implicitly learn the underlying multimodal style distribution of the individual category domains. By sampling style codes from the learned distributions, we increase the variety of styles that our model can confer to a given reference object. Experimental results validate the effectiveness of the proposed 3D style transfer method on a number of benchmarks. The implementation of our framework and the pretrained models will be released upon acceptance.

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Neural Mesh Flow: 3D Manifold Mesh Generation via Diffeomorphic Flows

Cited by 7 publications

References 39 publications

A Deep-Learning Approach For Direct Whole-Heart Mesh Reconstruction

A Deep-Learning Approach For Direct Whole-Heart Mesh Reconstruction

MongeNet: Efficient Sampler for Geometric Deep Learning

3DSNet: Unsupervised Shape-to-Shape 3D Style Transfer

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