Improved Deep Point Cloud Geometry Compression

Quach, Maurice; Valenzise, Giuseppe; Dufaux, Frédéric

doi:10.1109/mmsp48831.2020.9287077

Cited by 95 publications

(66 citation statements)

References 15 publications

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“…Two early studies are presented in [11,12], using shallow architectures composed of convolution and de-convolution layers for analysis and synthesis. The impact of several parameters added to the initial version of the former network is evaluated in [13]. In [14], a rate-distortion performance analysis is conducted on the latent space of [12], which is enriched with a hyper-prior and the possibility of explicit quantization in [15].…”

Section: Related Workmentioning

confidence: 99%

On Block Prediction For Learning-Based Point Cloud Compression

Lazzarotto

Alexiou

Ebrahimi

2021

2021 IEEE International Conference on Image Processing (ICIP)

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Point clouds are among popular visual representations for immersive media. However, the vast amount of information generated during their acquisition requires effective compression for practical applications. Although relevant activities from standardization bodies have led to state-of-the-art compression using conventional methods, learning-based encoders have recently emerged as promising solutions with comparable performance while offering additional attractive features. Yet, there is still a large unexplored space for research that can lead to further advances. In this paper, we propose a block prediction module for bit-rate reduction of geometryonly point clouds. Our method exploits spatial redundancies at the decoding stage between block partitions in the point cloud, and predicts a query block using Generative Adversarial Networks. Results show performance improvements of the objective metrics at low bit-rates, after integration in a baseline auto-encoder architecture.

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Section: Related Workmentioning

confidence: 99%

On Block Prediction For Learning-Based Point Cloud Compression

Lazzarotto

Alexiou

Ebrahimi

2021

2021 IEEE International Conference on Image Processing (ICIP)

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“…This open source package offers a toolbox to compress point cloud geometry using deep neural networks. It implements all the contributions and experiments in our previous work [4]. The point cloud is partitioned into blocks and each block is compressed with a convolutional neural network, optimized with respect to a focal loss.…”

Section: Description and Overviewmentioning

confidence: 99%

“…At the decoder side, several parameters can be modified to adapt to the local point cloud density (balancing weight in the focal loss, optimal thresholding). Details on the choice of these parameters are reported in [4]. We complete the toolbox with a number of utility functions for evaluating and comparing the performance with other methods; we also provide pre-trained models and the datasets used to obtain them.…”

Section: Description and Overviewmentioning

confidence: 99%

“…This open source package is intended for researchers and engineers working on PCC. It has two main purposes: i) facilitating the reproduction and comparison with the family of codecs in [4]; ii) providing the tools and a starting point to foster new research on deep PCC. In particular, the adopted licensing scheme allows the use of this software as a base for implementation in an industrial context.…”

Section: Description and Overviewmentioning

confidence: 99%

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A Deep Point Cloud Geometry Coding Toolbox

Quach

Valenzise

Dufaux

2021

2021 IEEE International Conference on Multimedia &Amp; Expo Workshops (ICMEW)

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This short paper describes a TensorFlow toolbox for point cloud geometry coding based on deep neural networks. This coding method employs a deep auto-encoder trained with a focal loss to learn good representations for voxel occupancy. The software provides several coding parameters to achieve different rate-distortion trade-offs, and comes with pre-trained models to reproduce the results of the published paper. It also offers a number of utility functions for evaluating and comparing the codec. To our knowledge, this is the first publicly available open-source toolbox for deeplearning-based point cloud coding.

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“…been an increasing interest in the multimedia research community towards the definition of accurate quality metrics for point clouds. These efforts have been also partially motivated by the concurrent standardization activities for point cloud coding in MPEG [1], as well as due to the need of relevant loss functions in learning-based PC compression methods [2,3]. Different point cloud objective metrics have been proposed in the literature.…”

Section: Introductionmentioning

confidence: 99%

Deep Learning-Based Quality Assessment Of 3d Point Clouds Without Reference

Chetouani

Quach

Valenzise

et al. 2021

2021 IEEE International Conference on Multimedia &Amp; Expo Workshops (ICMEW)

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Point cloud (PC) quality assessment is of fundamental importance to enable the efficient processing, coding and transmission of 3D data for virtual/augmented reality, autonomous driving, cultural heritage, etc. The quality metrics proposed so far aim at quantifying the distortion in the PC geometry and/or attributes with respect to a reference pristine point cloud, using simple features extracted by the points. In this work, we target instead a blind (no-reference) scenario in which the original point cloud is not available. In addition, we learn features from data using deep neural networks. Given the limited availability of subjectively annotated datasets of corrupted point clouds, and the consequent difficulty to learn in an end-to-end fashion PC quality features, in this work we use instead a two-step procedure. First, we extract from local patches three relevant low-level features which have been commonly used in other PC quality metrics, i.e., geometric distance, local curvature and luminance values. Afterwards, we employ a deep neural network to learn, from these lowlevel features, a mapping to the PC ground truth mean opinion score. Our results on two state-of-the-art PC quality datasets show the potential of the proposed approach. The code is

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Improved Deep Point Cloud Geometry Compression

Cited by 95 publications

References 15 publications

On Block Prediction For Learning-Based Point Cloud Compression

On Block Prediction For Learning-Based Point Cloud Compression

A Deep Point Cloud Geometry Coding Toolbox

Deep Learning-Based Quality Assessment Of 3d Point Clouds Without Reference

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