Zhongang Qi scite author profile

Unlike images which are represented in regular dense grids, 3D point clouds are irregular and unordered, hence applying convolution on them can be difficult. In this paper, we extend the dynamic filter to a new convolution operation, named PointConv. PointConv can be applied on point clouds to build deep convolutional networks. We treat convolution kernels as nonlinear functions of the local coordinates of 3D points comprised of weight and density functions. With respect to a given point, the weight functions are learned with multi-layer perceptron networks and density functions through kernel density estimation. The most important contribution of this work is a novel reformulation proposed for efficiently computing the weight functions, which allowed us to dramatically scale up the network and significantly improve its performance. The learned convolution kernel can be used to compute translation-invariant and permutation-invariant convolution on any point set in the 3D space. Besides, PointConv can also be used as deconvolution operators to propagate features from a subsampled point cloud back to its original resolution. Experiments on ModelNet40, ShapeNet, and ScanNet show that deep convolutional neural networks built on PointConv are able to achieve state-of-the-art on challenging semantic segmentation benchmarks on 3D point clouds. Besides, our experiments converting CIFAR-10 into a point cloud showed that networks built on PointConv can match the performance of convolutional networks in 2D images of a similar structure.

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Persistent Ocular Hypertension Following Intravitreal Bevacizumab and Ranibizumab Injections

Adelman

Mayer

2010

Journal of Ocular Pharmacology and Therapeutics

147

112

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Deep Air Learning: Interpolation, Prediction, and Feature Analysis of Fine-Grained Air Quality

Qi¹,

Wang²,

Song³

et al. 2018

IEEE Trans. Knowl. Data Eng.

221

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The interpolation, prediction, and feature analysis of fine-gained air quality are three important topics in the area of urban air computing. The solutions to these topics can provide extremely useful information to support air pollution control, and consequently generate great societal and technical impacts. Most of the existing work solves the three problems separately by different models. In this paper, we propose a general and effective approach to solve the three problems in one model called the Deep Air Learning (DAL). The main idea of DAL lies in embedding feature selection and semi-supervised learning in different layers of the deep learning network. The proposed approach utilizes the information pertaining to the unlabeled spatio-temporal data to improve the performance of the interpolation and the prediction, and performs feature selection and association analysis to reveal the main relevant features to the variation of the air quality. We evaluate our approach with extensive experiments based on real data sources obtained in Beijing, China. Experiments show that DAL is superior to the peer models from the recent literature when solving the topics of interpolation, prediction, and feature analysis of fine-gained air quality.

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Prognostic significance of thrombocytosis, platelet parameters and aggregation rates in epithelial ovarian cancer

Wang

Sheng

et al. 2013

J of Obstet and Gynaecol

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Visualizing Deep Networks by Optimizing with Integrated Gradients

Khorram

2020

AAAI

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Understanding and interpreting the decisions made by deep learning models is valuable in many domains. In computer vision, computing heatmaps from a deep network is a popular approach for visualizing and understanding deep networks. However, heatmaps that do not correlate with the network may mislead human, hence the performance of heatmaps in providing a faithful explanation to the underlying deep network is crucial. In this paper, we propose I-GOS, which optimizes for a heatmap so that the classification scores on the masked image would maximally decrease. The main novelty of the approach is to compute descent directions based on the integrated gradients instead of the normal gradient, which avoids local optima and speeds up convergence. Compared with previous approaches, our method can flexibly compute heatmaps at any resolution for different user needs. Extensive experiments on several benchmark datasets show that the heatmaps produced by our approach are more correlated with the decision of the underlying deep network, in comparison with other state-of-the-art approaches.

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Open-book Video Captioning with Retrieve-Copy-Generate Network

Zhang

Yuan

et al. 2021

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T2I-Adapter: Learning Adapters to Dig out More Controllable Ability for Text-to-Image Diffusion Models

Mou¹,

Wang²,

Xie³

et al. 2023

Preprint

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PointConv: Deep Convolutional Networks on 3D Point Clouds

Wu¹,

Qi²,

Li³

2018

Preprint

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Zhongang Qi

PointConv: Deep Convolutional Networks on 3D Point Clouds

Persistent Ocular Hypertension Following Intravitreal Bevacizumab and Ranibizumab Injections

Deep Air Learning: Interpolation, Prediction, and Feature Analysis of Fine-Grained Air Quality

Prognostic significance of thrombocytosis, platelet parameters and aggregation rates in epithelial ovarian cancer

Visualizing Deep Networks by Optimizing with Integrated Gradients

Open-book Video Captioning with Retrieve-Copy-Generate Network

T2I-Adapter: Learning Adapters to Dig out More Controllable Ability for Text-to-Image Diffusion Models

PointConv: Deep Convolutional Networks on 3D Point Clouds

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