1 code implementation • 15 Jul 2024 • Rong Wang, Wei Mao, Changsheng Lu, Hongdong Li
In contrast, we present a novel method aiming for high-quality motion transfer with realistic apparel animation.
no code implementations • 18 Apr 2024 • Jinwu Wang, Wei Mao, Miaomiao Liu
In this paper, we introduce a MusIc conditioned 3D Dance GEneraTion model, named MIDGET based on Dance motion Vector Quantised Variational AutoEncoder (VQ-VAE) model and Motion Generative Pre-Training (GPT) model to generate vibrant and highquality dances that match the music rhythm.
1 code implementation • NeurIPS 2023 • Rong Wang, Wei Mao, Hongdong Li
Specifically, for an initial hand-object pose estimated by a base network, we forward it to a physics simulator to evaluate its stability.
1 code implementation • 1 Oct 2023 • Chaoyue Xing, Wei Mao, Miaomiao Liu
In this paper, we tackle the problem of scene-aware 3D human motion forecasting.
Ranked #1 on Human Pose Forecasting on GTA-IM Dataset
1 code implementation • 15 Sep 2023 • Junkai Ji, Wei Mao, Feng Xi, Shengyao Chen
Direction of arrival (DOA) estimation employing low-resolution analog-to-digital convertors (ADCs) has emerged as a challenging and intriguing problem, particularly with the rise in popularity of large-scale arrays.
1 code implementation • CVPR 2023 • Huiyu Gao, Wei Mao, Miaomiao Liu
Different from their works which sparsify voxels globally with a fixed occupancy threshold, we perform the sparsification on a local feature volume along each visual ray to preserve at least one voxel per ray for more fine details.
1 code implementation • 16 Nov 2022 • Rong Wang, Wei Mao, Hongdong Li
In contrast, we propose a novel dense mutual attention mechanism that is able to model fine-grained dependencies between the hand and the object.
Ranked #2 on hand-object pose on HO-3D v2 (using extra training data)
1 code implementation • 8 Oct 2022 • Wei Mao, Miaomiao Liu, Richard Hartley, Mathieu Salzmann
In this paper, we tackle the task of scene-aware 3D human motion forecasting, which consists of predicting future human poses given a 3D scene and a past human motion.
Ranked #3 on Human Pose Forecasting on GTA-IM Dataset
1 code implementation • CVPR 2022 • Wei Mao, Miaomiao Liu, Mathieu Salzmann
We introduce the task of action-driven stochastic human motion prediction, which aims to predict multiple plausible future motions given a sequence of action labels and a short motion history.
1 code implementation • ICCV 2021 • Wei Mao, Miaomiao Liu, Mathieu Salzmann
Recent progress in stochastic motion prediction, i. e., predicting multiple possible future human motions given a single past pose sequence, has led to producing truly diverse future motions and even providing control over the motion of some body parts.
Ranked #2 on Human Pose Forecasting on AMASS (APD metric)
1 code implementation • 17 Jun 2021 • Wei Mao, Miaomiao Liu, Mathieu Salzmann, Hongdong Li
Whether based on recurrent or feed-forward neural networks, existing learning based methods fail to model the observation that human motion tends to repeat itself, even for complex sports actions and cooking activities.
1 code implementation • 6 Mar 2021 • Wei Mao, Jiaming Zhang, Kailun Yang, Rainer Stiefelhagen
Based on Lintention, we then devise a novel panoptic segmentation model which we term Panoptic Lintention Net.
3 code implementations • ECCV 2020 • Wei Mao, Miaomiao Liu, Mathieu Salzmann
Human motion prediction aims to forecast future human poses given a past motion.
no code implementations • 20 Jul 2020 • Wei Mao, Jiaming Zhang, Kailun Yang, Rainer Stiefelhagen
Navigational perception for visually impaired people has been substantially promoted by both classic and deep learning based segmentation methods.
1 code implementation • CVPR 2020 • Jiayu Yang, Wei Mao, Jose M. Alvarez, Miaomiao Liu
We propose a cost volume-based neural network for depth inference from multi-view images.
Ranked #15 on 3D Reconstruction on DTU
5 code implementations • ICCV 2019 • Wei Mao, Miaomiao Liu, Mathieu Salzmann, Hongdong Li
In this paper, we propose a simple feed-forward deep network for motion prediction, which takes into account both temporal smoothness and spatial dependencies among human body joints.