Jacey Huang

Jiaxin Huang

I am currently pursuing my Master's degree at X-D Lab, Zhejiang University, under the guidance of Prof.Yiyi Liao. Prior to this, I completed my Bachelor's degree at the College of ISEE, Zhejiang University, graduating with a B.S. degree in Information Engineering in June 2023.

During my time at X-D Lab, I have focused on projects involving 3D scene editing and the development of generalizable techniques for 3D scene reconstruction.

My Chinese name is 黄嘉欣.

Email / Scholar / Twitter / Github

News

Feb 27, 2025: One paper is accepted to CVPR 2025.
Jul 1, 2024: One paper is accepted to ECCV 2024.
Jul 15, 2023: One paper is accepted to ICCV 2023.

Research

My research interests primarily revolve around 3D computer vision, encompassing areas such as 3D reconstruction and controllable generation of 3D scenes. * means equal contribution.

	Vivid4D: Improving 4D Reconstruction from Monocular Video by Video Inpainting Jiaxin Huang, Sheng Miao, Bangbang Yang, Yuewen Ma, Yiyi Liao, arxiv, 2025 project page / arXiv A generative framework that addresses the challenge of reconstructing dynamic scenes from casual monocular videos with video diffusion model.
	EVolSplat: Efficient Volume-based Gaussian Splatting for Urban View Synthesis Sheng Miao, Jiaxin Huang, Dongfeng Bai, Xu Yan, Hongyu Zhou, Yue Wang, Bingbing Liu, Andreas Geiger, Yiyi Liao, CVPR, 2025 project page / arXiv A generalizable framework that predicts 3D Gaussians across multiple frames within a unified volume using convolutional networks.
	Efficient Depth-Guided Urban View Synthesis Sheng Miao^∗, Jiaxin Huang^∗, Dongfeng Bai, Weichao Qiu, Bingbing Liu, Andreas Geiger, Yiyi Liao, ECCV, 2024 project page / arXiv A generalizable NeRF model that explicitly leverages geometric priors for feed-forward inference on unbounded sparse urban scenes.
	VeRi3D: Generative Vertex-based Radiance Fields for 3D Controllable Human Image Synthesis Xinya Chen, Jiaxin Huang, Yanrui Bin, Lu Yu, Yiyi Liao, ICCV, 2023 project page / arXiv A generative human vertex-based radiance field parameterized by vertices of the parametric human template, SMPL.