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Yanyan Li

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4 papers

1 author row

NeurIPS Conference 2025 Conference Paper

4D3R: Motion-Aware Neural Reconstruction and Rendering of Dynamic Scenes from Monocular Videos

Mengqi Guo
Bo Xu
Yanyan Li
Gim Hee Lee

Novel view synthesis from monocular videos of dynamic scenes with unknown camera poses remains a fundamental challenge in computer vision and graphics. While recent advances in 3D representations such as Neural Radiance Fields (NeRF) and 3D Gaussian Splatting (3DGS) have shown promising results for static scenes, they struggle with dynamic content and typically rely on pre-computed camera poses. We present 4D3R, a pose-free dynamic neural rendering framework that decouples static and dynamic components through a two-stage approach. Our method first leverages 3D foundational models for initial pose and geometry estimation, followed by motion-aware refinement. 4D3R introduces two key technical innovations: (1) a motion-aware bundle adjustment (MA-BA) module that combines transformer-based learned priors with SAM2 for robust dynamic object segmentation, enabling more accurate camera pose refinement; and (2) an efficient Motion-Aware Gaussian Splatting (MA-GS) representation that uses control points with a deformation field MLP and linear blend skinning to model dynamic motion, significantly reducing computational cost while maintaining high-quality reconstruction. Extensive experiments on real-world dynamic datasets demonstrate that our approach achieves up to 1. 8dB PSNR improvement over state-of-the-art methods, particularly in challenging scenarios with large dynamic objects, while reducing computational requirements by 5× compared to previous dynamic scene representations.

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TCS Journal 2024 Journal Article

Dynamic threshold spiking neural P systems with weights and multiple channels

Yanyan Li
Bosheng Song
Yuansheng Liu
Xiangxiang Zeng
Shengye Huang

Membrane computing represents a sophisticated branch of computational science that assimilates the characteristics of cellular membranes and harnesses mathematical principles. It derives inspiration from the intricate structure and functional attributes exhibited by biological cell membranes. This exposition is dedicated to an in-depth exploration of spiking neural P systems (SN P systems), meticulously crafted to emulate the intricate signaling and interaction phenomena between cellular entities. Nevertheless, conventional spiking neural P systems confront inherent constraints pertaining to their excitation rules, which hinder their applicability to real-world challenges. In pursuit of overcoming these limitations, we introduce a novel paradigm encompassing the dynamic thresholds, synaptic weights, and the integration of multiple channels within synapses. This innovative framework culminates in the dynamic threshold spiking neural P systems with weights of synapses and multiple channels in synapses (DSNP-WM systems). It is noteworthy that DSNP-WM systems demonstrate Turing universality, effectively functioning as versatile entities capable of both number generation and acceptance, in addition to performing intricate computations. Importantly, these systems showcase the efficiency in tackling challenges posed by semi-uniform solutions, exemplified by the Subsets Sum problem—a fundamental member of the NP-complete problem class, which employs a nondeterministic approach.

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TCS Journal 2023 Journal Article

Spiking neural P systems with weights and delays on synapses

Yanyan Li
Bosheng Song
Xiangxiang Zeng

Spiking neural P systems (SN P systems) are bio-inspired neural-like computational devices that mimic the communication between two nearby neurons and the spike changes in the neuron. This study incorporates concepts of the weight of synapses and the delay on synapses to increase the bio-explainability (the model can better simulate the communication between neurons), where the weight is a natural feature of synapses, and the delay is that in the communication between neurons, through synapses. Thus, an innovative type of spiking neural-like P system is defined, called spiking neural P systems with weights and delays on synapses ( W D S N P systems). In W D S N P systems, synapses are assigned weights and delays, where weights are real numbers and delays are natural numbers. Results proved in this paper show that W D S N P systems can reach Turing universality in the generating and accepting mode. The semi-uniform solution for the Subset Sum problem demonstrates that W D S N P systems can solve NP-complete problems efficiently.

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IJCAI Conference 2020 Conference Paper

Why We Go Where We Go: Profiling User Decisions on Choosing POIs

Renjun Hu
Xinjiang Lu
Chuanren Liu
Yanyan Li
Hao Liu
Jingjing Gu
Shuai Ma
Hui Xiong

While Point-of-Interest (POI) recommendation has been a popular topic of study for some time, little progress has been made for understanding why and how people make their decisions for the selection of POIs. To this end, in this paper, we propose a user decision profiling framework, named PROUD, which can identify the key factors in people's decisions on choosing POIs. Specifically, we treat each user decision as a set of factors and provide a method for learning factor embeddings. A unique perspective of our approach is to identify key factors, while preserving decision structures seamlessly, via a novel scalar projection maximization objective. Exactly solving the objective is non-trivial due to a sparsity constraint. To address this, our PROUD adopts a self projection attention and an L2 regularized sparse activation to directly estimate the likelihood of each factor to be a key factor. Finally, extensive experiments on real-world data validate the advantage of PROUD in preserving user decision structures. Also, our case study indicates that the identified key decision factors can help us to provide more interpretable recommendations and analyses.

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