Your search keyword '"Liu, Yong-An"' showing total 53,350 results

1. TimesBERT: A BERT-Style Foundation Model for Time Series Understanding

Author

Zhang, Haoran, Liu, Yong, Qiu, Yunzhong, Liu, Haixuan, Pei, Zhongyi, Wang, Jianmin, and Long, Mingsheng

Subjects

Computer Science - Machine Learning

Abstract

Time series analysis is crucial in diverse scenarios. Beyond forecasting, considerable real-world tasks are categorized into classification, imputation, and anomaly detection, underscoring different capabilities termed time series understanding in this paper. While GPT-style models have been positioned as foundation models for time series forecasting, the BERT-style architecture, which has made significant advances in natural language understanding, has not been fully unlocked for time series understanding, possibly attributed to the undesirable dropout of essential elements of BERT. In this paper, inspired by the shared multi-granularity structure between multivariate time series and multisentence documents, we design TimesBERT to learn generic representations of time series including temporal patterns and variate-centric characteristics. In addition to a natural adaptation of masked modeling, we propose a parallel task of functional token prediction to embody vital multi-granularity structures. Our model is pre-trained on 260 billion time points across diverse domains. Leveraging multi-granularity representations, TimesBERT achieves state-of-the-art performance across four typical downstream understanding tasks, outperforming task-specific models and language pre-trained backbones, positioning it as a versatile foundation model for time series understanding.

Published

2025

2. Disentangling Feature Structure: A Mathematically Provable Two-Stage Training Dynamics in Transformers

Author

Gong, Zixuan, Teng, Jiaye, and Liu, Yong

Subjects

Computer Science - Computation and Language, Computer Science - Artificial Intelligence, Computer Science - Machine Learning

Abstract

Transformers may exhibit two-stage training dynamics during the real-world training process. For instance, when training GPT-2 on the Counterfact dataset, the answers progress from syntactically incorrect to syntactically correct to semantically correct. However, existing theoretical analyses hardly account for this two-stage phenomenon. In this paper, we theoretically demonstrate how such two-stage training dynamics occur in transformers. Specifically, we analyze the dynamics of transformers using feature learning techniques under in-context learning regimes, based on a disentangled two-type feature structure. Such disentanglement of feature structure is general in practice, e.g., natural languages contain syntax and semantics, and proteins contain primary and secondary structures. To our best known, this is the first rigorous result regarding a two-stage optimization process in transformers. Additionally, a corollary indicates that such a two-stage process is closely related to the spectral properties of the attention weights, which accords well with empirical findings.

Published

2025

3. Towards Auto-Regressive Next-Token Prediction: In-Context Learning Emerges from Generalization

Author

Gong, Zixuan, Hu, Xiaolin, Tang, Huayi, and Liu, Yong

Subjects

Computer Science - Computation and Language, Computer Science - Machine Learning, Statistics - Machine Learning

Abstract

Large language models (LLMs) have demonstrated remarkable in-context learning (ICL) abilities. However, existing theoretical analysis of ICL primarily exhibits two limitations: (a) Limited i.i.d. Setting. Most studies focus on supervised function learning tasks where prompts are constructed with i.i.d. input-label pairs. This i.i.d. assumption diverges significantly from real language learning scenarios where prompt tokens are interdependent. (b) Lack of Emergence Explanation. Most literature answers what ICL does from an implicit optimization perspective but falls short in elucidating how ICL emerges and the impact of pre-training phase on ICL. In our paper, to extend (a), we adopt a more practical paradigm, auto-regressive next-token prediction (AR-NTP), which closely aligns with the actual training of language models. Specifically, within AR-NTP, we emphasize prompt token-dependency, which involves predicting each subsequent token based on the preceding sequence. To address (b), we formalize a systematic pre-training and ICL framework, highlighting the layer-wise structure of sequences and topics, alongside a two-level expectation. In conclusion, we present data-dependent, topic-dependent and optimization-dependent PAC-Bayesian generalization bounds for pre-trained LLMs, investigating that ICL emerges from the generalization of sequences and topics. Our theory is supported by experiments on numerical linear dynamic systems, synthetic GINC and real-world language datasets., Comment: Published at ICLR 2025

Published

2025

4. A Universal Framework for Compressing Embeddings in CTR Prediction

Author

Wang, Kefan, Wang, Hao, Song, Kenan, Guo, Wei, Cheng, Kai, Li, Zhi, Liu, Yong, Lian, Defu, and Chen, Enhong

Subjects

Computer Science - Information Retrieval

Abstract

Accurate click-through rate (CTR) prediction is vital for online advertising and recommendation systems. Recent deep learning advancements have improved the ability to capture feature interactions and understand user interests. However, optimizing the embedding layer often remains overlooked. Embedding tables, which represent categorical and sequential features, can become excessively large, surpassing GPU memory limits and necessitating storage in CPU memory. This results in high memory consumption and increased latency due to frequent GPU-CPU data transfers. To tackle these challenges, we introduce a Model-agnostic Embedding Compression (MEC) framework that compresses embedding tables by quantizing pre-trained embeddings, without sacrificing recommendation quality. Our approach consists of two stages: first, we apply popularity-weighted regularization to balance code distribution between high- and low-frequency features. Then, we integrate a contrastive learning mechanism to ensure a uniform distribution of quantized codes, enhancing the distinctiveness of embeddings. Experiments on three datasets reveal that our method reduces memory usage by over 50x while maintaining or improving recommendation performance compared to existing models. The implementation code is accessible in our project repository https://github.com/USTC-StarTeam/MEC., Comment: Accepted by DASFAA2025

Published

2025

5. Simulation Studies of the Effect of SiPM Dark Noise on the Performance of a Highly Granular Crystal ECAL

Author

Rolph, Jack, Liu, Yong, Qi, Baohua, and Zhao, Zhiyu

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

A proposal for the CEPC ECAL is a highly-granular scintillating crystal design that uses SiPMs to measure physics signals from photons. Radiation damage to the silicon will impair the performance of the calorimeter due to dark noise, which will affect the reconstruction capabilities of the calorimeter system. This paper presents a simulation study assessing the effect of radiation damage of SiPM dark noise on the response from calorimeter to electrons due to changing fluence and temperature. It was observed that dark noise significantly degrades the linearity of response, with up to 45% error in reconstructed energy for a 1 GeV shower at a fluence of $1 \times 10^{10}\mathrm{cm}^{-2}$. The stochastic and noise resolution terms was observed to remain stable, increasing only by 0.2% and 1% respectively in the range $1 \times 10^{7}-1 \times 10^{10}\mathrm{cm}^{-2}$ fluence. Under the assumption of no irradiation, the influence of dark noise with temperature in the normal operating range of the calorimeter system was estimated to be negligible.

Published

2025

6. Generative Large Recommendation Models: Emerging Trends in LLMs for Recommendation

Author

Wang, Hao, Guo, Wei, Zhang, Luankang, Chin, Jin Yao, Ye, Yufei, Guo, Huifeng, Liu, Yong, Lian, Defu, Tang, Ruiming, and Chen, Enhong

Subjects

Computer Science - Information Retrieval

Abstract

In the era of information overload, recommendation systems play a pivotal role in filtering data and delivering personalized content. Recent advancements in feature interaction and user behavior modeling have significantly enhanced the recall and ranking processes of these systems. With the rise of large language models (LLMs), new opportunities have emerged to further improve recommendation systems. This tutorial explores two primary approaches for integrating LLMs: LLMs-enhanced recommendations, which leverage the reasoning capabilities of general LLMs, and generative large recommendation models, which focus on scaling and sophistication. While the former has been extensively covered in existing literature, the latter remains underexplored. This tutorial aims to fill this gap by providing a comprehensive overview of generative large recommendation models, including their recent advancements, challenges, and potential research directions. Key topics include data quality, scaling laws, user behavior mining, and efficiency in training and inference. By engaging with this tutorial, participants will gain insights into the latest developments and future opportunities in the field, aiding both academic research and practical applications. The timely nature of this exploration supports the rapid evolution of recommendation systems, offering valuable guidance for researchers and practitioners alike., Comment: This paper has been accepted for the tutorial track at WWW 2025

Published

2025

7. AS-GCL: Asymmetric Spectral Augmentation on Graph Contrastive Learning

Author

Liu, Ruyue, Yin, Rong, Liu, Yong, Hao, Xiaoshuai, Shi, Haichao, Ma, Can, and Wang, Weiping

Subjects

Computer Science - Machine Learning

Abstract

Graph Contrastive Learning (GCL) has emerged as the foremost approach for self-supervised learning on graph-structured data. GCL reduces reliance on labeled data by learning robust representations from various augmented views. However, existing GCL methods typically depend on consistent stochastic augmentations, which overlook their impact on the intrinsic structure of the spectral domain, thereby limiting the model's ability to generalize effectively. To address these limitations, we propose a novel paradigm called AS-GCL that incorporates asymmetric spectral augmentation for graph contrastive learning. A typical GCL framework consists of three key components: graph data augmentation, view encoding, and contrastive loss. Our method introduces significant enhancements to each of these components. Specifically, for data augmentation, we apply spectral-based augmentation to minimize spectral variations, strengthen structural invariance, and reduce noise. With respect to encoding, we employ parameter-sharing encoders with distinct diffusion operators to generate diverse, noise-resistant graph views. For contrastive loss, we introduce an upper-bound loss function that promotes generalization by maintaining a balanced distribution of intra- and inter-class distance. To our knowledge, we are the first to encode augmentation views of the spectral domain using asymmetric encoders. Extensive experiments on eight benchmark datasets across various node-level tasks demonstrate the advantages of the proposed method., Comment: Accepted by TMM

Published

2025

8. SPPD: Self-training with Process Preference Learning Using Dynamic Value Margin

Author

Yi, Hao, Li, Qingyang, Hu, Yulan, Zhang, Fuzheng, Zhang, Di, and Liu, Yong

Subjects

Computer Science - Artificial Intelligence

Abstract

Recently, enhancing the numerical and logical reasoning capability of Large Language Models (LLMs) has emerged as a research hotspot. Existing methods face several limitations: inference-phase techniques (e.g., Chain of Thoughts) rely on prompt selection and the pretrained knowledge; sentence-level Supervised Fine-Tuning (SFT) and Direct Preference Optimization (DPO) struggle with step-wise mathematical correctness and depend on stronger models distillation or human annotations; while Reinforcement Learning (RL) approaches incur high GPU memory costs and unstable training. To address these, we propose \textbf{S}elf-training framework integrating \textbf{P}rocess \textbf{P}reference learning using \textbf{D}ynamic value margin (SPPD). SPPD leverages a process-based Markov Decision Process (MDP) and Bellman optimality equation to derive \textbf{dynamic value margin} on step-level preference optimization, which employs tree-based self-sampling on model responses \textbf{without any distillation} from other models. Furthermore, we theoretically prove that SPPD is \textbf{equivalent to on-policy policy gradient methods} under reward constraints. Experiments on 7B-scale models demonstrate superior performance across in-domain and out-domain mathematical benchmarks. We open-source our code at \href{https://anonymous.4open.science/r/SSDPO-D-DCDD}{https://anonymous.4open.science/r/SPPD-DCDD}.

Published

2025

9. Adaptive Tool Use in Large Language Models with Meta-Cognition Trigger

Author

Li, Wenjun, Li, Dexun, Dong, Kuicai, Zhang, Cong, Zhang, Hao, Liu, Weiwen, Wang, Yasheng, Tang, Ruiming, and Liu, Yong

Subjects

Computer Science - Artificial Intelligence, Computer Science - Computation and Language

Abstract

Large language models (LLMs) have shown remarkable emergent capabilities, transforming the execution of functional tasks by leveraging external tools for complex problems that require specialized processing or real-time data. While existing research expands LLMs access to diverse tools (e.g., program interpreters, search engines, weather/map apps), the necessity of using these tools is often overlooked, leading to indiscriminate tool invocation. This naive approach raises two key issues:(1) increased delays due to unnecessary tool calls, and (2) potential errors resulting from faulty interactions with external tools. In this paper, we introduce meta-cognition as a proxy for LLMs self-assessment of their capabilities, representing the model's awareness of its own limitations. Based on this, we propose MeCo, an adaptive decision-making strategy for external tool use. MeCo quantifies metacognitive scores by capturing high-level cognitive signals in the representation space, guiding when to invoke tools. Notably, MeCo is fine-tuning-free and incurs minimal cost. Our experiments show that MeCo accurately detects LLMs' internal cognitive signals and significantly improves tool-use decision-making across multiple base models and benchmarks.

Published

2025

10. Image Inversion: A Survey from GANs to Diffusion and Beyond

Author

Chen, Yinan, Zhang, Jiangning, Bi, Yali, Hu, Xiaobin, Hu, Teng, Xue, Zhucun, Yi, Ran, Liu, Yong, and Tai, Ying

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Image inversion is a fundamental task in generative models, aiming to map images back to their latent representations to enable downstream applications such as editing, restoration, and style transfer. This paper provides a comprehensive review of the latest advancements in image inversion techniques, focusing on two main paradigms: Generative Adversarial Network (GAN) inversion and diffusion model inversion. We categorize these techniques based on their optimization methods. For GAN inversion, we systematically classify existing methods into encoder-based approaches, latent optimization approaches, and hybrid approaches, analyzing their theoretical foundations, technical innovations, and practical trade-offs. For diffusion model inversion, we explore training-free strategies, fine-tuning methods, and the design of additional trainable modules, highlighting their unique advantages and limitations. Additionally, we discuss several popular downstream applications and emerging applications beyond image tasks, identifying current challenges and future research directions. By synthesizing the latest developments, this paper aims to provide researchers and practitioners with a valuable reference resource, promoting further advancements in the field of image inversion. We keep track of the latest works at https://github.com/RyanChenYN/ImageInversion, Comment: 10 pages, 2 figures

Published

2025

11. Understanding Generalization in Transformers: Error Bounds and Training Dynamics Under Benign and Harmful Overfitting

Author

Zhang, Yingying, Wu, Zhenyu, Li, Jian, and Liu, Yong

Subjects

Computer Science - Machine Learning

Abstract

Transformers serve as the foundational architecture for many successful large-scale models, demonstrating the ability to overfit the training data while maintaining strong generalization on unseen data, a phenomenon known as benign overfitting. However, research on how the training dynamics influence error bounds within the context of benign overfitting has been limited. This paper addresses this gap by developing a generalization theory for a two-layer transformer with labeled flip noise. Specifically, we present generalization error bounds for both benign and harmful overfitting under varying signal-to-noise ratios (SNR), where the training dynamics are categorized into three distinct stages, each with its corresponding error bounds. Additionally, we conduct extensive experiments to identify key factors that influence test errors in transformers. Our experimental results align closely with the theoretical predictions, validating our findings.

Published

2025

12. Revisiting Weak-to-Strong Generalization in Theory and Practice: Reverse KL vs. Forward KL

Author

Yao, Wei, Yang, Wenkai, Wang, Ziqiao, Lin, Yankai, and Liu, Yong

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence

Abstract

As large language models advance toward superhuman performance, ensuring their alignment with human values and abilities grows increasingly complex. Weak-to-strong generalization offers a promising approach by leveraging predictions from weaker models to guide stronger systems, but its effectiveness could be constrained by the inherent noise and inaccuracies in these weak predictions. To address this, we propose a theoretically grounded approach that replaces forward KL divergence-whose mass-covering behavior risks overfitting to imperfect weak signals-with reverse KL divergence. Reverse KL divergence's zero-forcing effect prioritizes high-confidence predictions, effectively mitigating the influence of unreliable weak supervision. Theoretically, we extend existing bounds and derive tighter lower bounds for both forward and reverse KL divergence, establishing that reverse KL achieves at least comparable guarantees to forward KL. Notably, when a sufficiently pre-trained strong model is fine-tuned on the last layer, reverse KL uniquely guarantees that it outperforms its weak supervisor by the magnitude of their disagreement-a guarantee that forward KL cannot provide. Empirically, we demonstrate that reverse KL and reverse cross-entropy enable strong models to consistently outperform those trained with forward KL and standard cross-entropy across most settings, highlighting the practical advantages of these reverse losses.

Published

2025

13. Commissioning of a radiofrequency quadrupole cooler-buncher for collinear laser spectroscopy

Author

Liu, Yin-Shen, Hu, Han-Rui, Yang, Xiao-Fei, Mei, Wen-Cong, Guo, Yang-Fan, Yan, Zhou, Chen, Shao-Jie, Bai, Shi-wei, Wang, Shu-Jing, Liu, Yong-Chao, Zhang, Peng, Chen, Dong-Yang, Ye, Yan-Lin, Li, Qi-Te, Yang, Jie, Malbrunot-Ettenauer, Stephan, Lechner, Simon, and Kanitz, Carina

Subjects

Physics - Instrumentation and Detectors, Nuclear Experiment, Physics - Accelerator Physics

Abstract

A RadioFrequency Quadrupole (RFQ) cooler-buncher system has been developed and implemented in a collinear laser spectroscopy setup. This system is dedicated to convert a continuous ion beam into short bunches, while enhancing beam quality and reducing energy spread. The functionality of the RFQ cooler-buncher has been verified through offline tests with stable rubidium and indium beam, delivered from a surface ion source and a laser ablation ion source, respectively. With a transmission efficiency exceeding 60%, bunched ion beams with a full width at half maximum of approximately 2{\mu}s in the time-of-flight spectrum have been successfully achieved. The implementation of RFQ cooler-buncher system has significantly improved the overall transmission efficiency of the collinear laser spectroscopy setup.

Published

2025

14. Multifunctional Altermagnet with Large Out-of-Plane Piezoelectric Response in Janus V$_{2}$AsBrO Monolayer

Author

Ma, Qiuyue, Wang, Busheng, Yang, Guochun, and Liu, Yong

Subjects

Condensed Matter - Materials Science

Abstract

Altermagnetism has emerged as a third fundamental category of collinear magnetism, characterized by spin-splitting in symmetry-compensated collinear antiferromagnets, opening new frontiers in spintronics and condensed matter physics. Here, based on first-principles calculations, we propose a novel altermagnetic semiconductor, the asymmetric Janus V$_2$AsBrO monolayer, which exhibits a magnetic easy axis favoring the out-of-plane direction and a N\'{e}el temperature ($T_N$) exceeding room temperature. The system exhibits a strain-tunable piezovalley effect, generating valley polarization under uniaxial strain. Notably, hole doping under uniaxial strain generates a net magnetization ($M$) through a piezomagnetic mechanism. Additionally, the broken inversion symmetry endows the monolayer with a substantial out-of-plane piezoelectric coefficient $d_{31}$ (2.19 pm/V), presenting broad prospects for the development and design of novel piezoelectric devices. Our findings provide a promising candidate material for the advancement of 2D multifunctional devices in nanoelectronics, spintronics, valleytronics, and piezoelectrics., Comment: 17 pages, 4 figures

Published

2025

15. AiRacleX: Automated Detection of Price Oracle Manipulations via LLM-Driven Knowledge Mining and Prompt Generation

Author

Gao, Bo, Wang, Yuan, Wei, Qingsong, Liu, Yong, Goh, Rick Siow Mong, and Lo, David

Subjects

Computer Science - Cryptography and Security, Computer Science - Artificial Intelligence

Abstract

Decentralized finance (DeFi) applications depend on accurate price oracles to ensure secure transactions, yet these oracles are highly vulnerable to manipulation, enabling attackers to exploit smart contract vulnerabilities for unfair asset valuation and financial gain. Detecting such manipulations traditionally relies on the manual effort of experienced experts, presenting significant challenges. In this paper, we propose a novel LLM-driven framework that automates the detection of price oracle manipulations by leveraging the complementary strengths of different LLM models (LLMs). Our approach begins with domain-specific knowledge extraction, where an LLM model synthesizes precise insights about price oracle vulnerabilities from top-tier academic papers, eliminating the need for profound expertise from developers or auditors. This knowledge forms the foundation for a second LLM model to generate structured, context-aware chain of thought prompts, which guide a third LLM model in accurately identifying manipulation patterns in smart contracts. We validate the effectiveness of framework through experiments on 60 known vulnerabilities from 46 real-world DeFi attacks or projects spanning 2021 to 2023. The best performing combination of LLMs (Haiku-Haiku-4o-mini) identified by AiRacleX demonstrate a 2.58-times improvement in recall (0.667 vs 0.259) compared to the state-of-the-art tool GPTScan, while maintaining comparable precision. Furthermore, our framework demonstrates the feasibility of replacing commercial models with open-source alternatives, enhancing privacy and security for developers.

Published

2025

16. Geometric origin of self-intersection points in non-Hermitian energy spectra

Author

Pi, Jinghui, Wang, Chenyang, Liu, Yong-Chun, and Yan, Yangqian

Subjects

Quantum Physics, Condensed Matter - Quantum Gases, Physics - Optics

Abstract

Unlike Hermitian systems, non-Hermitian energy spectra under periodic boundary conditions can form closed loops in the complex energy plane, a phenomenon known as point gap topology. In this paper, we investigate the self-intersection points of such non-Hermitian energy spectra and reveal their geometric origins. We rigorously demonstrate that these self-intersection points result from the intersection of the auxiliary generalized Brillouin zone and the Brillouin zone in one-band systems, as confirmed by an extended Hatano-Nelson model. This finding is further generalized to multi-band systems, illustrated through a non-Hermitian Su-Schrieffer-Heeger model. Moreover, we address multiple self-intersection points and derive the geometric conditions for general n-fold self-intersection points. Our results enhance the fundamental understanding of generic non-Hermitian quantum systems and provide theoretical support for further experimental investigations of energy self-intersection points., Comment: 11 pages, 5 figures

Published

2025

17. Unveiling the Mechanisms of Explicit CoT Training: How Chain-of-Thought Enhances Reasoning Generalization

Author

Yao, Xinhao, Ren, Ruifeng, Liao, Yun, and Liu, Yong

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Computer Science - Computation and Language

Abstract

Training large language models (LLMs) with high-quality Chain-of-Thought (CoT) annotations has become a widely adopted strategy due to its significant enhancement of reasoning capabilities. To fully comprehend this approach, two questions naturally arise: (Q1) What advantages does training with CoT offer compared to training without CoT? (Q2) If there are advantages, what are the underlying mechanisms of explicit CoT training? Analyzing the advantages and mechanisms of CoT training is challenging due to the many factors involved. To address this, we conduct a detailed analysis using clear and controllable data distributions and, for the first time, reveal that CoT training offers the following advantages: (1) Training with CoT markedly improves reasoning generalization, extending it from in-distribution (ID) to both ID and out-of-distribution (OOD) scenarios, while also speeding up convergence; (2) Even when training with CoT includes a certain range of erroneous reasoning steps, it still enables the model to learn reasoning patterns, leading to systematic generalization. We further explore the underlying mechanisms from a circuit perspective: (1) The data distribution (e.g., ratio $\lambda$ and pattern) plays a crucial role in influencing the model's systematic generalization; (2) CoT training (with two-hop facts) internalizes reasoning into a two-stage generalizing circuit, where the number of stages corresponds to the explicit reasoning steps during training. Our findings elucidate the mechanisms underlying explicit CoT training and offer critical insights into tuning strategies for LLMs to achieve robust generalization.

Published

2025

18. Semi-rPPG: Semi-Supervised Remote Physiological Measurement with Curriculum Pseudo-Labeling

Author

Wu, Bingjie, Yu, Zitong, Xie, Yiping, Liu, Wei, Luo, Chaoqi, Liu, Yong, and Goh, Rick Siow Mong

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Remote Photoplethysmography (rPPG) is a promising technique to monitor physiological signals such as heart rate from facial videos. However, the labeled facial videos in this research are challenging to collect. Current rPPG research is mainly based on several small public datasets collected in simple environments, which limits the generalization and scale of the AI models. Semi-supervised methods that leverage a small amount of labeled data and abundant unlabeled data can fill this gap for rPPG learning. In this study, a novel semi-supervised learning method named Semi-rPPG that combines curriculum pseudo-labeling and consistency regularization is proposed to extract intrinsic physiological features from unlabelled data without impairing the model from noises. Specifically, a curriculum pseudo-labeling strategy with signal-to-noise ratio (SNR) criteria is proposed to annotate the unlabelled data while adaptively filtering out the low-quality unlabelled data. Besides, a novel consistency regularization term for quasi-periodic signals is proposed through weak and strong augmented clips. To benefit the research on semi-supervised rPPG measurement, we establish a novel semi-supervised benchmark for rPPG learning through intra-dataset and cross-dataset evaluation on four public datasets. The proposed Semi-rPPG method achieves the best results compared with three classical semi-supervised methods under different protocols. Ablation studies are conducted to prove the effectiveness of the proposed methods., Comment: Accepted by IEEE Transactions on Instrumentation and Measurement (TIM)

Published

2025

19. FuXi-$\alpha$: Scaling Recommendation Model with Feature Interaction Enhanced Transformer

Author

Ye, Yufei, Guo, Wei, Chin, Jin Yao, Wang, Hao, Zhu, Hong, Lin, Xi, Ye, Yuyang, Liu, Yong, Tang, Ruiming, Lian, Defu, and Chen, Enhong

Subjects

Computer Science - Information Retrieval

Abstract

Inspired by scaling laws and large language models, research on large-scale recommendation models has gained significant attention. Recent advancements have shown that expanding sequential recommendation models to large-scale recommendation models can be an effective strategy. Current state-of-the-art sequential recommendation models primarily use self-attention mechanisms for explicit feature interactions among items, while implicit interactions are managed through Feed-Forward Networks (FFNs). However, these models often inadequately integrate temporal and positional information, either by adding them to attention weights or by blending them with latent representations, which limits their expressive power. A recent model, HSTU, further reduces the focus on implicit feature interactions, constraining its performance. We propose a new model called FuXi-$\alpha$ to address these issues. This model introduces an Adaptive Multi-channel Self-attention mechanism that distinctly models temporal, positional, and semantic features, along with a Multi-stage FFN to enhance implicit feature interactions. Our offline experiments demonstrate that our model outperforms existing models, with its performance continuously improving as the model size increases. Additionally, we conducted an online A/B test within the Huawei Music app, which showed a $4.76\%$ increase in the average number of songs played per user and a $5.10\%$ increase in the average listening duration per user. Our code has been released at https://github.com/USTC-StarTeam/FuXi-alpha., Comment: Accepted by WWW2025

Published

2025

20. qNBO: quasi-Newton Meets Bilevel Optimization

Author

Fang, Sheng, Liu, Yong-Jin, Yao, Wei, Yu, Chengming, and Zhang, Jin

Subjects

Computer Science - Machine Learning, Mathematics - Optimization and Control

Abstract

Bilevel optimization, addressing challenges in hierarchical learning tasks, has gained significant interest in machine learning. The practical implementation of the gradient descent method to bilevel optimization encounters computational hurdles, notably the computation of the exact lower-level solution and the inverse Hessian of the lower-level objective. Although these two aspects are inherently connected, existing methods typically handle them separately by solving the lower-level problem and a linear system for the inverse Hessian-vector product. In this paper, we introduce a general framework to address these computational challenges in a coordinated manner. Specifically, we leverage quasi-Newton algorithms to accelerate the resolution of the lower-level problem while efficiently approximating the inverse Hessian-vector product. Furthermore, by exploiting the superlinear convergence properties of BFGS, we establish the non-asymptotic convergence analysis of the BFGS adaptation within our framework. Numerical experiments demonstrate the comparable or superior performance of the proposed algorithms in real-world learning tasks, including hyperparameter optimization, data hyper-cleaning, and few-shot meta-learning.

Published

2025

21. Understanding the Capabilities and Limitations of Weak-to-Strong Generalization

Author

Yao, Wei, Yang, Wenkai, Wang, Ziqiao, Lin, Yankai, and Liu, Yong

Subjects

Computer Science - Machine Learning, Statistics - Machine Learning

Abstract

Weak-to-strong generalization, where weakly supervised strong models outperform their weaker teachers, offers a promising approach to aligning superhuman models with human values. To deepen the understanding of this approach, we provide theoretical insights into its capabilities and limitations. First, in the classification setting, we establish upper and lower generalization error bounds for the strong model, identifying the primary limitations as stemming from the weak model's generalization error and the optimization objective itself. Additionally, we derive lower and upper bounds on the calibration error of the strong model. These theoretical bounds reveal two critical insights: (1) the weak model should demonstrate strong generalization performance and maintain well-calibrated predictions, and (2) the strong model's training process must strike a careful balance, as excessive optimization could undermine its generalization capability by over-relying on the weak supervision signals. Finally, in the regression setting, we extend the work of Charikar et al. (2024) to a loss function based on Kullback-Leibler (KL) divergence, offering guarantees that the strong student can outperform its weak teacher by at least the magnitude of their disagreement. We conduct sufficient experiments to validate our theory.

Published

2025

22. Sundial: A Family of Highly Capable Time Series Foundation Models

Author

Liu, Yong, Qin, Guo, Shi, Zhiyuan, Chen, Zhi, Yang, Caiyin, Huang, Xiangdong, Wang, Jianmin, and Long, Mingsheng

Subjects

Computer Science - Machine Learning

Abstract

We introduce Sundial, a family of native, flexible, and scalable time series foundation models. To predict the next-patch's distribution, we propose a TimeFlow Loss based on flow-matching, which facilitates native pre-training of Transformers on time series without discrete tokenization. Conditioned on arbitrary-length time series, our model is pre-trained without specifying any prior distribution and can generate multiple probable predictions, achieving flexibility in representation learning beyond using parametric densities. Towards time series foundation models, we leverage minimal but crucial adaptations of Transformers and curate TimeBench with 1 trillion time points, comprising mostly real-world datasets and synthetic data. By mitigating mode collapse through TimeFlow Loss, we pre-train a family of Sundial models on TimeBench, which exhibit unprecedented model capacity and generalization performance on zero-shot forecasting. In addition to presenting good scaling behavior, Sundial achieves new state-of-the-art on both point forecasting and probabilistic forecasting benchmarks. We believe that Sundial's pioneering generative paradigm will facilitate a wide variety of forecasting scenarios.

Published

2025

23. A Diffusion Model Translator for Efficient Image-to-Image Translation

Author

Xia, Mengfei, Zhou, Yu, Yi, Ran, Liu, Yong-Jin, and Wang, Wenping

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Applying diffusion models to image-to-image translation (I2I) has recently received increasing attention due to its practical applications. Previous attempts inject information from the source image into each denoising step for an iterative refinement, thus resulting in a time-consuming implementation. We propose an efficient method that equips a diffusion model with a lightweight translator, dubbed a Diffusion Model Translator (DMT), to accomplish I2I. Specifically, we first offer theoretical justification that in employing the pioneering DDPM work for the I2I task, it is both feasible and sufficient to transfer the distribution from one domain to another only at some intermediate step. We further observe that the translation performance highly depends on the chosen timestep for domain transfer, and therefore propose a practical strategy to automatically select an appropriate timestep for a given task. We evaluate our approach on a range of I2I applications, including image stylization, image colorization, segmentation to image, and sketch to image, to validate its efficacy and general utility. The comparisons show that our DMT surpasses existing methods in both quality and efficiency. Code will be made publicly available.

Published

2025

24. Rethinking External Slow-Thinking: From Snowball Errors to Probability of Correct Reasoning

Author

Gan, Zeyu, Liao, Yun, and Liu, Yong

Subjects

Computer Science - Artificial Intelligence, Computer Science - Computation and Language

Abstract

Test-time scaling, which is also often referred to as slow-thinking, has been demonstrated to enhance multi-step reasoning in large language models (LLMs). However, despite its widespread utilization, the mechanisms underlying slow-thinking methods remain poorly understood. This paper explores the mechanisms of external slow-thinking from a theoretical standpoint. We begin by examining the snowball error effect within the LLM reasoning process and connect it to the likelihood of correct reasoning using information theory. Building on this, we show that external slow-thinking methods can be interpreted as strategies to mitigate the error probability. We further provide a comparative analysis of popular external slow-thinking approaches, ranging from simple to complex, highlighting their differences and interrelationships. Our findings suggest that the efficacy of these methods is not primarily determined by the specific framework employed, and that expanding the search scope or the model's internal reasoning capacity may yield more sustained improvements in the long term. We open-source our code at https://github.com/ZyGan1999/Snowball-Errors-and-Probability.

Published

2025

25. Towards Sharper Information-theoretic Generalization Bounds for Meta-Learning

Author

Wen, Wen, Gong, Tieliang, Dong, Yuxin, Liu, Yong-Jin, and Zhang, Weizhan

Subjects

Statistics - Machine Learning, Computer Science - Machine Learning

Abstract

In recent years, information-theoretic generalization bounds have emerged as a promising approach for analyzing the generalization capabilities of meta-learning algorithms. However, existing results are confined to two-step bounds, failing to provide a sharper characterization of the meta-generalization gap that simultaneously accounts for environment-level and task-level dependencies. This paper addresses this fundamental limitation by establishing novel single-step information-theoretic bounds for meta-learning. Our bounds exhibit substantial advantages over prior MI- and CMI-based bounds, especially in terms of tightness, scaling behavior associated with sampled tasks and samples per task, and computational tractability. Furthermore, we provide novel theoretical insights into the generalization behavior of two classes of noise and iterative meta-learning algorithms via gradient covariance analysis, where the meta-learner uses either the entire meta-training data (e.g., Reptile), or separate training and test data within the task (e.g., model agnostic meta-learning (MAML)). Numerical results validate the effectiveness of the derived bounds in capturing the generalization dynamics of meta-learning.

Published

2025

26. Towards Better Robustness: Progressively Joint Pose-3DGS Learning for Arbitrarily Long Videos

Author

Dong, Zhen-Hui, Ye, Sheng, Wen, Yu-Hui, Li, Nannan, and Liu, Yong-Jin

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

3D Gaussian Splatting (3DGS) has emerged as a powerful representation due to its efficiency and high-fidelity rendering. However, 3DGS training requires a known camera pose for each input view, typically obtained by Structure-from-Motion (SfM) pipelines. Pioneering works have attempted to relax this restriction but still face difficulties when handling long sequences with complex camera trajectories. In this work, we propose Rob-GS, a robust framework to progressively estimate camera poses and optimize 3DGS for arbitrarily long video sequences. Leveraging the inherent continuity of videos, we design an adjacent pose tracking method to ensure stable pose estimation between consecutive frames. To handle arbitrarily long inputs, we adopt a "divide and conquer" scheme that adaptively splits the video sequence into several segments and optimizes them separately. Extensive experiments on the Tanks and Temples dataset and our collected real-world dataset show that our Rob-GS outperforms the state-of-the-arts.

Published

2025

27. FreEformer: Frequency Enhanced Transformer for Multivariate Time Series Forecasting

Author

Yue, Wenzhen, Liu, Yong, Ying, Xianghua, Xing, Bowei, Guo, Ruohao, and Shi, Ji

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence

Abstract

This paper presents \textbf{FreEformer}, a simple yet effective model that leverages a \textbf{Fre}quency \textbf{E}nhanced Trans\textbf{former} for multivariate time series forecasting. Our work is based on the assumption that the frequency spectrum provides a global perspective on the composition of series across various frequencies and is highly suitable for robust representation learning. Specifically, we first convert time series into the complex frequency domain using the Discrete Fourier Transform (DFT). The Transformer architecture is then applied to the frequency spectra to capture cross-variate dependencies, with the real and imaginary parts processed independently. However, we observe that the vanilla attention matrix exhibits a low-rank characteristic, thus limiting representation diversity. This could be attributed to the inherent sparsity of the frequency domain and the strong-value-focused nature of Softmax in vanilla attention. To address this, we enhance the vanilla attention mechanism by introducing an additional learnable matrix to the original attention matrix, followed by row-wise L1 normalization. Theoretical analysis~demonstrates that this enhanced attention mechanism improves both feature diversity and gradient flow. Extensive experiments demonstrate that FreEformer consistently outperforms state-of-the-art models on eighteen real-world benchmarks covering electricity, traffic, weather, healthcare and finance. Notably, the enhanced attention mechanism also consistently improves the performance of state-of-the-art Transformer-based forecasters.

Published

2025

28. Coarse-to-Fine Process Reward Modeling for Mathematical Reasoning

Author

Hu, Yulan, Chen, Ge, Zhao, Jinman, Ouyang, Sheng, and Liu, Yong

Subjects

Computer Science - Artificial Intelligence

Abstract

The Process Reward Model (PRM) plays a crucial role in mathematical reasoning tasks, requiring high-quality supervised process data. However, we observe that reasoning steps generated by Large Language Models (LLMs) often fail to exhibit strictly incremental information, leading to redundancy that can hinder effective reasoning. To address this issue, we propose CFPRM, a simple yet effective coarse-to-fine strategy. Instead of focusing on the detection of redundant steps, our approach first establishes a coarse-grained window to merge adjacent reasoning steps into unified, holistic steps. The window size is then progressively reduced to extract fine-grained reasoning steps, enabling data collection at multiple granularities for training. By leveraging this hierarchical refinement process, CFPRM mitigates redundancy while preserving essential fine-grained knowledge. Extensive experiments on two reasoning datasets across three loss criteria validate the CFPRM's effectiveness and versatility.

Published

2025

29. LiT: Delving into a Simplified Linear Diffusion Transformer for Image Generation

Author

Wang, Jiahao, Kang, Ning, Yao, Lewei, Chen, Mengzhao, Wu, Chengyue, Zhang, Songyang, Xue, Shuchen, Liu, Yong, Wu, Taiqiang, Liu, Xihui, Zhang, Kaipeng, Zhang, Shifeng, Shao, Wenqi, Li, Zhenguo, and Luo, Ping

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

In commonly used sub-quadratic complexity modules, linear attention benefits from simplicity and high parallelism, making it promising for image synthesis tasks. However, the architectural design and learning strategy for linear attention remain underexplored in this field. In this paper, we offer a suite of ready-to-use solutions for efficient linear diffusion Transformers. Our core contributions include: (1) Simplified Linear Attention using few heads, observing the free-lunch effect of performance without latency increase. (2) Weight inheritance from a fully pre-trained diffusion Transformer: initializing linear Transformer using pre-trained diffusion Transformer and loading all parameters except for those related to linear attention. (3) Hybrid knowledge distillation objective: using a pre-trained diffusion Transformer to help the training of the student linear Transformer, supervising not only the predicted noise but also the variance of the reverse diffusion process. These guidelines lead to our proposed Linear Diffusion Transformer (LiT), an efficient text-to-image Transformer that can be deployed offline on a laptop. Experiments show that in class-conditional 256*256 and 512*512 ImageNet benchmark LiT achieves highly competitive FID while reducing training steps by 80% and 77% compared to DiT. LiT also rivals methods based on Mamba or Gated Linear Attention. Besides, for text-to-image generation, LiT allows for the rapid synthesis of up to 1K resolution photorealistic images. Project page: https://techmonsterwang.github.io/LiT/., Comment: 21 pages, 12 figures

Published

2025

30. Are Traditional Deep Learning Model Approaches as Effective as a Retinal-Specific Foundation Model for Ocular and Systemic Disease Detection?

Author

Yew, Samantha Min Er, Lei, Xiaofeng, Goh, Jocelyn Hui Lin, Chen, Yibing, Srinivasan, Sahana, Chee, Miao-li, Pushpanathan, Krithi, Zou, Ke, Hou, Qingshan, Da Soh, Zhi, Xue, Cancan, Yu, Marco Chak Yan, Sabanayagam, Charumathi, Tai, E Shyong, Sim, Xueling, Wang, Yaxing, Jonas, Jost B., Nangia, Vinay, Yang, Gabriel Dawei, Ran, Emma Anran, Cheung, Carol Yim-Lui, Feng, Yangqin, Zhou, Jun, Goh, Rick Siow Mong, Zhou, Yukun, Keane, Pearse A., Liu, Yong, Cheng, Ching-Yu, and Tham, Yih-Chung

Subjects

Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning

Abstract

Background: RETFound, a self-supervised, retina-specific foundation model (FM), showed potential in downstream applications. However, its comparative performance with traditional deep learning (DL) models remains incompletely understood. This study aimed to evaluate RETFound against three ImageNet-pretrained supervised DL models (ResNet50, ViT-base, SwinV2) in detecting ocular and systemic diseases. Methods: We fine-tuned/trained RETFound and three DL models on full datasets, 50%, 20%, and fixed sample sizes (400, 200, 100 images, with half comprising disease cases; for each DR severity class, 100 and 50 cases were used. Fine-tuned models were tested internally using the SEED (53,090 images) and APTOS-2019 (3,672 images) datasets and externally validated on population-based (BES, CIEMS, SP2, UKBB) and open-source datasets (ODIR-5k, PAPILA, GAMMA, IDRiD, MESSIDOR-2). Model performance was compared using area under the receiver operating characteristic curve (AUC) and Z-tests with Bonferroni correction (P<0.05/3). Interpretation: Traditional DL models are mostly comparable to RETFound for ocular disease detection with large datasets. However, RETFound is superior in systemic disease detection with smaller datasets. These findings offer valuable insights into the respective merits and limitation of traditional models and FMs.

Published

2025

31. A Survey on Multi-Turn Interaction Capabilities of Large Language Models

Author

Zhang, Chen, Dai, Xinyi, Wu, Yaxiong, Yang, Qu, Wang, Yasheng, Tang, Ruiming, and Liu, Yong

Subjects

Computer Science - Computation and Language

Abstract

Multi-turn interaction in the dialogue system research refers to a system's ability to maintain context across multiple dialogue turns, enabling it to generate coherent and contextually relevant responses. Recent advancements in large language models (LLMs) have significantly expanded the scope of multi-turn interaction, moving beyond chatbots to enable more dynamic agentic interactions with users or environments. In this paper, we provide a focused review of the multi-turn capabilities of LLMs, which are critical for a wide range of downstream applications, including conversational search and recommendation, consultation services, and interactive tutoring. This survey explores four key aspects: (1) the core model capabilities that contribute to effective multi-turn interaction, (2) how multi-turn interaction is evaluated in current practice, (3) the general algorithms used to enhance multi-turn interaction, and (4) potential future directions for research in this field., Comment: Draft Version, 14 pages, Ongoing refinement over time

Published

2025

32. MMDocIR: Benchmarking Multi-Modal Retrieval for Long Documents

Author

Dong, Kuicai, Chang, Yujing, Goh, Xin Deik, Li, Dexun, Tang, Ruiming, and Liu, Yong

Subjects

Computer Science - Information Retrieval, Computer Science - Artificial Intelligence, Computer Science - Computation and Language, Computer Science - Computer Vision and Pattern Recognition

Abstract

Multi-modal document retrieval is designed to identify and retrieve various forms of multi-modal content, such as figures, tables, charts, and layout information from extensive documents. Despite its significance, there is a notable lack of a robust benchmark to effectively evaluate the performance of systems in multi-modal document retrieval. To address this gap, this work introduces a new benchmark, named as MMDocIR, encompassing two distinct tasks: page-level and layout-level retrieval. The former focuses on localizing the most relevant pages within a long document, while the latter targets the detection of specific layouts, offering a more fine-grained granularity than whole-page analysis. A layout can refer to a variety of elements such as textual paragraphs, equations, figures, tables, or charts. The MMDocIR benchmark comprises a rich dataset featuring expertly annotated labels for 1,685 questions and bootstrapped labels for 173,843 questions, making it a pivotal resource for advancing multi-modal document retrieval for both training and evaluation. Through rigorous experiments, we reveal that (i) visual retrievers significantly outperform their text counterparts, (ii) MMDocIR train set can effectively benefit the training process of multi-modal document retrieval and (iii) text retrievers leveraging on VLM-text perform much better than those using OCR-text. These findings underscores the potential advantages of integrating visual elements for multi-modal document retrieval., Comment: https://huggingface.co/MMDocIR

Published

2025

33. Densely Connected Parameter-Efficient Tuning for Referring Image Segmentation

Author

Huang, Jiaqi, Xu, Zunnan, Liu, Ting, Liu, Yong, Han, Haonan, Yuan, Kehong, and Li, Xiu

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

In the domain of computer vision, Parameter-Efficient Tuning (PET) is increasingly replacing the traditional paradigm of pre-training followed by full fine-tuning. PET is particularly favored for its effectiveness in large foundation models, as it streamlines transfer learning costs and optimizes hardware utilization. However, the current PET methods are mainly designed for single-modal optimization. While some pioneering studies have undertaken preliminary explorations, they still remain at the level of aligned encoders (e.g., CLIP) and lack exploration of misaligned encoders. These methods show sub-optimal performance with misaligned encoders, as they fail to effectively align the multimodal features during fine-tuning. In this paper, we introduce DETRIS, a parameter-efficient tuning framework designed to enhance low-rank visual feature propagation by establishing dense interconnections between each layer and all preceding layers, which enables effective cross-modal feature interaction and adaptation to misaligned encoders. We also suggest using text adapters to improve textual features. Our simple yet efficient approach greatly surpasses state-of-the-art methods with 0.9% to 1.8% backbone parameter updates, evaluated on challenging benchmarks. Our project is available at \url{https://github.com/jiaqihuang01/DETRIS}., Comment: Accepted by AAAI2025

Published

2025

34. RWKV-UNet: Improving UNet with Long-Range Cooperation for Effective Medical Image Segmentation

Author

Jiang, Juntao, Zhang, Jiangning, Liu, Weixuan, Gao, Muxuan, Hu, Xiaobin, Yan, Xiaoxiao, Huang, Feiyue, and Liu, Yong

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition

Abstract

In recent years, there have been significant advancements in deep learning for medical image analysis, especially with convolutional neural networks (CNNs) and transformer models. However, CNNs face limitations in capturing long-range dependencies while transformers suffer high computational complexities. To address this, we propose RWKV-UNet, a novel model that integrates the RWKV (Receptance Weighted Key Value) structure into the U-Net architecture. This integration enhances the model's ability to capture long-range dependencies and improve contextual understanding, which is crucial for accurate medical image segmentation. We build a strong encoder with developed inverted residual RWKV (IR-RWKV) blocks combining CNNs and RWKVs. We also propose a Cross-Channel Mix (CCM) module to improve skip connections with multi-scale feature fusion, achieving global channel information integration. Experiments on benchmark datasets, including Synapse, ACDC, BUSI, CVC-ClinicDB, CVC-ColonDB, Kvasir-SEG, ISIC 2017 and GLAS show that RWKV-UNet achieves state-of-the-art performance on various types of medical image segmentation. Additionally, smaller variants, RWKV-UNet-S and RWKV-UNet-T, balance accuracy and computational efficiency, making them suitable for broader clinical applications.

Published

2025

35. LeapVAD: A Leap in Autonomous Driving via Cognitive Perception and Dual-Process Thinking

Author

Ma, Yukai, Wei, Tiantian, Zhong, Naiting, Mei, Jianbiao, Hu, Tao, Wen, Licheng, Yang, Xuemeng, Shi, Botian, and Liu, Yong

Subjects

Computer Science - Artificial Intelligence

Abstract

While autonomous driving technology has made remarkable strides, data-driven approaches still struggle with complex scenarios due to their limited reasoning capabilities. Meanwhile, knowledge-driven autonomous driving systems have evolved considerably with the popularization of visual language models. In this paper, we propose LeapVAD, a novel method based on cognitive perception and dual-process thinking. Our approach implements a human-attentional mechanism to identify and focus on critical traffic elements that influence driving decisions. By characterizing these objects through comprehensive attributes - including appearance, motion patterns, and associated risks - LeapVAD achieves more effective environmental representation and streamlines the decision-making process. Furthermore, LeapVAD incorporates an innovative dual-process decision-making module miming the human-driving learning process. The system consists of an Analytic Process (System-II) that accumulates driving experience through logical reasoning and a Heuristic Process (System-I) that refines this knowledge via fine-tuning and few-shot learning. LeapVAD also includes reflective mechanisms and a growing memory bank, enabling it to learn from past mistakes and continuously improve its performance in a closed-loop environment. To enhance efficiency, we develop a scene encoder network that generates compact scene representations for rapid retrieval of relevant driving experiences. Extensive evaluations conducted on two leading autonomous driving simulators, CARLA and DriveArena, demonstrate that LeapVAD achieves superior performance compared to camera-only approaches despite limited training data. Comprehensive ablation studies further emphasize its effectiveness in continuous learning and domain adaptation. Project page: https://pjlab-adg.github.io/LeapVAD/.

Published

2025

36. Large deviation principle for the stationary solutions of stochastic functional differential equations with infinite delay

Author

Liu, Yong and Tang, Bin

Subjects

Mathematics - Probability, 60F10, 60G10, 34K50, 37A50

Abstract

We investigate the large deviation principle (LDP) of the stationary solutions of stochastic functional differential equations (SFDEs) with infinite delay under small random perturbation. First, we demonstrate the existence and uniqueness of the corresponding stationary solutions. Second, by the weak convergence approach, we show the uniform large deviation principle for the solution maps, and then prove the LDP for stationary solutions. Furthermore, we obtain the LDP for invariant measures of SFDEs through the LDP for stationary solutions and the contraction principle., Comment: 27 pages

Published

2025

37. Hyperbolic Binary Neural Network

Author

Chen, Jun, Xiang, Jingyang, Huang, Tianxin, Zhao, Xiangrui, and Liu, Yong

Subjects

Computer Science - Machine Learning, Computer Science - Computer Vision and Pattern Recognition

Abstract

Binary Neural Network (BNN) converts full-precision weights and activations into their extreme 1-bit counterparts, making it particularly suitable for deployment on lightweight mobile devices. While binary neural networks are typically formulated as a constrained optimization problem and optimized in the binarized space, general neural networks are formulated as an unconstrained optimization problem and optimized in the continuous space. This paper introduces the Hyperbolic Binary Neural Network (HBNN) by leveraging the framework of hyperbolic geometry to optimize the constrained problem. Specifically, we transform the constrained problem in hyperbolic space into an unconstrained one in Euclidean space using the Riemannian exponential map. On the other hand, we also propose the Exponential Parametrization Cluster (EPC) method, which, compared to the Riemannian exponential map, shrinks the segment domain based on a diffeomorphism. This approach increases the probability of weight flips, thereby maximizing the information gain in BNNs. Experimental results on CIFAR10, CIFAR100, and ImageNet classification datasets with VGGsmall, ResNet18, and ResNet34 models illustrate the superior performance of our HBNN over state-of-the-art methods.

Published

2025

38. ADePT: Adaptive Decomposed Prompt Tuning for Parameter-Efficient Fine-tuning

Author

Tang, Pengwei, Hu, Xiaolin, and Liu, Yong

Subjects

Computer Science - Computation and Language

Abstract

Prompt Tuning (PT) enables the adaptation of Pre-trained Large Language Models (PLMs) to downstream tasks by optimizing a small amount of soft virtual tokens, which are prepended to the input token embeddings. Recently, Decomposed Prompt Tuning (DePT) has demonstrated superior adaptation capabilities by decomposing the soft prompt into a shorter soft prompt and a pair of low-rank matrices. The product of the pair of low-rank matrices is added to the input token embeddings to offset them. Additionally, DePT achieves faster inference compared to PT due to the shorter soft prompt. However, in this paper, we find that the position-based token embedding offsets of DePT restricts its ability to generalize across diverse model inputs, and that the shared embedding offsets across many token embeddings result in sub-optimization. To tackle these issues, we introduce \textbf{A}daptive \textbf{De}composed \textbf{P}rompt \textbf{T}uning (ADePT), which is composed of a short soft prompt and a shallow token-shared feed-forward neural network. ADePT utilizes the token-shared feed-forward neural network to learn the embedding offsets for each token, enabling adaptive embedding offsets that vary according to the model input and better optimization of token embedding offsets. This enables ADePT to achieve superior adaptation performance without requiring more inference time or additional trainable parameters compared to vanilla PT and its variants. In comprehensive experiments across 23 natural language processing (NLP) tasks and 4 typical PLMs of different scales, we show that ADePT consistently surpasses the leading parameter-efficient fine-tuning (PEFT) methods, and even outperforms the full fine-tuning baseline in certain scenarios. Code is available at \url{https://github.com/HungerPWAY/ADePT}.

Published

2025

39. Look Back for More: Harnessing Historical Sequential Updates for Personalized Federated Adapter Tuning

Author

Peng, Danni, Wang, Yuan, Fu, Huazhu, Jiang, Jinpeng, Liu, Yong, Goh, Rick Siow Mong, and Wei, Qingsong

Subjects

Computer Science - Machine Learning, Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

Personalized federated learning (PFL) studies effective model personalization to address the data heterogeneity issue among clients in traditional federated learning (FL). Existing PFL approaches mainly generate personalized models by relying solely on the clients' latest updated models while ignoring their previous updates, which may result in suboptimal personalized model learning. To bridge this gap, we propose a novel framework termed pFedSeq, designed for personalizing adapters to fine-tune a foundation model in FL. In pFedSeq, the server maintains and trains a sequential learner, which processes a sequence of past adapter updates from clients and generates calibrations for personalized adapters. To effectively capture the cross-client and cross-step relations hidden in previous updates and generate high-performing personalized adapters, pFedSeq adopts the powerful selective state space model (SSM) as the architecture of sequential learner. Through extensive experiments on four public benchmark datasets, we demonstrate the superiority of pFedSeq over state-of-the-art PFL methods., Comment: Accepted by AAAI 2025

Published

2025

40. 3D convolutional deep learning for nonlinear estimation of body composition from whole body morphology.

Author

Tian, Isaac, Liu, Jason, Wong, Michael, Kelly, Nisa, Liu, Yong, Garber, Andrea, Heymsfield, Steven, Curless, Brian, and Shepherd, John

Abstract

Body composition prediction from 3D optical imagery has previously been studied with linear algorithms. In this study, we present a novel application of deep 3D convolutional graph networks and nonlinear Gaussian process regression for human body shape parameterization and body composition estimation. We trained and tested linear and nonlinear models with ablation studies on a novel ensemble body shape dataset containing 4286 scans. Nonlinear GPR produced up to a 20% reduction in prediction error and up to a 30% increase in precision over linear regression for both sexes in 10 tested body composition variables. Deep shape features produced 6-8% reduction in prediction error over linear PCA features for males only, and a 4-14% reduction in precision error for both sexes. All coefficients of determination (R2) for all predicted variables were above 0.86 and achieved lower estimation RMSEs than all previous work on 10 metrics of body composition.

Published

2025

41. DoTA: Weight-Decomposed Tensor Adaptation for Large Language Models

Author

Hu, Xiaolin, Cheng, Xiang, Liu, Peiyu, Liu, Wei, Luan, Jian, Wang, Bin, and Liu, Yong

Subjects

Computer Science - Computation and Language, Computer Science - Machine Learning

Abstract

Low-rank adaptation (LoRA) reduces the computational and memory demands of fine-tuning large language models (LLMs) by approximating updates with low-rank matrices. However, low-rank approximation in two-dimensional space fails to capture high-dimensional structures within the target matrix. Recently, tensor decomposition methods have been explored for fine-tuning LLMs, leveraging their ability to extract structured information. Yet, these approaches primarily rely on random initialization, and the impact of initialization on tensor adaptation remains underexplored. In this paper, we reveal that random initialization significantly diverges from the validation loss achieved by full fine-tuning. To address this, we propose Weight-Decomposed Tensor Adaptation (DoTA), which leverages the Matrix Product Operator (MPO) decomposition of pre-trained weights for effective initialization in fine-tuning LLMs. Additionally, we introduce QDoTA, a quantized version of DoTA designed for 4-bit quantization. Experiments on commonsense and arithmetic reasoning tasks show that DoTA outperforms random initialization methods with fewer parameters. QDoTA further reduces memory consumption and achieves comparable performance to DoTA on commonsense reasoning tasks. We will release our code to support future research., Comment: 12 pages, 6 figures

Published

2024

42. SoftPatch+: Fully Unsupervised Anomaly Classification and Segmentation

Author

Wang, Chengjie, Jiang, Xi, Gao, Bin-Bin, Gan, Zhenye, Liu, Yong, Zheng, Feng, and Ma, Lizhuang

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Although mainstream unsupervised anomaly detection (AD) (including image-level classification and pixel-level segmentation)algorithms perform well in academic datasets, their performance is limited in practical application due to the ideal experimental setting of clean training data. Training with noisy data is an inevitable problem in real-world anomaly detection but is seldom discussed. This paper is the first to consider fully unsupervised industrial anomaly detection (i.e., unsupervised AD with noisy data). To solve this problem, we proposed memory-based unsupervised AD methods, SoftPatch and SoftPatch+, which efficiently denoise the data at the patch level. Noise discriminators are utilized to generate outlier scores for patch-level noise elimination before coreset construction. The scores are then stored in the memory bank to soften the anomaly detection boundary. Compared with existing methods, SoftPatch maintains a strong modeling ability of normal data and alleviates the overconfidence problem in coreset, and SoftPatch+ has more robust performance which is articularly useful in real-world industrial inspection scenarios with high levels of noise (from 10% to 40%). Comprehensive experiments conducted in diverse noise scenarios demonstrate that both SoftPatch and SoftPatch+ outperform the state-of-the-art AD methods on the MVTecAD, ViSA, and BTAD benchmarks. Furthermore, the performance of SoftPatch and SoftPatch+ is comparable to that of the noise-free methods in conventional unsupervised AD setting. The code of the proposed methods can be found at https://github.com/TencentYoutuResearch/AnomalyDetection-SoftPatch., Comment: arXiv admin note: substantial text overlap with arXiv:2403.14233 paper has been accepted by Pattern Recognition

Published

2024

43. Flavor Physics at CEPC: a General Perspective

Author

Ai, Xiaocong, Altmannshofer, Wolfgang, Athron, Peter, Bai, Xiaozhi, Calibbi, Lorenzo, Cao, Lu, Che, Yuzhi, Chen, Chunhui, Chen, Ji-Yuan, Chen, Long, Chen, Mingshui, Chen, Shanzhen, Chen, Xuan, Cheng, Shan, Chiang, Cheng-Wei, Crivellin, Andreas, Cui, Hanhua, Deschamps, Olivier, Descotes-Genon, Sébastien, Du, Xiaokang, Fang, Shuangshi, Gao, Yu, Geng, Li-Sheng, Goldenzweig, Pablo, Gu, Jiayin, Guo, Feng-Kun, Guo, Yuchen, Guo, Zhi-Hui, Han, Tao, He, Hong-Jian, He, Jibo, He, Miao, Huang, Yanping, Isidori, Gino, Ji, Quan, Jiang, Jianfeng, Jiang, Xu-Hui, Kamenik, Jernej F., Kwok, Tsz Hong, Li, Gang, Li, Geng, Li, Haibo, Li, Haitao, Li, Hengne, Li, Honglei, Li, Liang, Li, Lingfeng, Li, Qiang, Li, Shu, Li, Xiaomei, Li, Xin-Qiang, Li, Yiming, Li, Yubo, Li, Yuji, Li, Zhao, Liang, Hao, Liang, Zhijun, Liao, Libo, Ligeti, Zoltan, Liu, Jia, Liu, Jianbei, Liu, Tao, Liu, Yi, Liu, Yong, Liu, Zhen, Lou, Xinchou, Lu, Peng-Cheng, Lusiani, Alberto, Ma, Hong-Hao, Ma, Kai, Mao, Yaxian, Marzocca, David, Niu, Juan-Juan, Prell, Soeren, Qi, Huirong, Qian, Sen, Qian, Wenbin, Qian, Zhuoni, Qin, Qin, Rock, Ariel, Rosner, Jonathan L., Ruan, Manqi, Shao, Dingyu, Shen, Chengping, Shen, Xiaoyan, Shi, Haoyu, Shi, Liaoshan, Si, Zong-Guo, Sierra, Cristian, Song, Huayang, Su, Shufang, Su, Wei, Tammaro, Michele, Wang, En, Wang, Fei, Wang, Hengyu, Wang, Jian, Wang, Jianchun, Wang, Kun, Wang, Lian-Tao, Wang, Wei, Wang, Xiaolong, Wang, Xiaoping, Wang, Yadi, Wang, Yifang, Wang, Yuexin, Wu, Xing-Gang, Wu, Yongcheng, Xiao, Rui-Qing, Xie, Ke-Pan, Xie, Yuehong, Xu, Zijun, Yang, Haijun, Yang, Hongtao, Yang, Lin, Yang, Shuo, Yin, Zhongbao, Yu, Fusheng, Yuan, Changzheng, Yuan, Xing-Bo, Yuan, Xuhao, Yue, Chongxing, Zhan, Xi-Jie, Zhang, Kaili, Zhang, Liming, Zhang, Xiaoming, Zhang, Yang, Zhang, Yanxi, Zhang, Yongchao, Zhang, Yu, Zhang, Zhen-Hua, Zhang, Zhong, Zhao, Mingrui, Zhao, Qiang, Zheng, Xu-Chang, Zheng, Yangheng, Zhou, Chen, Zhu, Pengxuan, Zhu, Yongfeng, Zuo, Xunwu, and Zupan, Jure

Subjects

High Energy Physics - Experiment, High Energy Physics - Phenomenology

Abstract

We discuss the landscape of flavor physics at the Circular Electron-Positron Collider (CEPC), based on the nominal luminosity outlined in its Technical Design Report. The CEPC is designed to operate in multiple modes to address a variety of tasks. At the $Z$ pole, the expected production of 4 Tera $Z$ bosons will provide unique and highly precise measurements of $Z$ boson couplings, while the substantial number of boosted heavy-flavored quarks and leptons produced in clean $Z$ decays will facilitate investigations into their flavor physics with unprecedented precision. We investigate the prospects of measuring various physics benchmarks and discuss their implications for particle theories and phenomenological models. Our studies indicate that, with its highlighted advantages and anticipated excellent detector performance, the CEPC can explore beauty and $\tau$ physics in ways that are superior to or complementary with the Belle II and Large-Hadron-Collider-beauty experiments, potentially enabling the detection of new physics at energy scales of 10 TeV and above. This potential also extends to the observation of yet-to-be-discovered rare and exotic processes, as well as testing fundamental principles such as lepton flavor universality, lepton and baryon number conservation, etc., making the CEPC a vibrant platform for flavor physics research. The $WW$ threshold scan, Higgs-factory operation and top-pair productions of the CEPC further enhance its merits in this regard, especially for measuring the Cabibbo-Kobayashi-Maskawa matrix elements, and Flavor-Changing-Neutral-Current physics of Higgs boson and top quarks. We outline the requirements for detector performance and considerations for future development to achieve the anticipated scientific goals.

Published

2024

44. Ergodicity for eventually continuous Markov--Feller semigroups on Polish spaces

Author

Gong, Fuzhou, Liu, Yong, Liu, Yuan, and Liu, Ziyu

Subjects

Mathematics - Probability

Abstract

This paper investigates the ergodicity of Markov--Feller semigroups on Polish spaces, focusing on very weak regularity conditions, particularly the Ces\`aro eventual continuity. First, it is showed that the Ces\`aro average of such semigroups weakly converges to an ergodic measure when starting from its support. This leads to a characterization of the relationship between Ces\`aro eventual continuity, Ces\`aro e-property, and weak-* mean ergodicity. Next, serval criteria are provided for the existence and uniqueness of invariant measures via Ces\`aro eventual continuity and lower bound conditions, establishing an equivalence relation between weak-* mean ergodicity and a lower bound condition. Additionally, some refined properties of ergodic decomposition are derived. Finally, the results are applied to several non-trivial examples, including iterated function systems, Hopf's turbulence model with random forces, and Lorenz system with noisy perturbations, either with or without Ces\`aro eventual continuity.

Published

2024

45. InstructSeg: Unifying Instructed Visual Segmentation with Multi-modal Large Language Models

Author

Wei, Cong, Zhong, Yujie, Tan, Haoxian, Zeng, Yingsen, Liu, Yong, Zhao, Zheng, and Yang, Yujiu

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Boosted by Multi-modal Large Language Models (MLLMs), text-guided universal segmentation models for the image and video domains have made rapid progress recently. However, these methods are often developed separately for specific domains, overlooking the similarities in task settings and solutions across these two areas. In this paper, we define the union of referring segmentation and reasoning segmentation at both the image and video levels as Instructed Visual Segmentation (IVS). Correspondingly, we propose InstructSeg, an end-to-end segmentation pipeline equipped with MLLMs for IVS. Specifically, we employ an object-aware video perceiver to extract temporal and object information from reference frames, facilitating comprehensive video understanding. Additionally, we introduce vision-guided multi-granularity text fusion to better integrate global and detailed text information with fine-grained visual guidance. By leveraging multi-task and end-to-end training, InstructSeg demonstrates superior performance across diverse image and video segmentation tasks, surpassing both segmentation specialists and MLLM-based methods with a single model. Our code is available at https://github.com/congvvc/InstructSeg.

Published

2024

46. Communication-Efficient Personalized Federal Graph Learning via Low-Rank Decomposition

Author

Liu, Ruyue, Yin, Rong, Bo, Xiangzhen, Hao, Xiaoshuai, Zhou, Xingrui, Liu, Yong, Ma, Can, and Wang, Weiping

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

Federated graph learning (FGL) has gained significant attention for enabling heterogeneous clients to process their private graph data locally while interacting with a centralized server, thus maintaining privacy. However, graph data on clients are typically non-IID, posing a challenge for a single model to perform well across all clients. Another major bottleneck of FGL is the high cost of communication. To address these challenges, we propose a communication-efficient personalized federated graph learning algorithm, CEFGL. Our method decomposes the model parameters into low-rank generic and sparse private models. We employ a dual-channel encoder to learn sparse local knowledge in a personalized manner and low-rank global knowledge in a shared manner. Additionally, we perform multiple local stochastic gradient descent iterations between communication phases and integrate efficient compression techniques into the algorithm. The advantage of CEFGL lies in its ability to capture common and individual knowledge more precisely. By utilizing low-rank and sparse parameters along with compression techniques, CEFGL significantly reduces communication complexity. Extensive experiments demonstrate that our method achieves optimal classification accuracy in a variety of heterogeneous environments across sixteen datasets. Specifically, compared to the state-of-the-art method FedStar, the proposed method (with GIN as the base model) improves accuracy by 5.64\% on cross-datasets setting CHEM, reduces communication bits by a factor of 18.58, and reduces the communication time by a factor of 1.65.

Published

2024

47. ColorFlow: Retrieval-Augmented Image Sequence Colorization

Author

Zhuang, Junhao, Ju, Xuan, Zhang, Zhaoyang, Liu, Yong, Zhang, Shiyi, Yuan, Chun, and Shan, Ying

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Automatic black-and-white image sequence colorization while preserving character and object identity (ID) is a complex task with significant market demand, such as in cartoon or comic series colorization. Despite advancements in visual colorization using large-scale generative models like diffusion models, challenges with controllability and identity consistency persist, making current solutions unsuitable for industrial application.To address this, we propose ColorFlow, a three-stage diffusion-based framework tailored for image sequence colorization in industrial applications. Unlike existing methods that require per-ID finetuning or explicit ID embedding extraction, we propose a novel robust and generalizable Retrieval Augmented Colorization pipeline for colorizing images with relevant color references. Our pipeline also features a dual-branch design: one branch for color identity extraction and the other for colorization, leveraging the strengths of diffusion models. We utilize the self-attention mechanism in diffusion models for strong in-context learning and color identity matching. To evaluate our model, we introduce ColorFlow-Bench, a comprehensive benchmark for reference-based colorization. Results show that ColorFlow outperforms existing models across multiple metrics, setting a new standard in sequential image colorization and potentially benefiting the art industry. We release our codes and models on our project page: https://zhuang2002.github.io/ColorFlow/., Comment: Project Page: https://zhuang2002.github.io/ColorFlow/

Published

2024

48. Visual Object Tracking across Diverse Data Modalities: A Review

Author

Wang, Mengmeng, Ma, Teli, Xin, Shuo, Hou, Xiaojun, Xing, Jiazheng, Dai, Guang, Wang, Jingdong, and Liu, Yong

Subjects

Computer Science - Computer Vision and Pattern Recognition, Computer Science - Artificial Intelligence

Abstract

Visual Object Tracking (VOT) is an attractive and significant research area in computer vision, which aims to recognize and track specific targets in video sequences where the target objects are arbitrary and class-agnostic. The VOT technology could be applied in various scenarios, processing data of diverse modalities such as RGB, thermal infrared and point cloud. Besides, since no one sensor could handle all the dynamic and varying environments, multi-modal VOT is also investigated. This paper presents a comprehensive survey of the recent progress of both single-modal and multi-modal VOT, especially the deep learning methods. Specifically, we first review three types of mainstream single-modal VOT, including RGB, thermal infrared and point cloud tracking. In particular, we conclude four widely-used single-modal frameworks, abstracting their schemas and categorizing the existing inheritors. Then we summarize four kinds of multi-modal VOT, including RGB-Depth, RGB-Thermal, RGB-LiDAR and RGB-Language. Moreover, the comparison results in plenty of VOT benchmarks of the discussed modalities are presented. Finally, we provide recommendations and insightful observations, inspiring the future development of this fast-growing literature.

Published

2024

49. Ultrastrong photon superbunching from electron shelving and time integral

Author

Zhang, He-bin, Tang, Yuanjiang, and Liu, Yong-Chun

Subjects

Quantum Physics

Abstract

Photon correlation is at the heart of quantum optics and has important applications in quantum technologies. Here we propose a universally applicable mechanism that can generate the superbunching light with ultrastrong second-order and higher-order correlations hitherto unreachable. This mechanism arises from the combined effect of electron shelving and time integral of fluorescence based on a cascaded quantum system comprising an emitter and a filter or a cavity QED system, and has high experimental feasibility according to current experimental techniques. Besides, both the correlation degrees and the frequency of the light can be flexibly varied over broad ranges. Both the research and technological applications on strong correlations can be extensively facilitated due to this readily accessible and manipulated mechanism for generating photon correlation.

Published

2024

50. Diffusion-Enhanced Test-time Adaptation with Text and Image Augmentation

Author

Feng, Chun-Mei, He, Yuanyang, Zou, Jian, Khan, Salman, Xiong, Huan, Li, Zhen, Zuo, Wangmeng, Goh, Rick Siow Mong, and Liu, Yong

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Existing test-time prompt tuning (TPT) methods focus on single-modality data, primarily enhancing images and using confidence ratings to filter out inaccurate images. However, while image generation models can produce visually diverse images, single-modality data enhancement techniques still fail to capture the comprehensive knowledge provided by different modalities. Additionally, we note that the performance of TPT-based methods drops significantly when the number of augmented images is limited, which is not unusual given the computational expense of generative augmentation. To address these issues, we introduce IT3A, a novel test-time adaptation method that utilizes a pre-trained generative model for multi-modal augmentation of each test sample from unknown new domains. By combining augmented data from pre-trained vision and language models, we enhance the ability of the model to adapt to unknown new test data. Additionally, to ensure that key semantics are accurately retained when generating various visual and text enhancements, we employ cosine similarity filtering between the logits of the enhanced images and text with the original test data. This process allows us to filter out some spurious augmentation and inadequate combinations. To leverage the diverse enhancements provided by the generation model across different modals, we have replaced prompt tuning with an adapter for greater flexibility in utilizing text templates. Our experiments on the test datasets with distribution shifts and domain gaps show that in a zero-shot setting, IT3A outperforms state-of-the-art test-time prompt tuning methods with a 5.50% increase in accuracy., Comment: Accepted by International Journal of Computer Vision

Published

2024