Search

Your search keyword '"Sun, Shuzhou"' showing total 24 results
Start Over Author "Sun, Shuzhou"
24 results on '"Sun, Shuzhou"'

1. Step-wise Distribution Alignment Guided Style Prompt Tuning for Source-free Cross-domain Few-shot Learning

Author

Xu, Huali, Liu, Yongxiang, Liu, Li, Zhi, Shuaifeng, Sun, Shuzhou, Liu, Tianpeng, and Cheng, MingMing

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Existing cross-domain few-shot learning (CDFSL) methods, which develop source-domain training strategies to enhance model transferability, face challenges with large-scale pre-trained models (LMs) due to inaccessible source data and training strategies. Moreover, fine-tuning LMs for CDFSL demands substantial computational resources, limiting practicality. This paper addresses the source-free CDFSL (SF-CDFSL) problem, tackling few-shot learning (FSL) in the target domain using only pre-trained models and a few target samples without source data or strategies. To overcome the challenge of inaccessible source data, this paper introduces Step-wise Distribution Alignment Guided Style Prompt Tuning (StepSPT), which implicitly narrows domain gaps through prediction distribution optimization. StepSPT proposes a style prompt to align target samples with the desired distribution and adopts a dual-phase optimization process. In the external process, a step-wise distribution alignment strategy factorizes prediction distribution optimization into a multi-step alignment problem to tune the style prompt. In the internal process, the classifier is updated using standard cross-entropy loss. Evaluations on five datasets demonstrate that StepSPT outperforms existing prompt tuning-based methods and SOTAs. Ablation studies further verify its effectiveness. Code will be made publicly available at \url{https://github.com/xuhuali-mxj/StepSPT}., Comment: 15 pages, 12 figures, 7 tables

Published
2024

2. Unbiased Scene Graph Generation via Two-stage Causal Modeling

Author

Sun, Shuzhou, Zhi, Shuaifeng, Liao, Qing, Heikkilä, Janne, and Liu, Li

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Despite the impressive performance of recent unbiased Scene Graph Generation (SGG) methods, the current debiasing literature mainly focuses on the long-tailed distribution problem, whereas it overlooks another source of bias, i.e., semantic confusion, which makes the SGG model prone to yield false predictions for similar relationships. In this paper, we explore a debiasing procedure for the SGG task leveraging causal inference. Our central insight is that the Sparse Mechanism Shift (SMS) in causality allows independent intervention on multiple biases, thereby potentially preserving head category performance while pursuing the prediction of high-informative tail relationships. However, the noisy datasets lead to unobserved confounders for the SGG task, and thus the constructed causal models are always causal-insufficient to benefit from SMS. To remedy this, we propose Two-stage Causal Modeling (TsCM) for the SGG task, which takes the long-tailed distribution and semantic confusion as confounders to the Structural Causal Model (SCM) and then decouples the causal intervention into two stages. The first stage is causal representation learning, where we use a novel Population Loss (P-Loss) to intervene in the semantic confusion confounder. The second stage introduces the Adaptive Logit Adjustment (AL-Adjustment) to eliminate the long-tailed distribution confounder to complete causal calibration learning. These two stages are model agnostic and thus can be used in any SGG model that seeks unbiased predictions. Comprehensive experiments conducted on the popular SGG backbones and benchmarks show that our TsCM can achieve state-of-the-art performance in terms of mean recall rate. Furthermore, TsCM can maintain a higher recall rate than other debiasing methods, which indicates that our method can achieve a better tradeoff between head and tail relationships., Comment: 17 pages, 9 figures. Accepted by IEEE Transactions on Pattern Analysis and Machine Intelligence

Published
2023

3. Deep Learning for Cross-Domain Few-Shot Visual Recognition: A Survey

Author

Xu, Huali, Zhi, Shuaifeng, Sun, Shuzhou, Patel, Vishal M., and Liu, Li

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

While deep learning excels in computer vision tasks with abundant labeled data, its performance diminishes significantly in scenarios with limited labeled samples. To address this, Few-shot learning (FSL) enables models to perform the target tasks with very few labeled examples by leveraging prior knowledge from related tasks. However, traditional FSL assumes that both the related and target tasks come from the same domain, which is a restrictive assumption in many real-world scenarios where domain differences are common. To overcome this limitation, Cross-domain few-shot learning (CDFSL) has gained attention, as it allows source and target data to come from different domains and label spaces. This paper presents the first comprehensive review of Cross-domain Few-shot Learning (CDFSL), a field that has received less attention compared to traditional FSL due to its unique challenges. We aim to provide both a position paper and a tutorial for researchers, covering key problems, existing methods, and future research directions. The review begins with a formal definition of CDFSL, outlining its core challenges, followed by a systematic analysis of current approaches, organized under a clear taxonomy. Finally, we discuss promising future directions in terms of problem setups, applications, and theoretical advancements., Comment: 37 pages, 12 figures, 6 tables

Published
2023

7. Concessive Online/Offline Attribute Based Encryption with Cryptographic Reverse Firewalls—Secure and Efficient Fine-Grained Access Control on Corrupted Machines

Author

Ma, Hui, Zhang, Rui, Yang, Guomin, Song, Zishuai, Sun, Shuzhou, Xiao, Yuting, Hutchison, David, Series Editor, Kanade, Takeo, Series Editor, Kittler, Josef, Series Editor, Kleinberg, Jon M., Series Editor, Mattern, Friedemann, Series Editor, Mitchell, John C., Series Editor, Naor, Moni, Series Editor, Pandu Rangan, C., Series Editor, Steffen, Bernhard, Series Editor, Terzopoulos, Demetri, Series Editor, Tygar, Doug, Series Editor, Weikum, Gerhard, Series Editor, Lopez, Javier, editor, Zhou, Jianying, editor, and Soriano, Miguel, editor

Published
2018
Full Text
View/download PDF

15. Rainbow: reliable personally identifiable information retrieval across multi-cloud.

Author

Song, Zishuai, Ma, Hui, Sun, Shuzhou, Xin, Yansen, and Zhang, Rui

Subjects
DATA privacy, PERSONALLY identifiable information, INFORMATION retrieval, RAINBOWS, CLOUD storage, ACCESS control, MICROSOFT Azure (Computing platform)
Abstract

Personally identifiable information (PII) refers to any information that links to an individual. Sharing PII is extremely useful in public affairs yet hard to implement due to the worries about privacy violations. Building a PII retrieval service over multi-cloud, which is a modern strategy to make services stable where multiple servers are deployed, seems to be a promising solution. However, three major technical challenges remain to be solved. The first is the privacy and access control of PII. In fact, each entry in PII can be shared to different users with different access rights. Hence, flexible and fine-grained access control is needed. Second, a reliable user revocation mechanism is required to ensure that users can be revoked efficiently, even if few cloud servers are compromised or collapse, to avoid data leakage. Third, verifying the correctness of received PII and locating a misbehaved server when wrong data are returned is crucial to guarantee user's privacy, but challenging to realize. In this paper, we propose Rainbow, a secure and practical PII retrieval scheme to solve the above issues. In particular, we design an important cryptographic tool, called Reliable Outsourced Attribute Based Encryption (ROABE) which provides data privacy, flexible and fine-grained access control, reliable immediate user revocation and verification for multiple servers simultaneously, to support Rainbow. Moreover, we present how to build Rainbow with ROABE and several necessary cloud techniques in real world. To evaluate the performance, we deploy Rainbow on multiple mainstream clouds, namely, AWS, GCP and Microsoft Azure, and experiment in browsers on mobile phones and computers. Both theoretical analysis and experimental results indicate that Rainbow is secure and practical. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

16. Unsupervised Fusion Feature Matching for Data Bias in Uncertainty Active Learning

Author

Huang, Wei, Sun, Shuzhou, Lin, Xiao, Li, Ping, Zhu, Lei, Wang, Jihong, Chen, C. L. Philip, Sheng, Bin, Huang, Wei, Sun, Shuzhou, Lin, Xiao, Li, Ping, Zhu, Lei, Wang, Jihong, Chen, C. L. Philip, and Sheng, Bin

Abstract

Active learning (AL) aims to sample the most valuable data for model improvement from the unlabeled pool. Traditional works, especially uncertainty-based methods, are prone to suffer from a data bias issue, which means that selected data cannot cover the entire unlabeled pool well. Although there have been lots of literature works focusing on this issue recently, they mainly benefit from the huge additional training costs and the artificially designed complex loss. The latter causes these methods to be redesigned when facing new models or tasks, which is very time-consuming and laborious. This article proposes a feature-matching-based uncertainty that resamples selected uncertainty data by feature matching, thus removing similar data to alleviate the data bias issue. To ensure that our proposed method does not introduce a lot of additional costs, we specially design a unsupervised fusion feature matching (UFFM), which does not require any training in our novel AL framework. Besides, we also redesign several classic uncertainty methods to be applied to more complex visual tasks. We conduct rigorous experiments on lots of standard benchmark datasets to validate our work. The experimental results show that our UFFM is better than the similar unsupervised feature matching technologies, and our proposed uncertainty calculation method outperforms random sampling, classic uncertainty approaches, and recent state-of-the-art (SOTA) uncertainty approaches. IEEE

Published
2022

23. Experimental and Kinetic Modeling Study on Self-Ignition of α-Methylnaphthalene in a Heated Rapid Compression Machine

Author

Sun, Shuzhou, Yu, Liang, Wang, Sixu, Mao, Yebing, and Lu, Xingcai

Abstract

As an important component of diesel and kerosene surrogates, the experimental study and chemical kinetic modeling of α-methylnaphthalene (AMN) are still very insufficient. The ignition delay of an AMN/O2/Ar mixture in a heated rapid compression machine (RCM) was measured in this study. The data were obtained for equivalence ratios of 0.7, 1, and 1.2, at pressures of 12, 15, and 20 bar, over the temperature range of 860–1040 K. A semi-detailed kinetic mechanism for the oxidation of AMN was established, which consists of 196 species and 1330 reactions. In comparison to the different previous mechanism, the new mechanism can more accurately predict the ignition delay of AMN in RCM and shock tube experiments. It can also accurately predict the experimental data obtained in a jet-stirred reactor from the literature. The ignition delays using adiabatic constant-volume simulation and RCM simulation were compared, which indicated that RCM simulation could better predict the experimental data. Sensitivity and reaction path analysis were also carried out to explore the effect of key reactions and paths on AMN ignition.

Published
2017
Full Text
View/download PDF

24. Unbiased Scene Graph Generation via Two-Stage Causal Modeling.

Author

Sun S, Zhi S, Liao Q, Heikkila J, and Liu L

Abstract

Despite the impressive performance of recent unbiased Scene Graph Generation (SGG) methods, the current debiasing literature mainly focuses on the long-tailed distribution problem, whereas it overlooks another source of bias, i.e., semantic confusion, which makes the SGG model prone to yield false predictions for similar relationships. In this paper, we explore a debiasing procedure for the SGG task leveraging causal inference. Our central insight is that the Sparse Mechanism Shift (SMS) in causality allows independent intervention on multiple biases, thereby potentially preserving head category performance while pursuing the prediction of high-informative tail relationships. However, the noisy datasets lead to unobserved confounders for the SGG task, and thus the constructed causal models are always causal-insufficient to benefit from SMS. To remedy this, we propose Two-stage Causal Modeling (TsCM) for the SGG task, which takes the long-tailed distribution and semantic confusion as confounders to the Structural Causal Model (SCM) and then decouples the causal intervention into two stages. The first stage is causal representation learning, where we use a novel Population Loss (P-Loss) to intervene in the semantic confusion confounder. The second stage introduces the Adaptive Logit Adjustment (AL-Adjustment) to eliminate the long-tailed distribution confounder to complete causal calibration learning. These two stages are model agnostic and thus can be used in any SGG model that seeks unbiased predictions. Comprehensive experiments conducted on the popular SGG backbones and benchmarks show that our TsCM can achieve state-of-the-art performance in terms of mean recall rate. Furthermore, TsCM can maintain a higher recall rate than other debiasing methods, which indicates that our method can achieve a better tradeoff between head and tail relationships.

Published
2023
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results