Visible to the public Biblio

Filters: Author is Zhao, Liang  [Clear All Filters]
2021-08-18
Zhao, Huifang, Yang, Fang, Cui, Yuxiang, Yang, Rui, Pan, Dafeng, Zhao, Liang.  2020.  Design of a New Lightweight Stream Cipher VHFO Algorithm. 2020 3rd International Conference on Advanced Electronic Materials, Computers and Software Engineering (AEMCSE). :379—382.
This paper designed the lightweight stream ciphers named VHFO. It used OFB. The key-stream size is 128-bit while the IV is specified to be 128 bits. Our security evaluation shows that VHFO can achieve enough security margin against known attacks. The implementation efficiency of both software and hardware based on VHFO is higher than others in RFID environment.
2020-01-27
Zhang, Yiming, Fan, Yujie, Song, Wei, Hou, Shifu, Ye, Yanfang, Li, Xin, Zhao, Liang, Shi, Chuan, Wang, Jiabin, Xiong, Qi.  2019.  Your Style Your Identity: Leveraging Writing and Photography Styles for Drug Trafficker Identification in Darknet Markets over Attributed Heterogeneous Information Network. The World Wide Web Conference. :3448–3454.
Due to its anonymity, there has been a dramatic growth of underground drug markets hosted in the darknet (e.g., Dream Market and Valhalla). To combat drug trafficking (a.k.a. illicit drug trading) in the cyberspace, there is an urgent need for automatic analysis of participants in darknet markets. However, one of the key challenges is that drug traffickers (i.e., vendors) may maintain multiple accounts across different markets or within the same market. To address this issue, in this paper, we propose and develop an intelligent system named uStyle-uID leveraging both writing and photography styles for drug trafficker identification at the first attempt. At the core of uStyle-uID is an attributed heterogeneous information network (AHIN) which elegantly integrates both writing and photography styles along with the text and photo contents, as well as other supporting attributes (i.e., trafficker and drug information) and various kinds of relations. Built on the constructed AHIN, to efficiently measure the relatedness over nodes (i.e., traffickers) in the constructed AHIN, we propose a new network embedding model Vendor2Vec to learn the low-dimensional representations for the nodes in AHIN, which leverages complementary attribute information attached in the nodes to guide the meta-path based random walk for path instances sampling. After that, we devise a learning model named vIdentifier to classify if a given pair of traffickers are the same individual. Comprehensive experiments on the data collections from four different darknet markets are conducted to validate the effectiveness of uStyle-uID which integrates our proposed method in drug trafficker identification by comparisons with alternative approaches.
2019-12-16
Zhao, Liang, Chen, Liqun.  2018.  A Linear Distinguisher and Its Application for Analyzing Privacy-Preserving Transformation Used in Verifiable (Outsourced) Computation. Proceedings of the 2018 on Asia Conference on Computer and Communications Security. :253-260.

A distinguisher is employed by an adversary to explore the privacy property of a cryptographic primitive. If a cryptographic primitive is said to be private, there is no distinguisher algorithm that can be used by an adversary to distinguish the encodings generated by this primitive with non-negligible advantage. Recently, two privacy-preserving matrix transformations first proposed by Salinas et al. have been widely used to achieve the matrix-related verifiable (outsourced) computation in data protection. Salinas et al. proved that these transformations are private (in terms of indistinguishability). In this paper, we first propose the concept of a linear distinguisher and two constructions of the linear distinguisher algorithms. Then, we take those two matrix transformations (including Salinas et al.\$'\$s original work and Yu et al.\$'\$s modification) as example targets and analyze their privacy property when our linear distinguisher algorithms are employed by the adversaries. The results show that those transformations are not private even against passive eavesdropping.