A Blockchain-Enabled Group Covert Channel against Transaction Forgery

Shen, Tongzhou; Zhu, Liehuang; Gao, Feng; Chen, Zhuo; Zhang, Zijian; Li, Meng

doi:10.3390/math12020251

Mathematics

2024

DOI: 10.3390/math12020251

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A Blockchain-Enabled Group Covert Channel against Transaction Forgery

Tongzhou Shen,

Liehuang Zhu,

Feng Gao

et al.

Abstract: As a decentralized network infrastructure, the data sent to the blockchain are public and temper-evident. The cover of massive normal transactions in a blockchain network is ideal for constructing a stable and reliable covert channel to achieve one-to-many group covert communication. Existing blockchain-based covert communication schemes face challenges in balancing concealment, embedding rate and filtering efficiency, making them unsuitable for direct extension to group scenarios. Adopting a key-leakage schem… Show more

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2024

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Cited by 3 publications

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A Blockchain Network Admission Control Mechanism Using Anonymous Identity-Based Cryptography

Zhang,

Jiang,

Ding

2024

Applied Sciences

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Permissioned blockchains are increasingly used in areas like supply chain management, financial transactions, and medical data sharing, where ensuring data consistency and security is critical. However, these systems are vulnerable to threats such as DDoS attacks, forged transactions, and certificate authority compromises, primarily due to inadequate network layer admission control. Existing solutions, like static whitelisting, struggle with scalability and adaptability in dynamic environments. This paper proposes a novel admission control mechanism based on identity-based cryptography, utilizing multi-level anonymous identifiers and decentralized private key generation to enhance user authentication and privacy. The mechanism dynamically updates whitelists and selectively filters network traffic, ensuring a balance between security and performance. Experimental results validate its effectiveness in mitigating key threats while maintaining operational efficiency.

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A Blockchain Network Admission Control Mechanism Using Anonymous Identity-Based Cryptography

Zhang,

Jiang,

Ding

2024

Applied Sciences

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A Stealthy Communication Model with Blockchain Smart Contract for Bidding Systems

Liang,

Shi,

Tan

et al. 2024

Electronics

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With the widespread adoption of blockchain technology, its public ledger characteristic enhances transaction transparency but also amplifies the risk of privacy breaches. Attackers can infer users’ real identities and behaviors by analyzing public transaction patterns and address relationships, posing a severe threat to users’ privacy and security, and thus hindering further advancements in blockchain applications. To address this challenge, covert communication has emerged as an effective strategy for safeguarding the privacy of blockchain users and preventing information leakage. But existing blockchain-based covert communication schemes rely solely on the immutability of blockchain itself for robustness and suffer from low transmission efficiency. To tackle these issues, this paper proposes a stealthy communication model with blockchain smart contract for bidding systems. The model initiates by preprocessing sensitive information using a secret-sharing algorithm-the Shamir (t, n) threshold scheme-and subsequently embeds this information into bidding amounts, facilitating the covert transfer of sensitive data. We implemented and deployed this model on the Ethereum platform and conducted comprehensive performance evaluations. To assess the stealthiness of our approach, we employed a suite of statistical tests including the CDF, the Kolmogorov–Smirnov test, Welch’s t-test and K–L divergence. These analyses confirmed that amounts carrying concealed information were statistically indistinguishable from regular transactions, thus validating the effectiveness of our solution in maintaining the anonymity and confidentiality of information transmission within the blockchain ecosystem.

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A Stealthy Communication Model for Protecting Aggregated Results Integrity in Federated Learning

Li,

Sun,

Shi

et al. 2024

Electronics

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Given how quickly artificial intelligence technology is developing, federated learning (FL) has emerged to enable effective model training while protecting data privacy. However, when using homomorphic encryption (HE) techniques for privacy protection, FL faces challenges related to the integrity of HE ciphertexts. In the HE-based privacy-preserving FL framework, the public disclosure of the public key and the homomorphic additive property of the HE algorithm pose serious threats to the integrity of the ciphertext of FL’s aggregated results. For the first time, this paper employs covert communication by embedding the hash value of the aggregated result ciphertext received by the client into the ciphertext of local model parameters using the lossless homomorphic additive property of the Paillier algorithm. When the server receives the ciphertext of the local model parameters, it can extract and verify the hash value to determine whether the ciphertext of the FL’s aggregated results has been tampered with. We also used chaotic sequences to select the embedding positions, further enhancing the concealment of the scheme. The experimental findings demonstrate that the suggested plan passed the Welch’s t-test, the K–L divergence test, and the K–S test. These findings confirm that ciphertexts containing covert information are statistically indistinguishable from normal ciphertexts, thereby affirming the proposed scheme’s effectiveness in safeguarding the integrity of the FL’s aggregated ciphertext results. The channel capacity of this scheme can reach up to 512 bits per round, which is higher compared to other FL-based covert channels.

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A Blockchain-Enabled Group Covert Channel against Transaction Forgery

Cited by 3 publications

References 25 publications

A Blockchain Network Admission Control Mechanism Using Anonymous Identity-Based Cryptography

A Blockchain Network Admission Control Mechanism Using Anonymous Identity-Based Cryptography

A Stealthy Communication Model with Blockchain Smart Contract for Bidding Systems

A Stealthy Communication Model for Protecting Aggregated Results Integrity in Federated Learning

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