Your search keyword '"Rusnak, Alex"' showing total 14 results

1. Efficient and Universal Merkle Tree Inclusion Proofs via OR Aggregation

Author

Kuznetsov, Oleksandr, Rusnak, Alex, Yezhov, Anton, Kanonik, Dzianis, Kuznetsova, Kateryna, and Domin, Oleksandr

Subjects

Computer Science - Cryptography and Security

Abstract

Zero-knowledge proofs have emerged as a powerful tool for enhancing privacy and security in blockchain applications. However, the efficiency and scalability of proof systems remain a significant challenge, particularly in the context of Merkle tree inclusion proofs. Traditional proof aggregation techniques based on AND logic suffer from high verification complexity and data communication overhead, limiting their practicality for large-scale applications. In this paper, we propose a novel proof aggregation approach based on OR logic, which enables the generation of compact and universally verifiable proofs for Merkle tree inclusion. By aggregating proofs using OR logic, we achieve a proof size that is independent of the number of leaves in the tree, and verification can be performed using any single valid leaf hash. This represents a significant improvement over AND aggregation, which requires the verifier to process all leaf hashes. We formally define the OR aggregation logic, describe the process of generating universal proofs, and provide a comparative analysis demonstrating the advantages of our approach in terms of proof size, verification data, and universality. Furthermore, we discuss the potential of combining OR and AND aggregation logics to create complex acceptance functions, enabling the development of expressive and efficient proof systems for various blockchain applications. The proposed techniques have the potential to significantly enhance the scalability, efficiency, and flexibility of zero-knowledge proof systems, paving the way for more practical and adaptive solutions in the blockchain ecosystem.

Published

2024

2. Evaluating the Security of Merkle Trees in the Internet of Things: An Analysis of Data Falsification Probabilities

Author

Kuznetsov, Oleksandr, Rusnak, Alex, Yezhov, Anton, Kuznetsova, Kateryna, Kanonik, Dzianis, and Domin, Oleksandr

Subjects

Computer Science - Cryptography and Security

Abstract

Addressing the critical challenge of ensuring data integrity in decentralized systems, this paper delves into the underexplored area of data falsification probabilities within Merkle Trees, which are pivotal in blockchain and Internet of Things (IoT) technologies. Despite their widespread use, a comprehensive understanding of the probabilistic aspects of data security in these structures remains a gap in current research. Our study aims to bridge this gap by developing a theoretical framework to calculate the probability of data falsification, taking into account various scenarios based on the length of the Merkle path and hash length. The research progresses from the derivation of an exact formula for falsification probability to an approximation suitable for cases with significantly large hash lengths. Empirical experiments validate the theoretical models, exploring simulations with diverse hash lengths and Merkle path lengths. The findings reveal a decrease in falsification probability with increasing hash length and an inverse relationship with longer Merkle paths. A numerical analysis quantifies the discrepancy between exact and approximate probabilities, underscoring the conditions for the effective application of the approximation. This work offers crucial insights into optimizing Merkle Tree structures for bolstering security in blockchain and IoT systems, achieving a balance between computational efficiency and data integrity., Comment: 7 pages

Published

2024

3. Adaptive Restructuring of Merkle and Verkle Trees for Enhanced Blockchain Scalability

Author

Kuznetsov, Oleksandr, Kanonik, Dzianis, Rusnak, Alex, Yezhov, Anton, and Domin, Oleksandr

Subjects

Computer Science - Cryptography and Security

Abstract

The scalability of blockchain technology remains a pivotal challenge, impeding its widespread adoption across various sectors. This study introduces an innovative approach to address this challenge by proposing the adaptive restructuring of Merkle and Verkle trees, fundamental components of blockchain architecture responsible for ensuring data integrity and facilitating efficient verification processes. Unlike traditional static tree structures, our adaptive model dynamically adjusts the configuration of these trees based on usage patterns, significantly reducing the average path length required for verification and, consequently, the computational overhead associated with these processes. Through a comprehensive conceptual framework, we delineate the methodology for adaptive restructuring, encompassing both binary and non-binary tree configurations. This framework is validated through a series of detailed examples, demonstrating the practical feasibility and the efficiency gains achievable with our approach. Moreover, we present a comparative analysis with existing scalability solutions, highlighting the unique advantages of adaptive restructuring in terms of simplicity, security, and efficiency enhancement without introducing additional complexities or dependencies. This study's implications extend beyond theoretical advancements, offering a scalable, secure, and efficient method for blockchain data verification that could facilitate broader adoption of blockchain technology in finance, supply chain management, and beyond. As the blockchain ecosystem continues to evolve, the principles and methodologies outlined herein are poised to contribute significantly to its growth and maturity.

Published

2024

4. Merkle Trees in Blockchain: A Study of Collision Probability and Security Implications

Author

Kuznetsov, Oleksandr, Rusnak, Alex, Yezhov, Anton, Kuznetsova, Kateryna, Kanonik, Dzianis, and Domin, Oleksandr

Subjects

Computer Science - Cryptography and Security

Abstract

In the rapidly evolving landscape of blockchain technology, ensuring the integrity and security of data is paramount. This study delves into the security aspects of Merkle Trees, a fundamental component in blockchain architectures, such as Ethereum. We critically examine the susceptibility of Merkle Trees to hash collisions, a potential vulnerability that poses significant risks to data security within blockchain systems. Despite their widespread application, the collision resistance of Merkle Trees and their robustness against preimage attacks have not been thoroughly investigated, leading to a notable gap in the comprehensive understanding of blockchain security mechanisms. Our research endeavors to bridge this gap through a meticulous blend of theoretical analysis and empirical validation. We scrutinize the probability of root collisions in Merkle Trees, considering various factors such as hash length and path length within the tree. Our findings reveal a direct correlation between the increase in path length and the heightened probability of root collisions, thereby underscoring potential security vulnerabilities. Conversely, we observe that an increase in hash length significantly reduces the likelihood of collisions, highlighting its critical role in fortifying security. The insights garnered from our research offer valuable guidance for blockchain developers and researchers, aiming to bolster the security and operational efficacy of blockchain-based systems., Comment: 4 figures

Published

2024

5. Enhanced Security and Efficiency in Blockchain with Aggregated Zero-Knowledge Proof Mechanisms

Author

Kuznetsov, Oleksandr, Rusnak, Alex, Yezhov, Anton, Kanonik, Dzianis, Kuznetsova, Kateryna, and Karashchuk, Stanislav

Subjects

Computer Science - Cryptography and Security

Abstract

Blockchain technology has emerged as a revolutionary tool in ensuring data integrity and security in digital transactions. However, the current approaches to data verification in blockchain systems, particularly in Ethereum, face challenges in terms of efficiency and computational overhead. The traditional use of Merkle Trees and cryptographic hash functions, while effective, leads to significant resource consumption, especially for large datasets. This highlights a gap in existing research: the need for more efficient methods of data verification in blockchain networks. Our study addresses this gap by proposing an innovative aggregation scheme for Zero-Knowledge Proofs within the structure of Merkle Trees. We develop a system that significantly reduces the size of the proof and the computational resources needed for its generation and verification. Our approach represents a paradigm shift in blockchain data verification, balancing security with efficiency. We conducted extensive experimental evaluations using real Ethereum block data to validate the effectiveness of our proposed scheme. The results demonstrate a drastic reduction in proof size and computational requirements compared to traditional methods, making the verification process more efficient and economically viable. Our contribution fills a critical research void, offering a scalable and secure solution for blockchain data verification. The implications of our work are far-reaching, enhancing the overall performance and adaptability of blockchain technology in various applications, from financial transactions to supply chain management., Comment: 18 pages, 7 figures

Published

2024

6. Proximity-based Networking: Small world overlays optimized with particle swarm optimization

Author

Smith, Chase and Rusnak, Alex

Subjects

Computer Science - Networking and Internet Architecture, Computer Science - Neural and Evolutionary Computing, I.2.11

Abstract

Information dissemination is a fundamental and frequently occurring problem in large, dynamic, distributed systems. In order to solve this, there has been an increased interest in creating efficient overlay networks that can maintain decentralized peer-to-peer networks. Within these overlay networks nodes take the patterns of small world networks, whose connections are based on proximity. These small-world systems can be incredibly useful in the dissemination and lookup of information within an internet network. The data can be efficiently transferred and routing with minimal information loss through forward error correct (FEC) and the User Datagram Protocol (UDP). We propose a networking scheme that incorporates geographic location in chord for the organization of peers within each node's partitioned key space. When we combine this with a proximity-based neighborhood set {based on the small world structure} we can mimic the efficient of solutions designed to solve traditional small-world problems, with the additional benefit of resilience and fault-tolerance. Furthermore, the routing and address book can be updated based on the neighborhood requirements. The flexibility of our proposed schemes enables a variety of swarm models, and agents. This enables our network to as an underlying networking model that can be applied to file-sharing, streaming, and synchronization of networks.

Published

2020

7. Dynamic Merkle B-tree with Efficient Proofs

Author

Smith, Chase and Rusnak, Alex

Subjects

Computer Science - Cryptography and Security, Computer Science - Databases, E.3, H.1, H.3

Abstract

We propose and define a recursive Merkle structure with q-mercurial commitments, in order to create a concise B-Merkle tree. This Merkle B-Tree builds on previous work of q-ary Merkle trees which use concise, constant size, q-mercurial commitments for intranode proofs. Although these q-ary trees reduce the branching factor and height, they still have their heights based on the key length, and are forced to fixed heights. Instead of basing nodes on q-ary prefix trees, the B Merkle Tree incorporates concise intranode commitments within a self-balancing tree. The tree is based on the ordering of elements, which requires extra information to determine element placement, but it enables significantly smaller proof sizes. This allows for much lower tree heights (directed by the order of elements, not the size of the key), and therefore creates smaller and more efficient proofs and operations. Additionally, the B Merkle Tree is defined with subset queries that feature similar communication costs to non-membership proofs. Our scheme has the potential to benefit outsourced database models, like blockchain, which use authenticated data structures and database indices to ensure immutability and integrity of data. We present potential applications in key-value stores, relational databases, and, in part, Merkle forests.

Published

2020

8. Evaluating the Security of Merkle Trees: An Analysis of Data Falsification Probabilities.

Author

Kuznetsov, Oleksandr, Rusnak, Alex, Yezhov, Anton, Kuznetsova, Kateryna, Kanonik, Dzianis, and Domin, Oleksandr

Subjects

DATA integrity, DATA security, INTERNET of things, EVIDENCE gaps, NUMERICAL analysis

Abstract

Addressing the critical challenge of ensuring data integrity in decentralized systems, this paper delves into the underexplored area of data falsification probabilities within Merkle Trees, which are pivotal in blockchain and Internet of Things (IoT) technologies. Despite their widespread use, a comprehensive understanding of the probabilistic aspects of data security in these structures remains a gap in current research. Our study aims to bridge this gap by developing a theoretical framework to calculate the probability of data falsification, taking into account various scenarios based on the length of the Merkle path and hash length. The research progresses from the derivation of an exact formula for falsification probability to an approximation suitable for cases with significantly large hash lengths. Empirical experiments validate the theoretical models, exploring simulations with diverse hash lengths and Merkle path lengths. The findings reveal a decrease in falsification probability with increasing hash length and an inverse relationship with longer Merkle paths. A numerical analysis quantifies the discrepancy between exact and approximate probabilities, underscoring the conditions for the effective application of the approximation. This work offers crucial insights into optimizing Merkle Tree structures for bolstering security in blockchain and IoT systems, achieving a balance between computational efficiency and data integrity. [ABSTRACT FROM AUTHOR]

Published

2024

9. Merkle Trees in Blockchain: A Study of Collision Probability and Security Implications

Author

Kuznetsov, Oleksandr, primary, Rusnak, Alex, additional, Yezhov, Anton, additional, Kuznetsova, Kateryna, additional, Kanonik, Dzianis, additional, and Domin, Oleksandr, additional

Published

2024

10. Enhanced Security and Efficiency in Blockchain with Aggregated Zero-Knowledge Proof Mechanisms

Author

Kuznetsov, Oleksandr, primary, Rusnak, Alex, additional, Yezhov, Anton, additional, Kanonik, Dzianis, additional, Kuznetsova, Kateryna, additional, and Karashchuk, Stanislav, additional

Published

2024

11. Improving Maps Auto-Complete Through Query Expansion (Demo Paper)

Author

Mokhtari, Shekoofeh, primary, Rusnak, Alex, additional, Mutungu, Tsheko, additional, and Yankov, Dragomir, additional

Published

2021

12. Adaptive Merkle trees for enhanced blockchain scalability

Author

Kuznetsov, Oleksandr, Kanonik, Dzianis, Rusnak, Alex, Yezhov, Anton, Domin, Oleksandr, and Kuznetsova, Kateryna

Abstract

The scalability of blockchain technology remains a critical challenge, hindering its widespread adoption across various sectors. This study introduces an innovative approach to address this challenge by proposing the adaptive restructuring of Merkle trees, fundamental components of blockchain architecture responsible for ensuring data integrity and facilitating efficient verification processes. Unlike traditional static tree structures, our adaptive model dynamically adjusts the configuration of these trees based on usage patterns, significantly reducing the average path length required for verification and, consequently, the computational overhead associated with these processes. Through a comprehensive conceptual framework, we delineate the methodology for adaptive restructuring, encompassing both binary and non-binary tree configurations. This framework is validated through a series of detailed examples, demonstrating the practical feasibility and the efficiency gains achievable with our approach. To empirically assess the effectiveness of our proposed method, we conducted rigorous experiments using real-world data from the Ethereum blockchain. The results provide compelling evidence for the superiority of adaptive Merkle trees, with efficiency gains of up to 30% and higher observed during the initial stages of tree restructuring. Moreover, we present a comparative analysis with existing scalability solutions, highlighting the unique advantages of adaptive restructuring in terms of simplicity, security, and efficiency enhancement without introducing additional complexities or dependencies. This study’s implications extend beyond theoretical advancements, offering a scalable, secure, and efficient method for blockchain data verification that could facilitate broader adoption of blockchain technology in finance, supply chain management, and beyond. As the blockchain ecosystem continues to evolve, the principles, methodologies, and empirical findings outlined herein are poised to contribute significantly to its growth and maturity. StatementThe findings of this article were presented at ETHDenver 2024 (https://www.ethdenver.com/), a leading innovation festival that champions the Web3 community’s role in shaping the future of blockchain technology. A video of our presentation can be found at https://www.youtube.com/watch?v=-jjYVCAQkNE. The original manuscript of this article is available on the preprint archive at https://arxiv.org/abs/2403.00406.

Published

2024

13. PI kinase signaling in membrane trafficking

Author

Emr, Scott, Rusnak, Alex, Sun, Ji, Chu, Tony, Audhya, Jon, and Stefan, Chris

Subjects

Phosphoinositides -- Research, Membrane proteins -- Research, Biological sciences, Health

Abstract

Phosphoinositide lipids (PIs) function as spatially restricted membrane-signaling molecules that regulate diverse cellular processes including cell growth, differentiation, cytoskeletal rearrangements, and membrane trafficking. Activation of the Vps34 PI 3-kinase results in production of the lipid second messenger P13P, which triggers the recruitment/activation of FYVE domain and PX domain-containing effector proteins on endosomal membranes. One FYVE domain-containing protein, Vps27, and its mammalian homologue, HRS, are required for the formation of late endosomal compartments called multivesicular bodies (MVBs). The MVB sorting pathway is required for the down-regulation of numerous activated cell-surface receptors (e.g., EGFR) that subsequently are degraded in the lysosome. Ubiquitination of both biosynthetic and endocytic cargo by the Rsp5 HECT-domain Ub ligase in yeast serves as a signal for sorting into the MVB pathway. We recently identified three distinct protein complexes referred to as the endosomal sorting complex required for transport (ESCRT) complexes that function in the recognition and sorting of ubiquitinated MVB cargoes. Vps27 appears to serve as a docking site for the ESCRT-I complex, thereby initiating the MVB sorting reaction. Vps27 recruits ESCRT-I to endosomes via a short peptide sequence in the COOH terminus of Vps27 that is related to a sequence in the HIV-1 Gag protein required for both viral budding and interaction with human ESCRT-I. Our observations indicate that PI kinase signaling and monoubiquitination function as critical regulators of endosomal sorting, receptor down-regulation, and HIV viral budding.

Published

2004

14. NGF Signaling from Clathrin-Coated Vesicles

Author

Howe, Charles L, primary, Valletta, Janice S, additional, Rusnak, Alex S, additional, and Mobley, William C, additional

Published

2001