Efficient inner product arguments with sublogarithmic proof and sub-square-root verifier

Zibo Zhou; Zongyang Zhang; Jianwei Liu; Haifeng Qian

doi:10.1186/s42400-024-00304-x

Efficient inner product arguments with sublogarithmic proof and sub-square-root verifier

Zibo Zhou, Zongyang Zhang, Jianwei Liu, Haifeng Qian

Software Engineering Institute

Beihang University

Research output: Contribution to journal › Article › peer-review

Abstract

Inner product arguments are core building blocks of numerous cryptographic primitives and therefore minimizing their complexity is a central goal in this research area. In this paper, we follow the work of Kim et al. (ASIACRYPT’22) and propose the first inner product argument having sublogarithmic communication complexity and sub-square-root verifier complexity simultaneously. We first devise a new subvector combination method for recursion and utilize an aggregated multi-exponentiation argument to prove some committed group elements are valid. We then modify the commitment keys in inner product arguments to be structured and reduce the verifier complexity by delegating the costly computations to the prover. Compared with the state-of-the-art inner product arguments, our protocol is highly competitive in terms of asymptotic complexity.

Original language	English
Article number	45
Journal	Cybersecurity
Volume	8
Issue number	1
DOIs	https://doi.org/10.1186/s42400-024-00304-x
State	Published - Dec 2025

Keywords

Inner product arguments
Multi-exponentiation arguments
Vector commitments
Zero-knowledge proofs

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10.1186/s42400-024-00304-x

Cite this

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abstract = "Inner product arguments are core building blocks of numerous cryptographic primitives and therefore minimizing their complexity is a central goal in this research area. In this paper, we follow the work of Kim et al. (ASIACRYPT{\textquoteright}22) and propose the first inner product argument having sublogarithmic communication complexity and sub-square-root verifier complexity simultaneously. We first devise a new subvector combination method for recursion and utilize an aggregated multi-exponentiation argument to prove some committed group elements are valid. We then modify the commitment keys in inner product arguments to be structured and reduce the verifier complexity by delegating the costly computations to the prover. Compared with the state-of-the-art inner product arguments, our protocol is highly competitive in terms of asymptotic complexity.",

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AU - Zhou, Zibo

AU - Zhang, Zongyang

AU - Liu, Jianwei

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N1 - Publisher Copyright: © The Author(s) 2025.

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Y1 - 2025/12

N2 - Inner product arguments are core building blocks of numerous cryptographic primitives and therefore minimizing their complexity is a central goal in this research area. In this paper, we follow the work of Kim et al. (ASIACRYPT’22) and propose the first inner product argument having sublogarithmic communication complexity and sub-square-root verifier complexity simultaneously. We first devise a new subvector combination method for recursion and utilize an aggregated multi-exponentiation argument to prove some committed group elements are valid. We then modify the commitment keys in inner product arguments to be structured and reduce the verifier complexity by delegating the costly computations to the prover. Compared with the state-of-the-art inner product arguments, our protocol is highly competitive in terms of asymptotic complexity.

AB - Inner product arguments are core building blocks of numerous cryptographic primitives and therefore minimizing their complexity is a central goal in this research area. In this paper, we follow the work of Kim et al. (ASIACRYPT’22) and propose the first inner product argument having sublogarithmic communication complexity and sub-square-root verifier complexity simultaneously. We first devise a new subvector combination method for recursion and utilize an aggregated multi-exponentiation argument to prove some committed group elements are valid. We then modify the commitment keys in inner product arguments to be structured and reduce the verifier complexity by delegating the costly computations to the prover. Compared with the state-of-the-art inner product arguments, our protocol is highly competitive in terms of asymptotic complexity.

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KW - Vector commitments

KW - Zero-knowledge proofs

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Efficient inner product arguments with sublogarithmic proof and sub-square-root verifier

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Keywords

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