Short Non-Interactive Cryptographic Proofs

被引:0
|
作者
Joan Boyar
Ivan Damgård
René Peralta
机构
[1] Department of Mathematics and Computer Science,
[2] University of Southern Denmark,undefined
[3] Odense,undefined
[4] Denmark joan@imada.sdu.dk,undefined
[5] Department of Computer Science,undefined
[6] BRICS,undefined
[7] Aarhus University,undefined
[8] DC-8000 Aarhus C,undefined
[9] Denmark ivan@daimi.au.dk,undefined
[10] Department of Computer Science,undefined
[11] Yale University,undefined
[12] New Haven,undefined
[13] CT 06520-8285,undefined
[14] U.S.A. peralta-rene@cs.yale.edu,undefined
来源
Journal of Cryptology | 2000年 / 13卷
关键词
Key words. Cryptographic proofs, Non-interactive proofs, Discreet proofs, Circuit complexity, Multiplicative complexity.;
D O I
暂无
中图分类号
学科分类号
摘要
We show how to produce short proofs of theorems such that a distrusting Verifier can be convinced that the theorem is true yet obtains no information about the proof itself. We assume the theorem is represented by a boolean circuit, of size m gates, which is satisfiable if and only if the theorem holds. We use bit commitments of size k and bound the probability of false proofs going undetected by 2-r . We obtain non-interactive zero-knowledge proofs of size O(mk( log m +r)) bits. In the random oracle model, we obtain non-interactive proofs of size O(m( log m+r) + rk) bits. By simulating a random oracle, we obtain non-interactive proofs which are short enough to be used in practice. We call the latter proofs ``discreet.''
引用
下载
收藏
页码:449 / 472
页数:23
相关论文
共 50 条
  • [31] Toward Non-interactive Zero-Knowledge Proofs for NP from LWE
    Ron D. Rothblum
    Adam Sealfon
    Katerina Sotiraki
    Journal of Cryptology, 2021, 34
  • [32] Toward Non-interactive Zero-Knowledge Proofs for NP from LWE
    Rothblum, Ron D.
    Sealfon, Adam
    Sotiraki, Katerina
    JOURNAL OF CRYPTOLOGY, 2021, 34 (01)
  • [33] Verifiable Random Functions from Non-interactive Witness-Indistinguishable Proofs
    Bitansky, Nir
    JOURNAL OF CRYPTOLOGY, 2020, 33 (02) : 459 - 493
  • [34] Non-Interactive Zero-Knowledge Proofs with Fine-Grained Security
    Wang, Yuyu
    Pan, Jiaxin
    ADVANCES IN CRYPTOLOGY - EUROCRYPT 2022, PT II, 2022, 13276 : 305 - 335
  • [35] Authentication Based on Non-Interactive Zero-Knowledge Proofs for the Internet of Things
    Martin-Fernandez, Francisco
    Caballero-Gil, Pino
    Caballero-Gil, Candido
    SENSORS, 2016, 16 (01):
  • [36] The electronic cash system based on non-interactive zero-knowledge proofs
    Zhou, Fucai
    Li, Yuxi
    Zhou, Qingshi
    Miao, Jingwei
    Xu, Jian
    INTERNATIONAL JOURNAL OF COMPUTER MATHEMATICS, 2016, 93 (02) : 239 - 257
  • [37] Non-interactive distributed-verifier proofs and proving relations among commitments
    Abe, M
    Cramer, R
    Fehr, S
    ADVANCES IN CRYPTOLOGY - ASIACRYPT 2002, PROCEEDINGS, 2002, 2501 : 206 - 223
  • [38] On non-interactive zero-knowledge proofs of knowledge in the shared random string model
    Persiano, Giuseppe
    Visconti, Ivan
    MATHEMATICAL FOUNDATIONS OF COMPUTER SCIENCE 2006, PROCEEDINGS, 2006, 4162 : 753 - 764
  • [39] Non-interactive zero knowledge proofs for the authentication of IoT devices in reduced connectivity environments
    Walshe, Marcus
    Epiphaniou, Gregory
    Al-Khateeb, Haider
    Hammoudeh, Mohammad
    Katos, Vasilios
    Dehghantanha, Ali
    AD HOC NETWORKS, 2019, 95
  • [40] Efficient Designated-Verifier Non-interactive Zero-Knowledge Proofs of Knowledge
    Chaidos, Pyrros
    Couteau, Geoffroy
    ADVANCES IN CRYPTOLOGY - EUROCRYPT 2018, PT III, 2018, 10822 : 193 - 221
12345