1,474 research outputs found

    More Compact E-Cash with Efficient Coin Tracing

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    In 1982, Chaum \cite{Chaum82} pioneered the anonymous e-cash which finds many applications in e-commerce. In 1993, Brands \cite{Brands93apr,Brands93,Brands93tm} and Ferguson \cite Ferguson93c,Ferguson93} published on single-term offline anonymous e-cash which were the first practical e-cash. Their constructions used blind signatures and were inefficient to implement multi-spendable e-cash. In 1995, Camenisch, Hohenberger, and Lysyanskaya \cite{CaHoLy05} gave the first compact 2â„“2^\ell-spendable e-cash, using zero-knowledge-proof techniques. They left an open problem of the simultaneous attainment of O(1)O(1)-unit wallet size and efficient coin tracing. The latter property is needed to revoke {\em bad} coins from over-spenders. In this paper, we solve \cite{CaHoLy05}\u27s open problem, and thus enable the first practical compact e-cash. We use a new technique whose security reduces to a new intractability Assumption: the {\em Decisional Harmonic-Relationed Diffie-Hellman (DHRDH) Assumption}

    Tracing-by-Linking Group Signautres

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    In a group signature \cite{CvH91}, any group member can sign on behalf of the group while remaining anonymous, but its identity can be traced in an future dispute investigation. Essentially all state-of-the-art group signatures implement the tracing mechnism by requiring the signer to escrow its identity to an Open Authority (OA) \cite{ACJT00,CL02scn,BMW03,KiayiasYu04,BSZ05,BBS04,KiayiasTsYu04}. We call them {\em Tracing-by-Escrowing (TbE)} group signatures. One drawback is that the OA also has the unnecessary power to trace without proper cause. In this paper we introduce {\em Tracing-by-Linking (TbL)} group signatures. The signer\u27s anonymity is irrevocable by any authority if the group member signs only once (per event). But if a member signs twice, its identity can be traced by a public algorithm without needing any trapdoor. We initiate the formal study of TbL group signatures by introducing its security model, constructing the first examples, and give several applications. Our core construction technique is the successful transplant of the TbL technique from single-term offline e-cash from the blind signature framework \cite{Brands93,Ferguson93,Ferguson93c} to the group signature framework. Our signatures have size O(1)O(1)

    Signature from a New Subgroup Assumption

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    We present a new signature whose security is reducible to a new assumptions about subgroups, the {\em Computational Conjugate Subgroup Members (CCSM) Assumption}, in the random oracle model

    A Bilinear Spontaneous Anonymous Threshold Signature for Ad Hoc Groups

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    We present an adaptive chosen-plaintext cryptanalysis of Boneh, et al.\u27s bilinear spontaneous anonymous ad hoc group signature. Then we present a patch, and an extension to a threshold version complete with a security proof in the random oracle model (ROM)

    Tight Reductions among Strong Diffie-Hellman Assumptions

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    We derive some tight equivalence reductions between several Strong Diffie-Hellman (SDH) assumptions

    (Hierarchical Identity-Based) Threshold Ring Signatures

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    We construct the first several efficient threshold ring signatures (TRS) without random oracles. Specializing to a threshold of one, they are the first several efficient ring signatures without random oracles after the only earlier instantiation of Chow, Liu, Wei, and Yuen. Further specializing to a ring of just one user, they are the short (ordinary) signatures without random oracles summarized in Wei and Yuen. We also construct the first hierarchical identity-based threshold ring signature without random oracles. The signature size is O(nλs)O(n\lambda_s) bits, where λs\lambda_s is the security parameter and nn is the number of users in the ring. Specializing to a threshold of one, it is the first hierarchical identity-based ring signature without random oracles. Further specializing to a ring of one user, it is the constant-size hierarchical identity-based signature (HIBS) without random oracles in Yuen-Wei - the signature size is O(λs)O(\lambda_s) bits which is independent of the number of levels in the hierarchy

    Constant-Size Hierarchical Identity-Based Signature/Signcryption without Random Oracles

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    We construct the first constant-size hierarchical identity-based signature (HIBS) without random oracles - the signature size is O(λs)O(\lambda_s) bits, where λs\lambda_s is the security parameter, and it is independent of the number of levels in the hierarchy. We observe that an efficient hierarchical identity-based signcryption (HIBSC) scheme without random oracles can be compositioned from our HIBS and Boneh, Boyen, and Goh\u27s hierarchical identity-based encryption (HIBE). We further optimize it to a constant-factor efficiency improvement. This is the first constant-size HIBSC without random oracles

    Fast and Proven Secure Blind Identity-Based Signcryption from Pairings

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    We present the first blind identity-based signcryption (BIBSC). We formulate its security model and define the security notions of blindness and parallel one-more unforgeability (p1m-uf). We present an efficient construction from pairings, then prove a security theorem that reduces its p1m-uf to Schnorr¡¦s ROS Problem in the random oracle model plus the generic group and pairing model. The latter model is an extension of the generic group model to add support for pairings, which we introduce in this paper. In the process, we also introduce a new security model for (non-blind) identity-based signcryption (IBSC) which is a strengthening of Boyen¡¦s. We construct the first IBSC scheme proven secure in the strenghened model which is also the fastest (resp. shortest) IBSC in this model or Boyen¡¦s model. The shortcomings of several existing IBSC schemes in the strenghened model are shown

    ID-based Cryptography from Composite Degree Residuosity

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    We present identity-based identification (resp. encryption, signature, blind signature,ring signature) from composite degree residuosity (CDR). Constructions of identifications and signatures motivated by several existing CDR-based bandwidth-efficient encryption schemes are presented. Their securities are proven equivalent to famous hard problems, in the random oracle model. Motivated by Cocks,we construct an identity-based encryption from CDR. Its security is proven equivalent to a new problem, the JSR (Jacobi Symbol of Roots of two quadratic polynomials) Problem. We prove JSR is at least as hard as QRP (Quadratic Residuosity Problem). Furthermore, we present the first two-way equivalence reduction of the security of Cocks\u27 IBE, to the JSR Problem
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