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An efficient threshold RSA digital signature scheme

An efficient threshold RSA digital signature scheme. Source : Applied Mathematics and Computation, Volume 166, Issue 1, 6 July 2005, Pages 25-34 Author : Qiu-Liang Xu, Tzer-Shyong Chen Speaker : 李士勳 Date : 2005,12,14. Outline. Introduction Descriptions of the scheme

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An efficient threshold RSA digital signature scheme

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  1. An efficient threshold RSA digital signature scheme Source:Applied Mathematics and Computation, Volume 166, Issue 1, 6 July 2005, Pages 25-34 Author:Qiu-Liang Xu, Tzer-Shyong Chen Speaker:李士勳 Date:2005,12,14

  2. Outline • Introduction • Descriptions of the scheme • Analysis of security and efficiency • Conclusions

  3. Introduction • Resisting conspiracy attack • (t,n) threshold signature scheme

  4. Introduction • 1991:Desmedt and Frankel fist proposed the threshold signature scheme • 1994:Li et al. presented two (t,n) threshold signature schemes • 1997:Michels and Horster proved them insecure • 1998:Wang et al. presented two (t,n) threshold signature schemes

  5. Descriptions of the scheme p and q are large primes

  6. Descriptions of the scheme • represent the set of all members in the system

  7. Initialization phase • Key Dealing Center(KDC) must establish four parameters • RSA parameters • Lagrange interpolation parameters • Parameters used in modulus convention • Parameters used in partial signature verification

  8. RSA parameters • p,q,n,e and d to generatethe group signature, where n=p*q, p and p are two safe primes, (n,e) is the public key, and d is the private key • P,Q,N,E and D which is used by the signature generator(SG), where N=P*Q>n, P and Q are also two safe primes, (N,E) is the public key, and D is the private key

  9. Lagrange interpolation parameters • Select a large public prime r>n • Select a random polynomial f(x), d=f(0)

  10. Parameters used in modulus convention • Consider a sample message , so that the order of in group is • Compute • Make public

  11. Parameters used in partial signature verification • Select randomly an element of order compute i=1,2,…,n and send publicly v and to the signature generator SG

  12. Signature phase • Chaum-Pedersen zero-knowledge protocol

  13. Chaum-Pedersen zero-knowledge protocol • One-way hash function H(), and a random number u, compute z=xc+u • (z,c) proves , the verifier acepts the proof if and only if • Clearly, when ,the proof holds

  14. Signature phase • denotes the t shareholders who participate in signing

  15. Signature phase • Select a random number • Compute , • Send to SG • , , • (m,s(m),S(m)) is the signature on message m

  16. Signature phase • If then (m,s(m),S(m)) is appetped as a valid signature

  17. Analysis of security and efficiency • The fist step of the initialization phase builds only the RSA cryptosystem, without providing any extra information • The second step is to establish a (t,n) threshold system based on Lagrange interpolation • The third and forth step is hard to slove the discrete logarithm problem

  18. Conclusions • Resisting conspiracy attack

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