Mersenne's laws

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In cryptography, a secret sharing scheme is publicly verifiable (PVSS) if it is a verifiable secret sharing scheme and if any party involved can verify the validity of the shares distributed by the dealer. 36 year-old Diving Instructor (Open water ) Vancamp from Kuujjuaq, spends time with pursuits for instance gardening, public listed property developers in singapore developers in singapore and cigar smoking. Of late took some time to go China Danxia.

The method introduced here according to the paper by Chunming Tang, Dingyi Pei, Zhuo Liu, and Yong He is non-interactive and maintains this property throughout the protocol.

Initialization

The PVSS scheme dictates an initialization process in which:

  1. All system parameters are generated.
  2. Each participant must have a registered public key.

Excluding the initialization process, the PVSS consists of two phases:

Distribution

1.Distribution of secret s shares is performed by the dealer D, which does the following:

  • The dealer creates s1,s2...sn for each participant P1,P2...Pn respectively.
  • The dealer publishes the encrypted share Ei(si) for each Pi.
  • The dealer also publishes a string proofD to show that each Ei encrypts si

(note: proofD guarantees that the reconstruction protocol will result in the same s.

2. Verification of the shares:

  • Anybody knowing the public keys for the encryption methods Ei, can verify the shares.
  • If one or more verifications fails the dealer fails and the protocol is aborted.

Reconstruction

1. Decryption of the shares:

  • The Participants Pi decrypts their share of the secret si using Ei(si).

(note: fault-tolerance can be allowed here: it's not required that all participants succeed in decrypting Ei(si) as long as a qualified set of participants are successful to decrypt si).

  • The participant release si plus a string proofPi this shows the released share is correct.

2. Pooling the shares:

  • Using the strings proofPi to exclude the participants which are dishonest or failed to decrypt Ei(si).
  • Reconstruction s can be done from the shares of any qualified set of participants.

Chaums and Pedersen Scheme

A proposed protocol proving: logg1h1=logg2h2 :

  1. The prover chooses a random rZq*
  2. The verifier send a random challenge cRZq
  3. The prover responds with s=rcx(modq)
  4. The verifier checks α1=g1sh1c and α2=g2sh2c

Denote this protocol as: dleq(g1,h1,g2,h2)
A generalization of dleq(g1,h1,g2,h2) is denoted as: dleq(X,Y,g1,h1,g2,h2) where as: X=g1x1g2x2 and Y=h1x1h2x2:

  1. The prover chooses a random r1,r2Zq* and sends t1=g1r1g2r2 and t2=h1r1h2r2
  2. The verifier send a random challenge cRZq.
  3. The prover responds with s1=r1cx1(modq) , s2=r2cx2(modq).
  4. The verifier checks t1=Xcg1s1g2s2 and t2=Ych1s1h2s2

The Chaums and Pedersen method is an interactive method and needs some modification to be used in a non-interactive way: Replacing the randomly chosen c by a 'secure hash' function with m as input value.

See also

References