Anonymous veto network

In cryptography, the anonymous veto network (or AV-net) is a multi-party secure computation protocol to compute the boolean-OR function. It was first proposed by Feng Hao and Piotr Zieliński in 2006.^[1] This protocol presents an efficient solution to the Dining cryptographers problem.

A related protocol that securely computes a boolean-count function is open vote network (or OV-net).

Description[edit]

All participants agree on a group $\scriptstyle G$ with a generator $\scriptstyle g$ of prime order $\scriptstyle q$ in which the discrete logarithm problem is hard. For example, a Schnorr group can be used. For a group of $\scriptstyle n$ participants, the protocol executes in two rounds.

Round 1: each participant $\scriptstyle i$ selects a random value $\scriptstyle x_{i}\,\in _{R}\,\mathbb {Z} _{q}$ and publishes the ephemeral public key $\scriptstyle g^{x_{i}}$ together with a zero-knowledge proof for the proof of the exponent $\scriptstyle x_{i}$ . A detailed description of a method for such proofs is found in RFC 8235.

After this round, each participant computes:

g^{y_{i}}=\prod _{j<i}g^{x_{j}}/\prod _{j>i}g^{x_{j}}

Round 2: each participant $\scriptstyle i$ publishes $\scriptstyle g^{c_{i}y_{i}}$ and a zero-knowledge proof for the proof of the exponent $\scriptstyle c_{i}$ . Here, the participants chose $\scriptstyle c_{i}\;=\;x_{i}$ if they want to send a "0" bit (no veto), or a random value if they want to send a "1" bit (veto).

After round 2, each participant computes $\scriptstyle \prod g^{c_{i}y_{i}}$ . If no one vetoed, each will obtain $\scriptstyle \prod g^{c_{i}y_{i}}\;=\;1$ . On the other hand, if one or more participants vetoed, each will have $\scriptstyle \prod g^{c_{i}y_{i}}\;\neq \;1$ .

The protocol design[edit]

The protocol is designed by combining random public keys in such a structured way to achieve a vanishing effect. In this case, $\scriptstyle \sum {x_{i}\cdot y_{i}}\;=\;0$ . For example, if there are three participants, then $\scriptstyle x_{1}\cdot y_{1}\,+\,x_{1}\cdot y_{2}\,+\,x_{3}\cdot y_{3}\;=\;x_{1}\cdot (-x_{2}\,-\,x_{3})\,+\,x_{2}\cdot (x_{1}\,-\,x_{3})\,+\,x_{3}\cdot (x_{1}\,+\,x_{2})\;=\;0$ . A similar idea, though in a non-public-key context, can be traced back to David Chaum's original solution to the Dining cryptographers problem.^[2]

References[edit]

^ F. Hao, P. Zieliński. A 2-round anonymous veto protocol. Proceedings of the 14th International Workshop on Security Protocols, 2006.
^ David Chaum. The Dining Cryptographers Problem: Unconditional Sender and Recipient Untraceability Journal of Cryptology, vol. 1, No, 1, pp. 65-75, 1988

[1] F. Hao, P. Zieliński. A 2-round anonymous veto protocol. Proceedings of the 14th International Workshop on Security Protocols, 2006.

[2] David Chaum. The Dining Cryptographers Problem: Unconditional Sender and Recipient Untraceability Journal of Cryptology, vol. 1, No, 1, pp. 65-75, 1988

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