Interactive oracle proofs (IOPs) are a multi-round generalization of probabilistically checkable proofs that play a fundamental role in the construction of efficient cryptographic proofs.We present an IOP that simultaneously achieves the properties of zero knowledge, linear-time proving, and polylogarithmic-time verification. We construct a zero-knowledge IOP where, for the satisfiability of an N-gate arithmetic circuit over any field of size Omega(N), the prover uses O(N) field operations and the verifier uses polylog(N) field operations (with proof length O(N) and query complexity polylog(N)). Polylogarithmic verification is achieved in the holographic setting for every circuit (the verifier has oracle access to a linear-time-computable e...
We present a zero-knowledge proof system [19] for any NP language L, whichallows showing that x in L...
The celebrated PCP Theorem states that any language in NP can be decided via a verifier that reads O...
AbstractIn this paper we further study the complexity of zero-knowledge interactive proofs. We prove...
Minimizing the computational cost of the prover is a central goal in the area of succinct arguments....
Zero-knowledge protocols enable the truth of a mathematical statement to be certified by a verifier ...
We give computationally efficient zero-knowledge proofs of knowledge for arithmetic circuit satisfia...
Zero-knowledge proof is a powerful cryptographic primitive that has found various applications in th...
Interactive oracle proofs (IOPs) are a generalization of probabilistically checkable proofs that can...
There have been tremendous advances in reducing interaction, communication and verification time in ...
We provide a zero-knowledge argument for arithmetic circuit satisfiability with a communication comp...
We study interactive oracle proofs (IOPs) [BCS16,RRR16], which combine aspects of probabilistically ...
The notion of efficient computation is usually identified in cryptography and complexity with (stric...
AbstractA perfect zero-knowledge interactive protocol allows a prover to convince a verifier of the ...
We introduce and study a simple kind of proof system called line-point zero knowledge (LPZK). In an ...
A zero-knowledge interactive proof is a protocol by which Alice can convince a polynomially-bounded ...
We present a zero-knowledge proof system [19] for any NP language L, whichallows showing that x in L...
The celebrated PCP Theorem states that any language in NP can be decided via a verifier that reads O...
AbstractIn this paper we further study the complexity of zero-knowledge interactive proofs. We prove...
Minimizing the computational cost of the prover is a central goal in the area of succinct arguments....
Zero-knowledge protocols enable the truth of a mathematical statement to be certified by a verifier ...
We give computationally efficient zero-knowledge proofs of knowledge for arithmetic circuit satisfia...
Zero-knowledge proof is a powerful cryptographic primitive that has found various applications in th...
Interactive oracle proofs (IOPs) are a generalization of probabilistically checkable proofs that can...
There have been tremendous advances in reducing interaction, communication and verification time in ...
We provide a zero-knowledge argument for arithmetic circuit satisfiability with a communication comp...
We study interactive oracle proofs (IOPs) [BCS16,RRR16], which combine aspects of probabilistically ...
The notion of efficient computation is usually identified in cryptography and complexity with (stric...
AbstractA perfect zero-knowledge interactive protocol allows a prover to convince a verifier of the ...
We introduce and study a simple kind of proof system called line-point zero knowledge (LPZK). In an ...
A zero-knowledge interactive proof is a protocol by which Alice can convince a polynomially-bounded ...
We present a zero-knowledge proof system [19] for any NP language L, whichallows showing that x in L...
The celebrated PCP Theorem states that any language in NP can be decided via a verifier that reads O...
AbstractIn this paper we further study the complexity of zero-knowledge interactive proofs. We prove...