We analyze the situation where computationally binding string commitment schemes are used to force the receiver of a BB84 encoding of a classical bitstring to measure upon reception. Since measuring induces an irreversible collapse to the received quantum state, even given extra information after the measurement does not allow the receiver to evaluate reliably some predicates apply to the classical bits encoded in the state. This fundamental quantum primitive is called quantum measure commitment (QMC) and allows for secure two-party computation of classical functions. An adversary to QMC is one that can both provide valid proof of having measured the received states while still able to evaluate a predicate applied to the classical content o...
The Mayers-Lo-Chau theorem establishes that no quantum bit commitment protocol is unconditionally se...
Quantum computing allows us to revisit the study of quantum cryptographic primitives with informatio...
While unconditionally secure bit commitment (BC) is considered impossible within the quant...
We analyze the situation where computationally binding string commitment schemes are used to force t...
Quantum 2-party cryptography differs from its classical counterpart in at least one important way: G...
Abstract. Quantum 2-party cryptography differs from its classical counterpart in at least one import...
The concept of quantum bit commitment was introduced in the early 1980s for the purpose of basing bi...
It has been recently shown by Mayers that no bit commitment is secure if the participants have unlim...
We define $(varepsilon,delta)$-secure quantum computations between two parties that can play dishon...
In this paper we show how to convert a statistically bindingbut computationally concealing quantum b...
We show that all proposed quantum bit commitment schemes are insecure because the sender, Alice, can...
Unconditionally secure non-relativistic bit commitment is known to be impossible in both the classic...
We consider two-party quantum protocols starting with a transmission of some random BB84 qubits fol...
We initiate the study of two-party cryptographic primitives with unconditional security, assuming th...
AbstractIn this paper, we introduce a new quantum bit commitment protocol which is secure against en...
The Mayers-Lo-Chau theorem establishes that no quantum bit commitment protocol is unconditionally se...
Quantum computing allows us to revisit the study of quantum cryptographic primitives with informatio...
While unconditionally secure bit commitment (BC) is considered impossible within the quant...
We analyze the situation where computationally binding string commitment schemes are used to force t...
Quantum 2-party cryptography differs from its classical counterpart in at least one important way: G...
Abstract. Quantum 2-party cryptography differs from its classical counterpart in at least one import...
The concept of quantum bit commitment was introduced in the early 1980s for the purpose of basing bi...
It has been recently shown by Mayers that no bit commitment is secure if the participants have unlim...
We define $(varepsilon,delta)$-secure quantum computations between two parties that can play dishon...
In this paper we show how to convert a statistically bindingbut computationally concealing quantum b...
We show that all proposed quantum bit commitment schemes are insecure because the sender, Alice, can...
Unconditionally secure non-relativistic bit commitment is known to be impossible in both the classic...
We consider two-party quantum protocols starting with a transmission of some random BB84 qubits fol...
We initiate the study of two-party cryptographic primitives with unconditional security, assuming th...
AbstractIn this paper, we introduce a new quantum bit commitment protocol which is secure against en...
The Mayers-Lo-Chau theorem establishes that no quantum bit commitment protocol is unconditionally se...
Quantum computing allows us to revisit the study of quantum cryptographic primitives with informatio...
While unconditionally secure bit commitment (BC) is considered impossible within the quant...