Dominique Unruh scite author profile

Abstract. The Universal Composability model (UC) by Canetti (FOCS 2001) allows for secure composition of arbitrary protocols. We present a quantum version of the UC model which enjoys the same compositionality guarantees. We prove that in this model statistically secure oblivious transfer protocols can be constructed from commitments. Furthermore, we show that every statistically classically UC secure protocol is also statistically quantum UC secure. Such implications are not known for other quantum security definitions. As a corollary, we get that quantum UC secure protocols for general multi-party computation can be constructed from commitments.

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Quantum Proofs of Knowledge

Unruh

2012

118

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We motivate, define and construct quantum proofs of knowledge, that is, proofs of knowledge secure against quantum adversaries. Our constructions are based on a new quantum rewinding technique that allows us to extract witnesses in many classical proofs of knowledge. We give criteria under which a classical proof of knowledge is a quantum proof of knowledge. Combining our results with Watrous' results on quantum zero-knowledge, we show that there are zero-knowledge quantum proofs of knowledge for all languages in NP (assuming quantum 1-1 one-way functions).

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Quantum relational Hoare logic

Unruh

2019

Proc. ACM Program. Lang.

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We present a logic for reasoning about pairs of interactive quantum programs -quantum relational Hoare logic (qRHL). This logic follows the spirit of probabilistic relational Hoare logic (Barthe et al. 2009) and allows us to formulate how the outputs of two quantum programs relate given the relationship of their inputs. Probabilistic RHL was used extensively for computer-verified security proofs of classical cryptographic protocols. Since pRHL is not suitable for analyzing quantum cryptography, we present qRHL as a replacement, suitable for the security analysis of post-quantum cryptography and quantum protocols. The design of qRHL poses some challenges unique to the quantum setting, e.g., the definition of equality on quantum registers. Finally, we implemented a tool for verifying proofs in qRHL and developed several example security proofs in it.

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Compromising Reflections-or-How to Read LCD Monitors around the Corner

Backes

Dürmuth

Unruh

2008

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Computationally Binding Quantum Commitments

Unruh

2016

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Dominique Unruh

Universally Composable Quantum Multi-party Computation

Quantum Proofs of Knowledge

Quantum relational Hoare logic

Compromising Reflections-or-How to Read LCD Monitors around the Corner

Computationally Binding Quantum Commitments

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