Quantum Rabin oblivious transfer using two pure states

Lara Stroh; James T. Peat; Mats Kroneberg; Ittoop V. Puthoor; Erika Andersson

doi:10.1103/physrevresearch.6.043004

Quantum Rabin oblivious transfer using two pure states

Lara Stroh, James T. Peat, Mats Kroneberg, Ittoop V. Puthoor, Erika Andersson

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Abstract

Oblivious transfer between two untrusting parties is an important primitive in cryptography. There are different variants of oblivious transfer. In Rabin oblivious transfer, the sender Alice holds a bit, and the receiver Bob either obtains the bit, or obtains no information with probability p?. Alice should not know whether or not Bob obtained the bit. We examine a quantum Rabin oblivious transfer (OT) protocol that uses two pure states. Investigating different cheating scenarios for the sender and for the receiver, we determine optimal cheating probabilities in each case. Comparing the quantum Rabin oblivious transfer protocol to classical Rabin oblivious transfer protocols, we show that the quantum protocol outperforms classical protocols, which do not use a third party, for some values of p?. We find that quantum Rabin OT protocols that use mixed states can outperform quantum Rabin OT protocols that use pure states for some values of p?.

Original language	English
Article number	043004
Journal	Physical Review Research
Volume	6
Issue number	4
DOIs	https://doi.org/10.1103/physrevresearch.6.043004
Publication status	Published - 2 Oct 2024

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abstract = "Oblivious transfer between two untrusting parties is an important primitive in cryptography. There are different variants of oblivious transfer. In Rabin oblivious transfer, the sender Alice holds a bit, and the receiver Bob either obtains the bit, or obtains no information with probability p?. Alice should not know whether or not Bob obtained the bit. We examine a quantum Rabin oblivious transfer (OT) protocol that uses two pure states. Investigating different cheating scenarios for the sender and for the receiver, we determine optimal cheating probabilities in each case. Comparing the quantum Rabin oblivious transfer protocol to classical Rabin oblivious transfer protocols, we show that the quantum protocol outperforms classical protocols, which do not use a third party, for some values of p?. We find that quantum Rabin OT protocols that use mixed states can outperform quantum Rabin OT protocols that use pure states for some values of p?.",

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AU - Stroh, Lara

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Quantum Rabin oblivious transfer using two pure states

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