Demonstration of Blind Quantum Computing

Barz, Stefanie; Kashefi, Elham; Broadbent, Anne; Fitzsimons, Joseph F.; Zeilinger, Anton; Walther, Philip

doi:10.1126/science.1214707

Cited by 405 publications

(387 citation statements)

References 52 publications

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“…While some of these schemes, in principle, can be used to accomplish similar outcomes as our protocol, they can lead to very different client-server relationships in practice. For example, a recent experiment used the measurement-based model of quantum computing to demonstrate the complementary problem of hiding from a server the circuit that is to be performed 7,8 . This method, known as blind quantum computing, can be extended to compute on encrypted data, but would require more than eight times as many auxiliary qubits and significantly more rounds of classical communication.…”

Section: Resultsmentioning

confidence: 99%

“…The overhead in quantum resources required to compute on encrypted quantum data is so low (only one auxiliary qubit per non-Clifford gate) that it will be straightforward for future quantum servers to incorporate our protocol in their design, dramatically enhancing the security of client-server quantum computing; our protocol has even less overhead than the best classical fully homomorphic encryption scheme, and provides information-theoretic (as opposed to just computational) security. This method for computing on encrypted quantum data, combined with the techniques developed for quantum circuit hiding 7,8 , form a complete security system that will enable secure distributed quantum computing to take place, ensuring the privacy and security of future quantum networks.…”

Section: Discussionmentioning

confidence: 99%

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Quantum computing on encrypted data

et al. 2014

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The ability to perform computations on encrypted data is a powerful tool for protecting privacy. Recently, protocols to achieve this on classical computing systems have been found. Here, we present an efficient solution to the quantum analogue of this problem that enables arbitrary quantum computations to be carried out on encrypted quantum data. We prove that an untrusted server can implement a universal set of quantum gates on encrypted quantum bits (qubits) without learning any information about the inputs, while the client, knowing the decryption key, can easily decrypt the results of the computation. We experimentally demonstrate, using single photons and linear optics, the encryption and decryption scheme on a set of gates sufficient for arbitrary quantum computations. As our protocol requires few extra resources compared with other schemes it can be easily incorporated into the design of future quantum servers. These results will play a key role in enabling the development of secure distributed quantum systems.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Quantum computing on encrypted data

et al. 2014

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“…Among them is the universal blind quantum computation (UBQC) protocol of [3], which is developed based on the measurement-based quantum computation model (MBQC) [7] that appears as the most promising physical implementation for a networked architecture [8]. In the UBQC framework, the only quantum requirement for the client is the offline creation of random single qubit states, which is a currently available technology and has been demonstrated experimentally [9].…”

Section: Introductionmentioning

confidence: 99%

Garbled Quantum Computation

Kashefi

Wallden

2017

Cryptography

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Abstract:The universal blind quantum computation protocol (UBQC) enables an almost classical client to delegate a quantum computation to an untrusted quantum server (in the form of a garbled quantum circuit) while the security for the client is unconditional. In this contribution, we explore the possibility of extending the verifiable UBQC, to achieve further functionalities following the analogous research for classical circuits (Yao 1986). First, exploring the asymmetric nature of UBQC (the client preparing only single qubits, while the server runs the entire quantum computation), we present a "Yao"-type protocol for secure two-party quantum computation. Similar to the classical setting, our quantum Yao protocol is secure against a specious (quantum honest-but-curious) garbler, but in our case, against a (fully) malicious evaluator. Unlike the previous work on quantum two-party computation of Dupuis et al., 2010, we do not require any online-quantum communication between the garbler and the evaluator and, thus, no extra cryptographic primitive. This feature will allow us to construct a simple universal one-time compiler for any quantum computation using one-time memory, in a similar way to the classical work of Goldwasser et al., 2008, while more efficiently than the previous work of Broadbent et al., 2013.

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“…Universal classical homomorphic encryption was only first discovered in 2009 [6] and subsequently simplified [7]. Closely related is blind computing, where Alice possesses both the data and the algorithm, and Bob owns the computer [8][9][10], as is the quantum private queries protocol [11], which is used to query a database while keeping the query secret.In this paper we describe a technique for solving the above problem, and hence achieving a limited quantum homomorphic encryption using the Boson sampling and multi-walker quantum walk models for quantum computation.The Boson sampling model -A first protocol for universal LOQC was introduced by Knill, Laflamme & Milburn (KLM) [4]. While universal for quantum computation, their protocol is extremely demanding, requiring fast-feedforward and quantum memory, which are technologically challenging and well beyond the capabilities of present-day experiments.…”

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Quantum Walks with Encrypted Data

2012

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In the setting of networked computation, data security can be a significant concern. Here we consider the problem of allowing a server to remotely manipulate client supplied data, in such a way that both the information obtained by the client about the server's operation and the information obtained by the server about the client's data are significantly limited. We present a protocol for achieving such functionality in two closely related models of restricted quantum computation -the Boson sampling and quantum walk models. Due to the limited technological requirements of the Boson scattering model, small scale implementations of this technique are feasible with present-day technology.Introduction -Quantum information processing [1] allows certain key problems, which are believed to be classically hard, to be efficiently solved. Well known examples with real world applications include Shor's algorithm for integer factorisation [2] and Grover's search algorithm [3]. One of the more promising approaches to implementing quantum algorithms is linear optics quantum computation (LOQC) [4,5], where information is encoded into single photons and the their wave properties are manipulated using linear optics elements. Photons are ideally suited to communication, leading naturally to models of distributed quantum computation.A key consideration in any distributed computation scheme is security. Consider two parties, Alice and Bob. Alice has some data to which she would like to apply a computation, whilst Bob has a quantum computer and an algorithm with which he can process the data. However both sides have proprietary knowledge. Alice wants to keep her data secret from others, and Bob wants to keep his algorithm secret. This is related to the problem of homomorphic encryption which allows data to be manipulated without decrypting, so Bob can perform a universal set of operations on Alice's data without ever learning Alice's input state. Universal classical homomorphic encryption was only first discovered in 2009 [6] and subsequently simplified [7]. Closely related is blind computing, where Alice possesses both the data and the algorithm, and Bob owns the computer [8][9][10], as is the quantum private queries protocol [11], which is used to query a database while keeping the query secret.In this paper we describe a technique for solving the above problem, and hence achieving a limited quantum homomorphic encryption using the Boson sampling and multi-walker quantum walk models for quantum computation.The Boson sampling model -A first protocol for universal LOQC was introduced by Knill, Laflamme & Milburn (KLM) [4]. While universal for quantum computation, their protocol is extremely demanding, requiring fast-feedforward and quantum memory, which are technologically challenging and well beyond the capabilities of present-day experiments. Since then numerous simplifications have been proposed, most notably approaches based on cluster states [12][13][14], which significantly reduce physical resource requirements. However they...

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Demonstration of Blind Quantum Computing

Cited by 405 publications

References 52 publications

Quantum computing on encrypted data

Quantum computing on encrypted data

Garbled Quantum Computation

Quantum Walks with Encrypted Data

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