Fault-tolerant quantum computing with photonics

Despite the great interest that the scientific community has in quantum computing, the scarcity and high cost of resources prevent to advance in this field. Specifically, qubits are very expensive to build, causing the few available quantum computers are tremendously limited in their number of qubits and delaying their progress. This work presents new reversible circuits that optimize the necessary resources for the conversion of a sign binary number into two's complement of N digits. The benefits of our work are two: on the one hand, the proposed two's complement converters are fault tolerant circuits and also are more efficient in terms of resources (essentially, quantum cost, number of qubits, and T-count) than the described in the literature. On the other hand, valuable information about available converters and, what is more, quantum adders, is summarized in tables for interested researchers. The converters have been measured using robust metrics and have been compared with the state-of-the-art circuits. The code to build them in a real quantum computer is given.

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Fault-tolerant blind quantum computing using GHZ states over depolarization channel

Quantum Information Processing ◽

10.1007/s11128-021-03197-8 ◽

2021 ◽

Vol 20 (9) ◽

Author(s):

Xiaoqing Tan ◽

Hong Tao ◽

Xiaoqian Zhang ◽

Xiaodan Zeng ◽

Qingshan Xu

Keyword(s):

Quantum Computing ◽

Fault Tolerant ◽

Ghz States

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A silicon-based surface code quantum computer

npj Quantum Information ◽

10.1038/npjqi.2015.19 ◽

2016 ◽

Vol 2 (1) ◽

Cited By ~ 29

Author(s):

Joe O’Gorman ◽

Naomi H Nickerson ◽

Philipp Ross ◽

John JL Morton ◽

Simon C Benjamin

Keyword(s):

Quantum Computing ◽

Solid State ◽

Quantum Computer ◽

Fault Tolerant ◽

Device Fabrication ◽

Impurity Atoms ◽

Dipole Interactions ◽

Total Phase ◽

Surface Code ◽

Silicon Based

Abstract Individual impurity atoms in silicon can make superb individual qubits, but it remains an immense challenge to build a multi-qubit processor: there is a basic conflict between nanometre separation desired for qubit–qubit interactions and the much larger scales that would enable control and addressing in a manufacturable and fault-tolerant architecture. Here we resolve this conflict by establishing the feasibility of surface code quantum computing using solid-state spins, or ‘data qubits’, that are widely separated from one another. We use a second set of ‘probe’ spins that are mechanically separate from the data qubits and move in and out of their proximity. The spin dipole–dipole interactions give rise to phase shifts; measuring a probe’s total phase reveals the collective parity of the data qubits along the probe’s path. Using a protocol that balances the systematic errors due to imperfect device fabrication, our detailed simulations show that substantial misalignments can be handled within fault-tolerant operations. We conclude that this simple ‘orbital probe’ architecture overcomes many of the difficulties facing solid-state quantum computing, while minimising the complexity and offering qubit densities that are several orders of magnitude greater than other systems.

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Fault-Tolerant Quantum Error Correction and Fault-Tolerant Quantum Computing

Quantum Information Processing and Quantum Error Correction ◽

10.1016/b978-0-12-385491-9.00011-3 ◽

2012 ◽

pp. 405-456

Author(s):

Ivan Djordjevic

Keyword(s):

Quantum Computing ◽

Error Correction ◽

Fault Tolerant ◽

Quantum Error Correction ◽

Quantum Error

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Improved Resource State for Verifiable Blind Quantum Computation

Entropy ◽

10.3390/e22090996 ◽

2020 ◽

Vol 22 (9) ◽

pp. 996

Author(s):

Qingshan Xu ◽

Xiaoqing Tan ◽

Rui Huang

Keyword(s):

Quantum Computing ◽

Quantum Computation ◽

Fault Tolerant ◽

Maximal Degree ◽

Recent Advances ◽

Quantum Computations ◽

Blind Quantum Computation ◽

Computation Graph ◽

Resource State

Recent advances in theoretical and experimental quantum computing raise the problem of verifying the outcome of these quantum computations. The recent verification protocols using blind quantum computing are fruitful for addressing this problem. Unfortunately, all known schemes have relatively high overhead. Here we present a novel construction for the resource state of verifiable blind quantum computation. This approach achieves a better verifiability of 0.866 in the case of classical output. In addition, the number of required qubits is 2N+4cN, where N and c are the number of vertices and the maximal degree in the original computation graph, respectively. In other words, our overhead is less linear in the size of the computational scale. Finally, we utilize the method of repetition and fault-tolerant code to optimise the verifiability.

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