Quantum Error Correction Protects Quantum Search Algorithms Against Decoherence

Botsinis, Panagiotis; Babar, Zunaira; Alanis, Dimitrios; Chandra, Daryus; Nguyen, Hung Viet; Ng, Soon Xin; Hanzo, Lajos

doi:10.1038/srep38095

Cited by 31 publications

(24 citation statements)

References 49 publications

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“…The employment of QSCs for protecting the quantum circuits indeed increases the reliability of quantum computing, as shown in [61]. However, in order to avoid a perpetual encoding and decoding process throughout the quantum circuit before the number of errors exceeds the error correction capability of the QSC, we present a more efficient framework, where we encode the logical qubits at the input of the quantum circuit and decode them afterwards at the output of In the physical implementation of (a), we can imagine two layers of physical qubits, where on each layer the physical qubits are arranged over a lattice structure portrayed in Fig.…”

Section: B Design Formulationmentioning

confidence: 98%

“…However, for colour codes [34], which belong to the QTECCs family, they can also be classified further as the member of a more specific category of quantum CSS codes, namely, the dual-containing CSS codes. For dual-containing CSS codes, a specific technique can be invoked for creating the associated quantum encoder V. This method of generating the quantum encoder V of dual-containing CSS codes has been detailed in [10], [61]. It is important to note that upon using the method detailed in [10], [57]- [59], [61], the number of quantum gates required to construct a quantum encoder V for a QSC C is linearly proportional to the number of physical qubits [57], [58].…”

Section: Quantum Encodermentioning

confidence: 99%

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Quantum Topological Error Correction Codes are Capable of Improving the Performance of Clifford Gates

et al. 2019

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The employment of quantum error correction codes (QECCs) within quantum computers potentially offers a reliability improvement for both quantum computation and communications tasks. However, incorporating quantum gates for performing error correction potentially introduces more sources of quantum decoherence into the quantum computers. In this scenario, the primary challenge is to find the sufficient condition required by each of the quantum gates for beneficially employing QECCs in order to yield reliability improvements given that the quantum gates utilized by the QECCs also introduce quantum decoherence. In this treatise, we approach this problem by firstly presenting the general framework of protecting quantum gates by the amalgamation of the transversal configuration of quantum gates and quantum stabilizer codes (QSCs), which can be viewed as syndrome-based QECCs. Secondly, we provide examples of the advocated framework by invoking quantum topological error correction codes (QTECCs) for protecting both transversal Hadamard gates and CNOT gates. The simulation and analytical results explicitly show that by utilizing QTECCs, the fidelity of the quantum gates can be beneficially improved, provided that quantum gates satisfying a certain minimum depolarization fidelity threshold (F th) are available. For instance, for protecting transversal Hadamard gates, the minimum fidelity values required for each of the gates in order to attain fidelity improvements are 99.74%, 99.73%, 99.87%, and 99.86%, when they are protected by colour, rotated-surface, surface, and toric codes, respectively. These specific F th values are obtained for a very large number of physical qubits (n → ∞), when the quantum coding rate of the QTECCs approaches zero (r Q → 0). Ultimately, the framework advocated can be beneficially exploited for employing QSCs to protect large-scale quantum computers. INDEX TERMS Quantum error correction codes, quantum stabilizer codes, fault-tolerant, quantum topological codes, quantum gates.

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Section: B Design Formulationmentioning

confidence: 98%

Section: Quantum Encodermentioning

confidence: 99%

Quantum Topological Error Correction Codes are Capable of Improving the Performance of Clifford Gates

et al. 2019

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“…In fact, a quantum annealing chipset [14] is already commercially available from D-Wave 1 [15], [16]. Apart from the quantum annealing architecture, the so-called gate-based architecture [10], which relies on building computational blocks using quantum gates in a similar fashion to classical logic gates, is attracting increasing attention due to the recent advances in quantum stabilizer codes [17]- [22], which are capable of mitigating the decoherence 2 effects encountered by quantum circuits [9]. In terms of implementation, D-Wave's most recent model, namely D-Wave 2000Q 3 , has a total of 2000 qubits, while IBM Q Experience 4 , which relies on the gated-based architecture, has currently only 20 qubits in total.…”

Section: A Why Quantum Computing?mentioning

confidence: 99%

“…The channel envelope of each of the four paths may be deemed to fade independently. Assuming that the channel envelope at each path is quasi-static 22 during the channel estimation process, we may either estimate the four time-domain (TD) channel gains of the four paths, or the 512 frequency-domain (FD) subcarrier gains, which represent the Fast Fourier Transform (FFT) of the time-domain PDP, having taken the delay spread of the channel and the sampling frequency into consideration. Typically the FD channel is represented by the terminology of FD CHannel Transfer Function factor (FD-CHTF) [71].…”

Section: B Joint Channel Estimation and Data Detectionmentioning

confidence: 99%

Quantum Search Algorithms for Wireless Communications

Botsinis

Alanis

Babar

et al. 2019

IEEE Commun. Surv. Tutorials

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Faster, ultra-reliable, low-power and secure communications has always been high on the wireless evolutionary agenda. However, the appetite for faster, more reliable, greener and more secure communications continues to grow. The stateof-the-art methods conceived for achieving the performance targets of the associated processes may be accompanied by an increase in computational complexity. Alternatively, a degraded performance may have to be accepted due to the lack of jointly optimized system components. In this survey we investigate the employment of quantum computing for solving problems in wireless communication systems. By exploiting the inherent parallelism of quantum computing, quantum algorithms may be invoked for approaching the optimal performance of classical wireless processes, despite their reduced number of cost-function evaluations. In this contribution we discuss the basics of quantum computing using linear algebra, before presenting the operation of the major quantum algorithms, which have been proposed in the literature for improving wireless communications systems. Furthermore, we investigate a number of optimization problems encountered both in the physical and network layer of wireless communications, while comparing their classical and quantumassisted solutions. Finally, we state a number of open problems in wireless communications that may benefit from quantum computing.

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“…This has the drawback that unknown information cannot be encoded. However, encoding unknown information is necessary because in many practical schemes QECC decoding and re-encoding are applied mid-way through the computation, as demonstrated in [4].…”

mentioning

confidence: 99%

Mitigation of Decoherence-Induced Quantum-Bit Errors and Quantum-Gate Errors Using Steane’s Code

Cane

Chandra

et al. 2020

IEEE Access

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Quantum processors require Quantum Error Correction Codes (QECC's) for improving the fidelity of quantum logic gates. Fault tolerant QECC's are capable of providing error rate improvements in quantum processors as long as the components are operating below a certain gate error probability. In this contribution, we quantify the depolarization probability bound, below which transversal QECC's would give a better error probability than an uncoded gate. Both a low-complexity repetition code and Steane's 7-bit QECC are characterized. INDEX TERMS Fault tolerance, quantum error correction codes, quantum stabilizer codes, quantum gates.

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Quantum Error Correction Protects Quantum Search Algorithms Against Decoherence

Cited by 31 publications

References 49 publications

Quantum Topological Error Correction Codes are Capable of Improving the Performance of Clifford Gates

Quantum Topological Error Correction Codes are Capable of Improving the Performance of Clifford Gates

Quantum Search Algorithms for Wireless Communications

Mitigation of Decoherence-Induced Quantum-Bit Errors and Quantum-Gate Errors Using Steane’s Code

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