Practical computational advantage from the quantum switch on a generalized family of promise problems

Jorge, Escandón-Monardes,; Delgado, A.; Walborn, S. P.

doi:10.22331/q-2023-03-09-945

Cited by 3 publications

(1 citation statement)

References 52 publications

(94 reference statements)

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“…The exploration of quantum switches and their role in entanglement phenomena are of remarkable relevance for quantum information processing 30 , 31 . The examples discussed in this context, particularly focusing on the force estimation, the creation of nonclassical states of microwave radiation, and the establishment of entanglement between NEMS, TLR and qubit, highlight the potential of quantum switches in manipulating quantum states for various applications.…”

Section: Discussionmentioning

confidence: 99%

Signal, detection and estimation using a hybrid quantum circuit

de Sá Neto,

de Oliveira

2024

Sci Rep

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We investigate a hybrid device allowing a photon–phonon coupling of a transmission line radiation (TLR) and a nanoeletromechanical system (NEMS), mediated by a superconducting qubit population imbalance. We demonstrate the derivation of an effective Hamiltonian for the strongly dispersive regime for this system. The qubit works as a quantum switch, allowing a conditioned transfer of excitations between the TLR and NEMS. We show that this regime allows the system to be employed for signal processing and force estimation. Additionally, we explore the ability of the quantum switch to generate non-classical states.

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Section: Discussionmentioning

confidence: 99%

Signal, detection and estimation using a hybrid quantum circuit

de Sá Neto,

de Oliveira

2024

Sci Rep

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Quantum‐Neural Network Model for Platform Independent Ddos Attack Classification in Cyber Security

Küçükkara,

Atban,

Bayılmış

2024

Adv Quantum Tech

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Quantum Machine Learning (QML) leverages the transformative power of quantum computing to explore a broad range of applications, including optimization, data analysis, and complex problem‐solving. Central to this study is the using of an innovative intrusion detection system leveraging QML models, with a preference for Quantum Neural Network (QNN) architectures for classification tasks. The inherent advantages of QNNs, notably their parallel processing capabilities facilitated by quantum computers and the exploitation of quantum superposition and parallelism, are elucidated. These attributes empower QNNs to execute certain classification tasks expediently and with heightened efficiency. Empirical validation is conducted through the deployment and testing of a QNN‐based intrusion detection system, employing a subset of the CIC‐DDoS 2019 dataset. Notably, despite employing a reduced feature set, the QNN‐based system exhibits remarkable classification accuracy, achieving a commendable rate of 92.63%. Moreover, the study advocates for the utilization of quantum computing libraries such as Qiskit, facilitating QNN training on local machines or quantum simulators. The findings underscore the efficacy of a QNN‐based intrusion detection system in attaining superior classification accuracy when confronted with large‐scale training datasets. However, it is imperative to acknowledge the constraints imposed by the limited number of qubits available on local machines and simulators.

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Experimentally Demonstrating Indefinite Causal Order Algorithms to Solve the Generalized Deutsch's Problem

Liu,

Meng,

Song

et al. 2024

Adv Quantum Tech

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Deutsch's algorithm is the first quantum algorithm to demonstrate an advantage over classical algorithms. Here, Deutsch's problem is generalized to functions and a quantum algorithm with an indefinite causal order is proposed to solve this problem. The algorithm not only reduces the number of queries to the black box by half compared to the classical algorithm, but also significantly decreases the complexity of the quantum circuit and the number of required quantum gates compared to the generalized Deutsch's algorithm. The algorithm is experimentally demonstrated in a stable Sagnac loop interferometer with a common path, which overcomes the obstacles of both phase instability and low fidelity of the Mach–Zehnder interferometer. The experimental results show both ultrahigh and robust success probabilities . This study opens a path toward solving practical problems with indefinite cause‐order quantum circuits.

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Practical computational advantage from the quantum switch on a generalized family of promise problems

Cited by 3 publications

References 52 publications

Signal, detection and estimation using a hybrid quantum circuit

Signal, detection and estimation using a hybrid quantum circuit

Quantum‐Neural Network Model for Platform Independent Ddos Attack Classification in Cyber Security

Experimentally Demonstrating Indefinite Causal Order Algorithms to Solve the Generalized Deutsch's Problem

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