2022
DOI: 10.1007/s11128-022-03649-9
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Development of a multi-technology, template-based quantum circuits compilation toolchain

Abstract: With noisy intermediate scale quantum computers (NISQ) becoming larger in scale and more reliable, quantum circuits are growing in size and complexity. In order to face the challenge of achieving optimal circuits, design automation approaches for improving and mapping quantum circuits on different architectures have been proposed, each one characterized by a specific optimization strategy. In this article, the use of a template-based approach for quantum circuits optimization purposes is explored, and the prop… Show more

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Cited by 2 publications
(5 citation statements)
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“…Moreover, in an application-driven scenario where quantum computing is going to be employed for facing realworld problems, manual quantum algorithm optimisation is unfeasible. Hence, the input quantum circuit, described in OpenQASM 2.0 -standard de facto for quantum algorithms -, is handled by a technology-aware compilation utility that translates the abstract input description into one compliant with the target coupling graph and gate native set, carrying out a technology-inspired logic -proposed in a previous article [50] -and layout synthesis, trying, at the same time, to reduce the number of gates, by introducing some fine-grain technology-dependent optimisations. The re-sulting output is a quantum circuit built to work smoothly with the target device, tailored to properly optimise specific performance parameters.…”
Section: Classical Modelling Of Noisy Quantum Hardwarementioning
confidence: 99%
“…Moreover, in an application-driven scenario where quantum computing is going to be employed for facing realworld problems, manual quantum algorithm optimisation is unfeasible. Hence, the input quantum circuit, described in OpenQASM 2.0 -standard de facto for quantum algorithms -, is handled by a technology-aware compilation utility that translates the abstract input description into one compliant with the target coupling graph and gate native set, carrying out a technology-inspired logic -proposed in a previous article [50] -and layout synthesis, trying, at the same time, to reduce the number of gates, by introducing some fine-grain technology-dependent optimisations. The re-sulting output is a quantum circuit built to work smoothly with the target device, tailored to properly optimise specific performance parameters.…”
Section: Classical Modelling Of Noisy Quantum Hardwarementioning
confidence: 99%
“…The presented layout library was integrated into the compilation toolchain presented in ref. [6], which supports superconducting qubits (with IBMQ native gates), NMR and trapped ions and performs only the logic synthesis .…”
Section: Integration In the Avitabile Et Al Toolchainmentioning
confidence: 99%
“…In fact, the single‐qubit gates Rx,y,z(θ)$R_{x,y,z}(\theta )$ are supported by both technologies and the quantum dots exchange interaction and the NMR J‐coupling have an analogous unitary evolution, traceable back to Rzz(θ)$R_{zz}(\theta )$. [ 6,9,15 ]…”
Section: Integration In the Avitabile Et Al Toolchainmentioning
confidence: 99%
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