Your search keyword '"Li, Quanxi"' showing total 3 results

1. CODAR: A Contextual Duration-Aware Qubit Mapping for Various NISQ Devices

Author

Deng, Haowei, Zhang, Yu, and Li, Quanxi

Subjects

Quantum Physics

Abstract

Quantum computing devices in the NISQ era share common features and challenges like limited connectivity between qubits. Since two-qubit gates are allowed on limited qubit pairs, quantum compilers must transform original quantum programs to fit the hardware constraints. Previous works on qubit mapping assume different gates have the same execution duration, which limits them to explore the parallelism from the program. To address this drawback, we propose a Multi-architecture Adaptive Quantum Abstract Machine (maQAM) and a COntext-sensitive and Duration-Aware Remapping algorithm (CODAR). The CODAR remapper is aware of gate duration difference and program context, enabling it to extract more parallelism from programs and speed up the quantum programs by 1.23 in simulation on average in different architectures and maintain the fidelity of circuits when running on Origin Quantum noisy simulator., Comment: arXiv admin note: substantial text overlap with arXiv:2001.06887

Published

2020

2. Context-Sensitive and Duration-Aware Qubit Mapping for Various NISQ Devices

Author

Zhang, Yu, Deng, Haowei, and Li, Quanxi

Subjects

Quantum Physics, Computer Science - Emerging Technologies

Abstract

Quantum computing (QC) technologies have reached a second renaissance in the last decade. Some fully programmable QC devices have been built based on superconducting or ion trap technologies. Although different quantum technologies have their own parameter indicators, QC devices in the NISQ era share common features and challenges such as limited qubits and connectivity, short coherence time and high gate error rates. Quantum programs written by programmers could hardly run on real hardware directly since two-qubit gates are usually allowed on few pairs of qubits. Therefore, quantum computing compilers must resolve the mapping problem and transform original programs to fit the hardware limitation. To address the issues mentioned above, we summarize different quantum technologies and abstractly define Quantum Abstract Machine (QAM); then propose a COntext-sensitive and Duration-Aware Remapping algorithm (Codar) based on the QAM. By introducing lock for each qubit, Codar is aware of gate duration difference and program context, which bring it abilities to extract more program's parallelism and reduce program execution time. Compared to the best-known algorithm, Codar halves the total execution time of several quantum algorithms and cut down 17.5% - 19.4% total execution time on average in different architectures., Comment: 9 pages,5 figures, 2 tables. This is the extended abstract of the talk accepted by the First International Workshop on Programming Languages for Quantum Computing (PLanQC 2020), Jan 19, 2020, New Orleans, Louisiana, USA. (https://popl20.sigplan.org/home/planqc-2020#program)

Published

2020

3. Optimizing Quantum Programs against Decoherence: Delaying Qubits into Quantum Superposition

Author

Zhang, Yu, Deng, Haowei, Li, Quanxi, Song, Haoze, and Nie, Leihai

Subjects

Quantum Physics, Computer Science - Programming Languages

Abstract

Quantum computing technology has reached a second renaissance in the last decade. However, in the NISQ era pointed out by John Preskill in 2018, quantum noise and decoherence, which affect the accuracy and execution effect of quantum programs, cannot be ignored and corrected by the near future NISQ computers. In order to let users more easily write quantum programs, the compiler and runtime system should consider underlying quantum hardware features such as decoherence. To address the challenges posed by decoherence, in this paper, we propose and prototype QLifeReducer to minimize the qubit lifetime in the input OpenQASM program by delaying qubits into quantum superposition. QLifeReducer includes three core modules, i.e.,the parser, parallelism analyzer and transformer. It introduces the layered bundle format to express the quantum program, where a set of parallelizable quantum operations is packaged into a bundle. We evaluate quantum programs before and after transformed by QLifeReducer on both real IBM Q 5 Tenerife and the self-developed simulator. The experimental results show that QLifeReducer reduces the error rate of a quantum program when executed on IBMQ 5 Tenerife by 11%; and can reduce the longest qubit lifetime as well as average qubit lifetime by more than 20% on most quantum workloads., Comment: To appear in TASE2019 - the 13th International Symposium on Theoretical Aspects of Software Engineering (submitted on Jan 25, 2019, and this is camera-ready version)

Published

2019