Realizing Scalable Conditional Operations through Auxiliary Energy Levels
Abstract
In the noisy intermediate-scale quantum (NISQ) era, flexible quantum operations are essential for advancing large-scale quantum computing, as they enable shorter circuits that mitigate decoherence and reduce gate errors. However, the complex control of quantum interactions poses significant experimental challenges that limit scalability. Here, we propose a transition composite gate scheme based on transition pathway engineering, which digitally implements conditional operations with reduced complexity by leveraging auxiliary energy levels. Experimentally, we demonstrate the controlled-unitary (CU) family and its applications. In entangled state preparation, our CU gate reduces the circuit depth for three-qubit Greenberger-Horne-Zeilinger (GHZ) and W states by approximately 40-44% compared to circuits using only CZ gates, leading to fidelity improvements of 1.5% and 4.2%, respectively. Furthermore, with a 72% reduction in circuit depth, we successfully implement a quantum comparator-a fundamental building block for quantum algorithms requiring conditional logic, which has remained experimentally challenging due to its inherent circuit complexity. These results demonstrate the scalability and practicality of our scheme, laying a solid foundation for the implementation of large-scale quantum algorithms in future quantum processors.
Cite
@article{arxiv.2407.06687,
title = {Realizing Scalable Conditional Operations through Auxiliary Energy Levels},
author = {Sheng Zhang and Peng Duan and Yun-Jie Wang and Tian-Le Wang and Peng Wang and Ren-Ze Zhao and Xiao-Yan Yang and Ze-An Zhao and Liang-Liang Guo and Yong Chen and Hai-Feng Zhang and Lei Du and Hao-Ran Tao and Zhi-Fei Li and Yuan Wu and Zhi-Long Jia and Wei-Cheng Kong and Zhao-Yun Chen and Zhuo-Zhi Zhang and Xiang-Xiang Song and Yu-Chun Wu and Guo-Ping Guo},
journal= {arXiv preprint arXiv:2407.06687},
year = {2025}
}
Comments
16 pages, 13 figures