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引用次数: 0
摘要
量子行走对开发量子算法和量子模拟有很大贡献。在这里,我们首次引入了d维量子域中的一维量子行走,其中\(d>2\),并展示了其在任意有限维量子逻辑中电路实现的等价性,以利用更大的状态空间优势,与传统的二进制量子系统相比,这有助于减少量子行走的运行时间。当有限维量子系统的维数为奇数时,我们提供了在一维位置空间中实现离散时间量子行走(DTQW)的高效量子电路,利用行走器在多量子态上演化的位置空间的适当逻辑映射。通过各种奇偶状态空间的示例电路,我们还探讨了 n 奇偶 d 偶量子系统的可扩展性。此外,我们还研究了在d维晶格上使用2d维硬币空间将一维DTQW扩展到d维DTQW,其中\(d\ge 2\).随后,我们描绘了在d-元量子系统中实现可扩展d维DTQW的电路设计。最后,我们展示了在各种搜索空间上使用不同硬币实现DTQW的电路设计。
Quantum walks contribute significantly to developing quantum algorithms and quantum simulations. Here, we introduce a first of its kind one-dimensional quantum walk in the d-dimensional quantum domain, where \(d>2\), and show its equivalence for circuit realization in an arbitrary finite-dimensional quantum logic for utilizing the advantage of larger state space, which helps to reduce the run-time of the quantum walks as compared to the conventional binary quantum systems. We provide efficient quantum circuits for the implementation of discrete-time quantum walks (DTQW) in one-dimensional position space in any finite-dimensional quantum system when the dimension is odd using an appropriate logical mapping of the position space on which a walker evolves onto the multi-qudit states. With example circuits for various qudit state spaces, we also explore scalability in terms of n-qudit d-ary quantum systems. Further, the extension of one-dimensional DTQW to d-dimensional DTQW using 2d-dimensional coin space on d-dimensional lattice has been studied, where \(d\ge 2\). Thereafter, the circuit design for the implementation of scalable d-dimensional DTQW in d-ary quantum systems has been portrayed. Lastly, we exhibit the circuit design for the implementation of DTQW using different coins on various search spaces.
期刊介绍:
The aims of this peer-reviewed online journal are to distribute and archive all relevant material required to document, assess, validate and reconstruct in detail the body of knowledge in the physical and related sciences.
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