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引用次数: 14
摘要
当在经典计算机上执行时,量子电路的模拟通常是一个指数级的工作。基于硬件描述语言的方法能够隔离作为仿真复杂性来源的纠缠。然而,研究表明,这种方法在存在总纠缠的情况下并不有效,而且这种情况的概率随着量子比特的数量呈指数增长[M. Udrescu, L. Prodan, M. Vladutiu(2004)]。气泡位技术旨在避免量子态的纠缠表示,从而允许对量子电路进行HDL结构描述,这需要多项式资源进行模拟。我们提供了通过模拟量子算法和Grover算法电路获得的实验运行时间,表明运行速度有很大的提高。
The bubble bit technique as improvement of HDL-based quantum circuits simulation
When performed on a classical computer, the simulation of quantum circuits is usually an exponential job. The methodology based on Hardware Description Languages is able to isolate the entanglement as source of simulation complexity. However, it was shown that this methodology is not efficient in the presence of total entanglement, and the probability of such a situation grows exponentially with the number of qubits [ M. Udrescu, L. Prodan, M Vladutiu (2004) ]. The bubble bit technique is designed to avoid the entangled representation of the quantum state, thus allowing the HDL structural description of the quantum circuit, which requires polynomial resources for simulation. We provide experimental runtimes, obtained by simulation of quantum arithmetic and Grover's algorithm circuits, which indicate substantial runtime speedup.
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