Physical Constraints on Quantum Circuits

2017 IEEE International Conference on Rebooting Computing (ICRC) Pub Date : 2017-11-01 DOI:10.1109/ICRC.2017.8123663

P. Civalleri, F. Corinto, Á. Csurgay

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Abstract

The physical constraints underlying the concept of quantum circuit are considered. In particular it is shown that the point of departure for their modeling starts from the interconnection of the components into a classical network, followed by quantization of the latter, and not by the interconnection of already quantized components. The procedure is straightforward for lossless networks but cannot be worked out in presence of resistors for the impossibility of constructing a Lagrangian function. However the difficulty is circumvented by distinguishing thermal from radiative resistors, the former being the usual ones, the latter being realized by semi-infinite LC transmission lines, for which the Lagrangian exists. In the complex plane s = σ + jω the impedance of a thermal resistor is Z(s) = R in the entire plane while that of a radiative resistor is Rsign(σ), so that the latter is lossless and does not dissipate energy but conveys it to the infinity. Comparison with Lindblad approach shows that the resistor fits into it in the RHP. Radiative resistors make evolution reversible, which is not true for a physical system including thermal.

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量子电路的物理约束

考虑了量子电路概念的物理约束。特别指出的是，他们的建模的出发点是从组件的互连到一个经典网络，然后是后者的量化，而不是由已经量化的组件的互连。这一过程对于无损网络来说很简单，但由于不可能构造拉格朗日函数，在电阻存在的情况下无法计算。然而，通过区分热电阻和辐射电阻，可以避免困难，前者是通常的电阻，后者是通过半无限LC传输线实现的，其中存在拉格朗日量。在复平面s = σ + jω中，热敏电阻在整个平面上的阻抗为Z(s) = R，而辐射电阻的阻抗为Rsign(σ)，因此后者是无损的，不耗散能量，而是将能量传递到无穷远。与Lindblad方法的比较表明，该电阻适合于RHP。辐射电阻使演化可逆，这对包括热系统在内的物理系统是不成立的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2017 IEEE International Conference on Rebooting Computing (ICRC)

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