The small-world effect for interferometer networks

IF 2.6 Q1 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS Journal of Physics Complexity Pub Date : 2024-05-27 DOI:10.1088/2632-072x/ad4c45
Benjamin Krawciw, Lincoln D Carr and Cecilia Diniz Behn
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Abstract

Complex network theory has focused on properties of networks with real-valued edge weights. However, in signal transfer networks, such as those representing the transfer of light across an interferometer, complex-valued edge weights are needed to represent the manipulation of the signal in both magnitude and phase. These complex-valued edge weights introduce interference into the signal transfer, but it is unknown how such interference affects network properties such as small-worldness. To address this gap, we have introduced a small-world interferometer network model with complex-valued edge weights and generalized existing network measures to define the interferometric clustering coefficient, the apparent path length, and the interferometric small-world coefficient. Using high-performance computing resources, we generated a large set of small-world interferometers over a wide range of parameters in system size, nearest-neighbor count, and edge-weight phase and computed their interferometric network measures. We found that the interferometric small-world coefficient depends significantly on the amount of phase on complex-valued edge weights: for small edge-weight phases, constructive interference led to a higher interferometric small-world coefficient; while larger edge-weight phases induced destructive interference which led to a lower interferometric small-world coefficient. Thus, for the small-world interferometer model, interferometric measures are necessary to capture the effect of interference on signal transfer. This model is an example of the type of problem that necessitates interferometric measures, and applies to any wave-based network including quantum networks.
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干涉仪网络的小世界效应
复杂网络理论侧重于具有实值边缘权重的网络特性。然而,在信号传输网络中,如表示光在干涉仪上传输的网络,需要复值边缘权重来表示信号在幅度和相位上的操作。这些复值边缘权重在信号传输中引入了干扰,但这种干扰如何影响网络特性(如小世界性),目前还不得而知。为了填补这一空白,我们引入了一个具有复值边缘权重的小世界干涉仪网络模型,并对现有的网络测量方法进行了归纳,以定义干涉聚类系数、表观路径长度和干涉小世界系数。我们利用高性能计算资源,在系统规模、最近邻数和边缘权重相位等广泛参数范围内生成了大量小世界干涉仪,并计算了它们的干涉网络度量。我们发现,干涉小世界系数在很大程度上取决于复值边缘权重相位的大小:对于较小的边缘权重相位,建设性干扰会导致较高的干涉小世界系数;而较大的边缘权重相位会引起破坏性干扰,从而导致较低的干涉小世界系数。因此,对于小世界干涉仪模型,干涉测量是捕捉干涉对信号传输影响的必要手段。该模型是需要采用干涉测量的问题类型的一个例子,适用于包括量子网络在内的任何基于波的网络。
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来源期刊
Journal of Physics Complexity
Journal of Physics Complexity Computer Science-Information Systems
CiteScore
4.30
自引率
11.10%
发文量
45
审稿时长
14 weeks
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