利用单个单光子雪崩探测器进行数态重构

Patrick R. Banner, Deniz Kurdak, Yaxin Li, Alan Migdall, J. V. Porto, and S. L. Rolston
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引用次数: 0

摘要

单光子雪崩探测器(SPAD)是许多领域和应用的重要光传感器。然而,单光子雪崩探测器无法分辨光子数量,因此必须使用更复杂、更昂贵的实验装置或设备来测量脉冲中的光子数量。在这里,我们介绍一种仅用一个 SPAD 就能进行光子数态重建的方法。该方法采用最大似然技术,使用参数可测量的探测器模型,成本低廉,易于实施。我们实现了已知输入脉冲与相干态重构之间的极佳一致性,相干态光子数最高≈10,输入光子峰值速率最高可达数个 Mcounts/s。当探测器的缺陷较小时,我们能在输入光子峰值速率超过 40 Mcounts/s 的相干脉冲中保持良好的一致性,每探测器死区时间大于一个光子。对于反束光,g(2)(0) 的重建值和独立测量的脉冲平均值也是一致的。我们的算法适用于脉冲宽度和相关时间尺度都至少是几个探测器死区时间的光脉冲。这些结果是利用单个市售 SPAD 实现的,提供了一种廉价的数态重建方法,并扩展了单光子探测器的功能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Number-state reconstruction with a single single-photon avalanche detector
Single-photon avalanche detectors (SPADs) are crucial sensors of light for many fields and applications. However, they are not able to resolve photon number, so typically more complex and more expensive experimental setups or devices must be used to measure the number of photons in a pulse. Here, we present a methodology for performing photon number-state reconstruction with only one SPAD. The methodology, which is cost-effective and easy to implement, uses maximum-likelihood techniques with a detector model whose parameters are measurable. We achieve excellent agreement between known input pulses and their reconstructions for coherent states with up to ≈10 photons and peak input photon rates up to several Mcounts/s. When detector imperfections are small, we maintain good agreement for coherent pulses with peak input photon rates of over 40 Mcounts/s, greater than one photon per detector dead time. For anti-bunched light, the reconstructed and independently measured pulse-averaged values of g(2)(0) are also consistent with one another. Our algorithm is applicable to light pulses whose pulse width and correlation time scales are both at least a few detector dead times. These results, achieved with single commercially available SPADs, provide an inexpensive number-state reconstruction method and expand the capabilities of single-photon detectors.
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