Building an ideal microwave photonic bandstop filter

Spie Newsroom Pub Date : 2017-05-12 DOI:10.1117/2.1201702.006836

D. Marpaung

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Abstract

Radio-frequency (RF) filtering, an important signal-processing function in wireless communications, is used to separate an information signal from unwanted noise and interference. Traditionally, sharp and high-extinction electronic filters operating at a fixed central frequency are used to remove interference. This approach severely limits the flexibility of the system, however. In modern software-defined radios, where wireless systems are expected to share the RF spectrum, high-quality filters that are tunable over a wide frequency range are desired.1 These filters must meet a number of requirements, including wide-frequency tuning, high resolution, high suppression, and low insertion loss. Achieving all of these requirements with electronic filters is extremely difficult, however, as a result of their performance degradation when tuned over a large bandwidth. Microwave photonic (MWP) filters,2–4 a technology that uses a tunable optical filter to select RF signals that are modulated onto an optical carrier, represent an alternative approach that can readily achieve frequency tuning of tens of gigahertz with no performance loss. These filters face their own challenges, however. For one, their resolution is on the order of a few GHz, which is at least two orders of magnitude lower than that required for RF signal processing. Additionally, they suffer from trade-offs between resolution and filter suppression. Because of the losses that are associated with optical modulation and detection processes, MWP filters also suffer from a high insertion loss that can be prohibitive for real-world applications. Finding solutions to these challenges will lead to a unique signal-processing technology with wide-ranging applications, from wireless communications to radar and radio astronomy. In our work,5 we have focused on the development of MWP bandstop filters with all-optimized performance. These filters are free from any tradeoffs, and as a result, their tuning range, resolution, suppression, Figure 1. Conceptual steps toward building an ideal microwave photonic (MWP) bandstop filter based on stimulated Brillouin scattering (SBS).

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构建理想的微波光子带阻滤波器

射频滤波是无线通信中一项重要的信号处理功能，用于将信息信号从不需要的噪声和干扰中分离出来。传统上，锐利和高消光电子滤波器工作在一个固定的中心频率被用来消除干扰。然而，这种方法严重限制了系统的灵活性。在现代软件定义无线电中，无线系统希望共享射频频谱，因此需要在宽频率范围内可调谐的高质量滤波器这些滤波器必须满足许多要求，包括宽频调谐、高分辨率、高抑制和低插入损耗。然而，通过电子滤波器实现所有这些要求是非常困难的，因为在大带宽上调谐时它们的性能会下降。微波光子(MWP)滤波器是一种使用可调谐光滤波器选择调制到光载波上的射频信号的技术，它代表了一种替代方法，可以很容易地实现几十千兆赫的频率调谐而不会造成性能损失。然而，这些过滤器也面临着自己的挑战。首先，它们的分辨率在几GHz的数量级上，这比射频信号处理所需的分辨率至少低两个数量级。此外，它们还需要在分辨率和滤波器抑制之间进行权衡。由于与光调制和检测过程相关的损耗，MWP滤波器还遭受高插入损耗的影响，这在实际应用中可能是令人望而却步的。寻找这些挑战的解决方案将导致一种独特的信号处理技术，具有广泛的应用，从无线通信到雷达和射电天文学。在我们的工作中，5我们专注于开发具有全优化性能的MWP带阻滤波器。这些滤波器没有任何权衡，因此，它们的调谐范围、分辨率、抑制，如图1所示。基于受激布里渊散射(SBS)构建理想微波光子带阻滤波器的概念步骤。

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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