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摘要:
基于加权时延结构的微波光子滤波器同时利用了光学器件和射频器件的优势,具有可重构、低成本、大带宽的特性,在微波频段提供了灵活高效的信号处理能力。然而,由于加权时延结构的复杂性,系统中分立的光电器件均会对不同波长上的权重抽头产生干扰,如:光频率梳的包络和增益竞争、EDFA的增益不均匀性和非线性、调制器受限的滤波带宽。这些因素均会导致抽头的权重偏离理想值,从而导致微波滤波器的畸变。本文提出了一种端到端优化的方式,通过将微波光子滤波器作为一个黑盒系统,通过实时监控系统最后输出的光谱形状(即每个tap的权重值),计算并反馈波长的抽头分布与理想抽头之间的差值,用于实时调整波长整型器的滤波系数,使得输出的光谱权重始终保持在设计的状态。通过这种端到端优化的方法,我们实现了0.05 dB的光谱重构精度,并且完成了带外抑制比高达47 dB的射频低通滤波器。
Abstract:The microwave photonic filter based on weighted delay structure simultaneously leverages the advantages of photonic and radio-frequency components, featuring reconfigurability, low cost, and wide bandwidth, providing flexible and efficient signal processing capabilities in the microwave band. However, due to the complexity of the weighted delay structure, discrete optoelectronic components in the system can interfere with the weighted taps at different wavelengths—such as the envelope and gain competition of optical frequency combs, the gain non-uniformity and nonlinearity of EDFA, and the limited filtering bandwidth of modulators. These factors cause deviations in the weighted taps from their designed values, leading to distortion in the microwave filter. This paper proposes an end-to-end optimization approach by treating the microwave photonic filter as a black-box system. By monitoring the spectral shape (i.e., the weight values of each tap) of the final output in real time, the difference between the wavelength taps and the ideal taps is calculated and feedbacked to adjust the filtering coefficients of the waveshaper in real time, ensuring the output spectral weights remain in the designed state. Through this end-to-end optimization approach, we achieved a spectral reconstruction accuracy of 0.05dB and completed an RF low-pass filter with an out-of-band rejection ratio of up to 47dB.
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Key words:
- photonic RF filters /
- microwave photonics /
- mode-locked laser.
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图 1 (a) 半导体锁模激光器;(b) 锁模激光器的频率梳
Figure 1. (a) Customized semiconductor mode-locked laser; (b) The frequency comb of the mode-locked laser
图 2 光子射频滤波器的实验装置。EDFA:掺铒光纤放大器。EOM:电光调制器。SMF:单模光纤。WSS:波长选择开关PD:光电探测器。VNA:矢量网络分析仪。OSA:光谱分析仪。
Figure 2. Experimental setup of the photonic RF filter. EDFA: erbium-doped fiber amplifier. EOM: Electro-optic modulator. SMF: single-mode fiber. WSS: wavelength selective switch PD: photodetector. VNA: vector network analyzer. OSA: optical spectrum analyzer.
图 3 (a) 经过一次迭代优化的光谱;(2)经过四次迭代优化的光谱
Figure 3. (a) Spectrum optimized through one iteration; (2) Spectrum optimized through four iterations
图 4 对应于不同抽头数的形状梳的光谱。(a)10个抽头;(b)16个抽头;(c)36个抽头;(d)72个抽头;
Figure 4. Optical spectra of the shaped comb corresponding to different tap numbers. (a) 10 taps; (b) 16 taps; (c) 36 taps; (d) 72 taps;
图 5 具有不同抽头数的sinc型光子射频滤波器
Figure 5. Sinc-style photonic RF filters with different tap numbers.
图 6 高斯切趾sinc滤波器对应的光谱. (a) σ=5, (a) σ=15, (a) σ=25, (a) σ=35.
Figure 6. Optical spectra of the Gaussian-apodized sinc filter. (a) σ=5, (a) σ=15, (a) σ=25, (a) σ=35.
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