集成光子储备池的可调谐光滤波器

Tunable optical filter with integrated photonic reservoir computing

  • 摘要: 为了适应滤波、波分复用等不同的应用场景,光子滤波器需要具备可调谐以及滤波形状可变的功能。提出一种集成光子储备池结构的新型可调谐光滤波器。该结构由输入层、储层、读出层三部分组成,输入层由2×1多模干涉仪组成,储层由定向耦合器以及波导组成,按螺旋拓扑规律相互连接组成梅花型网格,匹配粒子群寻优算法进行全光域训练,利用读出层的热光调制器和相移器对光信号的幅度和相位进行调整,实现无限冲激响应型与有限冲激响应型可调谐光滤波器。以无限冲激响应型光滤波器仿真结果为例,分析其自由光谱范围与储层中波导长度的关系,以及定向耦合器分光比对透射端透过率的影响。通过设置储层中波导的相位在0~3/2π范围内变化,实现了光滤波器中心波长在一个自由光谱范围(1.18 nm)内的连续可调。该滤波器采用集成光子储备池与粒子群算法结合方案设计,无需考虑储层光网络传输路径的权重配置,仅对读出层权重进行训练,大大简化了网络训练过程。同时,该滤波器具有尺寸小、功耗低、灵活性高、算法可控滤波参数的优势,广泛应用于集成微波光子学和光通信领域中。

     

    Abstract:
      Objective  A tunable optical filter is the key component in the optical communication systems and optical processing systems. By tuning the central wavelength, it can be used to choose a signal with arbitrary wavelength according to the practical requirement. However, due to the high loss and large size, optical filter based on discrete devices cannot meet the requirements of some photonic signal processor. Recently, based on Mach-Zehnder interferometers network and ring-assisted Mach-Zehnder interferometer, some research groups have proposed integrated optical filter. However, this type of optical filter has the disadvantages of being difficult to train and having a single waveform, which restricts its application in the fields of multi-purpose adaptive signal processing. For improving the flexibility of optical filter, a novel tunable optical filter with an integrated photonic reservoir computing (RC) is proposed. Since the filtering properties can be controlled by intelligence algorithm, this optical filter, which improves the flexibility in applications, can be widely applied in optical cross interconnection system and microwave photon signal shaping.
      Methods  Firstly, the structure of integrated photonic RC is constructed in detail, and scattering matrix theory is used to analyze the transmission function of integrated photonic RC. Then, the simulated transmission spectra of the reservoir are carried out by simulation software. Particle swarm optimization (PSO) algorithm is matched for training reservoir transmission spectra in optical domain to find optimal weights. Based on thermo-optical effects, optical weights are implemented by optical modulators (OMs). During training the weights in readout layer, OMs are used to adjust the amplitudes and phases of the optical signal. Using this integrated photonic RC chip, the infinite (IIR) and finite (FIR) impulse response optical filters are realized. Finally, by adjusting the parameters of waveguide (WG) and directional coupler (DC) in the reservoir, the filtering properties is studied.
      Results and Discussions   The achieved IIR and FIR optical filter waveform are almost exactly matched to the ideal waveform (Fig.5(a), Fig.6(a)). The error value of the training results decreases in a step-like trend with the increase of the number of iterations, and eventually tends to be stable (Fig.5(b), Fig.6(b)). Based on the IIR optical filter simulation results, the effect of the free spectral range (FSR) on the WG length is analyzed (Fig.8). The WG length is negatively correlated with the FSR. As the WG length increases, the corresponding FSR becomes smaller. In addition, the influence of the DC splitting ratio on the transmission power is analyzed (Fig.9). According to the actual needs, the adjustment of different filtering intensities is achieved by setting the splitting ratio of the even number of output nodes of the reservoir. Moreover, the filtering wavelength, which is influenced by the phase of the WG in the reservoir from 0 to 3/2π, is continuously adjustable in the FSR of 1.18 nm (Fig.10).
      Conclusions  In this study, a novel tunable optical filter basd on 12-node plum shaped integrated photonic RC chip is constructed. The PSO algorithm is used for training photonic RC weights to realize the IIR and FIR optical filters. The control of FSR is achieved by adjusting the length of the waveguide in the reservoir. Under the constant filter waveform, the filtering wavelength can be continuously tuned in the FSR by adjusting the phase of the WG in the reservoir (0-3π/2). The feasibility of this optical filter is verified by theory and simulation, and its tailorable performance can be used in multi-purpose adaptive signal processing application.

     

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