Abstract
In this paper, we use the inverse design method to design an optical interconnection system composed of wavelength demultiplexer and the same direction waveguide crossing on silicon-on-insulator (SOI) platform. A 2.4 μm × 3.6 μm wavelength demultiplexer with an input wavelength of 1.3–1.6 μm is designed. When the target wavelength of the device is 1.4 μm, the insertion loss of the output port is − 0.93 dB, and there is − 18.4 dB crosstalk, in TE0 mode. The insertion loss of the target wavelength of 1.6 μm in TE0 mode is − 0.88 dB, and the crosstalk is − 19.1 dB. Then, we designed a same direction waveguide crossing, the footprint is only 2.4 μm × 3.6 μm, the insertion loss of the wavelength 1.4 μm and 1.6 μm in TE0 mode is − 0.99 dB and − 1 dB, and the crosstalk is − 12.14 dB and − 14.34 dB, respectively. Finally, an optical interconnect structure composed of two devices is used, which can become the most basic component of the optical interconnect network. In TE0 mode, the insertion loss of the output wavelength of 1.4 μm at the output port is − 1.3 dB, and the crosstalk is − 29.36 dB. The insertion loss of the output wavelength of 1.6 μm is − 1.39 dB, and the crosstalk is − 38.99 dB.
Highlights
In this paper, we use the inverse design method to design an optical interconnection system composed of wavelength demultiplexer and the same direction waveguide crossing on silicon-on-insulator (SOI) platform
A wavelength demultiplexer for CWDM system is d esigned[25].The device experimentally displays low loss (− 2.3 dB), low crosstalk (− 16.4 dB), and broad 1-dB bandwidth (> 18 nm) with a compact size of 2.6 μm × 5 μm
They usually only discuss the input of the entire waveband and do not include waveguide crossing with different wavelengths that can be applied to the wavelength demultiplexer
Summary
We use the inverse design method to design an optical interconnection system composed of wavelength demultiplexer and the same direction waveguide crossing on silicon-on-insulator (SOI) platform. We designed a same direction waveguide crossing, the footprint is only 2.4 μm × 3.6 μm, the insertion loss of the wavelength 1.4 μm and 1.6 μm in TE0 mode is − 0.99 dB and − 1 dB, and the crosstalk is − 12.14 dB and − 14.34 dB, respectively. Regarding the above design ideas, we use the DBS algorithm to design a basic optical interconnection system that includes a wavelength demultiplexer and a waveguide crossing with different wavelengths in the same direction. The performance of the device is enhanced by adjusting the weight of the FOM and the discussion of the structural parameters It can reduce the insertion loss and crosstalk after the device is integrated, and lays the foundation for the realization of any wavelength routing optical interconnection network
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