High-performance 2D 1xN T-junction Wavelength (De)Multiplexer Systems by Inverse Design
Yusuf A. Yilmaz, Ahmet M. Alpkilic, Aydan Yeltik, Hamza Kurt

TL;DR
This paper introduces a novel inverse design method for creating high-performance, compact 2D 1xN wavelength demultiplexers with small footprints, high efficiency, and low crosstalk, surpassing traditional design approaches.
Contribution
It presents an inverse design algorithm for 2D 1xN wavelength demultiplexers, enabling more compact and efficient devices with multiple functionalities and improved fabrication considerations.
Findings
Achieved high transmission efficiency with minimal crosstalk in 1x2, 1x4, and 1x6 demultiplexers.
Designed devices with footprints as small as 2.80 μm x 2.80 μm.
Demonstrated the potential for more than six output channels using inverse design.
Abstract
Previously proposed designs of integrated photonic devices have used the intuitive brute force approach or optimization methods that employ parameter search algorithms. However, a small parameter space and poor exploitation of the underlying physics have limited device performance, functionality, and footprint. In this paper, we propose efficient and compact 2D 1xN in-plane-incidence wavelength demultiplexers by using recently developed objective-first inverse design algorithm. Output ports in the presented 1xN photonic devices are located along the transverse to the input channel. Ultra-high device performance was achieved for the specific designs of 1x2, 1x4, and 1x6 wavelength (de)multiplexers with small footprints 2.80 um x 2.80 um, 2.80 um x 4.60 um, 2.80 um x 6.95 um, respectively. We used two approaches to binarization-level-set and binarization-cost-to obtain silicon wavelength…
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Taxonomy
TopicsPhotonic and Optical Devices · Optical Network Technologies · Advanced Photonic Communication Systems
