Multimode waveguide crossing based on square Maxwell's fisheye lens

Mode-division multiplexing (MDM) is an emerging large-capacity data communication technology utilizing orthogonal guiding modes as independent data streams. One of the challenges of multimode waveguide routing in MDM systems is decreasing the mode leakage of waveguide crossings. In this article, a square Maxwell's fish-eye lens as waveguide crossing medium based on quasi-conformal transformation optics is designed and implemented on the silicon-on-insulator platform. Two approaches were taken to realize the designed lens: graded photonic crystal and varying the thickness of Si slab waveguide. Three-dimensional numerical simulations show that the designed multimode waveguide crossing has an ultrawide bandwidth from 1260 to 1675 nm with a compact footprint of only $3.77 \times 3.77 \mu m^2$. For the first three transverse electric modes $(TE_0, TE_1, \: and \: TE_2)$, the designed waveguide crossing exhibits an average insertion loss of 0.24, 0.55, and 0.45 dB and the crosstalk of less than -72, -61, and -27 dB, and a maximum return loss of 54, 53, and 30 dB, respectively. The designed waveguide crossing supports low distortion pulse transmission with a high fidelity factor of 0.9857. Furthermore, proposed method can be expanded to design waveguide crossings with even higher number of supporting modes by increasing the size of the lens.