Phase Errors in mid-IR Arrayed Waveguide Gratings based on graded index SiGe-Si technology

In this paper, we present a method for analysis of phase errors and power truncation in SiGe/Si graded index arrayed waveguide gratings (AWGs) operating in mid-infrared spectral range. Semi-analytical model used herein is based on Gaussian approximation of the modal field and Fourier Optics. This method is applied to study the correlation between crosstalk level, effective index deviation in array waveguides and power truncation in 3.4 micrometer, 4.5 micrometer, 5.7 micrometer and 7.6 micrometer central wavelength AWGs. We show that the impact of effective index variation is more critical for AWGs with smaller operational wavelengths and power truncation should not exceed 5% for these types of devices. In conclusion, we refer to experimental data of 4.5 {\mu}m, 5.7 {\mu}m and 7.6 {\mu}m central wavelength AWGs where a cross talk level of 24 dB is obtained, corresponding to relative errors of effective indices and equivalent path length deviations respectively lower than 2 10-5 and of 0.2 micrometer in 10 mm length of the devices.