Scalable and reconfigurable true time delay line based on an ultra-low-loss silica waveguide.

Abstract

A scalable and reconfigurable on-chip optical true time delay line consisting of Mach-Zehnder interferometer (MZI) switches and delay waveguides is proposed and demonstrated with the ultra-low-loss silica waveguide platform. The MZI switches provide the reconfiguration of the light traveling paths and hence different delays. Our proposed structure can be easily scaled to an M bit delay line with a slight increase in dimensions. The footprint of our fabricated 1bit delay line is 33 mm×13 mm (length×width) and can provide a delay of 6.0ps with an insertion loss of 1.2dB at the operating wavelength of 1550nm, while the footprint of the 4bit delay line is 43 mm×14 mm and can provide a discrete delay tuning from 6.0 to 90.2ps with a delay deviation lower than 0.2ps and a tuning response time of 0.84ms. The insertion losses are lower than ∼2.34 dB, and the extinction ratios are greater than 20.42dB. The average switching power is ∼132.6 mW. Our proposed optical true time delay lines could find applications for optical beamforming in phased array antennas.