US 12,068,778 B2
On-chip wavefront sensor, optical chip, and communication device
Shupeng Deng, Shenzhen (CN); Caiming Sun, Shenzhen (CN); Weiwei Liu, Shenzhen (CN); and Aidong Zhang, Shenzhen (CN)
Assigned to PENG CHENG LABORATORY, Shenzhen (CN)
Appl. No. 18/278,250
Filed by PENG CHENG LABORATORY, Shenzhen (CN)
PCT Filed Jun. 28, 2021, PCT No. PCT/CN2021/102734
§ 371(c)(1), (2) Date Aug. 22, 2023,
PCT Pub. No. WO2022/179019, PCT Pub. Date Sep. 1, 2022.
Claims priority of application No. 202110202688.1 (CN), filed on Feb. 23, 2021.
Prior Publication US 2024/0039628 A1, Feb. 1, 2024
Int. Cl. H04B 10/079 (2013.01); G01J 9/00 (2006.01)
CPC H04B 10/0795 (2013.01) [G01J 2009/002 (2013.01)] 5 Claims
OG exemplary drawing
 
1. An on-chip wavefront sensor, comprising: an antenna array, a reference light source module, a phase shifter array, and an optical detection module, wherein an output end of the antenna array is connected to an input end of the optical detection module, an output end of the reference light source module is connected to an input end of the phase shifter array, and an output end of the phase shifter array is connected to another input end of the optical detection module;
the antenna array comprises a plurality of antenna units, wherein the antenna units are respectively configured for separating received spatial light to obtain a plurality of sub-light spots and outputting the sub-light spots to the optical detection module;
the reference light source module is configured for generating a plurality of intrinsic light beams and outputting the intrinsic light beams to the phase shifter array;
the phase shifter array comprises a plurality of phase shifters, wherein the phase shifters are respectively configured for performing phase shifting processing on the intrinsic light beams to obtain reference light and outputting the reference light to the optical detection module;
the optical detection module is configured for performing coherent balanced detection according to the reference light and the sub-light spots to obtain a photocurrent corresponding to each of the sub-light spots;
the optical detection module comprises a beam combiner array and a plurality of photoelectric detectors; the beam combiner array comprises a plurality of beam combiners, one input end of each of the plurality of beam combiners is connected to an output end of a respective one of the plurality of phase shifters, another input end of each of the plurality of beam combiners is connected to an output end of a respective one of the plurality of antenna units, and an output end of each of the plurality of beam combiners is connected to an input end of a respective one of the plurality of photoelectric detectors;
each of the plurality of beam combiners is configured for combining the reference light and a respective one of the plurality of sub-light spots to obtain combined light and outputting the combined light to a respective one of the plurality of photoelectric detectors;
each of the plurality of photoelectric detectors is configured for converting the combined light into a photocurrent;
the optical detection module is further configured for outputting the photocurrent to a processor, so that the processor obtains phase distortion and intensity distribution information of an incident wavefront according to the photocurrent.