Patent ID: 11888531
Assignee: BEIJING ZHONGKE GUOGUANG QUANTUM TECHNOLOGY CO., LTD.
Field: Telecommunications (Electrical engineering)
Classification: CPC H  G | IPC G  H

Claim 8:
9. A polarization independent differential quadrature phase shift keying (DQPSK) demodulation integrated optical chip, comprising: a first beam splitter, a first polarization beam splitter rotator, a second polarization beam splitter rotator, a third polarization beam splitter rotator, a fourth polarization beam splitter rotator, a first quarter-wave plate, a first delayed optical waveguide, and four 45° polarization rotation structures, all of which are integrated on a same substrate,
two output ports of the first beam splitter are respectively connected to one of two input ports of the first polarization beam splitter rotator and one of two input ports of the second polarization beam splitter rotator through a first optical waveguide and a second optical waveguide; two output ports of the first polarization beam splitter rotator are respectively connected to one of two input ports of the third polarization beam splitter rotator and one of two input ports of the fourth polarization beam splitter rotator through third optical waveguides provided with a 45° polarization rotation structure; two output ports of the second polarization beam splitter rotator are respectively connected to one of the two input ports of the third polarization beam splitter rotator and one of the two input ports of the fourth polarization beam splitter rotator through fourth optical waveguides provided with the 45° polarization rotation structure; two output ports of the third polarization beam splitter rotator are respectively connected to the fourth polarization beam splitter rotator through the first quarter-wave plate and the first delayed optical waveguide to form a delay polarization interferometer;
the first beam splitter is configured to split an input signal optical to generate a first signal optical component and a second signal optical component;
the first polarization beam splitter rotator is configured to perform a polarization beam splitting on the first signal optical component incident to one of the two input ports of the first polarization beam splitter rotator to generate a first polarization component and a second polarization component, both of which are transverse-electric (TE) polarized;
the second polarization beam splitter rotator is configured to perform the polarization beam splitting on the second signal optical component incident to one of the two input ports of the second polarization beam splitter rotator to generate a third polarization component and a fourth polarization component, both of which are TE polarized;
the 45° polarization rotation structure is configured to rotate polarization of an optical signal by 45°;
the delay polarization interferometer is configured to perform a polarization self-interference with TE polarization, in the delay polarization interferometer, on the first polarization component that is incident to one of the two input ports of the third polarization beam splitter rotator and is subjected to a 45° polarization rotation to generate a first interference component to be emitted from one of the two input ports of the fourth polarization beam splitter rotator; and to perform the polarization self-interference with TE polarization, in the delay polarization interferometer, on the first polarization component that is incident to one of the two input ports of the third polarization beam splitter rotator and is subjected to the 45° polarization rotation to generate a second interference component to be emitted from one of the two input ports of the fourth polarization beam splitter rotator;
the delay polarization interferometer is configured to perform a polarization self-interference with transverse-magnetic (TM) polarization, in the delay polarization interferometer on the first polarization component that is incident to one of the two input ports of the third polarization beam splitter rotator and is subjected to the 45° polarization rotation to generate a third interference component to be emitted from one of the two input ports of the fourth polarization beam splitter rotator; and to perform the polarization self-interference with TM polarization, in the delay polarization interferometer on the first polarization component that is incident to one of the two input ports of the third polarization beam splitter rotator and is subjected to the 45° polarization rotation to generate a fourth interference component to be emitted from one of the two input ports of the fourth polarization beam splitter rotator;
a main axis direction of the first quarter-wave plate has an angle of 0° with TE polarization, such that a phase of a TM polarized optical signal is increased by π/2, and a phase of a TE polarized optical signal remains unchanged when passing through the first quarter-wave plate;
the first delayed optical waveguide is configured to increase a delay of a passing optical signal by τ;
the first polarization beam splitter rotator is further configured to perform a polarization and beam combination on the first interference component subjected to the 45° polarization rotation and the second interference component subjected to the 45° polarization rotation so that horizontal polarizations of the first interference component and the second interference component simultaneously emit from one of the two input ports of the first polarization beam splitter rotator to generate a first interference optical signal, and so that vertical polarization components of the first interference component and the second interference component simultaneously emit from one of the two input ports of the first polarization beam splitter rotator to generate a second interference optical signal;
the second polarization beam splitter rotator is further configured to perform the polarization and beam combination on the third interference component subjected to the 45° polarization rotation and the fourth interference component subjected to the 45° polarization rotation so that horizontal polarizations of the third interference component and the fourth interference component simultaneously emit from one of the two input ports of the second polarization beam splitter rotator to generate a third interference optical signal, and such that vertical polarization components of the third interference component and the fourth interference component simultaneously emit from one of the two input ports of the second polarization beam splitter rotator to generate a fourth interference optical signal.