Patent ID: 11892742
Assignee: NATIONAL UNIVERSITY OF DEFENSE TECHNOLOGY
Field: Optics (Instruments)
Classification: CPC G | IPC G

Claim 0:
1. A method for calibrating controllable phase shifters in multi-stage staggered Mach-Zehnder interferometer on optical chip, comprising a step 1, a step 2, a step 3, a step 4, a step 5, a step 6, a step 7, a step 8, a step 9, a step 10, and a step 11, wherein:
the step 1: applying a calibration method with satisfactory conditions to calibrate the controllable phase shifters that satisfy three calibration conditions; turning to the step 2 if some controllable phase shifters do not satisfy the three calibration conditions; turning to step 11 if all controllable phase shifters satisfy the three calibration conditions;
the three calibration conditions comprise:
calibration condition A: Mach-Zehnder interferometer structure condition, namely, the controllable phase shifter to be calibrated is an inner phase shifter of a Mach-Zehnder interferometer;
calibration condition B: single-ended optical signal input condition, namely the Mach-Zehnder interferometer has only one input port with optical signal input, but no optical signal is input into another input port; and
calibration condition C: direct independent output measurement condition, namely, a magnitude strength of the optical signal is measurable from single optical output port of the Mach-Zehnder interferometer, wherein the Mach-Zehnder interferometer has two optical output ports, and the direct independent output measurement condition requires that the magnitude strength of the optical signal output from any port is measurable;

the step 2: selecting an inner phase shifter of basic units that is not calibrated and is closest to an output end of a multi-stage staggered Mach-Zehnder interferometer network and marking it as inner phase shifter i, and constituting the calibration condition C; setting all calibrated inner phase shifters of the basic units to be in a straight waveguide mode, namely a power supply inputs an electrical signal corresponding to a π phase of the inner phase shifters, so as to conform to the calibration condition C; each of the basic units is one Mach-Zehnder interferometer;
the step 3: verifying whether the inner phase shifter i conforms to the calibration condition B; if the calibration condition B is conformed , executing the step 5; if the calibration condition B is not conformed, turning to the step 4;
the step 4: constituting the calibration condition B for the inner phase shifter i; the step 4 comprises a step 4.1, a step 4.2, and a step 4.3, wherein:
the step 4.1: according to a transmission path of the optical signal in the optical network, selecting the later one of the basic units whose one output port is connected to one input port of the basic units with the inner phase shifter i and marking it as a basic unit f; selecting any one of the two basic units if the two basic units are passed simultaneously;
the step 4.2: adjusting the electrical signal input to an outer phase shifter of the basic unit f by the power supply, and finding and maintaining the electrical signal with the minimum power sum of the optical signals from two optical output ports of the basic units of the inner phase shifter i; and
the step 4.3: adjusting the electrical signal input to the inner phase shifters of the basic unit f by the power supply, and finding and maintaining the electrical signal with the minimum power sum of the optical signals from the two optical output ports of the basic units of the inner phase shifter i, which meets the calibration condition B for the inner phase shifter i;

the step 5: applying the calibration conditions met the calibration method with the satisfactory conditions to calibrate the inner phase shifter i;
the step 6: verifying whether the inner phase shifters of all basic units have been calibrated; if yes, executing the step 7; if not, returning to the step 2;
the step 7: selecting one outer phase shifter of the basic units that is not calibrated and marking it as outer phase shifter t, and constituting a larger Mach-Zehnder interferometer and marking it as constituted Mach-Zehnder interferometer m, resulting the outer phase shifter t becomes the inner phase shifter relative to the constituted Mach-Zehnder interferometer m, so as to conform to the calibration condition A;
constituting the larger Mach-Zehnder interferometer comprising:
selecting two basic units located in front and back of the outer phase shifter t according to an optical network structure, and setting the two basic units to be in a beamsplitter mode, namely, an electrical signal corresponding to the π/2 phase is input into electrical input ports of the inner phase shifters by the power supply;

the step 8: constituting the calibration conditions B and C for the outer phase shifter t, namely, basic units of all calibrated inner phase shifters except the Mach-Zehnder interferometer m are set to be in the straight waveguide mode;
the step 9: applying the calibration conditions met the calibration method with the satisfactory conditions to calibrate the outer phase shifter t;
the step 10: verifying whether the outer phase shifters of all basic units have been calibrated; if yes, turning to the step 11; if not, returning to the step 7; and
the step 11: ending.