Method for increasing coupling efficiency between telescope and optical fiber

Abstract

In a ground station that receives light from satellites, the coupling efficiency between a telescope and an optical fiber or an optical communication sensor is increased.　Light emitted from an optical transmitter 41 passes through a telescope 11, is reflected by an optical reflection unit 43, and enters and is received by a tracking camera 21 via a first optical system 23. A drive control unit 31 controls a second optical system 27 so that the light reflected by the optical reflection unit 43 is incident on the center of a sensor unit 25 while continuing to control the first optical system 23 so that the light received by the tracking camera 21 is located at the lens center. While maintaining the control of the second optical system 27, the drive control unit 31 causes the telescope 11 to perform an operation that simulates orbit tracking. On the basis of the attitude of the telescope 11 and the light reception position in the sensor unit during the orbit tracking step, the drive control unit 31 obtains drive control information for controlling one or more of the first optical system 23, the second optical system 27, and the attitude of the telescope 11.

Description

Method for improving the coupling efficiency between a telescope and an optical fiber 【0001】 This invention relates to a method for improving the coupling efficiency between a telescope and an optical fiber, etc. 【0002】 In recent years, communication services via satellite constellations have been booming. On the other hand, due to the limited RF frequency resources, attention has been focused on optical communication technologies between satellites and the ground for future increases in communication capacity. Furthermore, in order to achieve the globalization of information-theoretically secure key sharing, the satellite-mounted quantum key distribution device is expected. 【0003】 The technology of mounting a quantum key distribution (QKD) device on a satellite is already known. For example, Japanese Patent Application Laid-Open No. 2022-535712 describes a system and method for quantum key distribution via a hybrid quantum channel. Japanese Patent Application Laid-Open No. 2024-505095 describes a QKD exchange system and protocol. 【0004】 In quantum key distribution, the average number of photons per pulse of the emitted light is determined, and it is a very weak optical signal. However, when considering the downlink to the ground, a system using a wavelength band that is safe for human eyes is expected. However, the wavelength of 1.5 μm in the eye-safe wavelength band is longer than visible light, and in principle, it is more difficult to collect light than visible light. On the other hand, in order to improve quantum key distribution and normal optical communication performance, it is necessary to reduce the communication path loss as much as possible. In the terrestrial system, an optical system using a telescope is required. That is, the problem is how to improve the coupling efficiency between a telescope system and an optical fiber (for example, a single-mode fiber) or an optical communication sensor used in high-speed optical communication. 【0005】 Japanese Patent Application Laid-Open No. 2022-535712 Japanese Patent Application Laid-Open No. 2024-505095 【0006】 Therefore, a method for improving the coupling efficiency between a telescope and an optical fiber or an optical communication sensor is desired. In particular, in a quantum key distribution system, in a ground station having a satellite and a telescope that receives light from the satellite, a method for improving the coupling efficiency between the telescope and the optical fiber is desired. 【0007】 This method is based on the findings from past implementations, which show that by performing a simulated operation that tracks the satellite's orbit, measuring the alignment deviation of the ground station's optical system, predicting the actual deviation during satellite tracking, and then preparing an optical system with an offset adjustment for that deviation, the coupling efficiency between the telescope and the optical fiber or optical communication sensor can be improved. 【0008】 The first invention relates to a method for improving the coupling efficiency between a telescope 11 and an optical fiber 13 or optical communication sensor in an optical circuit section 17 for an optical ground station 15 that transmits an optical signal received by a telescope 11 to an optical fiber 13 or an optical communication sensor. 【0009】 The optical circuit unit 17 includes a tracking camera 21, a first optical system 23, a sensor unit 25, a second optical system 27, an optical coupling unit 29, and a drive control unit 31. The tracking camera 21 is an element for receiving at least a portion of the light output from the telescope 11. The first optical system 23 is an element for guiding the light output from the telescope 11 to the tracking camera 21. The sensor unit 25 is an element for receiving at least a portion of the light output from the telescope 11. The second optical system 27 is an element for guiding the light output from the telescope 11 to the sensor unit 25. The optical coupling unit 29 is an element for optically coupling the telescope 11 with an optical fiber 13 or an optical communication sensor. The drive control unit 31 is an element for controlling the attitude of the first optical system 23, the second optical system 27, and the telescope 11. 【0010】The above method includes the following steps: Install an optical transmitter 41 to output light to the optical coupling unit 29. Install an optical reflector 43 to reflect the light emitted from the optical transmitter 41, through the optical circuit unit 17, and through the telescope 11. Emit light from the optical transmitter 41. The light emitted from the optical transmitter 41 passes through the optical circuit unit 17, through the telescope 11, is reflected by the optical reflector 43, enters the tracking camera 21 via the first optical system 23, and is received by the tracking camera 21. The drive control unit 31 controls the first optical system 23 so that the light received by the tracking camera 21 is centered on the lens of the tracking camera 21 (first control step). While maintaining the control state of the first optical system 23 in the first control step, the drive control unit 31 controls the second optical system 27 so that the light reflected by the optical reflector 43 enters the center of the sensor unit 25 (second control step). The drive control unit 31 maintains the control state of the second optical system 27 in the second control step and causes the telescope 11 to perform an operation that simulates orbit tracking (orbit tracking step). In the orbit tracking step, the drive control unit 31 stores the light reception position at the sensor unit for the light observed by the sensor unit 25 (light position storage step). The drive control unit 31 stores the relationship between the attitude of the telescope 11 in the orbit tracking step and the light reception position at the sensor unit (telescope attitude and light reception position storage step). Using the attitude of the telescope 11 in the orbit tracking step and the light reception position at the sensor unit, drive control information is obtained to control one or more of the first optical system 23, the second optical system 27, and the attitude of the telescope 11 (drive control information acquisition step). 【0011】 This invention provides a method for improving the coupling efficiency between a telescope and an optical fiber or optical communication sensor. In particular, in a quantum key distribution system, this invention provides a method for improving the coupling efficiency between a telescope and an optical fiber or optical communication sensor in a ground station having a satellite and a telescope that receives light from the satellite. 【0012】Figure 1 is a conceptual diagram illustrating an example of the relationship between a satellite, a ground station, and a receiver. Figure 2 is a block diagram illustrating the optical circuit section of an optical ground station. Figure 3 is a block diagram illustrating an example configuration of an alignment adjustment system. Figure 4 is a conceptual diagram illustrating an example of a system in an embodiment. Figure 5 is a block diagram illustrating the alignment adjustment system used in the embodiment. 【0013】 This invention relates to a method for improving the coupling efficiency between a telescope and an optical fiber or optical communication sensor. One example of the application of this invention is satellite-based quantum key distribution (QKD), in which the coupling efficiency between a telescope and an optical fiber (especially a single-mode fiber) can be effectively improved. Therefore, the method for improving the coupling efficiency between a telescope and an optical fiber or optical communication sensor will be described below, using satellite-based quantum key distribution as an example. 【0014】 Figure 1 is a conceptual diagram illustrating an example of the relationship between a satellite, a ground station, and a receiver. In the example shown in Figure 1, the optical ground station 15 receives an optical signal from satellite 3, analyzes the received optical signal as appropriate, and communicates with the receiver 7. Satellite 3 is an element that communicates with the optical ground station 15 while moving according to a predetermined orbit. Satellite communication itself is already known. Therefore, already known satellite communication methods can be used as appropriate. The example of satellite 3 is a quantum key distribution satellite adapted to generate quantum key distribution (QKD) free-space signals for telescope 11. In this example, satellite 3 is adapted to telescope 11, and telescope 11 can receive the QKD free-space signals output from satellite 3. 【0015】The optical ground station 15 includes a telescope 11 for receiving optical signals from a satellite, an optical circuit section 17 for receiving light from the telescope 11, and an optical fiber 13 (or optical coupling section 29) for connecting the light that has passed through the optical circuit section 17 to the receiver 7. The optical ground station 15 may have an optical communication sensor instead of the optical fiber 13. The optical communication sensor may be a small optical communication sensor used for free-space coupling. Instead of the optical fiber 13 in Figure 1, the optical communication sensor may be optically coupled with the optical coupler 29. In the example in Figure 1, the receiver 7 is located inside the QKD remote receiving station 9. The optical ground station 15 may be fixed to the ground or it may be mobile. Examples of the optical ground station 15 are a QKD fixed ground station and a QKD portable ground station. The optical ground station 15 transmits, for example, a QKD free-space signal to the optical fiber 13 via the optical circuit section 17, and then transmits it via the optical fiber 13 to the QKD remote receiving station 9, which is located inside the optical ground station 15 or in a different location from the optical ground station 15. A preferred example of the optical fiber 13 is a single-mode fiber. In the following example, the telescope 11 will be described in a manner in which it is optically coupled to the optical fiber 13 via the optical circuit section 17. However, using a similar principle, the telescope 11 can also be described in a manner in which it is optically coupled to an optical communication sensor via the optical circuit section 17. 【0016】 Figure 2 is a block diagram illustrating the optical circuit section of the optical ground station. As shown in Figure 2, the optical circuit section 17 includes a tracking camera 21, a first optical system 23, a sensor section 25, a second optical system 27, an optical coupling section 29, and a drive control section 31. The tracking camera 21 is an element for receiving at least a portion of the light output from the telescope 11. The tracking camera 21 may be controlled by the drive control section 31, which will be described later, and the drive control section 31 may be capable of controlling the position and orientation of the telescope 11 based on the output of the tracking camera 21. The tracking camera 21 can display images taken by the telescope 11. The tracking camera 21 only needs to be capable of detecting light over a certain area, and may be a general-purpose camera, a high-resolution camera for precise tracking, or a CCD camera, etc. 【0017】The first optical system 23 is an element for guiding the light output from the telescope 11 to the tracking camera 21. In the example in Figure 2, the first optical system 23 includes a pupil 33 that receives the light output from the telescope 11, a polarizing plate 35 for adjusting the polarization plane of the light emitted from the pupil 33, a beam splitter (BS) 37 for separating the light emitted from the polarizing plate 35, and a first movable mirror 39 to which a portion of the light separated by the BS 37 is input. The attitude (direction and position, or both, hereinafter the same) of the first movable mirror 39 can be adjusted by the drive control unit 31. The drive control unit 31 may also be able to adjust the aperture diaphragm of the pupil 33. The drive control unit 31 may also be able to adjust the polarization plane of the polarizing plate 35. When the drive control unit 31 adjusts the position and direction of the first movable mirror 39, the position at which the light emitted from the telescope 11 enters the tracking camera 21 can be adjusted. The beam splitter (BS) functions as a light separation unit. The mirror is used to adjust the direction of light propagation, and therefore functions as a light propagation direction adjustment unit. In the first optical system 23, the pupil 33 and polarizer 35 are optional. 【0018】 The sensor unit 25 is an element for receiving at least a portion of the light output from the telescope 11. The sensor unit 25 can be any device (light sensor) that can receive light over a certain area and detect the received light. Examples of the sensor unit 25 include a quadrature detection (QD) sensor and a position sensor. 【0019】The second optical system 27 is an element for guiding the light output from the telescope 11 to the sensor unit 25. The second optical system 27 can also be described as an element for guiding the light that has passed through the first optical system 23 (light output from the telescope 11) to the sensor unit 25. In the example in Figure 2, the second optical system 27 includes a first wavelength filter 51 into which the light that has passed through the first optical system 23 is incident, a second movable mirror 53 into which the light that has passed through the first wavelength filter 51 is incident, a second wavelength filter 55 into which the light that has passed through the second movable mirror is incident, and a second beam splitter (BS) 57 into which the light that has passed through the second wavelength filter 55 is incident. A portion of the light separated by the BS 57 is then emitted to the sensor unit 25. In Figure 2, 59 is an optional element, a lens. The lens 59 can adjust the reflected light. The second movable mirror 53 is configured so that its orientation can be adjusted by the drive control unit 31. When the drive control unit 31 adjusts the orientation of the second movable mirror 31, the position at which the light emitted from the telescope 11 enters the sensor unit 25 can be adjusted. 【0020】 The optical coupling unit 29 is an element for optically coupling the telescope 11 and the optical fiber 13. In the example shown in Figure 2, the optical coupling unit 29 functions as an element for coupling the light emitted from the telescope 11, which has passed through the first optical system 23 and the second optical system 27, with the optical fiber 13. Examples of optical coupling units 29 include photocouplers and fiber couplers. 【0021】 The drive control unit 31 is an element for controlling the attitudes of the first optical system 23, the second optical system 27, and the telescope 11. The drive control unit 31 may be implemented by a computer. In addition to controlling the attitudes of the first optical system 23, the second optical system 27, and the telescope 11, the drive control unit 31 may also control various drive systems. Although not specifically shown, it is preferable that the drive control unit 31 is connected to the various elements wirelessly or by wire to enable the exchange of information with the elements to be controlled. 【0022】A computer has an input unit, an output unit, a control unit, an arithmetic unit, and a memory unit, and each element is connected by a bus or the like to enable the exchange of information. Computers usually handle digital information. For example, a computer may store programs or various kinds of information in its memory unit. When predetermined information is input from the input unit, the control unit reads the program stored in the memory unit. The control unit then reads the information stored in the memory unit as appropriate and transmits it to the arithmetic unit. The control unit also transmits the input information to the arithmetic unit as appropriate. The arithmetic unit performs calculations using the received information and stores it in the memory unit. The control unit reads the calculation results stored in the memory unit and outputs them from the output unit. In this way, various processes and steps are executed. Each unit and each means is responsible for executing these various processes. A computer may have a processor, and the processor may implement various functions and steps. A computer may be standalone. A computer may have some of its functions distributed between a server and terminals. In that case, it is preferable that the server and terminals can exchange information via a network such as the internet or an intranet. A computer may include a processor and memory connected to the processor. The memory may store instructions, and when executed by the processor, these instructions may cause the computer to perform various processes and function as various components. The computer may build a learning model by providing various training data and perform various calculations through machine learning. In this case, the computer may perform various analyses and interpretations using the learning model created by AI (artificial intelligence) machine learning and deep learning. 【0023】Next, a method for improving the coupling efficiency between the telescope and the optical fiber will be described. This method includes the following steps: Alignment adjustment system construction step An optical transmitter 41 and an optical reflector 43 are installed at the optical ground station 15. If either or both of the optical transmitter 41 and the optical reflector 43 are already installed at the optical ground station 15, the already installed ones may be used. An optical receiver 45 may also be attached to the optical ground station 15. In this way, an alignment adjustment system can be constructed. Figure 3 is a block diagram illustrating an example of the configuration of the alignment adjustment system. Of the elements in Figure 3, those included in Figure 2 will be described by reference and their explanations will be omitted. 【0024】 The optical transmitter 41 is an element for outputting light to the optical coupling unit 29 included in the optical circuit unit 17 of the optical ground station 15. The optical transmitter 41 can function as any light source. 【0025】 The optical reflector 43 is an element that reflects light emitted from the light transmitter 41, through the optical circuit section 17, and after passing through the telescope 11. Examples of the optical reflector 43 include mirrors, reflectors, and corner cubes. 【0026】 The alignment adjustment system constructed in this manner is used to obtain offset information for improving the coupling efficiency between the telescope and the optical fiber. This specification also describes a method for obtaining offset information for improving the coupling efficiency between the telescope and the optical fiber using the alignment adjustment system. 【0027】 Light emission process First, light is emitted from the light transmitter 41. The light emitted from the light transmitter 41 is assumed to be light emitted from the satellite 3 and reaching the telescope 11, and may, for example, be light having wavelengths in the infrared region, or it may be weak light. The light output by the light transmitter 41 may be continuous light or pulsed light. 【0028】In the first control process, light emitted from the optical transmitter 41 passes through the optical circuit section 17, through the telescope 11, is reflected by the optical reflector 43, and enters the tracking camera 21 via the first optical system 23, where it is received by the tracking camera 21. Specifically, light emitted from the optical transmitter 41 is propagated to the optical circuit section 17 by the optical coupling section 29. In the example in Figure 3, the light that has passed through the optical coupling section 29 passes through the lens 59 and through the second optical system 27. The light that has passed through the second optical system 27 passes through the first optical system 23 and is emitted to the telescope 11. The light emitted to the telescope 11 passes through the telescope 11 and is reflected by the optical reflector 43. The light reflected by the optical reflector 43 enters the telescope 11 (as if it were light from a satellite). Light passing through the telescope 11 enters the tracking camera 21 via the first optical system 23 and is received by the tracking camera 21. Specifically, light passing through the telescope 11 enters the first BS 37 via the pupil 33 and polarizer 35. A portion of the light entering the first BS has its direction of travel adjusted by the first movable mirror 37 and proceeds to the tracking camera 21. The light entering the tracking camera 21 is received (photographed) by the tracking camera 21. Information regarding the light received by the tracking camera and information regarding the position of the received light in the lens of the tracking camera, or both, are transmitted to the drive control unit 31. 【0029】 The drive control unit 31 controls the first optical system 23 so that the light received by the tracking camera 21 is centered on the lens of the tracking camera 21 (first control step). When the drive control unit 31 receives the above control information from the tracking camera 21, it calculates a control command to control the first optical system 23 (for example, the posture of the first movable mirror 39) based on the program's commands. The drive control unit 31 stores the calculated control command in the memory unit as appropriate and outputs a command to control the first optical system 23 to the first optical system 23. The first optical system 23 (for example, the first movable mirror 39) has an actuator that is driven based on the command. Therefore, the first optical system 23 can be controlled based on the command from the drive control unit 31. The alignment of the first optical system 23 is achieved by the first control step. 【0030】The second control process drive control unit 31 controls the second optical system 27 so that the light reflected by the optical reflection unit 43 is incident on the center of the sensor unit 25, while maintaining the control state of the first optical system 23 in the first control process (second control process). The first optical system 23 is aligned by the first control process. The first optical system 23 is maintained in that state. Then, the light output from the aligned first optical system 23 passes through the second optical system 27 and is incident on the sensor unit 25. In the example of Figure 3, the light output from the first optical system 23 passes through the first wavelength filter 51 to remove unwanted wavelength components and reaches the second movable mirror 53. The light whose direction of travel has been adjusted by the second movable mirror 53 passes through the second wavelength filter and is incident on the second BS 57. A portion of the light incident on the second BS 57 has its direction of travel adjusted so that it is directed towards the sensor unit 25. The sensor unit 25 receives the light. Light incident on the sensor unit 25 is received (captured) by the sensor unit 25. Information regarding the light received by the sensor unit 25 and information regarding the position of the received light on the sensor surface of the sensor unit 25, or both, are transmitted to the drive control unit 31. 【0031】 The drive control unit 31 controls the second optical system 27 so that the light received by the sensor unit 25 is centered on the lens of the sensor unit 25. For example, when the drive control unit 31 receives the above control information from the sensor unit 25, it calculates a control command to control the second optical system 27 (for example, the posture of the second movable mirror 53) based on the program's commands. The drive control unit 31 stores the calculated control command in the memory unit as appropriate and outputs a command to control the second optical system 27 to the second optical system 27. The second optical system 27 (for example, the second movable mirror 53) has an actuator that is driven based on the command. Therefore, the second optical system 27 can be controlled based on the command from the drive control unit 31. The alignment of the second optical system 27 is achieved by the second control step. 【0032】The orbit tracking process drive control unit 31 maintains the control state of the second optical system 27 in the second control process and causes the telescope 11 to perform an operation that simulates orbit tracking (orbit tracking process). An operation that simulates orbit tracking means an operation in which the telescope 11 simulates the operation of tracking the orbit of the satellite 3, rather than actually tracking the satellite 3. The memory unit of the drive control unit 31 stores information on the change in the attitude of the telescope 11 when the telescope 11 received light from the satellite in the past and tracked the satellite's orbit, or control information for changing the telescope 11 to that attitude. Such stored information can be obtained by storing information on the change in the attitude of the telescope 11 when the telescope 11 actually tracked the satellite 3, or by storing commands for driving the telescope 11. The telescope 11 has a telescope drive unit 61 for driving the telescope 11. Therefore, the attitude (position and orientation) of the telescope 11 can be controlled by driving the drive unit 61 based on the commands output by the drive control unit 31. The drive control unit 31 reads the control information described above from the memory unit and drives the drive unit 61 to cause the telescope 11 to perform an operation that simulates orbital tracking. In other words, even if the telescope 11 does not actually trace the change in its relative position with the satellite 3, the drive control unit 31 can cause the telescope 11 to perform an operation as if it were tracking the orbit of the satellite 3. Note that there may be multiple types of satellites 3, and information corresponding to each satellite may be stored so that an operation simulating orbital tracking corresponding to each satellite 3 can be performed. In the orbital tracking process, although the telescope 11 is not actually tracking the satellite 3, the light reflected by the optical reflector 43 and incident on the telescope 11 functions as if it were light from the satellite 3. 【0033】The optical position memory process drive control unit 31 stores the light reception position at the sensor unit observed by the sensor unit 25 during the orbit tracking process (optical position memory process). As explained earlier, during the orbit tracking process, the telescope 11 performs an operation that simulates orbit tracking while maintaining the control state of the second optical system 27 in the second control process (the state in which the first and second optical systems 23 and 27 are aligned). During the orbit tracking process, the optical transmitter 41 continues to emit light. As a result, the position of the incident light at the sensor unit observed by the sensor unit 25 changes in accordance with the attitude of the telescope 11. During the orbit tracking process, the drive control unit 31 stores the light reception position at the sensor unit, which changes over time in relation to the change in the attitude of the telescope 11, in the memory unit. The drive control unit 31 may also store the light reception position at each timing of the orbit tracking process in the memory unit. 【0034】 The telescope attitude and light-receiving position memory process drive control unit 31 stores the relationship between the attitude of the telescope 11 during the orbit tracking process and the light-receiving position at the sensor unit. For example, the drive control unit 31 associates the attitude of the telescope 11 with the light-receiving position at the sensor unit at multiple timings during the orbit tracking process and stores this information in the memory unit. 【0035】 To obtain multiple data points, the orbit tracking process, the optical position memory process, and the telescope attitude and light reception position memory process may be repeated. 【0036】In the drive control information acquisition process, drive control information is obtained to control one or more of the attitudes of the first optical system 23, the second optical system 27, and the telescope 11, using the attitude of the telescope 11 in the trajectory tracking process and the light-receiving position of the sensor unit (drive control information acquisition process). The drive control unit 31 reads information regarding the relationship between the attitude of the telescope 11 and the light-receiving position of the sensor unit from the storage unit and analyzes drive control information such that, in a given attitude of the telescope 11, the light-receiving position of the sensor unit is at the center of the sensor unit. The drive control unit 31 may also store in advance drive control information for controlling one or more of the attitudes of the first optical system 23, the second optical system 27, and the telescope 11, corresponding to the light-receiving positions of various sensor units, and read the corresponding drive control information from the storage unit for the attitude of the telescope 11. In this way, offset information (information to correct the discrepancy between the actual attitude of the telescope 11 and the light-receiving position of the sensor) can be obtained to correct the drive control information of the first optical system 23, the second optical system 27, and the telescope 11 when the telescope 11 is actually tracking the satellite. Therefore, in this system, when the telescope 11 is actually tracking the satellite, the sensor can observe the signal appropriately by controlling one or more of the first optical system 23, the second optical system 27, and the attitude of the telescope 11 while taking the offset information into consideration. 【0037】The orbit tracking process drive control information acquisition process may include a step of controlling the second optical system 27 to pre-apply an offset if a correlation is found between the attitude of the telescope 11 in the orbit tracking process and the light-receiving position at the sensor unit. The drive control unit 31 examines whether or not there is a correlation between the attitude of the telescope 11 in the orbit tracking process and the light-receiving position at the sensor unit. The drive control unit 31 may have a correlation analysis unit. For example, if the orientation of the telescope 11 is facing a specific direction, and the light-receiving position at the sensor unit is located in a specific direction at the sensor unit, then it can be said that there is a correlation between the attitude of the telescope 11 and the light-receiving position at the sensor unit. Therefore, when tracking the satellite 3 and the orientation of the telescope 11 is in a specific direction, it is sufficient to obtain control information (offset information) such that the light received at the sensor unit is in the opposite direction to the specific direction. Then, when the telescope 11 is actually tracking satellite 3 and the orientation of satellite 3 is set to that specific direction, the drive control unit 31 controls the drive system with the offset added, so that the sensor unit 25 can properly receive the optical signal from satellite 3. 【0038】 The trajectory tracking process may be performed using a pre-trained model obtained through machine learning. 【0039】Method for constructing a pre-trained model In this case, a pre-trained model is constructed using training data to estimate the offset. To construct a pre-trained model, for example, a dataset is prepared in which the attitude of the telescope 11 and the light-receiving position at the sensor unit 25 are used as features, and the offset (correction information for adjusting the drive system) is used as a label. These datasets are used as training data with answers (labeled data) to train the AI ​​model. The AI ​​learns from these datasets and is trained to predict the correct label for new data. In this way, a pre-trained model can be constructed in which the attitude of the telescope 11 and the light-receiving position at the sensor unit 25 are used as features. Furthermore, the accuracy of the pre-trained model can be improved by inputting sample features into the pre-trained model and feeding back the obtained label, which is the offset (performing model learning). This invention also provides a pre-trained model for estimating the offset. Furthermore, the computer described above may be a computer that further has a pre-trained model for estimating the offset. 【0040】 Offset estimation method using a trained model When the optical ground station 15 actually tracks satellite 3, it reads out the attitude of the telescope 11 corresponding to the position of satellite 3 and the light-receiving position at the sensor unit 25 as features. The computer inputs these features into the trained model. As described above, the trained model is trained using multiple datasets so that when features are input, it can output offset information, which is a label. Therefore, when features are input into the trained model, offset information can be obtained. The offset information obtained in this way is appropriately stored in the memory unit. Then, when the optical ground station 15 actually tracks satellite 3, the drive control unit 31 controls the attitude of the telescope 11, taking into account the obtained offset information. 【0041】Next, the quantum key distribution (QKD) method will be described. This method uses the previously described method and appropriately includes steps to improve the coupling efficiency between the telescope and the optical fiber. In this method, satellite 3 outputs a QKD free-space signal. Next, the telescope 11 of the optical ground station 15 receives the QKD free-space signal. The optical ground station 15 transmits the QKD free-space signal to the optical fiber 13 via the optical circuit section 17, and also transmits it to the QKD remote receiving station 7 via the optical fiber 13. At this time, the relative relationship between satellite 3 and optical ground station 15 changes. From the perspective of optical ground station 15, this is observed as satellite 3 being displaced along a predetermined orbit. In response to the displacement of satellite 3, optical ground station 15 changes the attitude of the telescope 11. In this case, since the offset is stored in the memory unit, the drive control unit 31 does not control the attitude of the telescope 11 to correspond to the position of the satellite 3 that was actually observed, but rather changes the attitude of the telescope 11 after taking into account the read-out offset. In this way, the quantum key signal can be appropriately received and transmitted to the QKD remote receiving station 7. 【0042】 Figure 4 is a conceptual diagram illustrating an example of the system in the embodiment. Figure 5 is a block diagram showing the alignment adjustment system used in the embodiment. The following describes the highly efficient optical coupling method for the telescope for optical communication by the ground station described above. 1. First, light is emitted from the optical transmitter. The light is reflected by the corner cube after passing through the optical circuit. The light reflected by the corner cube enters the tracking camera. The first movable mirror is adjusted so that the light entering the tracking camera coincides with the center of the camera lens. In the example in Figure A1, a portion of the light reflected by the corner cube, separated by the first beam splitter (BS), enters the tracking camera via the first movable mirror. By adjusting the position and orientation of the first movable mirror, the position of the light entering the tracking camera can be adjusted. 【0043】Adjust the second movable mirror so that light is incident on the center of the QD sensor (or position sensor) in the state of 2.1. In the example of FIG. A1, among the light reflected by the corner cube, the remainder of the light separated by the first beam splitter (BS) is incident on the second beam splitter (BS) via the second movable mirror. A part of the light incident on the second beam splitter (BS) is incident on the QD sensor (or position sensor). By adjusting the position and orientation of the second movable mirror, the position of the light incident on the QD sensor (or position sensor) can be adjusted. In this way, the primary alignment of the optical system can be performed. 【0044】 Perform an operation simulating the orbital tracking to be observed by the telescope in the state of 3.2. Record the position (light receiving position) of the light in the QD sensor (or position sensor) during 4.3. Record the relationship between the state (position and orientation) of the telescope and the light receiving position of the QD sensor (or position sensor). Repeat the operations of 6.4 to 5 (or 3 to 5) to confirm the correlation between the attitude (position and orientation) of the telescope and the light receiving position of the QD sensor (or position sensor). When a correlation is observed in 7.6, an offset is previously applied to the operation of the second movable mirror so as to condense light at the center of the position sensor with respect to the attitude (position) of the telescope during actual observation, and an optical link with the satellite is formed. Actually, when quantum key distribution was performed based on this protocol, the optical coupling performance between the telescope and the single mode fiber was remarkably improved. 【0045】 In our country, the temperature changes from below zero to nearly 40 degrees. Therefore, when a temperature difference occurs, an optical axis deviation due to the expansion and contraction of the optical system will occur. In addition, the telescope has a Cassegrain, Nasmyth, and coude focus, but as the optical path becomes longer and the number of mirrors increases, the optical axis deviation becomes more apparent. Furthermore, when tracking a low-earth orbit satellite, the telescope adjusts the elevation and azimuth, and an optical axis deviation due to the lack of mechanical accuracy also occurs at that time. According to the present invention, these deviations can be measured in advance, and the optical axis alignment during actual optical communication can be facilitated. Therefore, the present invention is an extremely useful technology for optical communication between a satellite and the ground. 【0046】This invention can be preferably used in the field of satellite communications. In particular, this invention can be used in the field of quantum key distribution technology in which a quantum key distribution device is mounted on a satellite. 【0047】 3 Satellite 7 Receiver 9 QKD Remote Receiving Station 11 Telescope 13 Optical Fiber 15 Optical Ground Station 17 Optical Circuit Section 21 Tracking Camera 23 First Optical System 25 Sensor Section 27 Second Optical System 29 Optical Coupler 31 Drive Control Section 33 Pupil 35 Polarizer 37 Beam Splitter 39 First Movable Mirror 41 Optical Transmitter 43 Optical Reflector 51 First Wavelength Filter 53 Second Movable Mirror 55 Second Wavelength Filter 57 Second Beam Splitter 59 Lens 61 Telescope Drive Section

Claims

1. A method for improving the coupling efficiency between a telescope and an optical fiber in an optical circuit section (17) for an optical ground station (15) for transmitting an optical signal received by a telescope (11) to an optical fiber (13) or an optical communication sensor, wherein the optical circuit section (17) includes: a tracking camera (21) that receives at least a portion of the light output from the telescope (11); a first optical system (23) for guiding the light output from the telescope (11) to the tracking camera (21); a sensor section (25) that receives at least a portion of the light output from the telescope (11); a second optical system (27) for guiding the light output from the telescope (11) to the sensor section (25); an optical coupling section (29) for optically coupling with the optical fiber (13); and a drive control section (31) for controlling the attitude of the first optical system (23), the second optical system (27), and the telescope (11). The steps include: installing an optical transmitter (41) for outputting light to the optical coupling unit (29); installing an optical reflector (43) for reflecting light that has passed through the telescope (11); emitting light from the optical transmitter (41); the light emitted from the optical transmitter (41) passing through the telescope (11), being reflected by the optical reflector (43), and being received by the tracking camera (21) via the first optical system (23); and the first control step in which the drive control unit (31) controls the first optical system (23) so that the light received by the tracking camera (21) is centered on the lens of the tracking camera (21). A second control step in which the drive control unit (31) controls the second optical system (27) so that the light reflected by the optical reflector (43) is incident on the center of the sensor unit (25), while maintaining the control state of the first optical system (23) in the first control step; an orbital tracking step in which the drive control unit (31) causes the telescope (11) to perform an operation that simulates orbital tracking, while maintaining the control state of the second optical system (27) in the second control step; and an optical position storage step in which the drive control unit (31) stores the light receiving position of the light observed by the sensor unit (25) in the orbital tracking step.A method comprising: a telescope attitude and light-receiving position storage step, which is a step of storing the relationship between the attitude of the telescope (11) in the orbit tracking step and the light-receiving position in the sensor unit; and a drive control information acquisition step, which is a step of obtaining drive control information for controlling one or more of the first optical system (23), the second optical system (27), and the attitude of the telescope (11) using the attitude of the telescope (11) in the orbit tracking step and the light-receiving position in the sensor unit.

2. A method according to claim 1, wherein the optical ground station (15) is configured such that the telescope (11) receives the QKD free-space signal from a quantum key distribution satellite (3) adapted to generate the QKD free-space signal, and transmits the QKD free-space signal to the optical fiber (13) via the optical circuit section (17), and transmits it via the optical fiber (13) to a QKD remote receiving station (9) located at a different location from the optical ground station (15).

3. The method according to claim 2, wherein the optical fiber (13) is a single-mode fiber.

4. The method according to claim 2, wherein the drive control information acquisition step includes a step of controlling the second optical system (27) to pre-apply an offset when a correlation is found between the attitude of the telescope (11) in the orbit tracking step and the light receiving position in the sensor unit.

5. A quantum key distribution (QKD) method using any of claims 2 to 4, comprising the steps of: the satellite (3) outputting the QKD free-space signal; the telescope (11) of the optical ground station (15) receiving the QKD free-space signal; and the optical ground station (15) transmitting the QKD free-space signal to the optical fiber (13) via the optical circuit section (17) and to the QKD remote receiving station (9) via the optical fiber (13).

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