Mobile single-mode optical fiber tracking and aiming method and mobile single-mode optical fiber tracking and aiming device

文档序号:1295548 发布日期:2020-08-07 浏览:22次 中文

阅读说明:本技术 一种移动单模光纤跟瞄方法以及移动单模光纤跟瞄装置 (Mobile single-mode optical fiber tracking and aiming method and mobile single-mode optical fiber tracking and aiming device ) 是由 谢臻达 田晓慧 顾昌晟 范鹏飞 胡明哲 刘华颖 龚彦晓 赵刚 祝世宁 于 2020-05-20 设计创作,主要内容包括:本申请提供一种移动单模光纤跟瞄方法以及移动单模光纤跟瞄装置,该方法包括:接收处于移动状态的目标装置所发射的第一参考光信号;根据所述第一参考光信号,调整所述移动单模光纤跟瞄装置中无刷电机驱动的云台的俯仰角和偏航角;接收所述目标装置所发射的第二参考光信号;控制所述第二参考光信号进行偏转,以使经过偏转的第二参考光信号传输至所述移动单模光纤跟瞄装置的目标单模光纤内。这样,可以根据第一参考光信号,调整移动单模光纤跟瞄装置中无刷电机驱动的云台的俯仰角和偏航角;还可以控制第二参考光信号进行偏转,以使经过偏转的第二参考光信号传输至移动单模光纤跟瞄装置的目标单模光纤内。实现对移动装置的有效跟瞄。(The application provides a method and a device for mobile single-mode fiber tracking and aiming, wherein the method comprises the following steps: receiving a first reference optical signal transmitted by a target device in a moving state; adjusting the pitch angle and the yaw angle of a holder driven by a brushless motor in the mobile single-mode optical fiber tracking and aiming device according to the first reference light signal; receiving a second reference optical signal transmitted by the target device; and controlling the second reference light signal to deflect, so that the deflected second reference light signal is transmitted into a target single-mode optical fiber of the mobile single-mode optical fiber tracking device. Therefore, the pitch angle and the yaw angle of a holder driven by a brushless motor in the mobile single-mode optical fiber tracking and aiming device can be adjusted according to the first reference light signal; the second reference optical signal can also be controlled to deflect, so that the deflected second reference optical signal is transmitted into a target single-mode optical fiber of the mobile single-mode optical fiber tracking device. And the effective tracking of the mobile device is realized.)

1. A mobile single-mode optical fiber tracking and aiming method is applied to a mobile single-mode optical fiber tracking and aiming device and is characterized by comprising the following steps:

receiving a first reference optical signal transmitted by a target device in a moving state;

adjusting the pitch angle and the yaw angle of a holder driven by a brushless motor in the mobile single-mode optical fiber tracking and aiming device according to the first reference light signal;

receiving a second reference optical signal transmitted by the target device;

and controlling the second reference light signal to deflect, so that the deflected second reference light signal is transmitted into a target single-mode optical fiber of the mobile single-mode optical fiber tracking device.

2. The method of claim 1, wherein said adjusting the pitch angle and yaw angle of a brushless motor driven pan/tilt head in said mobile single mode fiber tracking device based on said first reference light signal comprises:

acquiring a first position coordinate of the first reference optical signal;

determining a second position coordinate of the zero position;

calculating a difference between the first position coordinate and the second position coordinate;

and adjusting the pitch angle and the yaw angle of the holder driven by the brushless motor according to the difference value so as to enable the absolute value of the difference value between the position coordinate of the first reference light signal and the second position coordinate of the zero position to be smaller than or equal to a preset threshold value.

3. The method of claim 1 or 2, wherein prior to the step of receiving the first reference optical signal transmitted by the target device in motion, the method further comprises:

detecting whether the space angle of the holder driven by the brushless motor changes;

and under the condition that the change of the space angle of the holder driven by the brushless motor is detected, controlling a pitching shaft, a yawing shaft and a rolling shaft contained in the holder driven by the brushless motor to rotate.

4. The method of claim 3, wherein after the step of controlling the second reference optical signal to deflect, the method further comprises:

receiving a target optical signal, wherein the target optical signal is obtained after a collimating telescope of the target device adjusts a divergence angle of an optical signal emitted by a laser in the target device.

5. The method of claim 1 or 2, wherein prior to the step of receiving the first reference optical signal transmitted by the target device in motion, the method further comprises:

windowing a detector contained in the mobile single-mode optical fiber tracking device;

the receiving of the first reference optical signal transmitted by the target device in the moving state includes:

receiving, by a detector that is subject to the windowing operation, the first reference light signal emitted by the target device in a moving state.

6. A mobile single mode fiber tracking device, comprising:

the first receiving module is used for receiving a first reference optical signal transmitted by a target device in a moving state;

the adjusting module is used for adjusting a pitch angle and a yaw angle of a holder driven by a brushless motor in the mobile single-mode optical fiber tracking and aiming device according to the first reference light signal;

a second receiving module, configured to receive a second reference optical signal transmitted by the target apparatus;

and the first control module is used for controlling the second reference light signal to deflect so that the deflected second reference light signal is transmitted into a target single-mode optical fiber of the mobile single-mode optical fiber tracking device.

7. The mobile single mode fiber tracking device of claim 6, wherein said adjustment module comprises:

the acquisition submodule is used for acquiring a first position coordinate of the first reference light signal;

a determination submodule for determining a second position coordinate of the zero point position;

a calculation submodule for calculating a difference between the first position coordinate and the second position coordinate;

and the adjusting submodule is used for adjusting the pitch angle and the yaw angle of the holder driven by the brushless motor according to the difference value so as to enable the absolute value of the difference value between the position coordinate of the first reference light signal and the second position coordinate of the zero position to be smaller than or equal to a preset threshold value.

8. The mobile single mode fiber tracking device of claim 6 or 7, further comprising:

the detection module is used for detecting whether the space angle of the holder driven by the brushless motor changes or not;

and the second control module is used for controlling the pitching shaft, the yawing shaft and the rolling shaft contained in the brushless motor-driven holder to rotate under the condition that the change of the space angle of the brushless motor-driven holder is detected.

9. The mobile single mode fiber tracking device of claim 8, further comprising:

and the third receiving module is used for receiving a target optical signal, wherein the target optical signal is obtained after a collimating telescope of the target device adjusts a divergence angle of an optical signal emitted by a laser in the target device.

10. The mobile single mode fiber tracking device of claim 6 or 7, further comprising:

the execution module is used for windowing a detector contained in the mobile single-mode optical fiber tracking device;

the first receiving module is used for receiving the first reference light signal emitted by the target device in a moving state through the detector subjected to windowing operation.

Technical Field

The application relates to the technical field of communication, in particular to a mobile single-mode optical fiber tracking and aiming method and a mobile single-mode optical fiber tracking and aiming device.

Background

Tracking from single mode fiber to single mode fiber means real-time pointing between two devices to the single mode fiber aperture level. The tracking is bidirectional, i.e. both the transmitting device and the receiving device identify and direct the other party, and after the link is established, the light beam can be transmitted. In the related art, the tracking device is mainly a relatively fixed device or a device that runs along a certain track. When the device to which the tracking is directed is a mobile device, such as an airplane, a boat, a car, or a hot air balloon, there are requirements on both the weight and the volume of the device as a whole, including the on-board tracking system. Fast moving devices have more stringent stability and accuracy requirements than fixed devices. In the related art, effective tracking of a mobile device cannot be achieved.

Disclosure of Invention

The application provides a mobile single-mode fiber tracking and aiming method and a mobile single-mode fiber tracking and aiming device, which solve the problem that effective tracking and aiming of a mobile device cannot be realized in the related technology.

In one aspect, the present application provides a mobile single-mode fiber tracking method, including:

receiving a first reference optical signal transmitted by a target device in a moving state;

adjusting the pitch angle and the yaw angle of a holder driven by a brushless motor in the mobile single-mode optical fiber tracking and aiming device according to the first reference light signal;

receiving a second reference optical signal transmitted by the target device;

and controlling the second reference light signal to deflect, so that the deflected second reference light signal is transmitted into a target single-mode optical fiber of the mobile single-mode optical fiber tracking device.

Optionally, the adjusting, according to the first reference light signal, a pitch angle and a yaw angle of a holder driven by a brushless motor in the mobile single-mode fiber tracking and aiming device includes:

acquiring a first position coordinate of the first reference optical signal;

determining a second position coordinate of the zero position;

calculating a difference between the first position coordinate and the second position coordinate;

and adjusting the pitch angle and the yaw angle of the holder driven by the brushless motor according to the difference value so as to enable the absolute value of the difference value between the position coordinate of the first reference light signal and the second position coordinate of the zero position to be smaller than or equal to a preset threshold value.

Optionally, before the step of receiving the first reference optical signal transmitted by the target device in the moving state, the method further includes:

detecting whether the space angle of the holder driven by the brushless motor changes;

and under the condition that the change of the space angle of the holder driven by the brushless motor is detected, controlling a pitching shaft, a yawing shaft and a rolling shaft contained in the holder driven by the brushless motor to rotate.

Optionally, after the step of controlling the second reference optical signal to deflect, the method further includes:

receiving a target optical signal, wherein the target optical signal is obtained after a collimating telescope of the target device adjusts a divergence angle of an optical signal emitted by a laser in the target device.

Optionally, before the step of receiving the first reference optical signal transmitted by the target device in the moving state, the method further includes:

windowing a detector contained in the mobile single-mode optical fiber tracking device;

the receiving of the first reference optical signal transmitted by the target device in the moving state includes:

receiving, by a detector that is subject to the windowing operation, the first reference light signal emitted by the target device in a moving state.

On the other hand, this application still provides a remove single mode fiber tracking and aims device, includes:

the first receiving module is used for receiving a first reference optical signal transmitted by a target device in a moving state;

the adjusting module is used for adjusting a pitch angle and a yaw angle of a holder driven by a brushless motor in the mobile single-mode optical fiber tracking and aiming device according to the first reference light signal;

a second receiving module, configured to receive a second reference optical signal transmitted by the target apparatus;

and the first control module is used for controlling the second reference light signal to deflect so that the deflected second reference light signal is transmitted into a target single-mode optical fiber of the mobile single-mode optical fiber tracking device.

Optionally, the adjusting module includes:

the acquisition submodule is used for acquiring a first position coordinate of the first reference light signal;

a determination submodule for determining a second position coordinate of the zero point position;

a calculation submodule for calculating a difference between the first position coordinate and the second position coordinate;

and the adjusting submodule is used for adjusting the pitch angle and the yaw angle of the holder driven by the brushless motor according to the difference value so as to enable the absolute value of the difference value between the position coordinate of the first reference light signal and the second position coordinate of the zero position to be smaller than or equal to a preset threshold value.

Optionally, the mobile single-mode fiber tracking device further includes:

the detection module is used for detecting whether the space angle of the holder driven by the brushless motor changes or not;

and the second control module is used for controlling the pitching shaft, the yawing shaft and the rolling shaft contained in the brushless motor-driven holder to rotate under the condition that the change of the space angle of the brushless motor-driven holder is detected.

Optionally, the mobile single-mode fiber tracking device further includes:

and the third receiving module is used for receiving a target optical signal, wherein the target optical signal is obtained after a collimating telescope of the target device adjusts a divergence angle of an optical signal emitted by a laser in the target device.

Optionally, the mobile single-mode fiber tracking device further includes:

the execution module is used for windowing a detector contained in the mobile single-mode optical fiber tracking device;

the first receiving module is used for receiving the first reference light signal emitted by the target device in a moving state through the detector subjected to windowing operation.

According to the technical scheme, the application provides a mobile single-mode optical fiber tracking method and a mobile single-mode optical fiber tracking device, and the method comprises the following steps: receiving a first reference optical signal transmitted by a target device in a moving state; adjusting the pitch angle and the yaw angle of a holder driven by a brushless motor in the mobile single-mode optical fiber tracking and aiming device according to the first reference light signal; receiving a second reference optical signal transmitted by the target device; and controlling the second reference light signal to deflect, so that the deflected second reference light signal is transmitted into a target single-mode optical fiber of the mobile single-mode optical fiber tracking device. Therefore, the pitch angle and the yaw angle of a holder driven by a brushless motor in the mobile single-mode optical fiber tracking and aiming device can be adjusted according to the first reference light signal; the second reference optical signal can also be controlled to deflect, so that the deflected second reference optical signal is transmitted into a target single-mode optical fiber of the mobile single-mode optical fiber tracking device. And the effective tracking of the mobile device is realized.

Drawings

In order to more clearly explain the technical solution of the present application, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious to those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a flow chart of a method for moving a single mode fiber tracking system according to the present application;

FIG. 2 is a schematic view of a mobile single mode fiber tracking device provided herein;

FIG. 3 is a flow chart of another method of moving single mode fiber tracking provided herein;

FIG. 4 is a block diagram of a mobile single mode fiber tracking device according to the present application;

FIG. 5 is a block diagram of another mobile single mode fiber tracking device provided herein;

FIG. 6 is a block diagram of another mobile single mode fiber tracking device provided herein;

FIG. 7 is a block diagram of another mobile single mode fiber tracking device provided herein;

fig. 8 is a block diagram of another mobile single mode fiber tracking device provided in the present application.

Detailed Description

Reference will now be made in detail to embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following examples do not represent all embodiments consistent with the present application. But merely as exemplifications of systems and methods consistent with certain aspects of the application, as recited in the claims.

Referring to fig. 1, fig. 1 is a flowchart of a method for moving a single mode fiber tracking system according to the present application. As shown in fig. 1, the method comprises the following steps:

step 101, receiving a first reference optical signal transmitted by a target device in a moving state.

In step 101, as shown in fig. 2, a schematic diagram of moving a single mode fiber tracking device is shown. In fig. 2, the mobile single-mode fiber tracking and aiming device comprises a three-axis pan-tilt, and the pan-tilt is hung outside the mobile single-mode fiber tracking and aiming device through a damping device. The three axes are a yaw axis 1, a pitch axis 2 and a roll axis 3. A laser (accessory device 1) for emitting a reference beam; the detector (accessory device 2) can be a Complementary Metal Oxide Semiconductor (CMOS), and a field of view can be adjusted by adding a conversion lens. A collimating telescope 6 for adjusting the divergence angle of the transmitted beam so that the beam can be transmitted at a long distance; the fine tracking system 7 can further adjust the direction of the light beam to achieve the tracking accuracy of the single-mode optical fiber level.

A first reference optical signal transmitted by a target device in a moving state may be received.

And 102, adjusting the pitch angle and the yaw angle of a holder driven by a brushless motor in the mobile single-mode optical fiber tracking and aiming device according to the first reference light signal.

In step 102, a pitch angle and a yaw angle of a brushless motor-driven pan/tilt head in the mobile single-mode fiber tracking device may be adjusted according to the first reference light signal.

Note that, at this time, the position coordinates of the opposite reference light signal detected on the local detector are (x1, y1), and the difference between the position coordinates (x1, y1) of the reference light signal and the position coordinates of the zero point position can be obtained. And then the difference value can be used as an input signal, and the pitch angle and the yaw angle of a holder driven by a brushless motor in the moving single-mode optical fiber tracking device are controlled and adjusted through a proportional-integral-derivative (PID) so that the position of the reference light signal moves to the zero point position. After PID parameters are reasonably selected, the position of the reference light signal can be always near the zero position, so that the integral pointing of the holder is ensured. According to different application distances and precision requirements, a conversion lens can be added in front of the detector to adjust a receiving view field, and the detector can also be assisted with windowing operation to further improve the response frequency.

And 103, receiving a second reference optical signal transmitted by the target device.

In step 103, fine tracking can be performed when the transmitted beam needs to be further collected into a single mode fiber. The fine tracking system may include a detector and a deflection mirror. The detector may be a CMOS, a Charge-coupled Device (CCD), or a four quadrant detector. The deflection mirror may be a piezo ceramic driven deflection mirror.

A second reference optical signal transmitted by the target device may be received.

And 104, controlling the second reference light signal to deflect, so that the deflected second reference light signal is transmitted to a target single-mode optical fiber of the mobile single-mode optical fiber tracking device.

In step 104, the second reference light signal may be controlled by the deflection mirror to deflect, so that the deflected second reference light signal is transmitted into the target single mode fiber of the mobile single mode fiber tracking device. At this time, the link between the mobile single-mode fiber tracking device and the target device is established, and light beam transmission can be carried out.

The application provides a method for moving single mode fiber tracking and aiming, which is applied to a device for moving single mode fiber tracking and aiming. Receiving a first reference optical signal transmitted by a target device in a moving state; adjusting the pitch angle and the yaw angle of a holder driven by a brushless motor in the mobile single-mode optical fiber tracking and aiming device according to the first reference light signal; receiving a second reference optical signal transmitted by the target device; and controlling the second reference light signal to deflect, so that the deflected second reference light signal is transmitted into a target single-mode optical fiber of the mobile single-mode optical fiber tracking device. Therefore, the pitch angle and the yaw angle of a holder driven by a brushless motor in the mobile single-mode optical fiber tracking and aiming device can be adjusted according to the first reference light signal; the second reference optical signal can also be controlled to deflect, so that the deflected second reference optical signal is transmitted into a target single-mode optical fiber of the mobile single-mode optical fiber tracking device. And the effective tracking of the mobile device is realized.

Referring to fig. 3, fig. 3 is a flow chart of another method for moving single mode fiber tracking provided by the present application. As shown in fig. 3, the method comprises the following steps:

step 301, receiving a first reference optical signal transmitted by a target device in a moving state.

In step 301, still taking fig. 2 as an example, as shown in fig. 2, a schematic diagram of moving a single-mode fiber tracking device is shown. In fig. 2, the mobile single-mode fiber tracking and aiming device comprises a three-axis pan-tilt, and the pan-tilt is hung outside the mobile single-mode fiber tracking and aiming device through a damping device. The three axes are a yaw axis 1, a pitch axis 2 and a roll axis 3. A laser (accessory device 1) for emitting a reference beam; the detector (accessory device 2) can be a Complementary Metal Oxide Semiconductor (CMOS), and a field of view can be adjusted by adding an interchangeable lens. A collimating telescope 6 for adjusting the divergence angle of the transmitted beam so that the beam can be transmitted at a long distance; the fine tracking system 7 can further adjust the direction of the light beam to achieve the tracking accuracy of the single-mode optical fiber level.

A first reference optical signal transmitted by a target device in a moving state may be received.

Optionally, before the step of receiving the first reference optical signal transmitted by the target device in the moving state, the method further includes:

detecting whether the space angle of the holder driven by the brushless motor changes;

and under the condition that the change of the space angle of the holder driven by the brushless motor is detected, controlling a pitching shaft, a yawing shaft and a rolling shaft contained in the holder driven by the brushless motor to rotate.

It should be noted that, the axes of the yaw axis 1, the pitch axis 2 and the roll axis 3 are all provided with a gyroscope sensing chip, and when the pan-tilt moves relatively with the moving single-mode fiber tracking device, the gyroscope sensing chip can sense the corresponding angle change. Whether the space angle of the holder driven by the brushless motor changes or not can be detected.

Under the condition that the change of the space angle of the holder driven by the brushless motor is detected, the pitch shaft, the yaw shaft and the roll shaft contained in the holder driven by the brushless motor can be controlled to rotate. That is, the 3 axes of the pitch axis, the yaw axis and the roll axis can be driven to rotate by generating control signals through an internal control circuit. Thus, the equipment loaded on the holder is not influenced by external motion, and a relatively stable state is kept.

Optionally, before the step of receiving the first reference optical signal transmitted by the target device in the moving state, the method further includes:

windowing a detector contained in the mobile single-mode optical fiber tracking device;

the receiving of the first reference optical signal transmitted by the target device in the moving state includes:

receiving, by a detector that is subject to the windowing operation, the first reference light signal emitted by the target device in a moving state.

It should be noted that, a windowing operation may also be performed on a detector included in the moving single-mode fiber tracking device, and then the detector subjected to the windowing operation may receive the first reference light signal transmitted by the target device in the moving state. Thus, by windowing the detector, the response frequency can be further increased.

Step 302, obtaining a first position coordinate of the first reference optical signal.

In step 302, first position coordinates of a first reference optical signal may be acquired. The first position coordinate at which the opposite first reference light signal is detected on the local detector is (x1, y 1).

Step 303, determining a second position coordinate of the zero point position.

In step 303, a second position coordinate of the zero position may be determined.

And step 304, calculating a difference value between the first position coordinate and the second position coordinate.

In step 304, a difference between the first position coordinate and the second position coordinate may be calculated, i.e., a difference between the first position coordinate (x1, y1) of the first reference optical signal and the second position coordinate of the zero point position may be obtained.

And 305, adjusting the pitch angle and the yaw angle of the holder driven by the brushless motor according to the difference value so that the absolute value of the difference value between the position coordinate of the first reference light signal and the second position coordinate of the zero position is smaller than or equal to a preset threshold value.

In step 305, the pitch angle and yaw angle of the brushless motor driven pan/tilt head may be adjusted according to the difference value, so that the absolute value of the difference value between the position coordinate of the first reference light signal and the second position coordinate of the zero point position is less than or equal to a preset threshold value. The difference value can be used as an input signal, and the pitch angle and the yaw angle of a holder driven by a brushless motor in the moving single-mode optical fiber tracking device are adjusted through PID control, so that the position of the first reference light signal moves to the zero position. After the PID parameters are reasonably selected, the position of the first reference light signal can be always near the zero position, so that the integral pointing of the holder is ensured.

Step 306, receiving a second reference optical signal transmitted by the target device.

In step 306, fine tracking can be performed when the transmitted beam needs to be further collected into a single mode fiber. The fine tracking system may include a detector and a deflection mirror. The detector may be a CMOS, CCD or four quadrant detector. The deflection mirror may be a piezo ceramic driven deflection mirror. A second reference optical signal transmitted by the target device may be received.

And 307, controlling the second reference light signal to deflect, so that the deflected second reference light signal is transmitted to a target single-mode optical fiber of the mobile single-mode optical fiber tracking device.

In step 307, the second reference light signal may be deflected by controlling the deflection mirror, so that the deflected second reference light signal is transmitted into the target single mode fiber of the mobile single mode fiber tracking device. At this time, the link between the mobile single-mode fiber tracking device and the target device is established, and light beam transmission can be carried out.

Optionally, after the step of controlling the second reference optical signal to deflect, the method further includes:

receiving a target optical signal, wherein the target optical signal is obtained after a collimating telescope of the target device adjusts a divergence angle of an optical signal emitted by a laser in the target device.

After the link between the mobile single-mode fiber tracking device and the target device is established, the target optical signal can be received. The target optical signal is obtained after a collimating telescope of the target device adjusts the divergence angle of an optical signal emitted by a laser in the target device. It should be noted that the light emitted from the laser is divergent, and only parallel light can be transmitted in the air without much loss. The collimating telescope adjusts the divergence angle of the optical signal emitted by the laser from diverging to parallel.

The application provides a method for moving single mode fiber tracking and aiming, which is applied to a device for moving single mode fiber tracking and aiming. The pitch angle and the yaw angle of a holder driven by a brushless motor in the mobile single-mode optical fiber tracking and aiming device can be adjusted according to the first reference light signal; the second reference optical signal can also be controlled to deflect, so that the deflected second reference optical signal is transmitted into a target single-mode optical fiber of the mobile single-mode optical fiber tracking device. And the effective tracking of the mobile device is realized.

Referring to fig. 4, fig. 4 is a structural diagram of a mobile single-mode optical fiber tracking device provided by the present application. As shown in fig. 4, the mobile single-mode fiber tracking device 400 includes a first receiving module 401, an adjusting module 402, a second receiving module 403, and a first control module 404, wherein:

a first receiving module 401, configured to receive a first reference optical signal transmitted by a target device in a moving state;

an adjusting module 402, configured to adjust a pitch angle and a yaw angle of a pan/tilt head driven by a brushless motor in the mobile single-mode fiber tracking and sighting device according to the first reference light signal;

a second receiving module 403, configured to receive a second reference optical signal transmitted by the target device;

a first control module 404, configured to control the second reference light signal to deflect, so that the deflected second reference light signal is transmitted into a target single-mode fiber of the mobile single-mode fiber tracking device.

Optionally, as shown in fig. 5, the adjusting module 402 includes:

the obtaining sub-module 4021 is configured to obtain a first position coordinate of the first reference light signal;

a determination sub-module 4022 for determining a second position coordinate of the zero point position;

a calculation sub-module 4023, configured to calculate a difference between the first position coordinate and the second position coordinate;

the adjusting submodule 4024 is configured to adjust a pitch angle and a yaw angle of the pan/tilt head driven by the brushless motor according to the difference, so that an absolute value of the difference between the position coordinate of the first reference light signal and the second position coordinate of the zero point position is smaller than or equal to a preset threshold.

Optionally, as shown in fig. 6, the mobile single-mode fiber tracking device further includes:

a detection module 405, configured to detect whether a spatial angle of the pan/tilt head driven by the brushless motor changes;

and a second control module 406, configured to control a pitch axis, a yaw axis, and a roll axis included in the brushless motor-driven pan/tilt to rotate when detecting that the spatial angle of the brushless motor-driven pan/tilt changes.

Optionally, as shown in fig. 7, the mobile single-mode fiber tracking device further includes:

a third receiving module 407, configured to receive a target optical signal, where the target optical signal is obtained after a collimating telescope of the target apparatus adjusts a divergence angle of an optical signal emitted by a laser in the target apparatus.

Optionally, as shown in fig. 8, the mobile single-mode fiber tracking device further includes:

an executing module 408, configured to perform a windowing operation on a detector included in the mobile single-mode fiber tracking device;

the first receiving module 401 is configured to receive the first reference light signal emitted by the target device in a moving state through the detector that is subjected to the windowing operation.

The mobile single-mode fiber tracking device 400 can implement each process implemented by the mobile single-mode fiber tracking device in the method embodiments of fig. 1 and fig. 3, and is not described herein again to avoid repetition. The mobile single-mode optical fiber tracking and aiming device 400 can adjust the pitch angle and the yaw angle of a cradle head driven by a brushless motor in the mobile single-mode optical fiber tracking and aiming device according to the first reference light signal; the second reference optical signal can also be controlled to deflect, so that the deflected second reference optical signal is transmitted into a target single-mode optical fiber of the mobile single-mode optical fiber tracking device. And the effective tracking of the mobile device is realized.

The embodiments provided in the present application are only a few examples of the general concept of the present application, and do not limit the scope of the present application. Any other embodiments extended according to the scheme of the present application without inventive efforts will be within the scope of protection of the present application for a person skilled in the art.

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