Disclosure of Invention
In order to solve the technical problems, the invention provides an automatic following control system and method for an unmanned model vehicle, which are used for realizing the automatic following of the unmanned model vehicle to a target.
The embodiment of the invention provides an automatic following control method of an unmanned model vehicle, which comprises the following steps:
s101, acquiring images shot by a camera device in a preset time period;
s102, selecting an initial following target according to the image shot by the camera device;
s103, carrying out blocking processing on the image shot by the camera device;
s104, selecting a central pixel as the pixel center of the image area from each image area after the image is partitioned, and taking other pixels of the image area as adjacent pixels; the distances from the adjacent pixels to the centers of the pixels are equal;
s105, performing data standardization processing on adjacent pixels of each image area to acquire characteristic information of the image areas;
s106, classifying the characteristic information of each image area into a combined group to obtain a characteristic image of the image;
s107, comparing the characteristic image of the image with the characteristic image in the previous frame of image, and judging whether the initial following target is a following target;
s108, if so, determining the initial following target as a following target;
and S109, acquiring the relative position of the following target and the center of the camera device according to the image, and adjusting the camera device.
Further, the preset time period is 60ms, and the image capturing device captures an image at the preset time period of one frame of 60 ms.
Further, before the step S102, the method further includes: processing the image shot by the camera device; the method comprises the following steps:
acquiring a light quantity value of each pixel in the image;
acquiring the ratio of the light quantity value of each pixel to a standard light quantity value acquired when the following target is irradiated;
comparing the ratio with the preset threshold; if the ratio is larger than the preset threshold value, judging the pixel as an abnormal pixel; if the ratio is smaller than the preset threshold value, judging the pixel to be a normal pixel;
and calculating a standard light value of the abnormal pixel according to the light values of the normal pixels adjacent to the abnormal pixel, and replacing the light value of the abnormal pixel with the standard light value.
Further, before the step S109, the method further includes: measuring a distance between the camera device and the following target; the method specifically comprises the following steps:
transmitting a laser signal to the following target and receiving a reflected laser signal;
acquiring the time interval between the emission of the laser signal and the reception of the reflected laser signal;
calculating a sample value of the change time of the received reflected laser signal;
correcting the time interval according to the sample value of the change time;
according to the corrected time interval, obtaining the distance between the following target and the unmanned model vehicle;
comparing the distance with a set distance threshold according to the distance; if the distance is smaller than or equal to the set threshold value, controlling the unmanned model vehicle to stop moving; if the distance is larger than the set threshold value, controlling the unmanned model vehicle to move;
wherein, the step of calculating the sample value of the change time of the received reflected laser signal further comprises: one parameter of the spectral width, wavelength and signal energy of the received laser signal is adjusted such that the sample value of the variation time is minimized.
Further, the image shot by the camera is subjected to blocking processing according to the following formula:
wherein QiIs an image matrix of the i-th frame image, Q, taken by the imaging deviceimnIs the pixel point of the mth row and the nth column in the image matrix of the ith frame image, AipkThe image matrix of the ith frame image is subjected to blocking processing to obtain a block matrix of the kth row and the kth column in the block matrix;
accordingly, the pixels of the feature information included in each block matrix after being partitioned are determined according to the following formula:
ti11∈Ai11;ti12∈Ai12;…ti1k∈Ai1k;…tipk∈Aipk;
wherein t isiCarrying out blocking processing on an image matrix of the ith frame image to obtain a pixel containing characteristic information in a block matrix corresponding to the block matrix, tipkPixel points of characteristic information of the kth row and the kth column in the block matrix; at tiOn the basis, a feature matrix of the ith frame image is formed according to the following formula:
and Ti is a characteristic matrix of the ith frame image, and the characteristic matrix of the ith frame image is compared with the characteristic matrix of the previous frame by using the following equation, so that the adjustment angle and the distance of the camera device are obtained:
in order to enable the camera to accurately follow the target, extracting coordinates corresponding to the same elements in the feature matrix of the previous frame, and then calculating as follows:
wherein θ is the angle to be adjusted by the image pickup device, (m)j,i,nj,i) Is composed ofCoordinates corresponding to the jth identical element in the feature matrix of the ith frame image (a)j,i-1,bj,i-1) The coordinate corresponding to the jth identical element in the feature matrix of the ith-1 frame image is shown, u is the total number of the identical elements in the feature matrix, and L is the distance to be adjusted by the camera device.
The coordinate corresponding to the same element and the formula are used for calculating the angle, so that the rotating accuracy of the camera is greatly improved, the moving distance is calculated in a mode that the coordinate and the characteristic matrix are integrally combined, the moving error of the camera can be reduced, and the camera can move more accurately.
Corresponding to the method, the embodiment of the invention provides an automatic following control system of an unmanned model vehicle, which comprises a camera device, a processing module, a following target identification module and an adjusting module;
the camera device is used for shooting according to a preset time period and transmitting the acquired image to the processing module;
the processing module is used for processing the image to obtain the initial following target;
the following target identification module comprises a blocking unit, a feature extraction unit, a feature image synthesis unit and a feature comparison unit; the blocking unit is used for carrying out blocking processing on the image shot by the camera device; the feature extraction unit is configured to acquire adjacent pixels in each image region after the image is segmented, and perform normalization processing on the adjacent pixels to acquire feature information in the image region; the characteristic image synthesis unit is used for classifying the characteristic information of each image area into a synthesis group and acquiring the characteristic image of the image; the characteristic comparison unit is used for comparing the characteristic image of the image with the characteristic image in the previous frame of image and judging whether the initial following target is the following target or not;
the adjusting module is used for acquiring the relative position of the following target and the center of the camera device according to the image and adjusting the angle of the camera device.
Further, the blocking unit performs a blocking process on the image captured by the image capturing device according to the following formula:
wherein QiIs an image matrix of the i-th frame image, Q, taken by the imaging deviceimnIs the pixel point of the mth row and the nth column in the image matrix of the ith frame image, AipkThe image matrix of the ith frame image is subjected to blocking processing to obtain a block matrix of the kth row and the kth column in the block matrix;
accordingly, the pixels of the feature information included in each block matrix after being partitioned are determined according to the following formula:
ti11∈Ai11;ti12∈Ai12;…ti1k∈Ai1k;…tipk∈Aipk;
wherein t isiCarrying out blocking processing on an image matrix of the ith frame image to obtain a pixel containing characteristic information in a block matrix corresponding to the block matrix, tipkPixel points of characteristic information of the kth row and the kth column in the block matrix; at tiOn the basis, a feature matrix of the ith frame image is formed according to the following formula:
wherein T isiComparing the feature matrix of the ith frame image with the feature matrix of the previous frame by using the following equations, thereby obtaining the adjustment angle and the distance of the camera device:
in order to enable the camera to accurately follow the target, extracting coordinates corresponding to the same elements in the feature matrix of the previous frame, and then calculating as follows:
wherein θ is the angle to be adjusted by the image pickup device, (m)j,i,nj,i) The coordinates corresponding to the jth identical element in the feature matrix of the ith frame image are (a)j,i-1,bj,i-1) The coordinate corresponding to the jth identical element in the feature matrix of the ith-1 frame image is shown, u is the total number of the identical elements in the feature matrix, and L is the distance to be adjusted by the camera device.
Further, the camera device comprises a timing unit, a camera and a microcontroller; the microcontroller is electrically connected with the timing unit and the camera; the timing unit is used for timing according to the preset time period and transmitting a timing ending signal to the microcontroller; the microcontroller is used for controlling the camera to shoot when receiving the timing ending signal;
in the preset time period, workers can set the time period manually according to actual requirements; the preset time period is set to 60ms by default.
Further, the system also comprises an unmanned model vehicle;
the unmanned model vehicle comprises a driving device, a solar power supply device, a storage battery and a control unit; the control units are electrically connected with the driving device, the solar cell panel and the storage battery; the control unit is used for controlling the solar power supply device to receive solar light energy and convert the solar light energy into electric energy to be stored in the storage battery; the control unit is also used for controlling the storage battery to transmit electric energy to the driving device to drive the unmanned model vehicle to move;
the solar power supply device comprises: the solar energy collecting device comprises a direction angle adjusting device and a solar panel; the direction angle adjusting device comprises a base, a first linking device is arranged above the base, a first support frame perpendicular to the base is arranged at the upper end of the first linking device, a second support frame is arranged on the right side of the first support frame, two ends of the linking device are respectively linked with the lower sides of the first support frame and the second support frame, the linking device is connected with a circular arc-shaped adjusting device, the lower end of the adjusting device is fixedly arranged on the base, the upper end of the adjusting device is fixedly arranged on the first support frame, a sliding groove is arranged on the adjusting device, a double-headed bolt is connected in the sliding groove, one end of the double-headed bolt is linked with the linking device, and the other end of the double-headed bolt is connected with a first control device through the adjusting device; the upper end of the first support frame and the upper end of the second support frame are both connected with the second connecting device, a fixed flat plate is arranged on the second connecting device, concave parts are arranged at two ends of the flat plate, an arc-shaped regulator is arranged at the concave parts of the flat plate, a stud is arranged on the regulator, the upper end of the stud is arranged on a battery installation device, the lower end of the stud is connected with a second control device through the regulator, a spring is arranged on the stud, one end of the spring is connected with the battery installation device, and the other end of the spring is connected with the regulator; the solar cell panel is arranged on the cell mounting device.
Further, the system also comprises a laser scanning device;
the laser scanning device comprises a laser emitting subunit, a laser receiving subunit and a processing subunit;
the laser emission subunit is used for emitting a laser signal to the following target;
the laser receiving subunit is used for receiving the laser signal reflected back by the following target;
the processing subunit is configured to process a laser signal received by the laser receiving subunit, a time interval between the laser emitted by the laser emitting subunit and a laser signal reflected back by the laser receiving subunit, and obtain a distance between the following target and the unmanned model vehicle.
Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.
The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.
Detailed Description
The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.
The embodiment of the invention provides an automatic following control method of an unmanned model vehicle, which comprises the following steps of:
s101, acquiring images shot by a camera device in a preset time period;
s102, selecting an initial following target according to an image shot by the camera device;
s103, carrying out blocking processing on the image shot by the camera device;
s104, selecting a central pixel as the pixel center of the image area from each image area after image blocking, and taking other pixels of the image area as adjacent pixels; the distances from the adjacent pixels to the centers of the pixels are equal;
s105, performing data standardization processing on adjacent pixels of each image area to acquire characteristic information of the image areas;
s106, classifying the characteristic information of each image area into a combined group to obtain a characteristic image of the image;
s107, comparing the characteristic image of the image with the characteristic image in the previous frame of image, and judging whether the initial following target is the following target or not;
s108, if so, determining the initial following target as a following target;
and S109, adjusting the camera device according to the relative position of the image acquisition following target and the center of the camera device.
The working principle of the method is as follows: the method comprises the following steps that a camera device shoots images according to a preset time period, and an initial following target is selected according to the shot images; the method comprises the steps of carrying out blocking processing on a camera device, obtaining adjacent pixels of each image area in an image, carrying out data standardization processing on the adjacent pixels, and obtaining characteristic information of each image area; the characteristic information of each image area is put into a combined group to form a characteristic image of the image; and comparing the characteristic image of the image with the characteristic image in the previous frame of image, judging whether the selected initial following target is the following target, if the initial following target is judged to be the following target, acquiring the relative position of the following target and the center of the camera device according to the shot image, and adjusting the angle of the camera device.
The method has the beneficial effects that: selecting an initial following target through an image shot by a camera device, realizing the initial selection of the following target by the unmanned model vehicle, carrying out block processing on the shot image to obtain adjacent pixels of each image area, carrying out data standardization processing and obtaining the characteristic information of each image area; the characteristic information of each image area is put into a combined group to form a characteristic image of the image; the extraction of the characteristic image of the shot image is realized; comparing the characteristic image of the acquired image with the characteristic image extracted from the previous frame of image, judging whether the image is the same following target or not, and if so, determining the initial following target as the following target; adjusting the shooting angle of the camera device according to the position of the following target in the image; the method realizes the identification of the initial following target in the image shot by the camera device, and judges and compares the obtained initial following target, thereby ensuring the uniqueness of the following target of the unmanned model vehicle; thereby realizing the automatic following function of the unmanned model vehicle.
In one embodiment, the preset time period is 60ms, and the image capturing device captures images in a preset time period of one frame of 60 ms. According to the technical scheme, the image is shot in one frame of 60ms through the camera device, the following target is judged and compared every 60ms, and the following of the following target by the unmanned model car is more accurate.
In one embodiment, before step S102, the method further comprises: processing an image shot by the camera device; the method comprises the following steps:
acquiring a light quantity value of each pixel in an image;
acquiring the ratio of the light quantity value of each pixel to a standard light quantity value acquired when the pixel irradiates a following target;
comparing the ratio with a preset threshold; if the ratio is larger than a preset threshold value, judging the pixel as an abnormal pixel; if the ratio is smaller than a preset threshold value, the pixel is judged to be a normal pixel;
and calculating a standard light value of the obtained abnormal pixel according to the light values of the normal pixels adjacent to the abnormal pixel, and replacing the light value of the abnormal pixel with the standard light value.
According to the technical scheme, after the image is shot by the camera device, the light quantity value of each pixel of the shot image is obtained, the light quantity value of the pixel is compared with the standard light quantity value to obtain a ratio, the ratio of each pixel is compared with a preset threshold value, and whether the pixel is an abnormal pixel or not is judged; if the abnormal pixel is judged, calculating a standard light value corresponding to the anti-positive pixel according to the normal pixels adjacent to the abnormal pixel and replacing the standard light value; therefore, the light quantity value of the pixel of the shot image is detected, and the abnormal pixel light quantity value is corrected and replaced, so that an image with higher quality can be obtained, and the image can be conveniently processed by other subsequent steps.
In one embodiment, before step S109, the method further comprises: measuring the distance between the camera device and the following target; the method specifically comprises the following steps:
transmitting a laser signal to a following target and receiving a reflected laser signal;
acquiring the time interval between the emission of the laser signal and the reception of the reflected laser signal;
calculating a sample value of the change time of the received reflected laser signal;
correcting the time interval according to the sample value of the change time;
acquiring the distance between the following target and the unmanned model vehicle according to the corrected time interval;
comparing the distance with a set distance threshold according to the distance; if the distance is smaller than or equal to the set threshold value, controlling the unmanned model vehicle to stop moving; if the distance is greater than the set threshold value, controlling the unmanned model vehicle to move;
wherein, the step of calculating the sample value of the change time of the received reflected laser signal further comprises: one parameter of the spectral width, wavelength and signal energy of the received laser signal is adjusted so that the sample value of the variation time is minimized.
According to the technical scheme, the laser signal is transmitted to the following target, and the reflected laser signal is received; acquiring a time interval between a transmitted laser signal and a received laser signal; correcting the time interval to obtain the distance between the measuring camera device and the following target; and comparing the acquired distance with a set distance threshold (for example, the set distance threshold is 5m), and judging whether the unmanned model vehicle moves along with the following target. According to the technical scheme, accurate distance measurement between the camera device and the following target is realized, the unmanned model vehicle moves according to the measured distance, and the distance between the unmanned model vehicle and the following target is adjusted.
In one embodiment, the image captured by the image capture device may be subjected to a blocking process according to the following formula:
wherein QiIs an image matrix of the i-th frame image, Q, taken by the imaging deviceimnIs the pixel point of the mth row and the nth column in the image matrix of the ith frame image, AipkThe image matrix of the ith frame image is subjected to blocking processing to obtain a block matrix of the kth row and the kth column in the block matrix;
accordingly, the pixels of the feature information included in each block matrix after being partitioned are determined according to the following formula:
ti11∈Ai11;ti12∈Ai12;…ti1k∈Ai1k;…tipk∈Aipk;
wherein t isiCarrying out blocking processing on an image matrix of the ith frame image to obtain a pixel containing characteristic information in a block matrix corresponding to the block matrix, tipkPixel points of characteristic information of the kth row and the kth column in the block matrix; at tiOn the basis, a feature matrix of the ith frame image is formed according to the following formula:
wherein T isiComparing the feature matrix of the ith frame image with the feature matrix of the previous frame by using the following equations, thereby obtaining the adjustment angle and the distance of the camera device:
in order to enable the camera to accurately follow the target, extracting coordinates corresponding to the same elements in the feature matrix of the previous frame, and then calculating as follows:
wherein θ is the angle to be adjusted by the image pickup device, (m)j,i,nj,i) The coordinates corresponding to the jth identical element in the feature matrix of the ith frame image are (a)j,i-1,bj,i-1) The coordinate corresponding to the jth identical element in the feature matrix of the ith-1 frame image is shown, u is the total number of the identical elements in the feature matrix, and L is the distance to be adjusted by the camera device.
The coordinate corresponding to the same element and the formula are used for calculating the angle, so that the rotating accuracy of the camera is greatly improved, the moving distance is calculated in a mode that the coordinate and the characteristic matrix are integrally combined, the moving error of the camera can be reduced, and the camera can move more accurately.
Corresponding to the foregoing method, an embodiment of the present invention further provides an automatic following control system for an unmanned model vehicle, as shown in fig. 2, including a camera 21, a processing module 22, a following target recognition module 23, and an adjusting module 24;
the camera device 21 is used for shooting according to a preset time period and transmitting the acquired image to the processing module;
the processing module 22 is used for processing the image and acquiring an initial following target;
the following target identification module 23 comprises a blocking unit, a feature extraction unit, a feature image synthesis unit and a feature comparison unit; the block unit is used for carrying out block processing on the image shot by the camera device; the characteristic extraction unit is used for acquiring adjacent pixels in each image area after the image is blocked, and carrying out standardization processing on the adjacent pixels to acquire characteristic information in the image area; the characteristic image synthesis unit is used for classifying the characteristic information of each image area into a synthesis group to obtain a characteristic image of the image; the characteristic comparison unit is used for comparing the characteristic image of the image with the characteristic image in the previous frame of image and judging whether the initial following target is the following target or not;
and the adjusting module 24 is configured to adjust an angle of the camera according to a relative position between the image acquisition following target and a center of the camera.
The working principle of the system is as follows: the image pickup device 21 performs image pickup according to a preset time period to obtain an image, and the processing module 22 processes the obtained image to obtain an initial following target; the image is subjected to blocking processing by following a blocking unit in the target identification module 23, the feature information of each image area acquired by the blocking unit is acquired by a feature extraction unit, and the feature information of each image area is classified into a combination group by a feature image synthesis unit to acquire a feature image of the image; the characteristic comparison unit compares the characteristic image of the image with the characteristic image in the previous frame of image and judges whether the initial following target is the following target or not; and the adjusting module 24 is used for adjusting the angle of the camera according to the position of the following target in the image after the following target is determined by the following target identifying module.
In practical application, an image shot by the camera device is an image matrix composed of pixels, and in order to solve the problem of blocking processing, namely, changing image partitions into block matrices and acquiring characteristic information in an image area so as to operate a camera moving mode, a specific process of establishing a model is as follows:
wherein QiIs an image matrix of the i-th frame image, Q, taken by the imaging deviceimnIs the pixel point of the mth row and the nth column in the image matrix of the ith frame image, AipkThe image matrix of the ith frame image is subjected to blocking processing to obtain a block matrix of the kth row and the kth column in the block matrix;
accordingly, the pixels of the feature information included in each block matrix after being partitioned are determined according to the following formula:
ti11∈Ai11;ti12∈Ai12;…ti1k∈Ai1k;…tipk∈Aipk;
wherein t isiCarrying out blocking processing on an image matrix of the ith frame image to obtain a pixel containing characteristic information in a block matrix corresponding to the block matrix, tipkPixel points of characteristic information of the kth row and the kth column in the block matrix; at tiOn the basis, a feature matrix of the ith frame image is formed according to the following formula:
wherein T isiComparing the feature matrix of the ith frame image with the feature matrix of the previous frame by using the following equations, thereby obtaining the adjustment angle and the distance of the camera device:
in order to enable the camera to accurately follow the target, extracting coordinates corresponding to the same elements in the feature matrix of the previous frame, and then calculating as follows:
wherein θ is the angle to be adjusted by the image pickup device, (m)j,i,nj,i) The coordinates corresponding to the jth identical element in the feature matrix of the ith frame image are (a)j,i-1,bj,i-1) The coordinate corresponding to the jth identical element in the feature matrix of the ith-1 frame image is shown, u is the total number of the identical elements in the feature matrix, and L is the distance to be adjusted by the camera device.
The beneficial effect of above-mentioned system lies in: the processing module selects an initial following target through an image shot by the camera device, so that the initial selection of the following target by the unmanned model vehicle is realized, and a blocking unit in the following target recognition module performs blocking processing on the shot image to divide the image into a plurality of image areas; the characteristic extraction unit is used for extracting characteristic information of each image area, and the characteristic information is classified into a combination group through the characteristic image combination unit to obtain a characteristic image of the image, so that the characteristic image of the image shot by the camera device is obtained; comparing the characteristic image of the image with the characteristic image in the previous frame of image through a characteristic comparison unit, judging whether the initial following target is the following target or not, if so, determining the initial following target as the following target, and adjusting the shooting angle of the camera device through an adjustment module according to the position of the following target in the image; the system realizes the identification of the initial following target in the image shot by the camera device through the processing module, and judges and compares the acquired initial following target through the following target identification module, thereby ensuring the following uniqueness of the unmanned model vehicle to the following target and realizing the automatic following function of the system.
In one embodiment, the camera device comprises a timing unit, a camera and a microcontroller; the microcontroller is electrically connected with the timing unit and the camera; the timing unit is used for timing according to a preset time period and transmitting a timing ending signal to the microcontroller; the microcontroller is used for controlling the camera to shoot when receiving the timing end signal;
the time period is preset, and workers can manually set the time period according to actual requirements; the preset time period is set to 60ms by default. According to the technical scheme, the timing unit, the camera and the microcontroller in the camera device are used for controlling the camera to perform timing shooting according to the preset time period in the timing unit through the microcontroller, so that the camera device can automatically perform timing shooting on the following target.
In one embodiment, the system further comprises an unmanned model vehicle;
the unmanned model vehicle comprises a driving device, a solar power supply device, a storage battery and a control unit; the control unit is electrically connected with the driving device, the solar cell panel and the storage battery; the control unit is used for controlling the solar power supply device to receive solar light energy and convert the solar light energy into electric energy to be stored in the storage battery; the control unit is also used for controlling the storage battery to transmit the electric energy to the driving device to drive the unmanned model vehicle to move;
solar power supply unit: as shown in fig. 3, the solar energy collecting device comprises a direction angle adjusting device 31 and a solar cell panel 32; the direction angle adjusting device 31 comprises a base 311, a first linking device 312 is arranged above the base 311, a first support frame 313 perpendicular to the base 311 is arranged at the upper end of the first linking device 312, a second support frame 314 is arranged on the right side of the first support frame 313, two ends of a linking device 315 are respectively linked with the lower sides of the first support frame 313 and the second support frame 314, the linking device 315 is connected with a circular arc-shaped adjusting device 316, the lower end of the adjusting device 316 is fixedly arranged on the base 311, the upper end of the adjusting device 316 is fixedly arranged on the first support frame 313, a sliding chute 3161 is arranged on the adjusting device 316, a stud 317 is connected in the sliding chute 3161, one end of the stud 317 is linked with the linking device 315, and the other end of the stud 317 is connected with a first control device 318 through the adjusting device 316; the upper end of the first support frame 313 and the upper end of the second support frame 314 are both connected with a second connecting device, the second connecting device is provided with a fixed flat plate 319, two ends of the flat plate 319 are provided with concave parts, the concave parts of the flat plate 319 are provided with arc-shaped regulators 3110, the regulators 3110 are provided with studs 3111, the upper ends of the studs 3111 are arranged on the battery installation device 3112, the lower ends of the studs 3111 are connected with a second control device 3113 through the regulators 3110, the studs 3111 are provided with springs 3114, one end of each spring 3114 is connected with the battery installation device 3112, and the other end of each spring 3110 is connected with the regulator 3110; the solar cell panel 32 is provided on the battery mounting apparatus 3112. In the above technical solution, the battery installation device 3112 is used for installing the solar panel 32, the battery installation device 3112, the first support frame 313, the second support frame 314 and the linkage device 315 form a parallelogram, and the linkage device 315 is used for adjusting the up-down angle of the battery installation device 3112; simultaneously through rotating second controlling means 3113, change between dull and stereotyped 319 and the battery installation device 3112 length of double-screw bolt 3111, alright realize battery installation device 3112 and control the rotation to realized the omnidirectional rotation of solar cell panel 32, above-mentioned technical scheme has realized the regulation to battery installation device 3112 angle, and then has improved solar cell panel 32's photoelectric conversion efficiency.
In one embodiment, the system further comprises a laser scanning device;
the laser scanning device comprises a laser emitting subunit, a laser receiving subunit and a processing subunit;
the laser emission subunit is used for emitting a laser signal to the following target;
the laser receiving subunit is used for receiving the laser signal reflected back by the target;
and the processing subunit is used for processing the laser signal received by the laser receiving subunit, the time interval between the laser emitted by the laser emitting subunit and the laser signal reflected by the laser receiving subunit to obtain the distance between the following target and the unmanned model vehicle. According to the technical scheme, the laser emission subunit in the laser scanning device emits laser signals to the following target, the laser receiving subunit receives the laser signals reflected back by the following target, the processing subunit acquires the time interval between the time of emitting the laser signals and the time of receiving the laser signals and processes the time interval, and distance measurement between the following target and the unmanned model vehicle is achieved.
It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.