Three-dimensional space positioning device and method based on thermal imaging technology
阅读说明:本技术 一种基于热成像技术的三维空间定位装置及方法 (Three-dimensional space positioning device and method based on thermal imaging technology ) 是由 吴倩 李韫良 杨立娜 于 2020-05-12 设计创作,主要内容包括:本发明公开了一种基于热成像技术的三维空间定位装置和方法,包括:平台移动装置,移动检测装置和热成像定位装置。所述平台移动装置包括横向平台和横向驱动件,横向平台上侧安装有升降平台和升降驱动件;所述移动检测装置包括弧形轨道,检测平台和检测平台移动机构;所述热成像定位装置连续生成、回传并分析处理待定位位置的热力学图像,实时标定待测位置的空间坐标。本发明可以利用尾气口排出的热尾气,采用热成像摄像机进行热点标定,判别尾气口位置,提高抗尾气口污染程度,气象条件等因素影响的能力,提高实用性,实现自动识别、定位待测位置,现场无人作业、自动化操作。(The invention discloses a three-dimensional space positioning device and a method based on thermal imaging technology, which comprises the following steps: the device comprises a platform moving device, a movement detection device and a thermal imaging positioning device. The platform moving device comprises a transverse platform and a transverse driving piece, and a lifting platform and a lifting driving piece are arranged on the upper side of the transverse platform; the mobile detection device comprises an arc-shaped track, a detection platform and a detection platform moving mechanism; the thermal imaging positioning device continuously generates, transmits back, analyzes and processes the thermodynamic image of the position to be positioned, and calibrates the space coordinate of the position to be measured in real time. The hot tail gas outlet hot spot calibration device can utilize the hot tail gas discharged from the tail gas outlet, adopts the thermal imaging camera to calibrate the hot spot, judges the position of the tail gas outlet, improves the capability of resisting the influence of factors such as the pollution degree of the tail gas outlet, meteorological conditions and the like, improves the practicability, realizes automatic identification and positioning of the position to be detected, and realizes unmanned operation and automatic operation on site.)
1. A three-dimensional space positioning device based on thermal imaging technology is characterized by comprising a platform moving device, a movement detection device and a thermal imaging positioning device, wherein,
the platform moving device comprises a transverse platform (1-1), a transverse driving piece (1-2), a lifting platform (1-3) and a lifting driving piece (1-4), wherein the transverse platform (1-1) is installed on the transverse driving piece, the transverse driving piece (1-2) drives the transverse platform (1-1) to move along the X-axis direction, the lifting driving piece (1-4) is installed on the transverse moving platform (1-1), the lifting platform (1-3) is installed at the upper end of the lifting driving piece (1-4), and the lifting driving piece (1-4) drives the lifting platform (1-3) to move along the Z-axis direction;
the mobile detection device comprises two arc-shaped rails (3-1), a detection platform (3-2) and a detection platform moving mechanism, wherein the detection platform (3-2) is connected between the two arc-shaped rails (3-1) in a sliding mode through the detection platform moving mechanism and slides along the arc-shaped rails (3-1), the two arc-shaped rails (3-1) are symmetrically arranged, and the tail end of each arc-shaped rail (3-1) is welded in the center of the lifting platform (1-3) through two supporting plates (3-4);
the thermal imaging positioning device comprises two thermal imaging cameras (4-1), an image information identification system (4-2) and an image processing system (4-3), wherein the two thermal imaging cameras (4-1) are symmetrically fixed on the upper half part of a detection platform, the image information identification system (4-2) and the image processing system (4-3) are both fixedly arranged on the detection platform, and the image information identification system (4-2) and the image processing system (4-3) are in information connection with the two thermal imaging cameras through data lines respectively.
2. The three-dimensional space positioning device based on the thermal imaging technology as claimed in claim 1, wherein the transverse driving member comprises two sliding guide rails (2-1), a lead screw (2-2), a lead screw motor (2-3) and two support plates (2-4), the two sliding guide rails (2-1) are arranged on two sides of the bottom of the transverse platform (1-1) in parallel along the X axis, the bottom of the transverse platform (1-1) is slidably connected with the two sliding guide rails (2-1), the two support plates (2-4) are symmetrically arranged on two sides of the transverse platform (1-1) along the X axis, two ends of the lead screw (2-2) are fixedly connected with the two support plates (2-4), respectively, and the lead screw (2-2) is parallel with the sliding guide rails (2-1), the lead screw motor (2-3) is installed on the lead screw (2-2), the lead screw motor (2-3) moves on the lead screw (2-2), and the lead screw motor (2-3) is connected with the bottom of the transverse platform (1-1) in a rotating fit mode through 4 lead screw nuts.
3. The three-dimensional space positioning device based on thermal imaging technology as claimed in claim 1 or 2, wherein the lifting driving member (1-4) is a cylinder, and two ends of the cylinder are respectively connected with the top end of the transverse platform (1-1) and the bottom end of the lifting platform (1-4).
4. The thermal imaging technology-based three-dimensional space positioning device according to claim 1, wherein two arc-shaped rails (3-1) are symmetrically arranged, the two arc-shaped rails (3-1) are 1/4 arc-shaped guide rails with the radius of 200mm, the top ends of the two arc-shaped rails (3-1) are welded through limiting plates (3-3), arc-shaped guide grooves (3-7) are arranged on two opposite side faces of the two arc-shaped rails (3-1), and racks (3-5) and rack protection grooves (3-6) are welded on the back faces of the two arc-shaped rails (3-1).
5. The three-dimensional space positioning device based on the thermal imaging technology as claimed in claim 3, wherein the detection platform moving mechanism comprises a support platform (5-1), four pulleys (5-2), two support rods (5-3), a transmission rod (5-4), two gears (5-5) and a detection platform motor, the support platform (5-1) is fixedly welded on the back of the detection platform (3-2), the transmission rod (5-4) is rotatably connected to the support platform (5-1), two ends of the transmission rod (5-4) are respectively and fixedly connected with the gears (5-5), two support rods (5-3) are respectively arranged at two ends of the upper and lower sides of the detection platform (3-2), and two ends of each support rod (5-3) are respectively provided with one pulley (5-2), the detection platform is characterized in that gears (5-5) at two ends of the transmission rod (5-4) are respectively meshed with racks (3-5) of the two arc-shaped rails (3-1) to be connected, pulleys at two ends of each supporting rod are respectively connected in the arc-shaped guide grooves (3-7) in a sliding mode, and the detection platform motor is arranged inside the supporting platform (5-1) and is in driving connection with the transmission rod (5-4).
6. The thermal imaging technology-based three-dimensional space positioning device according to claim 1, characterized in that the transverse platform (1-1) is a cuboid structure; the lifting platform (1-3) is a cube, and the initial position of the lifting platform (1-3) is set at the lowest height in the lifting range.
7. The thermal imaging technology-based three-dimensional space positioning device according to claim 1, wherein the sliding guide rail (2-1) is made of a steel structure of a H-shaped steel.
8. A three-dimensional space positioning method based on thermal imaging technology is characterized in that the positioning is realized by the three-dimensional space positioning device based on thermal imaging technology according to claims 1-7, and the specific steps are as follows:
step 1: the device is located at an initial position before detection is started, and the initial position is as follows: the transverse platform (1-1) is positioned at the left rear part of the tail part of the automobile to be detected, the air cylinder is in the shortest length state, the detection platform (3-2) is positioned at the highest part of the arc-shaped track (3-1), two thermal imaging cameras (4-1) on the detection platform (3-2) shoot thermodynamic images of the tail part of the automobile to be detected, the thermodynamic images comprise a left image L and a right image R, then the thermodynamic images shot by the two thermal imaging cameras (4-1) are respectively transmitted to the image information recognition system (4-2) and the image processing system (4-3), the image information recognition system (4-2) and the image processing system (4-3) carry out image preprocessing and image region segmentation on the received thermodynamic image, comparing the position thermodynamic image with a stored position thermodynamic image, and selecting a target image for further determining the position coordinate of the space position to be detected;
step 2: the image processing system (4-3) calibrates the processed thermodynamic image left image L and the processed thermodynamic image right image R through Zhang calibration to respectively obtain the camera internal and external parameters of the two corresponding thermal imaging cameras (4-1);
and step 3: the image processing system (4-3) corrects the left image L and the right image R through the internal and external parameters of the camera obtained in the step 2 so as to remove distortion of the left image L and the right image R and align polar lines of the two images;
and 4, step 4: aiming at the corrected left image L and right image R, parallel SGM algorithm calculation is utilized to obtain a disparity map, an image processing system (4-3) carries out post-processing on the obtained disparity map, noise is removed by a median filtering method, the relative position coordinate of the space position to be measured is calculated, the image processing system (4-3) transmits the calculated relative position coordinate to a transverse driving piece (1-2) through a data line, and a lead screw motor (2-3) is driven to work, so that the transverse platform (1-1) moves along the x-axis direction;
and 5: the transverse driving piece (1-2) starts to work, the transverse platform (1-1) starts to move from an initial position, when the lead screw motor (2-3) moves to a coordinate position in the x-axis direction which is the same as the spatial position to be measured, the transverse driving piece stops running, and the transverse platform (1-1) stops moving;
step 6: after the transverse driving piece (1-2) stops working, the initial position of the detection platform (3-2) is located at the highest position of the arc-shaped track (3-1), at the moment, the two thermal imaging cameras (4-1) shoot images, the shot thermodynamic images are transmitted to the image information identification system (4-2) and the image processing system (4-3), and the stored position thermodynamic images are compared to process the shot images;
and 7: according to the shot images, the detection platform moving mechanism moves, in the operation process of the detection platform moving mechanism, two thermal imaging cameras (4-1) continuously shoot thermodynamic images, corresponding image preprocessing and relative position coordinate real-time calibration in the step 1-3 are sequentially executed in real time, the image processing system (4-3) transmits the calculated relative position coordinate to a detection platform motor and an air cylinder through a data line, the air cylinder extends firstly, when the air cylinder operates to the real-time calibrated coordinate position in the direction of the z axis, the detection platform motor is controlled to drive a gear (5-5) to operate, the gear (5-5) and a rack (3-5) are meshed to realize the movement of the detection platform (3-2), when the relative position calibrated in the space of the position to be detected is closest to the thermal imaging cameras (4-1), detecting the stop motion of a platform motor, namely moving to corresponding y and z coordinates;
and 8: after the position of the space to be detected is found, the detection platform motor drives the detection platform (3-2) to recover to the highest position of the arc-shaped track (3-1), the lifting driving piece (1-4) contracts to the shortest position, the screw rod motor (2-3) rotates to drive the transverse platform (1-1) to return to the initial position, and detection is finished.
Technical Field
The invention relates to a three-dimensional space positioning device and method based on a thermal imaging technology, and belongs to the technical field of space positioning.
Background
In nature, all objects radiate infrared rays, so that different infrared images can be obtained by measuring the infrared ray difference between a target and a background by using a detector. The infrared thermal imager adopts an infrared thermal imaging technology to detect infrared radiation of a target object, and converts a temperature distribution image of the target object into a video image through means of photoelectric conversion, signal processing and the like.
A camera is a device that converts an optical image signal into an electrical signal for storage or transmission. When an object is shot, light reflected by the object is collected by a camera lens, so that the light is focused on a light receiving surface of an image pickup device (such as a target surface of an image pickup tube), and the light is converted into electric energy through the image pickup device, so that a video signal is obtained. The photoelectric signal is weak, and needs to be amplified through a pre-discharge circuit, and then processed and adjusted through various circuits, and finally the obtained standard signal can be sent to a recording medium such as a video recorder and the like to be recorded, or can be transmitted through a transmission system or sent to a monitor to be displayed. However, under the influence of environmental factors, such as rainy days and dark nights, the camera cannot work well. Therefore, a device capable of three-dimensional positioning using the property of heat generation of a part of an object is required.
The existing tail gas detection device in the market is partially manually held, and the other part is visual butt joint of a camera. Wherein, the human body is greatly injured by manual holding; the visual butt joint of camera receives factor influences such as tail gas mouth pollution degree, meteorological condition, and the condition that can't discern often can appear.
Disclosure of Invention
In order to overcome the defects in the prior art, the invention provides a three-dimensional space positioning device and a three-dimensional space positioning method based on a thermal imaging technology, which can utilize hot tail gas discharged from a tail gas port, adopt a thermal imaging camera to calibrate hot spots, judge the position of the tail gas port, improve the capability of resisting the influence of factors such as the pollution degree of the tail gas port, meteorological conditions and the like, improve the practicability, realize automatic identification and positioning of a position to be detected, and realize unmanned operation and automatic operation on site.
The invention mainly adopts the technical scheme that:
a three-dimensional space positioning device based on thermal imaging technology comprises a platform moving device, a movement detection device and a thermal imaging positioning device, wherein,
the platform moving device comprises a transverse platform, a transverse driving piece, a lifting platform and a lifting driving piece, wherein the transverse platform is installed on the transverse driving piece, the transverse driving piece drives the transverse platform to move along the X-axis direction, the lifting driving piece is installed on the transverse moving platform, the lifting platform is installed at the upper end of the lifting driving piece, and the lifting driving piece drives the lifting platform to move along the Z-axis direction;
the mobile detection device comprises two arc-shaped rails, a detection platform and a detection platform moving mechanism, wherein the detection platform is connected between the two arc-shaped rails in a sliding mode through the detection platform moving mechanism and slides along the arc-shaped rails, the two arc-shaped rails are symmetrically arranged, and the tail end of each arc-shaped rail is welded in the center of the lifting platform through two supporting plates;
the thermal imaging positioning device comprises two thermal imaging cameras, an image information identification system and an image processing system, wherein the two thermal imaging cameras are symmetrically fixed on the upper half part of the detection platform, the image information identification system and the image processing system are both fixedly arranged on the detection platform, and the image information identification system and the image processing system are respectively in information connection with the two thermal imaging cameras.
Preferably, the transverse driving member includes two sliding guide rails, a lead screw motor and two supporting plates, two sliding guide rails are arranged on two sides of the bottom of the transverse platform along the X axis in parallel, the bottom of the transverse platform is connected with the two sliding guide rails in a sliding manner, the two supporting plates are arranged on two sides of the transverse platform along the X axis in a symmetrical manner, two ends of the lead screw are respectively fixedly connected with the two supporting plates, the lead screw is parallel to the sliding guide rails, the lead screw motor moves on the lead screw, the lead screw motor is connected with the bottom of the transverse platform through 4 lead screw nuts in a rotating fit manner, and the lead screw motor is fixed with the transverse platform through the lead screw nuts to further realize the movement of the transverse platform.
Preferably, the lifting driving part is a cylinder, and two ends of the cylinder are respectively connected with the top end of the transverse platform and the bottom end of the lifting platform.
Preferably, two arc track symmetries set up, and two the arc track is radius 1/4 circular arc guide rail, two that is 200mm the orbital top of arc is passed through limiting plate welding and is constituteed, two be equipped with the arc guide way on the relative both sides face of arc track, two orbital back welding of arc has rack and rack protection groove along the setting of arc guide rail.
Preferably, testing platform moving mechanism includes supporting platform, four pulleys, two spinal branch vaulting poles, transfer line, two gears, testing platform motor, the fixed welding of supporting platform is at the testing platform back, the transfer line rotates to be connected on the supporting platform, the transfer line both ends respectively with gear fixed connection, two both sides both ends about the testing platform are worn to establish respectively to the bracing piece, and every the both ends of bracing piece all are equipped with a pulley, the gear at transfer line both ends respectively with two orbital rack intermeshing of arc is connected, every the pulley at bracing piece both ends is sliding connection respectively in the arc guide way, the testing platform motor sets up inside the supporting platform, and with the transfer line drive is connected.
Preferably, the transverse platform is a cuboid structure; the lifting platform is a cube, and the initial position of the lifting platform is set at the lowest height in the lifting range.
Preferably, the sliding guide rail is made of an i-shaped steel structure.
A three-dimensional space positioning method based on thermal imaging technology comprises the following specific steps:
step 1: the device is located at an initial position before detection is started, and the initial position is as follows: the system comprises a transverse platform, a cylinder, an arc-shaped track, two thermal imaging cameras, an image information identification system and an image processing system, wherein the transverse platform is positioned at the left rear part of the tail part of an automobile to be detected, the cylinder is in the shortest length state, the detection platform is positioned at the highest position of the arc-shaped track, the two thermal imaging cameras on the detection platform shoot thermodynamic images of the tail part of the automobile to be detected, the thermodynamic images comprise a left image L and a right image R, then the thermodynamic images shot by the two thermal imaging cameras are respectively transmitted to the image information identification system and the image processing system, the image information identification system and the image processing system carry out image preprocessing and image area segmentation on the received thermodynamic images, the thermodynamic images are compared with stored thermodynamic images, and;
step 2: the image processing system calibrates the processed thermodynamic image left image L and the processed thermodynamic image right image R through Zhang calibration to respectively obtain the camera internal and external parameters of the two corresponding thermal imaging cameras;
and step 3: the image processing system corrects the left image L and the right image R through the internal and external parameters of the camera obtained in the step 2, so that the distortion of the left image L and the distortion of the right image R are removed, and the polar lines of the two images are aligned;
and 4, step 4: aiming at the corrected left image L and right image R, parallel SGM algorithm calculation is utilized to obtain a disparity map, an image processing system carries out post-processing on the obtained disparity map, noise is removed by a median filtering method, the relative position coordinate of a space position to be measured is calculated, the image processing system transmits the calculated relative position coordinate to a transverse driving piece through a data line, and a lead screw motor is driven to work, so that the transverse platform moves along the x-axis direction;
and 5: the transverse driving piece starts to work, so that the transverse platform starts to move from an initial position, when the screw motor moves to a coordinate position in the x-axis direction which is the same as the spatial position to be measured, the operation is stopped, and the transverse platform stops moving;
step 6: after the transverse driving piece stops working, the initial position of the detection platform is located at the highest position of the arc-shaped track, at the moment, the two thermal imaging cameras shoot images and transmit the shot thermodynamic images to the image information recognition system and the image processing system, and the stored position thermodynamic images are compared to process the shot images;
and 7: according to the shot images, the detection platform moving mechanism moves, in the operation process of the detection platform moving mechanism, two thermal imaging cameras continuously shoot thermodynamic images, corresponding image preprocessing and relative position coordinates calibration in the steps are sequentially executed in real time, the image processing system transmits the calculated relative position coordinates to a detection platform motor and an air cylinder through a data line, the air cylinder extends firstly, when the air cylinder operates to a real-time calibrated z-axis coordinate position, the detection platform motor is controlled to drive a gear to operate, the detection platform moves through gear and rack meshing, and when the relative position calibrated in the space of the position to be detected is closest to the thermal imaging camera, the detection platform motor stops moving to the corresponding y and z coordinates;
and 8: after the position of the space to be detected is found, the detection platform is driven by the detection platform motor to recover to the highest position of the arc-shaped track, the lifting driving piece is contracted to the shortest position, the screw rod motor rotates to drive the transverse platform to return to the initial position, and detection is finished.
Has the advantages that: the invention discloses a three-dimensional space positioning device and a method based on a thermal imaging technology, wherein the existing visual positioning device is greatly influenced by environmental factors, such as under the conditions of rainy days, dark night, polluted environment and the like, a camera cannot work well.
Drawings
FIG. 1 is a schematic view of the overall structure of the present invention;
FIG. 2 is a schematic view of the transverse drive member assembly of the present invention;
FIG. 3 is a schematic view of a movement detection device according to the present invention;
FIG. 4 is a schematic view of a thermal imaging positioning apparatus of the present invention;
FIG. 5 is a schematic view of a moving mechanism of the testing platform according to the present invention;
FIG. 6 is a flow chart of the operation of the present invention;
in the figure: the device comprises a transverse platform 1-1, a transverse driving piece 1-2, a lifting platform 1-3, a lifting driving piece 1-4, a sliding guide rail 2-1, a screw rod 2-2, a screw rod motor 2-3, a support plate 2-4, an arc-shaped track 3-1, a detection platform 3-2, a limit plate 3-3, a support plate 3-4, a rack 3-5, a rack protection groove 3-6, an arc-shaped guide groove 3-7, a thermal imaging camera 4-1, an image information identification system 4-2, an image processing system 4-3, a support platform 5-1, a pulley 5-2, a support rod 5-3, a transmission rod 5-4 and a gear 5-5.
Detailed Description
In order to make those skilled in the art better understand the technical solutions in the present application, the technical solutions in the embodiments of the present application are clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.
A three-dimensional space positioning device based on thermal imaging technology comprises a platform moving device, a movement detection device and a thermal imaging positioning device, wherein,
the platform moving device comprises a transverse platform 1-1, a transverse driving piece 1-2, a lifting platform 1-3 and a lifting driving piece 1-4, wherein the transverse platform 1-1 is installed on the transverse driving piece, the transverse driving piece 1-2 drives the transverse platform 1-1 to move along the X-axis direction, the lifting driving piece 1-4 is installed on the transverse moving platform 1-1, the lifting platform 1-3 is installed at the upper end of the lifting driving piece 1-4, and the lifting driving piece 1-4 drives the lifting platform 1-3 to move along the Z-axis direction;
the mobile detection device comprises two arc-shaped rails 3-1, a detection platform 3-2 and a detection platform moving mechanism, wherein the detection platform 3-2 is connected between the two arc-shaped rails 3-1 in a sliding mode through the detection platform moving mechanism and slides along the arc-shaped rails 3-1, the two arc-shaped rails 3-1 are symmetrically arranged, and the tail end of each arc-shaped rail 3-1 is welded in the center of the lifting platform 1-3 through two supporting plates;
the thermal imaging positioning device comprises two thermal imaging cameras 4-1, an image information identification system 4-2 and an image processing system 4-3, wherein the two thermal imaging cameras 4-1 are symmetrically fixed on the upper half part of a detection platform, the image information identification system 4-2 and the image processing system 4-3 are both fixedly arranged on the detection platform, and the image information identification system 4-2 and the image processing system 4-3 are respectively in information connection with the two thermal imaging cameras.
Preferably, the transverse driving member comprises two sliding guide rails 2-1, a screw 2-2, a screw motor 2-3 and two support plates 2-4, the two sliding guide rails 2-1 are arranged on two sides of the bottom of the transverse platform 1-1 in parallel along an X axis, the bottom of the transverse platform 1-1 is connected with the two sliding guide rails 2-1 in a sliding manner, the two support plates 2-4 are symmetrically arranged on two sides of the transverse platform 1-1 along the X axis, two ends of the screw 2-2 are respectively fixedly connected with the two support plates 2-4, the screw 2-2 is parallel to the sliding guide rails 2-1, the screw motor 2-3 is arranged on the screw 2-2, and the screw motor 2-3 moves on the screw 2-2, the lead screw motor 2-3 is connected with the bottom of the transverse platform 1-1 in a rotating fit mode through 4 lead screw nuts, and the lead screw motor 2-2 is fixed with the transverse platform 1-1 through the lead screw nuts so as to realize the movement of the transverse platform 1-1.
Preferably, the lifting driving member 1-4 is an air cylinder, and two ends of the air cylinder are respectively connected with the top end of the transverse platform 1-1 and the bottom end of the lifting platform 1-4.
Preferably, two arc tracks 3-1 are symmetrically arranged, each arc track 3-1 is an 1/4 arc guide rail with the radius of 200mm, the top ends of the two arc tracks 3-1 are welded through limiting plates 3-3, arc guide grooves 3-7 are formed in two opposite side faces of the two arc tracks 3-1, racks 3-5 and rack protection grooves 3-6 are welded on the back faces of the two arc tracks 3-1 and arranged along the arc guide rails, and the rack protection grooves 3-6 are used for protecting racks (3-5) and gears (5-5).
Preferably, the detection platform moving mechanism comprises a supporting platform 5-1, four pulleys 5-2, two supporting rods 5-3, a transmission rod 5-4, two gears 5-5 and a detection platform motor, wherein the supporting platform 5-1 is fixedly welded on the back of the detection platform 3-2, the transmission rod 5-4 is rotatably connected to the supporting platform 5-1, two ends of the transmission rod 5-4 are respectively and fixedly connected with the gears 5-5, the two supporting rods 5-3 are respectively arranged at two ends of the upper side and the lower side of the detection platform 3-2 in a penetrating manner, two ends of each supporting rod 5-3 are respectively provided with one pulley, the gears at two ends of the transmission rod 5-4 are respectively and mutually meshed with racks of the two arc-shaped rails 3-1, and the pulleys 5-2 at two ends of each supporting rod are respectively and slidably connected with the arc-shaped guide grooves 3 And 7, the detection platform motor is arranged inside the supporting platform 5-1 and is in driving connection with the transmission rod 5-4.
Preferably, the transverse platform 1-1 is a cuboid structure; the lifting platform 1-3 is a cube, and the initial position of the lifting platform 1-3 is set at the lowest height in the lifting range.
Preferably, the sliding guide 2-1 is made of an i-shaped steel structure.
A three-dimensional space positioning method based on thermal imaging technology comprises the following specific steps:
step 1: the device is located at an initial position before detection is started, and the initial position is as follows: the method comprises the steps that a transverse platform 1-1 is located at the left rear part of the tail part of an automobile to be detected, an air cylinder is in the shortest length state, a detection platform 3-2 is located at the highest position of an arc-shaped track 3-1, two thermal imaging cameras 4-1 on the detection platform 3-2 shoot thermodynamic images of the tail part of the automobile to be detected, the thermodynamic images comprise a left image L and a right image R, then the thermodynamic images shot by the two thermal imaging cameras 4-1 are respectively transmitted to an image information recognition system 4-2 and an image processing system 4-3, the image information recognition system 4-2 and the image processing system (4-3) conduct image preprocessing and image area segmentation on the received thermodynamic images, the thermodynamic images are compared with stored position thermodynamic images, and a target image is selected for further determining the position coordinates of the space position to be detected (the target image refers to the fact that the thermal imaging images of the tail gas port shot pass through the stored images and the Comparing and determining the position of the hot spot (tail gas port) to be found more quickly);
step 2: the image processing system 4-3 calibrates the processed thermodynamic image left image L and the processed thermodynamic image right image R through Zhang calibration to respectively obtain the camera internal and external parameters of the two corresponding thermal imaging cameras 4-1;
and step 3: the image processing system 4-3 corrects the left image L and the right image R through the camera internal and external parameters obtained in the step 2, so that the distortion of the left image L and the distortion of the right image R are removed, and polar lines of the two images are aligned;
and 4, step 4: aiming at the corrected left image L and right image R, parallel SGM algorithm calculation is utilized to obtain a disparity map, an image processing system 4-3 carries out post-processing on the obtained disparity map, noise is removed by utilizing a median filtering method, the relative position coordinate of the space position to be measured is calculated, the image processing system 4-3 transmits the calculated relative position coordinate to a transverse driving piece 1-2 through a data line, and a screw motor 2-3 is driven to work, so that the transverse platform 1-1 moves along the direction of an x axis;
and 5: the transverse driving piece 1-2 starts to work, so that the transverse platform 1-1 starts to move from an initial position, when the screw motor 2-3 moves to a coordinate position in the x-axis direction which is the same as the spatial position to be measured, the operation is stopped, and the transverse platform 1-1 stops moving;
step 6: after the transverse driving piece 1-2 stops working, the initial position of the detection platform 3-2 is located at the highest position of the arc-shaped track 3-1, at the moment, the two thermal imaging cameras 4-1 shoot images, the shot thermodynamic images are transmitted to the image information identification system 4-2 and the image processing system 4-3, the stored position thermodynamic images are compared, and the shot images are processed;
and 7: according to the shot image, the detection platform moving mechanism moves, in the operation process of the detection platform moving mechanism, the thermal imaging camera 4-1 continuously shoots thermodynamic images, image preprocessing corresponding to the steps 1, 2 and 3 is executed in real time, relative position coordinates are calibrated in real time, the image processing system 4-3 transmits the calculated relative position coordinates to the detection platform motor and the air cylinder through a data line, the air cylinder firstly extends and operates to a real-time calibrated z-direction coordinate position, then the detection platform motor drives the gear 5-5 to operate, the movement of the detection platform 3-2 is realized through the meshing of the gear 5-5 and the rack 3-5, when the relative position calibrated in the space of the position to be detected is closest to the thermal imaging camera 4-1, the detection platform motor stops moving, then moving to corresponding y and z coordinates;
and 8: after the position to be detected is found, the detection platform motor drives the detection platform 3-2 to recover to the highest position of the arc-shaped track 3-1, the lifting driving piece 1-4 contracts to the shortest position, the screw rod motor 2-3 rotates to drive the transverse platform 1-1 to return to the initial position, and the detection is finished.
The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.