CN210725096U - Image system and mobile terminal - Google Patents

Abstract

The application relates to an image system and a mobile terminal, wherein the image system comprises a camera device and a control device, the camera device comprises a plurality of cameras, and the cameras are all connected with the control device, wherein the image system is provided with a plurality of shooting modes which respectively correspond to a camera combination, the camera combination comprises at least two cameras in the cameras, and the camera combination is used for shooting a target object to obtain an original image and sending the original image to the control device; the control equipment controls the camera combination to shoot the target object according to the current shooting mode, and processes the original image shot by the camera combination to obtain the target image. The user can set the shooting mode of the system according to the actual scene so that the system calls the corresponding camera combination to shoot and process to obtain the target image, the target image meeting the actual requirements of the user can be obtained when the target object is shot, and compared with the traditional image system, the shooting function is diversified.

Description

Image system and mobile terminal

Technical Field

The present application relates to the field of image capturing device technologies, and in particular, to an image system and a mobile terminal.

Background

With the development of science and technology and the continuous progress of society, the demand of people on image acquisition and monitoring in daily work and life is more and more increased. The image system is used for collecting images of the target object and the surrounding environment and feeding the images back to the main control center equipment, so that the main control center equipment can directly display the images, or the main control center equipment analyzes the images and then obtains the images, and an analysis result is displayed.

Traditional image system possesses the function of shooing, video recording and demonstration, generally adopts two cameras or three camera structures, and the purpose is to increase the definition of photo or video to satisfy the demand of work and life amusement. The traditional image system adopts a multi-module camera for shooting definition, outputs color pictures, is only suitable for shooting integral high-definition images, and has the defect of single shooting function.

SUMMERY OF THE UTILITY MODEL

Therefore, it is necessary to provide a multifunctional video system and a mobile terminal for solving the problem of single shooting function of the conventional video system.

An image system comprises image pickup equipment and control equipment, wherein the image pickup equipment comprises a plurality of cameras which are all connected with the control equipment, the image system is provided with a plurality of shooting modes, the shooting modes respectively correspond to a camera combination, the camera combination comprises at least two cameras in the cameras, and the camera combination is used for shooting a target object to obtain an original image and sending the original image to the control equipment; the control equipment is used for controlling the camera combination to shoot a target object according to the current shooting mode and processing the original image obtained by shooting through the camera combination to obtain a target image.

According to the image system, the control equipment controls the camera combination to shoot the target object according to the current shooting mode, and processes the original image shot by the camera combination to obtain the target image. The user can set the shooting mode of the system according to the actual scene so that the system calls the corresponding camera combination to shoot and process to obtain the target image, the target image meeting the actual requirements of the user can be obtained when the target object is shot, and compared with the traditional image system, the shooting function is diversified.

In one embodiment, the plurality of cameras includes a super thermal imaging camera and/or a night vision camera.

The required camera can be selected from the super thermal image sensing camera and the night vision camera to acquire and process images by combining the current shooting mode of the system.

In one embodiment, the plurality of cameras further comprises a super wide angle camera.

The required camera can be selected from the super thermal image sensing camera, the night vision camera and the super wide-angle camera to acquire and process images by combining the current shooting mode of the system.

In one embodiment, the plurality of cameras further comprises a tele camera.

The camera that combines the present shooting mode of system, can select needs from super wide-angle camera, long focus camera, thermal sensing camera and night vision type camera carries out image acquisition and processing, realizes that control equipment selects one or more in super wide-angle shooting, automatic zoom, heat radiation detection and night shooting function according to the actual scene and shoots, and the range of application is wide.

In one embodiment, the control device comprises a controller and a memory, wherein the controller is connected with each camera, and the memory is connected with the controller.

And controlling the cameras with corresponding type combinations to shoot the target object through the controller according to the current shooting mode of the system, and processing the shot image to obtain a target image and then storing the target image in the memory so as to be convenient for a user to call and view.

In one embodiment, the video system further comprises a display connected to the control device.

And the control equipment also sends the target image to the display for displaying so as to be convenient for the user to view.

In one embodiment, the video system further comprises a setting button connected to the control device.

The user can adjust the setting button according to actual demand and change the mode of making a video recording of system to control system calls the camera that corresponds type combination and shoots and handle and obtain the target image, obtains the target image that accords with user's actual demand.

In one embodiment, the imaging system further includes a mechanical adjustment device, the mechanical adjustment device carries the image pickup device, and the image pickup device is electrically connected to the control device through the mechanical adjustment device.

The shooting angle of the camera shooting equipment can be adjusted by the control equipment through the mechanical adjusting equipment, so that the camera shooting can be conveniently carried out aiming at a target object, and the shooting accuracy is improved.

In one embodiment, the video system further comprises a remote terminal wirelessly connected with the control device.

After the control equipment obtains the target image, the target image can be sent to the remote terminal for displaying in a wireless communication mode, so that a user can enter a remote environment monitoring mode through the remote terminal.

A mobile terminal comprises the image system.

According to the mobile terminal, a user can set the shooting mode of the system according to an actual scene, so that the system calls the corresponding camera combination to shoot and process to obtain the target image, the target image meeting the actual requirement of the user can be obtained when the target object is shot, and compared with a traditional image system, the shooting function is diversified.

Drawings

FIG. 1 is a block diagram of an embodiment of an imaging system;

FIG. 2 is a block diagram of an embodiment of an image capture device;

FIG. 3 is a block diagram of an image system according to another embodiment;

fig. 4 is a schematic flow chart of image capturing performed by combining the thermal camera a, the ultra-wide-angle camera B, the telephoto camera C, and the night vision camera D in one embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

As shown in fig. 1, an imaging system in one embodiment includes an imaging device 110 and a control device 120, where the imaging device 110 includes a plurality of cameras 112, and each of the plurality of cameras 112 is connected to the control device 120. The image system is provided with a plurality of shooting modes, the shooting modes respectively correspond to a camera combination, and the camera combination comprises at least two cameras in the cameras. The camera assembly is used for shooting a target object to obtain an original image and sending the original image to the control device 120. The control device 120 is used for controlling the camera combination to shoot the target object according to the current shooting mode. The control device 120 is further configured to process an original image captured by the camera combination to obtain a target image. The types of the cameras 112 in the imaging device 110 may be different or partially the same. Specifically, the image pickup apparatus 110 is at least a two-camera structure.

The number of the target objects can be one or more, and the target objects can be human beings, animals, plants or other objects. The control device 120 may be preset with different shooting modes of the imaging system, and the number, combination, and image processing methods of the cameras 112 called in the different shooting modes may also be different. When a user shoots, a shooting mode meeting requirements can be selected by combining with an actual scene, the control device 120 calls a corresponding camera combination to shoot according to the current shooting mode of the system, and a shot original image is processed to obtain a target object image. The control device 120 may send the finally obtained target object image to a display for displaying, or output the target object image to an external master controller for subsequent operations such as image displaying, data summarizing and storing, and environmental monitoring and analyzing.

In the imaging system, the control device 120 controls the camera assembly to shoot the target object according to the current shooting mode, and processes the shot original image to obtain the target image. The user can set the shooting mode of the system according to the actual scene so that the system calls the corresponding camera combination to shoot and process to obtain the target image, the target image meeting the actual requirements of the user can be obtained when the target object is shot, and compared with the traditional image system, the shooting function is diversified.

In one embodiment, control device 120 includes a controller 122 and a memory 124, controller 122 coupled to each camera 112, and memory 124 coupled to controller 122. The camera 112 of the corresponding type combination is controlled by the controller 122 according to the current shooting mode of the system to shoot the target object, and the shot image is processed to obtain the target image and then stored in the memory 124, so that the user can call and view the target image. In addition, the system includes a display connected to the control device 120. The control device 120, after obtaining the target image, sends the target image to the display for viewing by the user. The controller 122 may be an MCU (Micro Control Unit), a CPU (Central Processing Unit), and the like, and the memory 124 may include a nonvolatile and/or volatile memory. Non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), Double Data Rate SDRAM (DDRSDRAM), Enhanced SDRAM (ESDRAM), Synchronous Link DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM). The Display may be an LCD (Liquid Crystal Display) Display, an LED (light emitting Diode) Display, or the like.

In one embodiment, the video system further comprises a remote terminal 100 wirelessly connected to the control device 120. Specifically, the control device 120 includes a wireless signal transceiver 126 connected to the controller 122, and the controller 122 wirelessly communicates with the remote terminal 100 through the wireless signal transceiver 126. After obtaining the target image, the control device 120 may further transmit the target image to the remote terminal 100 for display through wireless communication, so that the user can perform remote monitoring through the remote terminal.

In one embodiment, the imaging system further comprises a setup button connected to the control device 120. The user can adjust the setting button according to actual demand and change the mode of making a video recording of system to control system calls the camera that corresponds type combination and shoots and handle and obtain the target image, obtains the target image that accords with user's actual demand.

The type of cameras in the imaging device 110 is not exclusive and in one embodiment, the plurality of cameras includes super thermal imaging cameras and/or night vision cameras. The required camera can be selected from the super thermal image sensing camera and the night vision camera to acquire and process images by combining the current shooting mode of the system.

Further, in one embodiment, the plurality of cameras further comprises an ultra-wide angle camera. The required camera can be selected from the super thermal image sensing camera, the night vision camera and the super wide-angle camera to acquire and process images by combining the current shooting mode of the system.

In addition, the plurality of cameras further include a tele camera. The camera that combines the present shooting mode of system, can select needs from super wide-angle camera, long focus camera, thermal sensing camera and night vision type camera carries out image acquisition and processing, realizes that control equipment selects one or more in super wide-angle shooting, automatic zoom, heat radiation detection and night shooting function according to the actual scene and shoots, and the range of application is wide.

Specifically, in one embodiment, as shown in FIG. 2, the plurality of cameras includes a super Wide camera A, a tele camera B, a thermal camera C, and a night vision camera D, and/or the plurality of cameras includes at least one periscopic camera.

Specifically, the imaging device of the imaging system is structured as follows: the camera comprises an ultra-wide-angle camera, a long-focus camera, a thermal sensing camera and a night vision camera. Each lens camera functions as follows:

A. super wide-angle camera: the shooting angle is large, and the viewing range is wide.

B. A long-focus camera: the zoom lens can automatically zoom, guarantee the definition of a small-range scene at a distance, and clearly see the details of a scene at the distance.

C. Thermal sensing like camera: and detecting heat radiation in the environment, converting the shot picture into thermal imaging and providing environment heat radiation information.

D. Night vision type camera: the device can be used for photographing in a dark environment for night observation, and can provide the light inlet quantity and improve the photographing quality.

By combining the current shooting mode of the system, the required cameras can be selected from the ultra-wide-angle camera A, the telephoto camera B, the thermal sensing camera C and the night vision camera D for image acquisition and processing, so that the control equipment 120 can select one or more of the functions of ultra-wide-angle shooting, automatic zooming, thermal radiation detection and night shooting according to the actual scene for shooting, and the application range is wide. And the camera is designed in a periscopic mode, so that the thickness of the camera is reduced.

Further, in an embodiment, when the current shooting mode is the first shooting mode, the control device 120 is configured to control the ultra-wide camera and the tele camera to shoot the target object, and synthesize first original images shot by the ultra-wide camera and the tele camera to obtain a first target image.

Specifically, the scene to which the first photographing mode is applied is not exclusive, and for example, the first photographing mode is defined as a "normal mode", and when a user needs to photograph a character or a scene in the daytime, the system mode may be set as the "normal mode" through a setting button of the video system. After the user sets the mode, the user makes the camera aim at the target object through the observation of the viewfinder and then presses the photographing button. After detecting that the user presses the photographing button, the control device 120 obtains a large-range image including the target object and the surrounding environment by using the super-wide-angle camera, and obtains a small-range clear image including the target object by using the long-focus camera to perform automatic zooming photographing on the target object. Finally, the control device 120 synthesizes the large-range image and the small-range clear image to obtain a first target image that reflects the entire environment and purposely enlarges the local environment.

The method for automatically zooming and shooting the target object by the long-focus camera is not unique, and the target object can be located at a preset zooming point position when a user observes through the viewfinder, so that the long-focus camera can directly aim at the target object to shoot to obtain a narrow-range clear image during shooting; it is also possible that the user determines the position of the object by changing the focus position when looking through the finder window, and the control device 120 controls the telephoto camera to change the shooting angle to be directed to the position of the object when shooting, and a small-range clear image containing the object can be shot as well.

In this embodiment, when the user selects the first shooting mode, the target object is shot and image-synthesized by combining the ultra-wide-angle camera and the telephoto camera, so that the overall environment can be observed, and the local target area can be enlarged in a targeted manner according to the shooting requirement, thereby achieving the purposes of shooting the overall environment and facilitating the user to clearly analyze the details of the target object.

In one embodiment, when the current shooting mode is the second shooting mode, the control device 120 is configured to control the thermal camera and the night vision camera to shoot the target object, and combine the second original images shot by the thermal camera and the night vision camera to obtain the second target image.

The second photographing mode is not limited to a specific scene, and for example, the second photographing mode is defined as a "night photographing mode", and when a user needs to photograph at night, the system mode is set as the "night photographing mode" through a setting button of the video system. Meanwhile, a thermal imaging camera and a night vision camera are used for shooting a target object to respectively obtain a target thermodynamic diagram and a target object diagram, and photo information shot at night is converted into a thermal imaging diagram which can be used for monitoring the heat change of the environment.

In this embodiment, when the user selects the second shooting mode, the thermal imaging camera and the night vision camera are combined to shoot the target object to generate a target thermodynamic diagram and a target object diagram, and when the target object is in an environment with poor light, the object diagram and the thermodynamic diagram can be provided at the same time so that the user can compare and view heat changes.

In one embodiment, as shown in fig. 3, the imaging system further includes a mechanical adjustment device 130, the mechanical adjustment device 130 carries the image capturing device 110, the image capturing device 110 is electrically connected to the control device 120 through the mechanical adjustment device 130, and the control device 120 controls the mechanical adjustment device 130 to adjust the shooting angle of the image capturing device 110. The control device 120 can adjust the shooting angle of the image pickup device 110 through the mechanical adjustment device 130 so as to shoot aiming at the target object, thereby improving the shooting accuracy.

In one embodiment, when the current shooting mode is the third shooting mode, the control device 120 determines the position of the object based on a thermal image captured by the thermal image camera, and controls the mechanical adjustment device 130 to adjust the shooting angle of the image capture device 120; and controlling the ultra-wide-angle camera and the tele-focus camera which are adjusted in shooting angle to shoot the target object, and synthesizing a third original image shot by the ultra-wide-angle camera and the tele-focus camera to obtain a third target image.

The scene to which the third shooting mode is applied is not unique, and taking the third shooting mode as the "automatic zoom mode" as an example, when the user cannot manually control to shoot the target object in the environment with strong light, the system mode can be set as the "automatic zoom mode" through the setting button of the imaging system. The control device 120 determines a position where the temperature changes as a target position according to an image obtained by the thermal imaging camera, then controls the mechanical adjustment device 130 to adjust the imaging angle of the camera, controls the ultra-wide camera and the tele camera after adjusting the imaging angle to image the target, respectively obtains a large-range image including the target and the surrounding environment and a small-range clear image including the target, and finally performs image synthesis to obtain a third target image which can reflect the whole environment and specifically amplify the local environment. In addition, the control device 120 may further generate a thermodynamic diagram corresponding to the target image from the image captured by the thermal imaging camera with the shooting angle adjusted, so as to output the target image in an environment with strong light and provide the corresponding thermodynamic diagram.

When the user selects the third shooting mode, the target object is found by using the image shot by the thermal imaging camera, the shooting angle of the camera is moved by the mechanical adjusting device to be aligned with the target object, and shooting and image synthesis are carried out by using the ultra-wide-angle camera and the telephoto camera after the shooting angle is adjusted, so that automatic detection and shooting of the target object are realized, the operation is simpler and more convenient, and the shooting is accurate and reliable.

Further, in one embodiment, when the current photographing mode is the fourth photographing mode, the control device 120 determines the position of the object based on the thermal image captured by the thermal image camera, controls the mechanical adjustment device 130 to adjust the photographing angle of the image pickup device 110; and controlling the ultra-wide-angle camera, the tele-camera and the night vision camera after the shooting angle is adjusted to shoot the target object, and synthesizing fourth original images shot by the ultra-wide-angle camera, the tele-camera and the night vision camera to obtain a fourth target image.

The scene to which the fourth photographing mode is applied is also not unique, and taking the fourth photographing mode as "night + auto zoom mode" as an example, when the user cannot manually control to shoot the target object in an environment with poor light such as night, the system mode can be set as "night + auto zoom mode" through the setting button of the imaging system. The control device 120 determines a position where the temperature changes as an object position from an image captured by the thermal imaging camera, and then controls the mechanical adjustment device 130 to adjust the capturing angle of the camera. The control device 120 controls the ultra-wide-angle camera and the telephoto camera after the shooting angle is adjusted to shoot the target object, so that a large-range image containing the target object and the surrounding environment and a small-range clear image containing the target object are obtained respectively, the night vision mode after the shooting angle is adjusted is used for shooting and supplementing light, the light entering amount is provided when the large-range image and the small-range clear image are subjected to image synthesis, and the shooting quality of the target image can be improved.

When the target object is in the environment with poor light, the user can select the fourth shooting mode, the image obtained by shooting through the thermal sensing camera is used for finding the target object, the shooting angle of the camera is moved through the mechanical adjusting device to be aligned to the target object, the control device 120 conducts shooting and image synthesis through the ultra-wide camera and the long-focus camera after the shooting angle is adjusted, sampling and shooting are conducted through the control device in cooperation with the night vision camera, automatic detection and shooting of the target object in the environment with poor light are achieved, and shooting quality in the environment with poor light is improved.

It should be noted that, the above provides the shooting modes of the imaging system in four different modes, and the user can set different shooting modes according to actual needs to shoot the target object. It is understood that the specific shooting mode of the imaging system is not limited to the above four modes, and for example, the shooting may be performed by combining a wide-angle camera with a thermal imaging camera, or by combining a wide-angle camera with a night vision camera. In addition, after obtaining the target image, the control device 120 may also transmit the target image to a remote terminal for displaying, so as to facilitate remote monitoring of the user, where the remote terminal may specifically be a mobile phone, a computer, or the like.

For a better understanding of the above-described imaging system, reference will now be made in detail to the embodiments illustrated in the drawings.

For convenience of description, A, B, C, D denotes an ultra wide-angle camera, a telephoto camera, a thermal camera, and a night vision camera. Wherein, long burnt camera specifically adopts periscopic long burnt camera, adopts periscopic design to long burnt camera, and is horizontal with the mirror group, introduces the sensor through a piece of prism with light, has reduced long burnt camera's thickness. The periscopic long-focus camera supports internal zooming and can shoot close or far scenery according to requirements. In addition, the thickness of the inner zooming camera is greatly reduced, and the size of the camera is reduced. The parameter settings of the multifunctional camera module are shown in table 1.

TABLE 1

The camera AB is matched, the whole environment is observed through the camera A in the daytime, the local environment is amplified in a targeted mode through the camera B according to the photographing requirement, the peripheral unimportant environment is weakened, the whole environment is photographed, and the details of a certain object are clearly analyzed. And taking a picture by using the camera A, taking a picture by using the camera B, and combining the two pictures into a picture. Specifically, the image collected by the RGGB pixel sensor is adopted for the camera A to extract panoramic characteristics, the image collected by the camera B through digital zooming is extracted to obtain detailed characteristics, the panoramic characteristics and the detailed characteristics are subjected to characteristic fusion to obtain a fused detailed color image, and the image is locally clear and can be seen globally. Because the shooting range of the camera B is small, the picture is clear, namely the picture is commonly called as high in pixel; the shooting range of the camera A is wide, the picture is fuzzy, namely the picture is commonly called as low in pixel, so that the synthesized picture is not only locally clear, but also can be seen globally. The camera A can adopt a 128-degree wide-angle camera, the camera B can adopt an 80-degree camera, and panoramic shooting can be achieved by adding the cameras, such as three super wide-angle cameras.

The camera CD cooperates: according to the principle that an object can generate infrared thermal radiation, the generated infrared radiation energy is different. The photo information taken at night can be converted into a thermal imaging graph to monitor the heat change of the environment, and the camera D can adopt RWWBsensor (Red White Blue sensor, Red, White, Blue sensor), rgbeir sensor (Red Green Blue Infrared sensor, Red, Green, Blue, Infrared sensor) or RGBW sensor (Red Green Blue White sensor, Red, Green, Blue, White sensor) and other types of sensors. Specifically, level signal fusion can be performed on signals acquired by the camera C and the camera D to obtain a thermal imaging image. And extracting an image frame according to the signal acquired by the camera D to obtain a target object image shot by the camera D. The camera CD cooperates with the photograph being taken in black and white, while the thermodynamic diagram is in color, particularly in red, whether during the day or at night. Similarly, the camera ABC, in cooperation with the camera ABC, can output a color picture in an environment with strong light and provide a corresponding thermodynamic diagram.

Combining four cameras of the ABCD, and matching with an image algorithm to perform image processing: when the temperature of a certain position changes, the camera C shoots and feeds back to the camera A, the camera AC finds a specific target in combination, and the camera B carries out fixed-focus shooting; can cooperate camera D to sample and shoot evening. Camera D is similar to surveillance, imaging at night, as camera AB cannot image in a dark environment. If the ambient light is not clear compared with the light of the poor camera AB combination, the light can be supplemented by the D to increase the definition of the photo. Specifically, signal processing is performed on signals acquired by the camera D, an image frame is extracted according to the signals, and then frame and color fusion is performed on the extracted image frame and information acquired by the camera A to obtain a high-brightness image. Meanwhile, frame and color fusion is carried out by combining the image frame and the information collected by the camera B, and a high-brightness image can also be obtained. And (4) carrying out extraction and feature fusion on panoramic features and detail features on the high-brightness images obtained by the two times of fusion, and obtaining local clear images and global images. In the daytime, the camera AB can be used for photographing, but in order to ensure wide photographing range and local clarity, the camera AB is combined, and further, the camera C is combined to see thermodynamic diagram at a certain position.

Specifically, the controller receives a thermal image shot by the camera C, finds a part with changed temperature in the thermal image as a target object through an image recognition algorithm, and then adjusts the angles of the cameras A, B, C and D to be aligned with the position of the target object through a mechanical adjusting device, so that the unified coordination control of shooting angles of the multiple cameras is realized, and the subsequent image synthesis of all shot target object images is ensured. After receiving the original images shot by the cameras A, B, C and D aiming at the target object, the controller synthesizes the images shot by the cameras A and B to obtain a locally clear synthesized picture capable of seeing the whole situation.

When imaging at night, the camera D filters out stray light by using the infrared filter, and infrared light and visible light pass through the camera, so that corresponding signals can be induced by reflection of infrared light. The controller extracts information collected by the image frame and the camera A according to the signal sensed by the camera D to fuse the frame and the color to obtain a high-brightness image, and then fuses the frame and the color according to the information collected by the image frame and the camera B to obtain another high-brightness image. And finally, respectively extracting the two high-brightness images to obtain panoramic features and detail features, and performing feature fusion to obtain a color image which embodies details and can see the whole situation. In addition, level signal fusion is carried out by combining signals collected by the camera C and the camera D to obtain a thermal imaging image.

The environment change information obtained by shooting can be linked with the mobile phone to monitor the environment change in real time, and the photo of the changed position can be received, and the flow is shown in fig. 4. The camera C can also detect the thermal change in the shielding object and the thermal change of an object invisible to naked eyes, the thermal radiation of the object with different heat is different, and the molecular motion, the pressure change and the like can also generate different thermal radiation. The camera C is used for detecting by adopting thermal radiation, so that the gas leakage, the local pressure change and other environmental temperatures can be effectively monitored.

The imaging system can be applied to an imaging system to convert the environment into thermal imaging. In addition, the system can be applied to security systems, such as real-time monitoring, searching crime evidence and the like, and specific examples are as follows:

example one: the monitoring system takes a picture in real time when night personnel enter a monitoring area, and feeds the picture back to the remote terminal in a thermodynamic diagram mode, and the remote terminal can be a mobile phone, an intelligent bracelet and other communication equipment and is applied to places such as families, markets, schools, banks and the like.

Example two: when the places without monitoring are stolen, murder and the like, the police can collect the footprints, search the places contacted by the suspects and collect the fingerprints of the suspects according to the difference of heat generated by the pressure of the suspects on the floor when the suspects walk. When the police collects the evidence, the footprint is detected without seeing the trace, and the detection by thermal imaging is simpler and more convenient. This application is through high integration, with the magnitude of thermal imaging technique discernment footprint, leads to the thermal imaging precision at home and abroad, for this application best bright point.

In one embodiment, a mobile terminal is also provided, which includes the above image system.

According to the mobile terminal, a user can set the shooting mode of the system according to an actual scene, so that the system calls the corresponding camera combination to shoot and process to obtain the target image, the target image meeting the actual requirement of the user can be obtained when the target object is shot, and compared with a traditional image system, the shooting function is diversified.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the utility model. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. An imaging system, comprising an imaging device and a control device, wherein the imaging device comprises a plurality of cameras, and the plurality of cameras are connected with the control device, wherein the imaging system has a plurality of shooting modes, the plurality of shooting modes respectively correspond to a camera combination, the camera combination comprises at least two cameras in the plurality of cameras,

the camera combination is used for shooting a target object to obtain an original image and sending the original image to the control equipment;

the control equipment is used for controlling the camera combination to shoot a target object according to the current shooting mode and processing the original image obtained by shooting through the camera combination to obtain a target image.

2. The imaging system of claim 1, wherein the plurality of cameras comprise super thermal imaging cameras and/or night vision cameras.

3. The imaging system of claim 2, wherein the plurality of cameras further comprises a super wide angle camera.

4. The imaging system of claim 2 or 3, wherein the plurality of cameras further comprises a tele camera.

5. The imaging system of claim 1, wherein the control device comprises a controller and a memory, the controller is connected to each camera, and the memory is connected to the controller.

6. The imaging system of claim 1, further comprising a display coupled to the control device.

7. The imaging system of claim 1, further comprising a setup button coupled to the control device.

8. The imaging system of claim 1, further comprising a mechanical adjustment device carrying the camera device, the camera device being electrically connected to the control device through the mechanical adjustment device.

9. The imaging system of any one of claims 1 to 6, further comprising a remote terminal wirelessly connected to the control device.

10. A mobile terminal characterized by comprising the imaging system of any one of claims 1 to 9.

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