阅读说明：本技术 太赫兹安检机器人 (Terahertz security inspection robot ) 是由 陈志强 赵自然 游�燕 李元景 张士新 解欢 马旭明 范锐 王英雷 于 2020-06-23 设计创作，主要内容包括：公开了一种太赫兹安检机器人,包括：壳体,所述壳体包括主壳体以及与所述主壳体转动式连接的头部壳体；太赫兹波成像机构,所述太赫兹波成像机构包括设置在所述头部壳体内的反射镜组件以及设置在所述主壳体内的探测器阵列；以及旋转机构,所述旋转机构用于使所述头部壳体及位于所述头部壳体内的反射镜组件相对于所述主壳体进行转动,从而使得所述太赫兹波成像机构的反射镜组件朝向不同的方向定向,以分别对安检场景中的不同检查区域内的被检查目标进行太赫兹扫描成像。(Disclosed is a terahertz security inspection robot, including: the shell comprises a main shell and a head shell rotatably connected with the main shell; a terahertz wave imaging mechanism comprising a mirror assembly disposed within the head housing and a detector array disposed within the main housing; and the rotating mechanism is used for enabling the head shell and the reflector assembly positioned in the head shell to rotate relative to the main shell, so that the reflector assembly of the terahertz wave imaging mechanism is oriented towards different directions, and terahertz scanning imaging is respectively carried out on the inspected objects in different inspection areas in a security inspection scene.)

1. A terahertz security inspection robot, comprising:

the shell comprises a main shell and a head shell rotatably connected with the main shell;

a terahertz wave imaging mechanism comprising a mirror assembly disposed within the head housing and a detector array disposed within the main housing; and

the rotating mechanism is used for enabling the head shell and the reflector component positioned in the head shell to rotate relative to the main shell, so that the reflector component of the terahertz wave imaging mechanism is oriented towards different directions, and terahertz scanning imaging is respectively carried out on the detected targets in different detection areas in a security detection scene.

2. The terahertz security inspection robot according to claim 1, wherein the mirror assembly comprises a mirror and a pitching and swinging mechanism, the pitching and swinging mechanism is used for driving the mirror to pitch and swing in a vertical direction, so that the mirror can perform terahertz scanning imaging on parts of the inspected object with different heights.

3. The terahertz security inspection robot of claim 1, wherein the rotation mechanism comprises:

a first gear ring connected with the head housing at a junction between the head housing and the main housing;

a second ring gear located within the main housing and meshed with the first ring gear; and

and the driving mechanism is used for driving the second gear ring to rotate so as to drive the first gear ring to rotate, so that the head shell and the reflector assembly positioned in the head shell are driven to rotate.

4. The terahertz security inspection robot according to claim 1, wherein the head housing is provided with a window through which terahertz waves spontaneously radiated from the object to be inspected can pass and reach a mirror assembly of the terahertz wave imaging mechanism.

5. The terahertz security inspection robot of claim 1, wherein the detectors in the detector array are arranged in a single or multiple rows of arcs or straight lines.

6. The terahertz security inspection robot of claim 5, wherein when the detectors are arranged in a plurality of rows, the plurality of rows of detectors are aligned or staggered, and polarization directions of the plurality of rows of detectors are different.

7. The terahertz security inspection robot as claimed in any one of claims 1 to 6, further comprising a visible light imaging mechanism disposed on the head housing, the visible light imaging mechanism being configured to capture a visible light image of an object under inspection entering the security inspection scene and being used to determine an orientation and a distance of the object under inspection from the terahertz security inspection robot before the terahertz wave imaging mechanism is activated for terahertz scanning imaging.

8. The terahertz security inspection robot according to claim 7, wherein the visible light image generated by the visible light imaging mechanism matches a terahertz wave image generated based on the terahertz wave image data acquired by the terahertz wave imaging mechanism within a depth of field of the terahertz wave imaging mechanism.

9. The terahertz security inspection robot of claim 8, wherein the matching of the visible light image generated by the visible light imaging mechanism and the terahertz wave image generated based on the terahertz wave image data acquired by the terahertz wave imaging mechanism within the depth of field of the terahertz wave imaging mechanism comprises: the visible light image generated by the visible light imaging mechanism is matched with the generated terahertz wave image within the depth of field range of the terahertz wave imaging mechanism after being cut.

10. The terahertz security inspection robot according to claim 8, further comprising a data processing device configured to receive scanning data for the object to be inspected from the terahertz wave imaging mechanism and generate a terahertz wave image, the data processing device being further configured to receive a visible light image from the visible light imaging mechanism and determine whether the object to be inspected has a suspected object based on the terahertz wave image and the visible light image, and if it is determined that the suspected object exists, further determine whether the suspected object is an forbidden object.

11. The terahertz security inspection robot of claim 10, further comprising an image display device data-coupled with the data processing device and configured to receive and display the terahertz wave image and/or the visible light image from the data processing device.

12. The terahertz security inspection robot according to any one of claims 1 to 6, wherein the receiving antenna unit of the detector array comprises at least one horn antenna, the horn antenna comprises a horn body and a waveguide connected with the horn body, and the ratio of the long side to the short side of a horn opening of the horn body is greater than 1.2.

13. The terahertz security inspection robot according to any one of claims 1 to 6, further comprising an instruction interaction module for input and output of various forms of instruction information.

14. The terahertz security inspection robot of claim 13, further comprising a main control module for generating an operation instruction according to the received instruction.

Technical Field

The utility model relates to a security check field especially relates to a terahertz security check robot.

Background

In airport, railway station, hotel front desk, campus door, bank and other special places, the density of people stream is high, and once an accident occurs, the security inspection requirement is high. At present, manual inspection, handheld metal detectors, metal detector doors, X-ray machines, trace detection of explosives, liquid detectors and the like are generally adopted to carry out security inspection on the places. However, manual detection is highly accurate but inefficient, and the person to be inspected is likely to be a conflicting feeling due to physical contact. The handheld metal detector and the metal detection door only can respond to metal and cannot detect nonmetal dangerous goods. Both the trace explosive detection and the liquid detector have the defects of single function and limited application. The X-ray machine can only be used for detecting luggage or in special places such as prisons due to the ionization property of X-rays, and is easily questioned by the public in terms of safety.

Disclosure of Invention

An object of the present disclosure is to solve at least one aspect of the above problems and disadvantages in the related art.

According to an embodiment of the present disclosure, a terahertz security inspection robot is provided, including:

the shell comprises a main shell and a head shell rotatably connected with the main shell;

a terahertz wave imaging mechanism comprising a mirror assembly disposed within the head housing and a detector array disposed within the main housing; and

the rotating mechanism is used for enabling the head shell and the reflector component positioned in the head shell to rotate relative to the main shell, so that the reflector component of the terahertz wave imaging mechanism is oriented towards different directions, and terahertz scanning imaging is respectively carried out on the detected targets in different detection areas in a security detection scene.

In some exemplary embodiments, the mirror assembly includes a mirror and a pitching mechanism for driving the mirror to pitch in a vertical direction, so that the mirror images portions of the inspected object at different heights by terahertz scanning.

In some exemplary embodiments, the rotation mechanism comprises: a first gear ring connected with the head housing at a junction between the head housing and the main housing; a second ring gear located within the main housing and meshed with the first ring gear; and the driving mechanism is used for driving the second gear ring to rotate so as to drive the first gear ring to rotate, so that the head shell and the reflector assembly positioned in the head shell are driven to rotate.

In some exemplary embodiments, the head housing is provided with a window through which the terahertz waves spontaneously radiated from the object to be inspected can pass and reach a mirror assembly of the terahertz wave imaging mechanism.

In some exemplary embodiments, the detectors in the detector array are arranged in a single or multiple rows of arcs or lines.

In some exemplary embodiments, the detectors are arranged in a plurality of rows, the plurality of rows of detectors are aligned or staggered, and the polarization directions of the plurality of rows of detectors are different.

In some exemplary embodiments, the terahertz security inspection robot further comprises a visible light imaging mechanism disposed on the head housing, the visible light imaging mechanism being configured to capture visible light images of an object under inspection entering the security inspection scene and used to determine the orientation and distance of the object under inspection from the terahertz security inspection robot before the terahertz wave imaging mechanism is activated for terahertz scanning imaging.

In some exemplary embodiments, the visible light image generated by the visible light imaging mechanism matches a terahertz wave image generated based on terahertz wave image data acquired by the terahertz wave imaging mechanism within a depth of field of the terahertz wave imaging mechanism.

In some exemplary embodiments, matching the visible light image generated by the visible light imaging mechanism with the terahertz wave image generated based on the terahertz wave image data acquired by the terahertz wave imaging mechanism within the depth of field of the terahertz wave imaging mechanism comprises: the visible light image generated by the visible light imaging mechanism is matched with the generated terahertz wave image within the depth of field range of the terahertz wave imaging mechanism after being cut.

In some exemplary embodiments, the terahertz security inspection robot further includes a data processing device configured to receive scanning data of the object to be inspected from the terahertz wave imaging mechanism and generate a terahertz wave image, and the data processing device is further configured to receive a visible light image from the visible light imaging mechanism and determine whether the object to be inspected has a suspected object based on the terahertz wave image and the visible light image, and if it is determined that the suspected object exists, further determine whether the suspected object is an forbidden object.

In some exemplary embodiments, the terahertz security inspection robot further comprises an image display device, which is data-coupled with the data processing device and configured to receive and display the terahertz wave image and/or the visible light image from the data processing device.

In some exemplary embodiments, the receiving antenna unit of the detector array includes at least one horn antenna, the horn antenna includes a horn body and a waveguide connected to the horn body, and a ratio of a long side to a short side of a horn opening of the horn body is greater than 1.2.

In some exemplary embodiments, the terahertz security inspection robot further comprises an instruction interaction module for inputting and outputting various forms of instruction information.

In some exemplary embodiments, the terahertz security inspection robot further includes a main control module for generating an operation instruction according to the received instruction.

According to the terahertz security inspection robot disclosed by the various exemplary embodiments of the present disclosure, the head housing and the mirror assembly located in the head housing are rotated relative to the main housing by using the rotating mechanism, so that the mirror assembly of the terahertz wave imaging mechanism is oriented in different directions, and terahertz scanning imaging of the inspected object in different directions is realized.

Drawings

Fig. 1 is a block diagram of a terahertz security check robot according to another exemplary embodiment of the present disclosure.

Fig. 2 is a schematic diagram of a terahertz security inspection robot according to an exemplary embodiment of the present disclosure.

Fig. 3 is a schematic diagram of a terahertz wave imaging mechanism of a terahertz security robot according to an exemplary embodiment of the present disclosure.

Fig. 4 is a schematic diagram of a pitch and swing mechanism of a terahertz security inspection robot according to an exemplary embodiment of the present disclosure.

Fig. 5 is a right side view of the pitching and swinging mechanism of the terahertz security inspection robot shown in fig. 4.

Fig. 6 is a perspective view of a rotation mechanism, a head housing, and a pitch and swing mechanism within the head housing of a terahertz security robot according to an exemplary embodiment of the present disclosure.

Fig. 7 is a schematic diagram of a rotation mechanism of a terahertz security robot according to an exemplary embodiment of the present disclosure.

Fig. 8 is a schematic diagram of a horn antenna of a terahertz wave imaging mechanism according to an exemplary embodiment of the present disclosure.

Fig. 9(a) to 9(e) are schematic diagrams of several arrangements of a detector array of a terahertz wave imaging mechanism according to an exemplary embodiment of the present disclosure.

Fig. 10 is a schematic view of a terahertz wave imaging mechanism of a terahertz security robot according to another exemplary embodiment of the present disclosure.

Fig. 11 is a schematic view of a terahertz wave imaging mechanism of a terahertz security robot according to still another exemplary embodiment of the present disclosure.

Detailed Description

While the present disclosure will be fully described with reference to the accompanying drawings, which contain preferred embodiments of the disclosure, it should be understood, prior to this description, that one of ordinary skill in the art can modify the inventions described herein while obtaining the technical effects of the present disclosure. Therefore, it should be understood that the foregoing description is a broad disclosure directed to persons of ordinary skill in the art, and that there is no intent to limit the exemplary embodiments described in this disclosure.

Furthermore, in the following detailed description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the embodiments of the disclosure. It may be evident, however, that one or more embodiments may be practiced without these specific details. In other instances, well-known structures and devices are shown in schematic form in order to simplify the drawing.

According to the general inventive concept of the present disclosure, there is provided a terahertz security inspection robot including: the shell comprises a main shell and a head shell rotatably connected with the main shell; a terahertz wave imaging mechanism configured to generate a terahertz wave image of an object under inspection and including a mirror assembly disposed within the head housing and a detector array disposed within the main housing; and the rotating mechanism is used for enabling the head shell and the reflector assembly positioned in the head shell to rotate relative to the main shell, so that the reflector assembly of the terahertz wave imaging mechanism is oriented towards different directions, and terahertz scanning imaging is respectively carried out on the inspected objects in different inspection areas in a security inspection scene.

As shown in fig. 1 to 3, a terahertz security robot according to an exemplary embodiment of the present disclosure includes a housing and a terahertz wave imaging mechanism 20. The housing comprises a main housing 1 and a head housing 2 rotatably connected to the main housing 1. The terahertz wave imaging mechanism 20 comprises a reflector 21, a focusing lens 22 and a detector array 23, wherein the terahertz wave spontaneously radiated by the object P to be inspected is reflected to the focusing lens 22 by the reflector 21 for focusing, the focused terahertz wave is received by the detector array 23 at the focal position, and the detector array 23 converts the terahertz wave signal into an electric signal, so that the terahertz wave scanning imaging of the object P to be inspected is realized. The terahertz security inspection robot further comprises a rotating mechanism 40, wherein the rotating mechanism 40 is used for rotating the head shell 2 and a reflector assembly positioned in the head shell 2 relative to the main shell 1, so that the reflector assembly of the terahertz wave imaging mechanism 20 is oriented to different directions to respectively perform terahertz scanning imaging on the inspected object P in different inspection areas in a security inspection scene.

According to the terahertz security inspection robot disclosed by the invention, the head shell 2 and the reflector assembly positioned in the head shell 2 are rotated relative to the main shell 1 by adopting the rotating mechanism 40, so that the reflector assembly of the terahertz wave imaging mechanism 20 is oriented towards different directions, and terahertz scanning imaging of the inspected target P in different directions is realized.

In an exemplary embodiment, as shown in fig. 4 and 5, the mirror assembly includes a mirror 21 and a pitching mechanism for driving the mirror 21 to pitch in a vertical direction, so that the mirror 21 performs terahertz scanning imaging on portions of the inspected object P at different heights. Specifically, the pitch and yaw mechanism may include, for example, a holder 24 connected to the head housing 2, and an encoder 25 connected to the mirror, and a voice coil motor 26 connected to the encoder. Of course, the pitch and yaw mechanism may also employ pitch and yaw mechanisms known in the art or otherwise suitable.

In one exemplary embodiment, as shown in FIGS. 3-5, the shape of the mirror 21 may be selected to be elliptical, with a minor axis matching the size of the focusing lens 22, which may be, for example, 20cm-50cm, and a major axis, which may be, for example, 30cm-60 cm. The size of the focusing lens 22 is determined according to the imaging distance and the resolution requirement, and should satisfy δ -1.22 × lam × L/D, where δ is the resolution, L is the imaging distance, lam is the operating wavelength, and D is the aperture of the focusing lens 22. According to the application scenario of the present disclosure, D is typically chosen to be 20-40cm.

In an exemplary embodiment, as shown in fig. 6 and 7, the rotation mechanism 40 includes a first gear ring 41, a second gear ring 43, and a driving mechanism 45, wherein the first gear ring 41 is connected with the head housing 2 and is located at the connection between the head housing 2 and the main housing 1; the second ring gear 43 is located within the main housing 1 and meshes with the first ring gear 41; the driving mechanism 45 is used for driving the first gear ring 41 to rotate, so as to drive the first gear ring 41 to rotate, thereby driving the head housing 2 and the reflector assembly located in the head housing 2 to rotate. The driving mechanism 45 may be, for example, a motor, which may drive the second gear ring 43 to rotate via the coupling 44, so as to drive the first gear ring 41 engaged with the second gear ring 43 to rotate, and thus drive the head housing 2 and the mirror assembly located in the head housing 2 to rotate together. It should be noted that the first ring gear 41 can rotate clockwise or counterclockwise. The focus lens 22 is disposed inside the first ring gear 41 and is connected to the first ring gear 41 via a slip ring 42, so that the focus lens 22 remains stationary during rotation of the first ring gear 41.

In an exemplary embodiment, the head housing 2 is provided with a window, which may be formed of, for example, polyethylene, polytetrafluoroethylene, high-density polytetrafluoroethylene, PE, or the like, through which terahertz waves spontaneously radiated by the object P to be inspected can pass and reach the mirror 21. Other parts of the head housing 2 and the main housing 1 may be made of a material that is not easily penetrated by terahertz waves, such as metal or the like.

In an exemplary embodiment, the receiving antenna unit of the detector array 23 includes a plurality of horn antennas (the distance between two adjacent horn antennas is Δ), as shown in fig. 8, the horn antenna includes a horn body 231 and a rectangular waveguide 232 (with its length, width and high resolution as a, b and L) connected to the horn body 231, the ratio of the long side a1 to the short side b1 of the horn opening of the horn body 231 is greater than 1.2, preferably greater than or equal to 1.5, wherein the size of the long side a1 is determined according to the resolution required by the system under the condition of ensuring the radiation performance of the horn antenna, and the short side b1 is determined according to the radiometer interval satisfying rayleigh sampling, typically a1 > a, b1 > b. However, the ratio of the long side a1 to the short side b1 of the horn antenna cannot be too large, otherwise the resolution is sacrificed, and a1/b1 is usually ≦ 5. In addition, in order to provide the horn antenna with characteristics of high radiation efficiency, high gain, positive radiation, low side lobe, etc., the height H of the horn body 231 of the horn antenna generally satisfies H ≧ a1, preferably H in the range of 1.2a1 to 1.5a1, or in the range of 1.5a1 to 2a1, or in the range of 2a1 to 3a1, for example H is 1.5a1, 2a1, etc.

Fig. 9 illustrates several methods of arranging the detector array 23 of the terahertz wave imaging mechanism 20 according to the present disclosure. In some embodiments, the detectors in the detector array 23 may be arranged in a single or multiple rows of arcs or lines, the radius of the arcs being determined by the image distance of the lenses. When the detectors are arranged in multiple rows, the multiple rows of detectors are aligned (as shown in fig. 9(b), (d), (e)) or staggered (as shown in fig. 9(a), (c)), in some embodiments, the polarization directions of the multiple rows of detectors are different when the detectors are arranged in multiple rows, so as to improve the sensitivity of the terahertz wave imaging mechanism 20 and improve the image quality.

In the exemplary embodiment shown in fig. 8 and 9, the receiving antenna unit of the detector array 23 is a horn antenna, however, it should be understood by those skilled in the art that in other embodiments of the present disclosure, the receiving antenna unit of the detector array 23 may also be a dielectric rod antenna, and similarly, may be arranged in a single row, a double row, three rows or more, and when arranged in multiple rows, may also be staggered or aligned.

In an exemplary embodiment, as shown in fig. 1 and 2, the terahertz security robot further includes a visible light imaging mechanism 30, such as a depth camera, disposed on the head housing 2, the visible light imaging mechanism 30 being configured to capture a visible light image of the object P to be inspected entering the security scene and used to determine the orientation and distance of the object P to be inspected from the terahertz security robot before the terahertz wave imaging mechanism 20 is activated for terahertz scanning imaging.

In an exemplary embodiment, the visible light image generated by the visible light imaging mechanism 30 matches the terahertz wave image generated based on the scanning data of the terahertz wave imaging mechanism 20 within the depth of field of the terahertz wave imaging mechanism 20. Here, the fact that the visible light image generated by the visible light imaging mechanism 30 matches the terahertz wave image generated based on the scanning data of the terahertz wave imaging mechanism 20 within the depth of field range of the terahertz wave imaging mechanism 20 means that the visible light image generated by the visible light imaging mechanism 30 substantially corresponds in spatial position to the terahertz wave image generated based on the scanning data of the terahertz wave imaging mechanism 20 within the depth of field range (for example, 0.5m to 5m) of the terahertz wave imaging mechanism 20, that is, the position and size of the object P to be inspected in the visible light image substantially correspond to the position and size in the terahertz wave image.

In an exemplary embodiment, the field angle of the visible light imaging mechanism 30 is generally larger than the field angle of the terahertz wave imaging mechanism 20, in which case the matching of the visible light image generated by the visible light imaging mechanism 30 and the terahertz wave image generated based on the scanning data of the terahertz wave imaging mechanism 20 within the depth of field of the terahertz wave imaging mechanism 20 includes: the visible light image generated by the visible light imaging mechanism 30 after clipping matches the terahertz-wave image generated based on the scanning data of the terahertz-wave imaging mechanism 20 within the depth of field of the terahertz-wave imaging mechanism 20.

In an exemplary embodiment, in order to ensure that the visible light image generated by the visible light imaging mechanism 30 matches the terahertz wave image generated based on the scanning data of the terahertz wave imaging mechanism 20 within the depth of field of the terahertz wave imaging mechanism 20, the visible light imaging mechanism 30 is positioned such that an extension of the optical axis thereof passes through the center of the mirror 21 of the terahertz wave imaging mechanism 20 (i.e., the intersection of the pitch swing axis and the rotation axis).

In an exemplary embodiment, as shown in fig. 1, the terahertz security robot further includes a data processing device 70, and the data processing device 70 is configured to receive scan data for the object P to be inspected from the terahertz wave imaging mechanism 20 and generate a terahertz wave image. The data processing device 70 is also configured to receive the visible light image from the visible light imaging mechanism 30, and make a determination as to whether the inspected target P includes contraband based on the terahertz wave image and the visible light image. Specifically, the data processing device 70 may make a determination as to whether or not a suspect article is present in the inspected object based on the terahertz-wave image. If the data processing device 70 determines that there is a suspected item, it further determines whether the suspected item is an prohibited item based on the visible light image and the terahertz wave image.

In an exemplary embodiment, the data processing device 70 may be configured to, when it determines whether the object to be inspected has a suspected object based on the terahertz wave image, employ a depth learning algorithm to mark one or more regions of the terahertz wave image as suspected regions where the suspected object may exist; also, the data processing device 70 may be further configured to, when it determines whether the prohibited area of the suspected item is an prohibited item based on the visible light image and the terahertz wave image, first identify the area where the object to be inspected is located based on the visible light image using a depth learning algorithm, and remove the suspected area if the suspected area corresponds to an area other than the area where the object to be inspected is located in the visible light image.

In an exemplary embodiment, the data processing device 70 is further configured to identify whether the object in the region corresponding to the suspected region in the visible light image is a non-concealed object, for example, by using a deep learning algorithm if the suspected region corresponds to the region in which the inspected object is located in the visible light image, and if so, determine that the suspected region does not include the prohibited object, otherwise, determine that the suspected region includes the prohibited object.

In the terahertz wave image, the outer packaging materials such as plastics, paper sheets, textiles and leather are transmitted by the terahertz wave, so when a human body carries an article which cannot be penetrated by the terahertz wave, the terahertz wave is reflected by the article, and the outline of the article appears in the terahertz wave image. However, although the outline of the object is displayed, the terahertz wave image cannot exactly identify whether the object belongs to the prohibited object, and only can determine that the object is a suspected object. In the present embodiment, the visible light imaging mechanism 30 is simultaneously arranged to capture a visible light image of the object to be inspected, and the visible light image generated by the visible light imaging mechanism 30 matches the terahertz wave image generated by the terahertz wave imaging mechanism 20 within the depth of field of the terahertz wave imaging mechanism 20, so as to more easily and accurately determine whether the suspected object in the terahertz wave image is an contraband or not.

In an exemplary embodiment, as shown in fig. 1, the terahertz security inspection robot further includes an instruction interaction module 60 for inputting and outputting various forms of instruction information. The terahertz security inspection robot further comprises a main control module 10, which is used for generating an operation instruction according to the received user instruction. Specifically, the main control module 10 may receive voice information, analyze the received voice information, respond to feedback text information corresponding to the voice information, synthesize the feedback text information into feedback voice information by voice, and transmit the feedback voice information to the voice interaction module of the instruction interaction module 60; in addition, the main control module 10 may also control a rotation mechanism 40 for driving the head housing of the security robot and the mirror assembly located in the head housing to rotate. The terahertz security inspection robot further comprises a power supply 90 for supplying power.

In an exemplary embodiment, as shown in fig. 1, the terahertz security robot further includes a data transmission module 80, and the data transmission module 80 is configured to transmit data processed by the data processing device 70 to a remote terminal under the control of the main control module 10. The data transmission module 80 may adopt, for example, a 5G transmission technology, and transmits the visible light image and the terahertz wave image from the data processing device 70 to the cloud platform, and finally displays and alarms through the image display device at the inspection terminal.

In some embodiments of the present disclosure, a Field Programmable Gate Array (FPGA) may be used to collect a visible light image collected by the visible light imaging mechanism 30 and scan data of the terahertz wave imaging mechanism 20, the scan data is filtered in the FPGA, then the position information of the mirror 21, the visible light image and the scan data are packed according to a certain data format, and are transmitted to an upper computer through a gigabit ethernet or a wireless WiFi mode, and are re-converted into a terahertz wave image after receiving the scan data through a processing device 70 disposed at the upper computer, after a suspicious object is identified in the terahertz wave image, a suspicious object is marked at a corresponding position of the visible light image, and the marked visible image is compressed and stored in a cloud platform.

In an exemplary embodiment, the terahertz wave security inspection system 100 further comprises an image display device in data communication with the data processing device 70, the image display device being capable of receiving and displaying terahertz wave images and/or visible light images from the data combing device.

In an exemplary embodiment, the data processing device 70 may be configured to frame a suspected area where the suspected item/contraband is located on the terahertz wave image and/or the visible light image with a specific color. The image display device can display visible light images and terahertz wave images of a suspected area where the suspected object/the forbidden object is framed, so that the inspection personnel can compare and contrast the images.

In an exemplary embodiment, as shown in fig. 1 and 2, the terahertz security inspection robot further includes a plurality of omnidirectional moving wheels 50 disposed at the bottom of the terahertz security inspection robot, so that the terahertz security inspection robot can travel to a specific position according to an instruction from the main control module 10 to perform security inspection work, or remotely control the position and orientation of the terahertz security inspection robot to switch an inspection area at any time, detect a crowd, or perform tracking monitoring on an inspected object P.

In the above exemplary embodiment, the terahertz wave imaging mechanism 20 employs the focusing lens 22 for focusing, however, it should be understood by those skilled in the art that in other embodiments of the present disclosure, the terahertz wave imaging mechanism 20 may employ an ellipsoidal reflecting surface or a hyperbolic reflecting surface or an even aspheric surface or a free-form surface 22' for focusing, as shown in fig. 10. In the above example, the reflector 21 is in the form of a flat oval, however, it will be understood by those skilled in the art that in other embodiments of the present disclosure, the reflector 21 may be a polygonal drum 21' (as shown in fig. 11) rotating 360 ° around a rotation axis, or may be in the form of a flat rectangle, etc.

According to the terahertz security inspection robot disclosed by the various embodiments of the present disclosure, the head housing and the mirror assembly located in the head housing are rotated, for example, 180 ° or 360 ° with respect to the main housing by using the rotating mechanism, so that the mirror assembly of the terahertz wave imaging mechanism is oriented in different directions, thereby implementing terahertz scanning imaging on the inspected object in different directions. The terahertz security inspection robot can be installed in places with high flow such as subways and railway stations to shoot local videos of a human body in an all-around mode, and for example, positions which are easy to carry dangerous goods such as the waist of the human body and a handbag are monitored in an important mode to detect. The terahertz security inspection robot can be conveniently installed in places where existing security inspection technologies cannot be used or are inconvenient to use, such as banks, hotel proscenums, campus entrances, buses, offices, transceiving rooms, jewelry stores and the like. The terahertz security inspection robot can perform video imaging in the whole process, the person to be inspected does not need to stay, the security inspection efficiency can reach 6 times of that of the traditional manual inspection, and the number of people per hour is about 1500; compared with the traditional security inspection which only can mainly detect metal articles, the terahertz security inspection system can detect various contraband articles such as metal, liquid, ceramic, powder, colloid and the like; whole journey need not the physical contact, has not only improved security check efficiency, has more promoted the security check and has experienced. In a word, the device has the advantages of portability, firmness, small volume, high sensitivity, convenience in moving and carrying, no radiation, no stop, no touch, no perception, high safety and good concealment, can shoot local video of a human body in real time, and can alarm weapons, drugs and explosives in an imaging area in real time.

It will be appreciated by those skilled in the art that the embodiments described above are exemplary and can be modified by those skilled in the art, and that the structures described in the various embodiments can be freely combined without conflict in structure or principle.

Having described preferred embodiments of the present disclosure in detail, it will be apparent to those skilled in the art that various changes and modifications may be made without departing from the scope and spirit of the appended claims, and the disclosure is not limited to the exemplary embodiments set forth herein.