阅读说明：本技术 移动式快速部署警卫系统 (Mobile rapid deployment guard system ) 是由 宋源辉 于 2021-09-30 设计创作，主要内容包括：本发明公开了一种移动式快速部署警卫系统,包括若干组微波发射端、微波接收端,每一组微波发射端、微波接收端形成微波对射单元,并分别放置于防区的边缘；若干组微波对射单元通过发射、接收微波,整体形成区域性微波电磁场,来形成防区；本发明移动式快速部署警卫系统,用于雷达车、特种车辆野外执行任务,或者其它需要快速建立临时警戒区域,通过移动式快速部署警卫系统进行快速入侵防护部署,实现对入侵人员的实时探测。快速警卫系统可通过多套设备在现场快速部署,组合成立体、封闭的防护区域。(The invention discloses a mobile rapid deployment guard system, which comprises a plurality of groups of microwave transmitting ends and microwave receiving ends, wherein each group of microwave transmitting ends and each group of microwave receiving ends form a microwave correlation unit and are respectively arranged at the edge of a defense area; the microwave emitting units emit and receive microwaves to integrally form a regional microwave electromagnetic field so as to form a defense area; the mobile rapid deployment guard system is used for the radar vehicle and the special vehicle to carry out tasks in the field or other temporary warning areas needing to be established rapidly, and the mobile rapid deployment guard system is used for rapid intrusion protection deployment to realize real-time detection of intruders. The rapid guard system can be rapidly deployed on site through a plurality of sets of equipment to form a three-dimensional and closed protection area.)

1. A mobile rapid deployment guard system is characterized by comprising a plurality of groups of microwave transmitting ends and microwave receiving ends, wherein each group of microwave transmitting ends and each group of microwave receiving ends form a microwave correlation unit and are respectively arranged at the edge of a defense area; the plurality of groups of microwave opposite-emitting units integrally form a regional microwave electromagnetic field by emitting and receiving microwaves to form a precaution area;

a group of microwave transmitting terminals and microwave receiving terminals which are opposite to each other are matched and debugged equipment, gain correction is carried out after the equipment works, the distance between the equipment is confirmed through microwave carrier communication, then automatic gain adjustment is carried out, and the transmitting power of the microwave transmitting terminals is adjusted to obtain microwave signals with correct intensity;

after the equipment works, the detection microwave carrier waves transmitted by the planar radiation unit matrix antennas are communicated with each other, the angle between the microwave transmitting end and the microwave receiving end is confirmed, each radiation unit in the planar radiation unit matrix antennas of the microwave transmitting end is controlled to obtain a correct microwave beam, and the microwave correlation equipment enters a detection state.

2. The mobile rapid deployment guard system according to claim 1, wherein a plurality of defense points are disposed in the defense area, a microwave correlation prevention area is formed between two adjacent defense points, and each microwave correlation prevention area is provided with a set of 1 microwave transmitting end and 1 microwave receiving end which are paired; the microwave correlation prevention areas are connected in a head-to-tail cross mode to form a closed-loop microwave detection field.

3. The mobile rapid deployment guard system according to claim 1, wherein the microwave transmitting end and the microwave receiving end are arranged at a distance of 5m-200m, the microwave receiving end continuously receives microwave energy, detects activities in the microwave electromagnetic field, changes signals received by the receiving end due to any intrusion behaviors of interference, reflection and interruption of the microwave electromagnetic field, processes the changed signals by the receiving end, distinguishes the intrusion behaviors of walking, running and crawling of an intruder, and triggers an alarm when the signals meet the determination condition of an effective target.

4. The mobile rapid deployment guard system of claim 1, wherein the microwave transmitting end and the microwave receiving end operate in a 24G frequency band and are divided into 10 bands of detection frequencies for selection.

5. The mobile rapid deployment guard system according to claim 1, further comprising a receiving unit, wherein the receiving unit comprises a wireless alarm module, a wireless remote sensing control terminal or a mobile communication internet client, and the alarm signal generated by the microwave receiving terminal is transmitted to the wireless remote sensing control terminal or the mobile communication internet client through the general wireless alarm module to display and output the alarm signal.

6. The mobile rapid deployment guard system according to claim 1, wherein the mobile rapid deployment guard system further comprises a plurality of tripods, each tripod comprises a central support column, a tripod support column and a rapid installation interface, the microwave transmitting end and the microwave receiving end are installed on the central support column through the rapid installation interface, meanwhile, the central support column is a cavity structure, the internal cavity of the central support column directly forms a battery compartment, and a low temperature resistant lithium battery for supplying power to equipment is directly installed in the battery compartment.

7. The mobile rapid deployment guard system according to claim 6, wherein a telescopic support column is sleeved in the tripod support column, a fixed support is arranged at the tail end of the telescopic support column, and a fixed nail hole is formed in the fixed support.

8. The mobile rapid deployment guard system according to claim 6, wherein the microwave transmitting end, the microwave receiving end, the low temperature resistant lithium battery and the tripod are stored in an aviation safety box, and a prefabricated sponge buffer layer is arranged in the aviation safety box, so that the whole set of equipment can be stored and transported conveniently.

9. The mobile rapid deployment guard system of claim 5, wherein the wireless alarm module comprises an input interface, a power management module, and an extended communication interface, and the wireless communication sub-module is inserted into the extended communication interface to alarm via multiple communication links.

10. The mobile rapid deployment guard system of claim 9, wherein the wireless communication sub-module comprises a 2.4G point-to-point wireless sub-module, a 4GLTE communication module, wherein,

in the whole alarm link, a 2.4G point-to-point wireless submodule is used as an access layer, collected front-end alarm signals are forwarded out through the 2.4G point-to-point wireless submodule, the wireless remote sensing control terminal is used as a convergence layer, alarms are carried out through a built-in sound-light alarm device, the alarm signals are forwarded to a management platform through an alarm output port, and the alarm signals are displayed in a picture-text mode through an electronic map;

or in the whole alarm link, the 4G LET communication submodule is used as an access layer to forward the collected front-end alarm signals through a 4GLET communication network, a wireless base station in the 4G communication network is used as a convergence layer to converge and forward the signals to a management platform, the management platform classifies and arranges all the received alarm signals according to the sequence, and the alarm signals are displayed in the form of pictures and texts through clients in different forms; the 4G LET communication sub-modules are bound on each microwave correlation receiving unit through the management platform to form one-to-one corresponding alarm relation.

11. The mobile rapid deployment guard system of claim 10, wherein the wireless remote sensing control terminal cooperates with the 2.4G point-to-point wireless sub-module to receive an alarm signal, and the wireless remote sensing control terminal is integrated into a portable aviation safety box.

12. The mobile rapid deployment guard system according to claim 5, wherein a data output interface is arranged in the wireless remote sensing control terminal and can be connected with a Beidou integrated transceiver, the alarm signal received by the wireless remote sensing control terminal is transmitted to the Beidou integrated transceiver through the data output interface, the Beidou integrated transceiver forwards the alarm signal to a control center in a different place through a Beidou satellite in the form of a Beidou short message, and the alarm state is displayed on an electronic map in the form of pictures and texts through data processing.

Technical Field

The invention relates to the technical field of security protection, in particular to a mobile rapid deployment guard system.

Background

The intrusion alarm system is widely applied to a plurality of fields such as army, bank, museum, industrial and mining enterprises, public security and the like, and at present, the space intrusion alarm system commonly used at home and abroad mainly adopts a passive infrared intrusion detector, a microwave intrusion detector and a dual-technology intrusion detector (the combination of passive infrared and microwave).

The above alarm systems all have their specific conditions of use, all have certain limitations from the installation and use angles of the detection device, for example: the passive infrared intrusion detector has the detection method that the change of the thermal radiation in a certain three-dimensional precaution space is monitored, and when a human body moves in a detection range, the level of the received infrared radiation is changed, so that the alarm is triggered. The passive infrared detection method is easily interfered by various heat sources (air conditioner, cold and hot air convection) and light sources, but when the ambient temperature and the human body temperature are close, the detection and the sensitivity are obviously reduced, short-time detection failure is sometimes caused, and the detector also fails when a shelter (a heat insulation object such as a large umbrella, a raincoat, glass and the like) is used for blocking the body. Active intrusion detectors such as microwave intrusion detectors and dual-technology intrusion detectors can avoid the above weaknesses by adopting the doppler principle, but have a high false alarm rate, and the devices can be detected only after being fixedly installed and debugged, and cannot be movably installed and deployed at any time.

The detection method of microwave correlation comprises the following steps: the microwave transmitting end transmits microwave signals to the precaution area through the antenna, and when the precaution area does not move the target, the receiving end receives the complete microwave signals and does not give an alarm. When the prevention area has a moving target, the effective target can reflect, absorb and block microwave signals because the microwaves have heat effect and reflection effect, and the receiving end generates alarm signals after analysis. Although the microwave correlation detector can avoid the defects of the equipment, the microwave correlation detector generally needs to be fixedly installed and cannot be rapidly deployed, and even if the microwave correlation detector is rapidly installed, cables must be adopted to transmit power and signals, so that the problems of low deployment efficiency, poor concealment and the like are caused.

Disclosure of Invention

Aiming at the problems in the prior art, the invention aims to provide a mobile rapid deployment guard system which is simple in structure and convenient to deploy.

In order to achieve the purpose, the mobile rapid deployment guard system comprises a plurality of groups of microwave transmitting ends and microwave receiving ends, wherein each group of microwave transmitting ends and each group of microwave receiving ends form a microwave correlation unit and are respectively arranged at the edge of a defense area; the microwave emitting units emit and receive microwaves to integrally form a regional microwave electromagnetic field so as to form a defense area;

and the group of microwave transmitting ends and microwave receiving ends which are opposite to each other are matched debugging equipment, gain correction is carried out after the equipment works, the distance between the equipment is confirmed through microwave carrier communication, then automatic gain adjustment is carried out, and the transmitting power of the microwave transmitting ends is adjusted to obtain microwave signals with correct intensity.

After the equipment works, the detection microwave carrier waves transmitted by the planar radiation unit matrix antennas are communicated with each other, the angle between the microwave transmitting end and the microwave receiving end is confirmed, each radiation unit in the planar radiation unit matrix antennas of the microwave transmitting end is controlled to obtain a correct microwave beam, and the microwave correlation equipment enters a detection state.

When the microwave is lost due to the influence of weather conditions, such as rain, snow, fog or rapid change of outdoor air temperature, the transmitting end can also adjust the transmitting power through the automatic gain to compensate.

The transmitting antenna and the receiving antenna of each microwave correlation unit both adopt flat-plate microstrip antennas, so that the directivity of the antennas is excellent, the volume of the microwave units is reduced, and the power consumption is reduced.

Furthermore, a plurality of defense deployment points are arranged in the defense area, each defense deployment point is provided with 2 microwave transmitting ends or 2 microwave receiving ends, the microwave transmitting ends and the microwave receiving ends are respectively installed at two adjacent defense deployment points, and the microwave transmitting ends and the microwave receiving ends of the two adjacent defense deployment points are in one-to-one correlation to form a microwave correlation unit and a closed-loop microwave detection field.

Furthermore, the arrangement distance between the microwave transmitting end and the microwave receiving end is 5m-200m, the microwave receiving end continuously receives microwave energy, the movement in a microwave electromagnetic field is detected, any invasion behaviors of interference, reflection and interruption of the microwave electromagnetic field can change signals received by the receiving end, the receiving end processes the changed signals, the invasion behaviors of walking, running and crawling of an intruder are distinguished, and an alarm is triggered when the signals meet the judgment condition of an effective target.

Further, the microwave transmitting end and the microwave receiving end work in a 24G frequency band and are divided into detection frequencies of 10 wave bands for selection.

And the system further comprises a receiving unit, wherein the receiving unit comprises a wireless alarm module, a wireless remote sensing control terminal or a mobile communication internet client, and an alarm signal generated by the microwave receiving end is sent to the wireless remote sensing control terminal or the mobile communication internet client through the universal wireless alarm module to display and output the alarm signal.

Further, the system still includes a plurality of tripod, and this tripod includes central support column, tripod support column, quick installation interface, microwave emission end, microwave receiving terminal are installed on the central support column through quick installation interface, and simultaneously, the central support column is the cavity structure, and its inside cavity directly forms the battery compartment, and direct mount gives the low temperature resistant lithium cell of equipment power supply in this battery compartment.

Furthermore, a telescopic support column is sleeved in the tripod support column, a fixed support is arranged at the tail end of the telescopic support column, and a fixed nail hole is formed in the fixed support.

Further, microwave transmitting terminal, microwave receiving terminal, low temperature resistant lithium cell, tripod are all accomodate and are saved in an aviation safety box, are provided with prefabricated sponge buffer layer in the aviation safety box, are convenient for whole equipment's storage, transportation.

Furthermore, the wireless alarm module comprises an input interface, a power management module and an extended communication interface, and a wireless communication submodule is inserted into the extended communication interface to alarm through multiple communication links.

Further, the wireless communication sub-module comprises a 2.4G point-to-point wireless sub-module and a 4GLTE communication module, wherein,

in the whole alarm link, a 2.4G point-to-point wireless submodule is used as an access layer, collected front-end alarm signals are forwarded out through the 2.4G point-to-point wireless submodule, the wireless remote sensing control terminal is used as a convergence layer, alarms are carried out through a built-in sound-light alarm device, the alarm signals are forwarded to a management platform through an alarm output port, and the alarm signals are displayed in a picture-text mode through an electronic map;

or in the whole alarm link, the 4G LET communication submodule is used as an access layer to forward the collected front-end alarm signals through a 4GLET communication network, a wireless base station in the 4G communication network is used as a convergence layer to converge and forward the signals to a management platform, the management platform classifies and arranges all the received alarm signals according to the sequence, and the alarm signals are displayed in the form of pictures and texts through clients in different forms; the 4G LET communication sub-modules are bound on each microwave correlation receiving unit through the management platform to form one-to-one corresponding alarm relation.

Further, the wireless remote sensing control terminal is matched with the 2.4G point-to-point wireless submodule to receive an alarm signal, and the wireless remote sensing control terminal is integrated in the portable aviation safety box.

Further, a data output interface is arranged in the wireless remote sensing control terminal and can be connected with the Beidou integrated transceiver, the alarming signal received by the wireless remote sensing control terminal is transmitted to the Beidou integrated transceiver through the data output interface, the Beidou integrated transceiver forwards the alarming signal to a control center in a different place through a Beidou satellite in a Beidou short message mode, and the alarming state is displayed on an electronic map in a picture and text mode through data processing.

The mobile rapid deployment guard system is used for the radar vehicle and the special vehicle to carry out tasks in the field or other temporary warning areas needing to be established rapidly, and the mobile rapid deployment guard system is used for rapid intrusion protection deployment to realize real-time detection of intruders. The rapid guard system can be rapidly deployed on site through a plurality of sets of equipment to form a three-dimensional and closed protection area.

Drawings

Fig. 1 is a defense schematic diagram of a mobile rapid deployment guard system;

fig. 2 is a schematic diagram of the electromagnetic field of a mobile rapid deployment guard system;

FIG. 3 is a schematic view of a tripod configuration;

FIG. 4 is a schematic view of an open-box structure of the detection unit;

FIG. 5 is a schematic diagram of a wireless alarm module architecture;

FIG. 6 is a schematic diagram of a 2.4G peer-to-peer wireless alarm framework;

FIG. 7 is a schematic diagram of a 4GLET wireless alarm framework;

FIG. 8 is a schematic structural diagram of a wireless remote sensing control terminal;

FIG. 9 is a Beidou satellite Transponding Unit architecture diagram;

fig. 10 is a mobile communication internet client architecture diagram.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. 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 invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

The following detailed description of embodiments of the invention refers to the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating the present invention, are given by way of illustration and explanation only, not limitation.

As shown in fig. 1 to 10, the mobile rapid deployment guard system of the present invention is a defense area type intrusion alarm device, and the length of the defense area 1 may be 5m to 200 m. The mobile rapid deployment guard system comprises a detection unit and a receiving unit, wherein waves in the detection unit are oppositely emitted to form an invisible microwave detection field 2, so as to detect the invasion behavior of an invader walking, running or crawling into a defense area, and the detection unit comprises 1 set of microwave opposite emission unit 6, a multifunctional tripod 9 and a low-temperature-resistant lithium battery; the receiving unit is responsible for receiving, displaying and forwarding the alarm signal, provides alarm display and output, can be a wireless remote sensing control terminal 8, and can also be a mobile phone client adopting a mobile communication internet client or a PC client accessing the internet.

In the invention, a detection unit is provided with a plurality of groups of microwave transmitting ends 4 and microwave receiving ends 5, each group of microwave transmitting ends 4 and microwave receiving ends 5 which are paired and oppositely emitted form a microwave oppositely-emitting unit 6, and the microwave transmitting ends 4 and the microwave receiving ends 5 are both arranged at the edge of a defense area 1; the plurality of microwave correlation units 6 are used for forming the defense area 1 by integrally forming regional microwave electromagnetic fields through microwave correlation. The specific setting mode is as follows: a plurality of defense deployment points 3 are arranged in the defense area 1, a microwave correlation prevention area is formed between every two adjacent defense deployment points 3, and a microwave transmitting end 4 and a microwave receiving end 5 are both arranged in the defense deployment points 3; each microwave correlation prevention area is provided with a group of 1 microwave transmitting end 4 and 1 microwave receiving end 5 which are paired; the microwave correlation prevention areas are connected in a cross way end to form a closed-loop microwave detection field 2 to protect the defense area 1.

In the present invention, both the microwave transmitting terminal 4 and the microwave receiving terminal 5 are provided with a plane radiating element matrix antenna, and the planar radiation element matrix antennas are small in size and light in weight relative to the parabolic antennas, the planar radiation element matrix antennas are fixedly arranged in the microwave correlation equipment, and each planar radiation element matrix antenna is provided with an angle with set parameters, so that the angle change of the antennas cannot happen even if the equipment is frequently disassembled and boxed. Therefore, the problem that the antenna needs to be adjusted for a long time during installation to obtain a correct microwave beam signal can be solved.

The control plane radiation unit matrix antenna can be rapidly deployed and detected. When a group of microwave transmitting terminal 4 and microwave receiving terminal 5 which are paired and adopt the planar radiation unit matrix antenna are installed quickly, only the microwave equipment needs to be aligned visually without operations such as adjusting the angle of the antenna, and the planar radiation unit matrix antenna is controlled to enter a detection state by a built-in program. After the equipment is powered on, the detected microwave carriers transmitted by the planar radiation element matrix antenna are communicated with each other, signals of microwave communication are analyzed by an internal program of the equipment to confirm the distance between the two pieces of equipment and the angle between the two antennas, and then each radiation element in the planar radiation element matrix antenna at the microwave transmitting end is controlled to obtain correct microwave beams, so that the microwave correlation equipment can rapidly enter a detection state. When the correctly installed microwave correlation equipment is electrified and enters a defense deployment detection working state, the overall time is less than 10 seconds, and therefore rapid deployment is achieved.

In this embodiment, each defense deployment point 3 is provided with 2 microwave transmitting terminals 4 or 2 microwave receiving terminals 5, and two adjacent defense deployment points 3 are respectively provided with a microwave transmitting terminal 4 and a microwave receiving terminal 5, namely: the first defense deployment point 3 is provided with 2 microwave transmitting ends 4, the second defense deployment point 3 is provided with 2 microwave receiving ends 5, the third defense deployment point 3 is provided with 2 microwave transmitting ends 4, the fourth defense deployment point 3 is provided with 2 microwave receiving ends 5, and so on. Microwave transmitting ends 4 and microwave receiving ends 5 of two adjacent defense points 3 are in one-to-one correlation to form a microwave correlation prevention area, a pair of microwave transmitting ends 4 and microwave receiving ends 5 which are in mutual correlation to form a microwave correlation unit 6, and the whole microwave correlation prevention area is formed into 4 microwave correlation prevention areas and forms a closed-loop microwave detection field 2.

In operation, the plurality of groups of microwave correlation units 6 form a regional microwave intrusion detection electromagnetic field, namely the microwave detection field 2, through the microwave electromagnetic field. After the microwave correlation unit 6 is properly placed, the microwave correlation is aligned visually, and it is ensured that no obstacle (which may cause false alarm) or ground depression (which may form a blind area) exists in the microwave beam region; switching on power supplies of a microwave transmitting end 4 and a microwave receiving end 5, enabling microwave correlation to communicate with each other through microwave carriers, firstly entering a self-checking state, and confirming that the devices are normally paired and debugged; and then the microwave correlation unit 6 enters an automatic distance correction state, the distance between the microwave correlation unit 6 and the transmitting end is confirmed through microwave carrier communication because the propagation speed of the microwave in the air is a fixed value, and finally the microwave correlation unit 6 performs automatic gain adjustment according to the determined distance to adjust the transmitting power of the transmitting end. If the signal with the correct intensity cannot be obtained after the transmitting power is adjusted within the determined using distance, the microwave correlation can continuously give an alarm to prompt until the microwave correlation unit 6 is arranged to be correctly and accurately aligned, so that the microwave signal with the correct intensity is obtained.

In the invention, each set of microwave correlation unit 6 comprises 1 microwave transmitting end 4 and 1 microwave receiving end 5, and the arrangement distance of the microwave correlation units 6 can be arranged between 5m and 200m according to the field environment. As shown in fig. 2, the microwave emitting end 4 emits microwave energy to form a microwave electromagnetic field with narrow ends and wide middle (the beam width is 4% of the beam length), which is invisible. The microwave receiving end 5 continuously receives microwave energy, detects activities in a microwave electromagnetic field, any invasion behaviors of interfering, reflecting and blocking the microwave electromagnetic field change signals received by the microwave receiving end 5, the microwave receiving end 5 processes the changed signals to distinguish other invasion behaviors of an invader such as walking, running and crawling, and an alarm is triggered when the signals meet judgment conditions of effective targets.

The microwave correlation alarm conditions are as follows:

1. under normal conditions, microwave correlation can detect intruders with speed between 3 cm/s and 15 m/s;

2. in the range of 200m, the microwave correlation can detect the invasion of an invader in a walking, running or jumping way;

3. in the range of 150m, microwave correlation can detect the invasion of an invader in a mode of walking, running, bending knees, crawling or jumping;

4. in the range of 100m, the microwave correlation can detect the invasion of the invader in the modes of walking, running, bending knees and crawling, creeping, rolling or jumping;

5. the microwave receiving end 5 only receives microwave signals transmitted by the paired microwave transmitting ends 4, and if the microwave signals are cracked by malicious intrusion, the system triggers an alarm;

6. if any one of the units is damaged and stolen, the microwave signal is lost and interrupted, or the microwave signal is interfered by an intruder, the system triggers an alarm.

When an intruder enters the microwave electromagnetic field in walking, running, crawling and other postures, the microwave has a heat effect and a reflection effect, the microwave electromagnetic field is interfered by the human body because the microwave has constant microwave absorption and reflection amount, and in addition, the walking, running and crawling postures of the intruder appear at different spatial positions of the microwave detection electromagnetic field, and microwave signals with different intensities and positions can be received on the antenna at the receiving end. The characteristic signal data formed by these intrusion behaviors (but not limited to the above behaviors) is stored in the memory of the receiving end. Due to the weather conditions such as rain, snow and fog in the external environment or electromagnetic interference generated by other equipment, continuous background environment noise interference can be generated on the wave beams of the microwaves, and the background environment noise can interfere with or even shield the intrusion signals to influence the accurate judgment of the receiving end on the intrusion signals; therefore, when the receiving end receives the effective intrusion signal, the intrusion signal is firstly analyzed by the digital signal processor to be separated from the background environment noise to obtain a real intrusion signal, then the real intrusion signal is compared with the stored intrusion characteristic data, and when the signal meets the judgment condition of an effective target, an alarm is triggered.

When the microwave is lost due to the influence of weather conditions, such as rain, snow, fog or rapid change of outdoor air temperature, the transmitting end can also adjust the transmitting power through the automatic gain to compensate. The transmitting antenna and the receiving antenna of each microwave correlation unit both adopt flat-plate microstrip antennas, so that the directivity of the antennas is excellent, the volume of the microwave units is reduced, and the power consumption is reduced.

In the invention, the microwave transmitting end 4 and the microwave receiving end 5 work in a 24G frequency band, and the frequency band can be divided into 10 bands of detection frequencies for selection, so that a plurality of sets of microwave correlation devices can work in a short distance without mutual interference.

Data communication between the microwave transmitting end 4 and the microwave receiving end 5 adopts the modulated microwave detection signal as a carrier wave for communication, and a communication cable does not need to be additionally arranged. The receiving unit comprises a wireless alarm module 7, a wireless remote sensing control terminal 8 or a mobile communication internet client, an alarm signal generated by the microwave receiving end 5 is sent to the wireless remote sensing control terminal 8 through the wireless alarm module 7 arranged in the receiving unit, and the wireless remote sensing control terminal 8 displays and outputs the alarm signal; or the wireless alarm module 7 sends the alarm signal to the mobile communication internet client, and the mobile phone client, the tablet computer client and the PC client display and output the alarm signal, namely the mobile communication internet client can be a mobile phone client, a tablet computer client and a PC client.

The microwave transmitting end 4 and the microwave receiving end 5 are both fixedly mounted through a tripod 9, as shown in fig. 3, the tripod 9 includes a battery compartment cover 10, a quick mounting interface 11, a central support column 12, a telescopic support column 13, a power line 14, a tripod support column 15, a telescopic support column locking nut 16, a fixed support 17 and a fixed nail hole 18.

Microwave emission end 4, microwave receiving terminal 5 are installed on tripod 9 through installing interface 11 fast, and the locking mechanical system of installing interface 11 fast not only ensures that microwave emission end 4, microwave receiving terminal 5 are stable firm after the installation, can ensure convenient quick installation and dismantlement simultaneously.

During installation, the microwave transmitting end 4 and the microwave receiving end 5 are inserted into the quick installation interface 11 at the upper part of the tripod 9, and the microwave transmitting end 4 and the microwave receiving end 5 can be locked and fixed by the lock catch of the quick installation interface 11 after the microwave transmitting end 4 and the microwave receiving end 5 are inserted in place.

The central support column 12 of the tripod 9 is a cavity structure, the internal cavity of which directly forms a battery compartment in which a low temperature resistant lithium battery 19 for supplying power to the equipment is directly installed. When the battery is replaced, the low-temperature resistant lithium battery 19 can be taken out and replaced only by unscrewing the battery bin cover 10 on the upper part of the central support column 12. The microwave transmitting terminal 4 and the microwave receiving terminal 5 are connected with a low temperature resistant lithium battery 19 through a power line 14, so as to provide electric energy.

The tripod 9 comprises three tripod support columns 15, and a telescopic support column 13 is sleeved on the lower part of each tripod support column 15 and is used for the following two points:

1. when the ground where the microwave transmitting end 4 and the microwave receiving end 5 are placed is uneven, the length of the three telescopic supporting columns 13 can be adjusted to ensure that each microwave transmitting end 4 and each microwave receiving end 5 are in a horizontal state, so that the detected microwave beams are aligned between the microwave opposite emission units 6, and false alarm or missing alarm caused by microwave beam deviation can be avoided.

2. Because the detection beam characteristics of microwave correlation are narrow at two ends and wide in the middle, a certain microwave coverage blind area is generated near the microwave transmitting end 4 and the microwave receiving end 5 before the beam contacts the ground, and in order to reduce the blind area, the microwave correlation is usually arranged in a staggered mode to perform blind compensation. When the distance between the microwave correlation units 6 is less than 50m, the length of the coverage dead zone is larger relative to the detection distance, and in order to further reduce the dead zone, each microwave correlation unit 6 needs to be inclined to the ground by 5 degrees, so that the beam grounding distance can be shortened, the microwave dead zone is reduced, and the microwave coverage range is improved.

The operation is realized on the tripod 9, the tripod 9 is firstly ensured to be installed horizontally and stably, the three telescopic support columns 13 are not pulled out, then the telescopic support columns 13 at the rear part of the microwave correlation unit 6 are all pulled out, the telescopic support column locking nuts 16 are screwed, and meanwhile, the other two telescopic support columns are ensured to be immobile, so that the microwave correlation unit 6 can be detected in a state of inclining 5 degrees to the ground.

The tripod 9 comprises three telescopic support columns 13, the tail ends of which are fixed supports 17, the fixed supports 17 can freely move in a certain range and are used for adapting to the ground and stably supporting the tripod 9; the tail end of each fixed support 17 is provided with a fixing nail hole 18, the function of the fixing nail hole is that when severe weather of strong wind is met or the slope of the ground is relatively large, the tripod 9 needs to be fixedly installed relative to the ground, fixing nails can be driven into the fixing nail holes 18 for fixing, and the stability and the firmness of the tripod 9 are ensured.

All the equipment in the detection unit, including the microwave transmitting end 4, the microwave receiving end 5, the tripod 9, the low temperature resistant lithium battery 19 and the like are placed in the prefabricated sponge buffer layer 34 in the aviation safety box 20, so that the collision of the whole set of equipment in the storage and transportation processes is avoided, and the safety and reliability of the equipment are ensured.

As shown in fig. 4, 2 low temperature resistant lithium batteries 19, 2 chargers 21, a microwave transmitting terminal 4, a microwave receiving terminal 5 and 2 tripods 9 are arranged in the aviation safety box 20, and all the components are isolated from each other through a prefabricated sponge buffer layer 34.

The wireless alarm module 7 is installed in the receiving unit and is used for forwarding the alarm signal output by the receiving unit in a wireless mode, so that the detection unit can alarm without an alarm data line.

As shown in fig. 5, the wireless alarm module 7 adopts a combined modular structure, and the master of the module includes an input interface, a power management module and an extended communication interface. According to different actual requirements on the site, wireless communication sub-modules, such as a 2.4G point-to-point wireless sub-module and a 4GLTE communication module, can be inserted into the expansion communication interface to perform multi-communication link alarm.

When the wireless communication sub-module is set as a 2.4G point-to-point wireless sub-module, as shown in fig. 6, the 2.4G point-to-point wireless sub-module can transmit an alarm signal in an environment without any wireless communication network, the alarm signal of the microwave correlation unit 6 is transmitted to the wireless remote sensing control terminal 8 serving as a receiving unit through 2.4G wireless codes, and the connection between the microwave correlation unit 6 and a control center can be quickly established (the receiving distance in an open area is more than or equal to 2000 m). 4 sets of microwave correlation units 6 adopting 2.4G point-to-point wireless sub-modules can form a closed alarm defense area, and a wireless remote sensing control terminal 8 is arranged to receive the alarm signals of the 4 sets of microwave correlation units 6 and display and output the alarm signals.

In the whole alarm link, the wireless alarm module 7 serves as an access layer, collected front-end alarm signals are forwarded through a 2.4G point-to-point wireless submodule, the wireless remote sensing control terminal 8 serves as a convergence layer to receive the alarm signals, an audible and visual alarm device is arranged to give an alarm, the alarm signals can be forwarded to a management platform (cloud server) through an alarm output port, and the alarm signals are displayed in an image-text mode through an electronic map.

When the wireless communication sub-module is set as the 4G LET communication sub-module, as shown in fig. 7, the 4G LET communication sub-module may use the existing 4G communication network to forward the alarm signal of the microwave correlation unit 6, and the 4G LET communication sub-module is bound to each microwave correlation receiving unit through a management platform (cloud server) at the rear end to form a one-to-one corresponding alarm relationship. The front end receiving unit triggers an alarm signal, the alarm signal is forwarded by the 4G LET communication submodule, and the position of the alarm signal is displayed in time by the rear end management platform system (the 4G LET communication submodule supports the GPS geographic positioning function); the alarm signal can be displayed by a PC client or a mobile client of a mobile phone, so that alarm management and processing can be more flexibly carried out.

In the whole alarm link, a wireless alarm module 7 comprising a 4G LET communication submodule is used as an access layer, collected front-end alarm signals are forwarded out through a 4GLET communication network, a wireless base station in the 4G communication network is used as a convergence layer to converge the signals and then forward the signals to a management platform, the management platform is used as the core of the whole system, all the received alarm signals are sorted and sorted according to sequence, and finally the alarm signals are displayed in a picture and text mode through clients in different forms.

In the mobile rapid deployment guard system, the receiving unit mainly receives the alarm signal and displays and controls the alarm signal. The receiving unit can adopt various wireless transmission links in cooperation with the wireless alarm module 7, is also provided with an output port while being used as a client for displaying and controlling alarm signals, and can output the alarm signals to other systems for integration, thereby achieving the purpose of meeting various environments and various customer requirements.

The receiving unit has the following types according to the wireless transmission type of the wireless alarm module 7:

1. the wireless alarm module 7 selects a 2.4G point-to-point wireless submodule as a transmission mode, and can select a 2.4G wireless remote sensing control terminal 8 to transmit alarm signals.

2. The wireless alarm module 7 selects a 4G LET communication submodule as a transmission mode, and can select a mobile communication client or an Internet PC client to transmit alarm signals.

3. If the detection unit is arranged at the place without a mobile communication network, the structure of a 2.4G point-to-point wireless submodule + a 2.4G wireless remote sensing control terminal 8+ a Beidou transceiver all-in-one machine can be adopted for transmitting alarm signals.

In the invention, the wireless remote sensing control terminal 8 is an independent device, the wireless remote sensing control terminal 8 is matched with a 2.4G point-to-point wireless submodule to receive an alarm signal, all display and control parts of the wireless remote sensing control terminal 8 are integrated in a portable aviation safety box 35, the wireless remote sensing control terminal 8 is powered by a built-in low-temperature-resistant lithium battery, and the running time is not less than 30 hours. The communication distance between the wireless remote sensing control terminal 8 and the 2.4G point-to-point wireless sub-module is more than or equal to 2000m (open area).

The panel of the wireless remote sensing control terminal 8 is divided into a control unit, a display unit, an input and output unit and a grouping control unit. As shown in fig. 8, the wireless remote sensing control terminal 8 includes: portable aviation safety box 35, audible and visual alarm indicator 22, status indicator 23, power input 24, power switch 25, code matching button B26, antenna interface 27, code matching button A28, data output interface 29, relay output interface 30, alarm confirmation button 31 and accessory box 32. The functions of its various components are as follows:

1. controlling and displaying:

the acousto-optic alarm indicator 22, the antenna interface 27 and the alarm confirmation button are main control and display parts of the wireless remote sensing control terminal 8. The antenna receives the alarm signal sent by the detection unit, the signal is output to the sound-light alarm indicator after decoding, after the security personnel hear the alarm prompt tone, the alarm is rechecked, and after the alarm is confirmed, the sound-light alarm indicator stops sound-light prompt by pressing the alarm confirmation button. In order to prevent the alarm from being terminated by misoperation, when the detection unit is in an alarm state and the alarm signal is not stopped, the alarm acousto-optic prompt cannot be stopped even if the alarm confirmation button of the wireless remote sensing control terminal 8 is pressed.

2. Input/output

The power input 24, the data output interface 29 and the relay output interface 30 are input and output parts of the wireless remote sensing control terminal 8, wherein the power input 24 can adopt terminal type power input or 5.5mm plug-in type power input; all power input ends can adopt 5-24V direct current for power supply, so that the power supply can be suitable for different environments and occasions.

The relay output interface 30 can provide relay alarm contacts corresponding to 4 defense areas, and when the wireless remote sensing control terminal 8 receives an alarm signal, the sound-light alarm indicator 22 is triggered and the alarm electric appliances of corresponding channels are also triggered. The 4 alarm relays are C-type relays, can provide normally open and normally closed signals simultaneously, and can link systems such as a camera, an alarm lamp and a broadcast to carry out system integration.

The data output interface 29 adopts an RS232 bus structure and can provide alarm data signals for data output by the Beidou integrated transceiver 33.

3. Consist control

The status indication 23, the code-matching button B26, the antenna interface 27 and the code-matching button A28 are the grouping control part of the wireless remote sensing control terminal 8. The code matching button A28 and the code matching button B26 are used when the 2.4G point-to-point wireless submodule is matched with the wireless remote sensing control terminal 8, the code matching button A28 and the code matching button B26 of the receiver are pressed at the same time, the flicker time and the flicker frequency of the state indicator 23 are matched, and the wireless remote sensing control terminal 8 and the 2.4G point-to-point wireless submodule can be bound and unbound.

4. Big dipper satellite forwarding

As shown in fig. 9, if the mobile rapid deployment security system of the present invention is installed and deployed in an area without a mobile communication internet, but a command control center located in a different place needs to constantly master the perimeter defense state and the alarm state of the site, in this case, the big dipper satellite can be used to forward the alarm signal.

When the wireless remote sensing control terminal 8 receives an alarm signal sent by a detection unit, the alarm signal is transmitted to the Beidou integrated transceiver 33 through the data output interface 29, the Beidou integrated transceiver 33 forwards the alarm signal to a control center in a different place through a Beidou satellite in the form of a Beidou short message, and after the Beidou integrated transceiver 33 in the control center and matched with a site receives the alarm signal, the alarm state can be displayed on an electronic map in the form of pictures and texts through the processing of a background management system.

As shown in fig. 10, when the detection unit is installed in a 4G communication network, a 4G LET communication sub-module is inserted into the wireless alarm module 7, so that real-time monitoring of alarm through a mobile communication internet client can be realized. The mobile communication internet client can be a mobile phone client, a tablet computer client or a PC client. The real-time alarm monitoring is carried out by depending on the mobile communication network and the Internet, so that the real-time alarm monitoring can be carried out as long as the mobile communication Internet client side can be connected with the Internet no matter where the mobile communication Internet client side is located, and the alarm display can be accurately carried out by depending on the GPS and the Beidou system through the electronic map.

The core of the mobile communication internet client is a management platform established in a cloud server, and the management platform forwards and pushes real-time alarm information, so that the real-time alarm information can be displayed on an electronic map of a PC client and can also be integrated into a WeChat platform for simple alarm positioning display. Meanwhile, the telephone voice alarm and the short message alarm can be carried out.

The invention relates to a mobile rapid deployment guard system, which has the following main technical indexes:

1. detection unit

A. Microwave correlation detector:

detection range:

a walking target: 5 to 200 m;

crawling the target: 5 to 150 m;

creeping target: 5 to 100 m;

detection performance: greater than 99% when properly installed;

the rate of missing reports: 0, missing report;

false alarm rate: less than or equal to 1 time/pair/year;

headroom requirement: the clearance width is a space with 4% of the distance between the transmitter and the receiver, and all grass, plants and other obstacles are removed;

physical specification:

weight: the microwave transmitting end and the microwave receiving end are both 0.9 kg;

detector shell: high density ABS plastic;

environmental specification:

temperature: -40 to 70 ℃;

humidity: 0 to 95% no condensation;

electrical specification:

input voltage: 12-48V DC;

microwave detector 10 selectable frequency bands: 24.075 to 24.175GHz, 24dBm output.

B. Tripod:

tripod: aluminum-magnesium alloy;

a power supply battery: 12V low-temperature-resistant lithium battery 19, and the standby time is more than or equal to 30 hours.

C. The wireless alarm module:

2.4G point-to-point wireless submodule:

the working frequency is as follows: 2.4G;

communication distance: the receiving distance in an open area is more than or equal to 2000 m;

power supply: 5VDC-24 VDC;

4-channel main contact input;

2.4G point-to-point wireless submodule:

communication system: 4G;

LTE-FDD：B1/B3/B5/B8；

LTE-TDD：B34/B38/B39/B40/B41；

power supply: 5VDC-24 VDC;

1 path of main contact input;

2. receiving unit

Wireless remote sensing control terminal:

the working frequency is as follows: 2.4G;

communication distance: the receiving distance in an open area is more than or equal to 2000 m;

4 paths of C-type relay outputs, 1.0A and 30 VDC;

power supply: 5VDC-24 VDC;

a power supply battery: the low-temperature resistant lithium battery has the standby time of more than or equal to 30 hours.