JP2020193791A - Target detection system and method - Google Patents

Abstract

To realize a target detection system capable of detecting a plurality of targets without using a plurality of radar devices.SOLUTION: The target detection system according to the embodiment comprises: a missile for detecting and tracking a target; a radar device in communication with the missile; and an unmanned aircraft. The unmanned aircraft receives a reflection wave reflected from the target for the radio wave transmitted from the missile or the radar device in a direction of the target and transmits reception information relating to the received reflection wave to the radar device. The radar device receives the reception information transmitted from the unmanned aircraft, generates target location information relating to the target based on the reception information, and transmits the target location information to the missile.SELECTED DRAWING: Figure 1

Description

Embodiments of the present invention relate to a target detection system and method for detecting a target.

Conventionally, a target detection system has been developed to detect an aircraft or the like (hereinafter referred to as a target) arriving from a distance. The target detection system is a system in which a radar device installed on the ground and a flying object launched from a launching device cooperate to detect a target. The projectile includes a radar that uses radio waves as well as a ground-based radar device.

The projectile transmits radio waves, receives reflected waves from the target, and detects the target. Here, when the radar cross section of the target is small, the electric power of the reflected wave to the flying object with respect to the radio wave transmitted from the flying object is weak, and more strongly reflected in another direction such as backward. For this reason, it is difficult to detect a target arriving from a distance by radar radio waves. Conventionally, a target detection system that includes a plurality of radar devices in addition to a flying object receives reflected waves from the target and detects the target.

In the conventional target detection system, the projectile and multiple radar devices cooperate to transmit radio waves to one target, so if there are multiple targets, the resources of the radar device become insufficient, and each target There is a high possibility that it cannot be detected.

Japanese Patent No. 5349169

Therefore, an object of the present embodiment is to realize a target detection system capable of detecting a plurality of targets without using a plurality of radar devices.

The target detection system of the present embodiment includes a flying object that detects and tracks a target, a radar device that communicates with the flying object, and an unmanned aerial vehicle. The unmanned aerial vehicle receives a reflected wave reflected from the target with respect to a radio wave transmitted from the flying object or the radar device in the direction of the target, and receives received information on the received reflected wave from the radar device. Send to. The radar device receives the received information transmitted from the unmanned aerial vehicle, generates target position information regarding the target based on the received information, and transmits the target position information to the projectile.

The block diagram for demonstrating the structure of the target detection system which concerns on embodiment. The block diagram which shows an example of the structure of the flying object which concerns on embodiment. A flowchart for explaining a target detection process according to an embodiment.

Embodiments will be described below with reference to the drawings.
[System configuration]
FIG. 1 is a block diagram showing a configuration of a target detection system of the present embodiment. As shown in FIG. 1, the target detection system of the present embodiment has a configuration including a projectile 1, a launcher 6, a radar device 7, and a plurality of unmanned aerial vehicles 10 that detect and track the target 8. Target 8 is a flying object such as a single aircraft or a plurality of aircraft, and is made of a material having a small radar cross section.

The launching device 6 is a device for launching the flying object 1 and is installed on the ground. In addition to the radar function, the radar device 7 includes a control function that communicates with each of the flying object 1 and the unmanned aerial vehicle 10 described later to control the flight of the flying object 1 and the unmanned aerial vehicle 10, and is installed on the ground. The launching device 6 and the radar device 7 may be included in the control device that controls the flying object 1 and the unmanned aerial vehicle 10. The control device may be mounted on an aircraft or a ship.

FIG. 2 is a diagram showing an example of the configuration of the flying object 1. As shown in FIG. 2, the projectile 1 includes a guidance device 2 for detecting and tracking the target 8. The guidance device 2 includes a target detection device 4 for detecting a target 8 by transmitting and receiving radio waves using a radar function, and a target tracking device 5 for generating a guidance signal. The target detection device 4 transmits the radio wave (transmitted wave) 20 in the direction of the target 8 and receives the reflected wave 21 from the target 8. Further, the flying object 1 includes a steering device 3 that executes attitude control of the flying object 1 in accordance with a guidance signal output from the guidance device 2 in order to guide in the direction of the target 8.

Returning to FIG. 1, the unmanned aerial vehicles 10 are various unmanned aerial vehicles including, for example, drones, and each of them can constantly communicate with the radar device 7. The unmanned aerial vehicle 10 can fly to a designated position (coordinate position) transmitted from the radar device 7 based on the position information of GPS or an inertial navigation system, and can stand by by hovering or the like. The unmanned aerial vehicle 10 can recognize the waiting position and the moved position in chronological order.

Further, each of the unmanned aerial vehicles 10 is equipped with a receiver 11 capable of receiving radio waves, and can receive radio waves transmitted from the radar device 7 or the flying object 1. Further, each of the unmanned aerial vehicles 10 can receive the reflected wave 21 from the target 8 by the receiver 11. Each of the unmanned aerial vehicles 10 can generate reception information 22 based on the reflected wave 21 from the target 8 received by the receiver 11 and transmit it to the radar device 7. The reception information 22 includes the reception timing of the reflected wave 21, the reception intensity, the direction of the reflected wave 21, the reception time, and the like.
[Target detection process]
Hereinafter, the operation of the target detection system of the present embodiment will be described with reference to the flowcharts of FIGS. 1 and 3.

In the present embodiment, the projectile 1 is mounted on the launching device 6 and receives the target position information from the radar device 7 before being launched from the launching device 6 (S1). When the radar device 7 detects a target 8 arriving within a predetermined monitoring range, it generates target position information indicating a predicted position of the target 8 and transmits it to the projectile 1 (23 in FIG. 1). When the projectile 1 is launched from the launching device 6 (S2), the projectile 1 transmits a radio wave 20 in the direction in which the target 8 exists (S3) based on the target position information (23) from the radar device 7. Next, the projectile 1 receives the reflected wave 21 from the target 8 (S4).

Here, in the present embodiment, since the target 8 is made of a material having a small radar cross section, the reflected wave 21 with respect to the radio wave 20 transmitted from the projectile 1 is a weak reflected wave in the direction of the projectile 1. (See S4). Therefore, the projectile 1 cannot receive the reflected wave 21 having sufficient intensity from the target 8 by the mounted target detection device 4, and cannot detect the target 8. Even in such a state, the projectile 1 may be able to detect when the distance from the target 8 is close.

On the other hand, each of the unmanned aerial vehicles 10 receives the position information of the GPS or the inertial navigation system by the receiver 11, and stands by by hovering or the like at the designated position transmitted from the radar device 7 (S11). The radar device 7 transmits different position information for each unmanned aerial vehicle 10 to each of the unmanned aerial vehicles 10 based on the target position information (23) indicating the predicted position of the target 8. Therefore, each of the unmanned aerial vehicles 10 has a different designated position to stand by.

Each of the unmanned aerial vehicles 10 can receive radio waves transmitted from the radar device 7 or the flying object 1 by the receiver 11 mounted on the unmanned aerial vehicle 10, and can also receive the reflected wave 21 from the target 8. Here, if a part or all of the unmanned aerial vehicle 10 exists at a position different from the direction in which the projectile 1 exists, the unmanned aerial vehicle 10 can receive the strong reflected wave 21 from the target 8 (S12). When the unmanned aerial vehicle 10 can receive the reflected wave 21, it generates the received information 22 regarding the target 8 and transmits it to the radar device 7 (S13). As described above, the reception information 22 includes the reception timing of the reflected wave 21, the reception intensity, the direction of the reflected wave 21, the reception time, and the like.

Based on the received information 22 received from the unmanned aerial vehicle 10, the radar device 7 generates new target position information updated from the previous target position information regarding the target 8 and transmits it to the projectile 1 (23 in FIG. 1). ). The new target position information is calculated from the position of the unmanned aerial vehicle 10 that transmitted the received information 22, the received direction, the time, and the like, and is information indicating the position and direction of the target 8.

The projectile 1 receives the updated new target position information (23) from the radar device 7 (S5). The projectile 1 is controlled to detect and track the target 8 based on the new target position information (23) received. By repeating the above processing (S3 to S5), the projectile 1 flies to a distance where the strong reflected wave 21 from the target 8 can be received, and detects and tracks the target 8 (S6). Further, the unmanned aerial vehicle 10 repeats the above-described processing (S11 to S13) until, for example, the radar device 7 gives an instruction to end transmission / reception (YES in S14).

As described above, according to the present embodiment, since the target 8 has a small radar cross section, the reflected wave 21 with respect to the radio wave 20 transmitted from the projectile 1 becomes a weak reflected wave in the direction of the projectile 1. Therefore, the projectile 1 cannot receive the reflected wave 21 having sufficient intensity from the target 8 by the mounted target detection device 4, and cannot detect the target 8. In the present embodiment, each of the plurality of unmanned aerial vehicles 10 stands by at a designated position based on the predicted position of the target 8 based on the communication with the radar device 7. The radar device 7 generates different position information for each unmanned aerial vehicle 10 based on the target position information (23) and transmits it to each of the unmanned aerial vehicles 10. Therefore, each of the unmanned aerial vehicles 10 has a different designated position to stand by.

The unmanned aerial vehicle 10 may be able to receive the strong reflected wave 21 from the target 8 if it exists at a position different from the direction in which the projectile 1 exists. When the unmanned aerial vehicle 10 can receive the reflected wave 21, it generates the received information 22 regarding the target 8 and transmits it to the radar device 7. Therefore, the radar device 7 can update the target position information regarding the target 8 and transmit it to the projectile 1 based on the received information 22. As a result, the projectile 1 can fly to a distance where the strong reflected wave 21 from the target 8 can be received, and can detect and track the target 8.

Here, according to the present embodiment, no radar device other than the radar device 7 is required, and the plurality of unmanned aerial vehicles 10 receive the strong reflected wave 21 from the target 8. Therefore, in the target detection system of the present embodiment, even if there are a plurality of targets 8, the reflected waves 21 from each of the targets 8 can be reliably confirmed in cooperation with the plurality of unmanned aerial vehicles 10 whose number and position can be adjusted. Can be received by. That is, in the conventional system, since the plurality of radar devices are set on the ground, it is difficult to adjust the number and position setting, and when there are a plurality of targets, the resources of the radar devices become insufficient and each target is detected. There is a high possibility that it cannot be done.

In the present embodiment, the flying object 1 transmits radio waves to the target 8, but the radar device 7 may transmit radio waves to the target 8. In this case, the unmanned aerial vehicle 10 receives the reflected wave 21 from the target 8 with respect to the radio wave transmitted by the radar device 7.

Further, the unmanned aerial vehicle 10 may be either a type that can float in the air such as a drone or a mobile type that flies. Further, the unmanned aerial vehicle 10 may be a type capable of waiting while hovering at a designated position, or a type set on the ground at a designated position.

Further, as described above, in the case where the launching device 6 and the radar device 7 are included in the control device that controls the flying object 1 and the unmanned aerial vehicle 10, the received information 22 transmitted from the unmanned aerial vehicle 10 is the radar device. It may be received by the communication device included in the control device instead of 7.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

1 ... Flying object, 2 ... Guidance device, 3 ... Steering device, 4 ... Target detection device,
5 ... target follower, 6 ... launcher, 7 ... radar device, 8 ... target,
10 ... unmanned aerial vehicle, 11 ... receiver.

Claims (8)

A projectile that detects and tracks a target,
A radar device that communicates with the projectile,
An unmanned aerial vehicle that receives a reflected wave reflected from the target with respect to a radio wave transmitted from the flying object or the radar device in the direction of the target, and transmits received information about the received reflected wave to the radar device. With the aircraft
Equipped with
The radar device is
Upon receiving the received information transmitted from the unmanned aerial vehicle,
Generate target position information about the target based on the received information,
A target detection system that transmits the target position information to the projectile. The radar device is
The first target position information regarding the target is transmitted to the projectile,
The target detection system according to claim 1, wherein the target position information generated based on the received information is transmitted to the projectile as a second target position information updated from the first target position information. The unmanned aerial vehicle
The target detection system according to claim 1 or 2, which waits at a designated position based on the position information transmitted from the radar device. The radar device is
Based on the first target position information, position information indicating a designated position where the unmanned aerial vehicle should wait is generated.
The target detection system according to claim 2, wherein the generated position information is transmitted to the unmanned aerial vehicle. The projectile is
Before being launched from the launcher, it receives the first target position information transmitted from the radar device and receives the first target position information.
The target detection system according to claim 2, wherein after being launched from the launching device, it flies in a designated direction based on the first target position information. The projectile is
Radio waves are transmitted in the direction of the target,
The reflected wave reflected from the target is received and
The target detection system according to claim 1, wherein the target is detected and tracked based on the target position information transmitted from the radar device. A projectile that detects and tracks a target,
A radar device that communicates with the projectile,
An unmanned person who receives a reflected wave reflected from the target with respect to a radio wave transmitted from the flying object or the radar device in the direction of the target, and transmits received information about the received reflected wave to the radar device. A target detection method applied to a target detection system equipped with an aircraft.
The radar device is
Upon receiving the received information transmitted from the unmanned aerial vehicle,
Generate target position information about the target based on the received information,
A target detection method for transmitting the target position information to the projectile. The projectile is
Radio waves are transmitted in the direction of the target,
The reflected wave reflected from the target is received and
The target detection method according to claim 7, wherein the target is detected and tracked based on the target position information transmitted from the radar device.