JP2000085694A - Landing support sensor device, and landing support system of vertical launching/landing plane using this - Google Patents

Abstract

PROBLEM TO BE SOLVED: To certainly land a plane at a predetermined position in a simple structure by synchronize an attitude angle of a landed object based on an attitude control signal with an attitude angle of a vertical launching/landing plane, and controlling the position of the vertical launching/landing plane so that a photographing image of the landed object at a given area matches with a standard pattern. SOLUTION: A synchronization control circuit 220 outputs difference between attitude data, as standard data, detected by an attitude angle sensor 11 of a ship received by a data receiving device 20 and attitude angle data of a helicopter 2 detected by an attitude angle sensor 23. A pattern matching circuit 221 compares a photographed image of a heliport 10 of a ship 1 picked up by a visible camera 21 with a standard pattern read from a standard pattern holding circuit 222, and outputs a signal corresponding to size of overlap of the images. A thrust/direction control device 223 inputs output from the synchronization control circuit 220 and the pattern matching circuit 221, determines thrust and direction so that difference and image size respectively approach zero and size of the standard pattern, and controls them.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a landing support sensor device for supporting a vertical take-off and landing aircraft such as a helicopter to land on a shaking target area such as a helipad on a ship, and a landing support sensor device.
It relates to a landing support system using this.

[0002]

2. Description of the Related Art A vertical take-off and landing aircraft such as a helicopter (hereinafter, simply referred to as a helicopter) is safely and securely landed on a helipad on a ship, a crude oil drilling rig swaying under strong wind, or a heliport on a high-rise building. Requires advanced maneuvering skills.

[0003] Accordingly, landing support systems have been developed to assist maneuvers when landing a helicopter in a narrow area such as a heliport.

FIG. 5 is a view for explaining a conventional landing support system for landing (landing) a helicopter 2 on a heliport 10 of a ship 1. In FIG. 5, the attitude angle (pitch angle, roll angle, and yaw angle) of the ship 1 constantly changes according to the state of the sea. Thus, the surface of the heliport 10 is constantly changing.

Accordingly, it is necessary for the helicopter 2 to perform control in synchronization with the attitude of the boat 1 when landing. For such control, the helicopter 2 is equipped with a posture angle sensor 20 for obtaining the posture angle thereof, and a laser beam transmitting / receiving device 21.

In the example shown in FIG. 5, the operator first guides the helicopter 2 to the sky above the helipad 10 of the ship 1. Then, the distance between the ship 1 and the helicopter 2 is measured from the reflected light of the laser light transmitted toward the heliport 10 of the ship 1 by the laser light transmitting / receiving device 21 above the heliport 10. At the same time, the aircraft controls the attitude of the helicopter 2 so that the attitude angle sensor 20 of the helicopter 2 becomes a predetermined value in accordance with the attitude of the ship to be visually observed, and then lands. In the landing method described with reference to FIG. 5, the ship 1 is greatly swayed in bad weather, and it is very difficult to land at a fixed position such as the heliport 10 on the ship 1.

To solve the problem in the method shown in FIG. 5, the present applicant has filed an earlier patent application (Japanese Patent Application No. 5-033).
No. 152) proposes a landing support sensor device. The technology disclosed in this patent application detects the relative information (relative distance and relative speed) between a specific location on a ship and a specific location on a helicopter (machine), and displays the result in the cockpit of the helicopter. Or output to an autopilot.

In the above calculation, a vector between a specific position on the ship side, for example, a restraint device (bear trap), and a specific position on the helicopter side, for example, a restraint device (main lobe), and a time change rate thereof are obtained. Things.

Therefore, in order to obtain such a vector and its time rate of change, the ship's sway sensor,
It has a laser sensor including a gimbal mechanism and a data transmission device. On the other hand, on the helicopter side,
Corner cube reflector, data receiving device,
An arithmetic processing unit is provided.

[0010]

In view of the above, the conventional method described above with reference to FIG. 5 has a problem that it is not easy to land at a fixed position due to the motion of the ship. In the landing support sensor device according to the earlier application,
There is a problem that the required configuration is complicated and therefore the cost is increased.

Accordingly, an object of the present invention is to provide a landing support sensor device which enables a helicopter to land at a fixed position with a simple configuration and a landing support system for a vertical take-off and landing aircraft using the same. Is to do.

[0012]

A landing support sensor device according to the present invention for solving the above-mentioned problems of the present invention is mounted on a vertical take-off and landing aircraft and receives a posture angle information of a landing object;
A posture angle sensor for detecting the posture angle of the vertical take-off and landing aircraft, a posture angle information received by the receiving device, a circuit for outputting a posture control signal for synchronizing the posture angle detected by the posture angle sensor, and the landing Imaging means for imaging a predetermined area of the target; a circuit for holding a reference pattern corresponding to the predetermined area of the landing target; comparing the captured image from the imaging means with the image of the reference pattern to control the position of the vertical take-off and landing aircraft A circuit for outputting a signal; and a control device for controlling the thrust and direction of the vertical take-off and landing aircraft based on the attitude control signal and the position control signal.

With this configuration, the landing support sensor device according to the present invention synchronizes the attitude angle of the landing target with the attitude angle of the vertical take-off and landing aircraft based on the attitude control signal from the circuit that outputs the attitude control signal. At the same time, the position of the vertical take-off and landing aircraft is controlled such that the captured image of the predetermined area of the landing target matches the reference pattern.

Further, when a landing support system is configured using the above-mentioned landing support sensor device, the landing target includes:
It has a posture angle sensor for detecting the posture angle, and a transmission device for transmitting posture angle information obtained by the posture angle sensor.

As described above, in the technique of the prior application, the control is performed by the relative distance by the radar and, therefore, by the point. On the other hand, in the present invention, a change such as distortion of an image is controlled by a surface. Therefore, considering the ship's upset,
It is possible to control the helicopter to land more safely.

Further objects and features of the present invention will become apparent from the following description of embodiments with reference to the drawings.

[0017]

Embodiments of the present invention will be described below with reference to the drawings. In the drawings, the same or similar components will be described with the same reference numerals and reference symbols.

FIG. 1 is a diagram for explaining an outline of an embodiment of a landing support system of a vertical take-off and landing aircraft such as a helicopter to which the present invention is applied.

FIG. 1 shows an example in which the helicopter 2 lands on the helipad 10 on the deck of the boat 1 as described with reference to FIG. When the landing support system of the present invention is applied, a posture angle sensor 11 for detecting the posture angle of the ship, and posture angle information of the ship 1 detected by the posture angle sensor 11, that is, a posture angle (Pitch angle, roll angle, and nose magnetic direction).

On the other hand, on the side of the helicopter 2 to which the landing support system of the present invention is applied, data reception for receiving attitude angle (pitch angle, roll angle, and heading magnetic direction) data transmitted from the data transmission device 12 is performed. Device 20, a visible camera 21 for imaging the heliport 10 on the deck of the ship 1, and
It has a posture angle sensor 23 that detects the posture angle of the helicopter 2 and is similar to the posture angle sensor 11 on the ship 1 side.

Further, the output of the attitude angle sensor 23 and the output signal of the data receiving device 20 are processed by the helicopter 2,
Further, it has a control device 22 for processing the output of the visible camera 21.

The output of the control device 22 controls the rotation and angle of the main rotors 24 and 25, and the helicopter 2 is landed on the helipad 10 on the deck of the boat 1.

FIG. 2 is a block diagram of an embodiment of the landing support system of the present invention corresponding to the embodiment of FIG. 1, and particularly shows a detailed configuration example of the control device 22 in FIG. In the control device 22 shown in FIG.
0 inputs the output of the attitude angle sensor 23 and the output of the receiving device 20, and outputs a control signal to the propulsion / direction control device 223 so that they are synchronized.

That is, the synchronization control circuit 220
Is a circuit that synchronizes the attitude angle of the helicopter 2 with the attitude angle of the helicopter 2 so that the attitude of the ship 1 and the attitude of the helicopter 2 become parallel. This is a circuit for controlling the pitch angle and the roll angle of the helicopter 2 to coincide with at least the pitch angle and the roll angle of the attitude angle of the boat 1. More specifically, it is a circuit that outputs the difference between the current pitch angle and roll angle of the helicopter 2 to the propulsion / direction control device 223 based on each of the pitch angle and roll angle of the boat 1. As will be described later, the propulsion / direction control device 223
Controls the main rotor 24 and the tail rotor 25 in accordance with the difference inputted to the synchronization control circuit 220.

If the difference between the pitch angle and the roll angle of the ship 1 and the helicopter 2 becomes zero, the helicopter 2
Are parallel.

Further, in the control device 22 of FIG. 2, the pattern matching circuit 221 compares the captured image of the heliport 10 of the ship 1 captured by the visible camera 21 with the image of the reference pattern read from the reference pattern holding circuit 222. Circuit.

The reference pattern is a pattern similar to the heliport 10. That is, when the pattern of the heliport 10 has a circular shape as illustrated, the pattern held by the reference pattern holding circuit 222 is also a circular pattern.

Here, the size of the image of the circular pattern read from the reference pattern holding circuit 222 is constant. On the other hand, when the imaging magnification of the visible camera 21 is constant, the heliport 1 imaged by the visible camera 21 is
The size of the captured image of 0 varies depending on the altitude of the helicopter 2.

Therefore, the pattern matching circuit 22
The output gain of the visible camera 21 is adjusted in conjunction with the altitude of the helicopter 2 in order to keep the size of the captured image of the heliport 10 to be compared with the reference pattern at 1. Alternatively, by controlling the imaging magnification (zoom rate) of the visible camera 21 in conjunction with the altitude of the helicopter 2, the size of the image captured by the heliport 10 can be made constant.

FIG. 3 shows the relationship between the captured image 100 of the heliport 10 captured at a fixed size and the image 200 of the reference pattern read from the reference pattern holding circuit 222 on a monitor (not shown). FIG.

An image 100 captured by the heliport 10 is captured by a visible camera 21 mounted at a predetermined position on the helicopter 2 at a predetermined angle. Therefore, when displaying the image 200 of the reference pattern corresponding to the sky position of the heliport 10 on the monitor and displaying the captured image 100 of the heliport 10 corresponding to the position of the visible camera 2, that is, the position of the helicopter 2, The positional relationship of FIG.
(A).

Therefore, the relative distance between the image 200 of the reference pattern and the photographed image 100 corresponds to the distance between the sky position of the helipad 10 and the helicopter 2.

Further, in the example shown in FIG. 3A, the image 200 of the reference pattern and the photographed image 100 of the heliport 10 are shown.
Are partially overlapped. Therefore, control is performed so as to move the photographed image 100 of the heliport 10 in FIG. 3A so as to increase the overlap of the images.

At this time, since the image 200 of the reference pattern and the photographed image 100 of the heliport 10 are both circular, the direction in which the overlapping of the images increases is unique. Therefore, in FIG. 3A, the moving direction is a direction indicated by an arrow.

That is, a signal corresponding to the size of the image overlap is input from the pattern matching circuit 221 to the thrust / direction control device 223. As a result, the thrust / direction control device 223 performs control to propel the helicopter 2 so as to approach the position above the heliport 10.

Therefore, as shown in FIG. 3B, the image 200 of the reference pattern and the image 10
The overlap of 0 becomes large, and in this state, it can be recognized that the helicopter 2 is located above the heliport 10.

Here, the thrust / direction control device 223 includes:
As described above, the difference signal of the posture angle is input from the synchronization control circuit 220, and the signal of the magnitude of the image overlap is input from the pattern matching circuit 221. Therefore, the thrust / direction control device 223 obtains the thrust and the direction such that the difference signal of the attitude angle becomes zero and the size of the overlapping image approaches the size of the reference pattern.

Then, the main rotor 24 and the tail rotor 25 are controlled so that the thrust and the direction are obtained by the thrust / direction control device 223. As described above, the function of the thrust / direction control device 223 that controls the helicopter 2 based on the attitude angle to be controlled and the propulsion direction required by the present invention can be easily realized by the function of the existing automatic pilot device. .

On the other hand, in the description of FIG.
Is based on the assumption that the optical axis of the visible camera 21 is perpendicular to the plane of the heliport 10. That is, the helicopter 2 and the helicopter 1
The planes of 0 are parallel.

Therefore, the helicopter 2 may be lowered as it is when the positioning is completed according to FIG. However, when the ship 1 shakes, the plane of the helicopter 2 and the surface of the helipad 10 that lands are not parallel. Therefore,
In this case, it is necessary to control the attitude of the helicopter 2 in accordance with the angle of the heliport 10.

FIG. 4 is a diagram for explaining attitude control in such a case.

FIG. 4A shows a state where the planes of the helicopter 2 and the heliport 10 are parallel to each other. In this case, the image of the heliport 10 captured by the visible camera 21 is circular. Therefore, the ratio B / A of the diameters A and B on the two axes of the image of the heliport 10 is 1.

On the other hand, FIG. 4B shows a state in which the ship 1 shakes and the planes of the helicopter 2 and the heliport 10 are not parallel. In this case, the image of the heliport 10 captured by the visible camera 21 is distorted as illustrated.

Accordingly, the ratio B / A of the diameters A and B on the two axes of the image of the heliport 10 is 1 or less. Based on such a relationship, the attitude control of the helicopter 2 is performed as follows.

That is, the pattern matching circuit 221
Calculates the ratio B / A of the diameters A and B on the two axes of the image of the heliport 10 captured above. Further, the attitude angle sensor 2
3, the attitude angle data of the helicopter 2 is input. Therefore, the pattern matching circuit 221 calculates a correction value of the attitude angle of the helicopter 2 in a direction in which the ratio B / A of the diameters A and B becomes “1”.

The correction value of the calculated attitude angle is sent to the thrust / direction control device 223, and the attitude angle of the helicopter 2 is corrected and controlled. Thereby, the attitude of the helicopter 2 and the surface of the heliport 10 are made parallel.

As described above, according to the present invention, the position of the helicopter 2 and the heliport 10 can be adjusted and the helicopter 2 and the heliport 10 can be automatically controlled on the basis of the image of the heliport 10 to be laid. It is.

Further, in the embodiment of FIG.
The heat generating source 13 is arranged corresponding to the shape of 0.
This makes it easy to land the helicopter 2 on the heliport 10 at night.

That is, by using the infrared camera as the visible camera 21, the pattern of the heat source 13 can be obtained as a photographed image of the helipad 10 at night. Thus, the captured pattern of the heat source 13, that is, the captured image of the heliport 10 and the reference pattern 20
0 can be displayed as described with reference to FIGS. Other processing is as described with reference to FIGS.

[0050]

According to the present invention, a vertical take-off and landing aircraft such as a helicopter supports landing when landing on a predetermined area to be landed, such as a ship, as described above with reference to the drawings. A landing support sensor device mounted on a take-off and landing aircraft and a landing support system using the same are provided.

The landing support sensor device according to the present invention outputs a posture control signal for synchronizing the posture angle information of the landing object sent from the landing object with the posture angle detected by the posture angle sensor of the vertical take-off and landing aircraft. And a reference image corresponding to the predetermined area of the landing target is compared with a captured image of the predetermined area of the landing target, and a position control signal of the vertical take-off and landing aircraft is output. Further, a control device for controlling the thrust and direction of the vertical take-off and landing aircraft based on the attitude control signal and the position control signal is provided.

Therefore, generation of control signals for attitude control and position control of the vertical take-off and landing aircraft is performed independently, and control signals for position control are performed based on image data. In response to the features of such a landing support sensor device,
The landing target need only be equipped with a sensor for obtaining the attitude angle and a transmission device for transmitting the obtained attitude angle information.

Thus, according to the present invention, it is possible to provide a landing support system that performs reliable landing support with a simple configuration.

The embodiment described above,
The drawings are for understanding the present invention, and the scope of protection of the present invention is not limited thereto. Furthermore, the scope equivalent to the description in the claims is also included in the protection scope of the present invention.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating an outline of an embodiment of a landing support system of a vertical take-off and landing aircraft such as a helicopter to which the present invention is applied.

FIG. 2 is a block diagram of a landing support system according to an embodiment of the present invention, corresponding to the embodiment of FIG. 1;

FIG. 3 is a diagram illustrating a relationship between a captured image 100 of the heliport 10 and an image 200 of a reference pattern read from a reference pattern holding circuit 222 when the image is displayed.

FIG. 4 is a diagram illustrating attitude angle control when the attitude of the helicopter 2 and the surface of the heliport 10 are not parallel.

FIG. 5 is a diagram illustrating a conventional landing support system for landing a helicopter 2 on a heliport 10 of a ship 1.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Ship 10 Heliport 11 Ship attitude angle sensor 12 Data transmission device 13 Heat generation source 2 Helicopter 20 Data reception device 21 Visible camera 22 Control device 23 Helicopter attitude angle sensor 24 Main rotor 25 Tail rotor 220 Synchronous control circuit 221 Pattern matching circuit 222 Reference pattern holding circuit 223 Thrust / direction control device

Claims (2)

[Claims] A landing support sensor device mounted on a vertical take-off and landing aircraft for performing landing assistance when the vertical take-off and landing aircraft lands on a predetermined area to be landed. A receiving device for receiving, a posture angle sensor for detecting a posture angle of the vertical take-off and landing aircraft, and a posture control signal for synchronizing the posture angle information received by the receiving device with a posture angle detected by the posture angle sensor. A circuit for outputting, an imaging unit for imaging the predetermined area of the landing target, a circuit for holding a reference pattern corresponding to the predetermined area of the landing target, and a photographed image from the imaging unit and an image of the reference pattern. A circuit for comparing and outputting a position control signal of the vertical take-off and landing aircraft; and a control device for controlling the thrust and direction of the vertical take-off and landing aircraft based on the attitude control signal and the position control signal. Landing support sensor device. 2. A landing support system for performing a landing support when a vertical take-off and landing aircraft lands on a predetermined area to be landed, comprising: a posture angle sensor for detecting the posture angle of the landing object; A transmitting device for transmitting attitude angle information obtained by the attitude angle sensor, a receiving device for receiving the attitude angle information transmitted from the landing target transmitting device to the vertical take-off and landing aircraft, and the vertical take-off and landing aircraft A posture angle sensor for detecting the posture angle of the vehicle, a circuit for outputting a posture control signal for synchronizing the posture angle information received by the receiving device with the posture angle detected by the posture angle sensor, Image pickup means for picking up an area, a circuit for holding a reference pattern corresponding to a predetermined area of the landing object, and comparing the captured image from the image pickup means with the image of the reference pattern to control the position of the vertical take-off and landing aircraft Signal A circuit for, attitude control signal and, based on the position control signal,
A control device for controlling the thrust and direction of the vertical take-off and landing aircraft.