JP2021184620A - Flying object and program - Google Patents

Abstract

To more effectively reduce interference with other radio systems.SOLUTION: A flying object includes: an array antenna that communicates with a radio communication device; an acquisition unit that acquires plan information indicating a planned route, which is a route along which the flying object is planned to move; a calculation unit that calculates a complex weight for giving directivity to transmission of a radio signal from the array antenna to the radio communication device; and a transmission control unit that identifies a predicted fluctuation area where attitude fluctuation of the flying object is predicted to occur on the planned route based on the plan information, and stops transmission of the radio signal to the radio communication device when the flying object is located in the predicted fluctuation area.SELECTED DRAWING: Figure 4

Description

The present invention relates to flying objects and programs.

Conventionally, as a technique for reducing interference when sharing a frequency with multiple wireless systems, the base station estimates the direction of arrival of radio waves from radio wave sources located in the vicinity using an array antenna, and mainly uses the desired wave. Adaptive antenna technology is known that directs the beam and directs the null point to other incoming waves to form directivity.

Further, Patent Documents 1 to 5 disclose various communication technologies using directivity. For example, Patent Document 1 discloses an adaptive antenna technique applied to a mobile terminal, which controls antenna directivity according to the orientation or tilt of the mobile terminal. Further, Patent Document 2 is a device equipped with a plurality of wireless devices and antennas. Focusing on one wireless device and antenna, the antenna is rotated while directivity is directed to the communication target of the wireless device. A device that directs a null to the radio antenna of is disclosed. Further, Patent Document 3 discloses a wireless device provided with an acceleration sensor, which changes the direction of a beam according to the movement detected by the sensor. Further, Patent Document 4 discloses a technique for increasing a transmission output when it detects that a wireless device has been shaken. Further, Patent Document 5 discloses a device that communicates with a moving body and that changes a beam width or a direction according to the speed of the moving body.

Japanese Unexamined Patent Publication No. 2004-64741 International Publication No. 2017/018070 Japanese Unexamined Patent Publication No. 2013-236301 Japanese Unexamined Patent Publication No. 2008-199099 Japanese Unexamined Patent Publication No. 2016-144194

However, in the conventional technology, directional transmission from an air vehicle may interfere with communication in other wireless systems. For example, when a sudden attitude change occurs in an air vehicle, a transient error may occur between the estimated value of the attitude angle of the air vehicle and the actual attitude angle of the air vehicle. In the technique described in Patent Document 1, since the transmission directivity is determined without considering the error of the attitude angle, the beam may be directed to the direction of the other wireless system and may interfere with the other wireless system. .. Further, Patent Document 5 discloses a technique for widening the beam width in a target direction as the speed of the moving body is faster. However, even if the speed is slow, if the change in speed is large, the error may be large. It is difficult to sufficiently reduce the effect of error.

Therefore, the present invention has been made in view of the above problems, and an object of the present invention is new and improved so as to be able to more effectively reduce interference with other wireless systems. To provide aircraft and programs.

In order to solve the above problems, according to a certain aspect of the present invention, there is an array antenna that is a flying object and communicates with a wireless communication device, and a planned path that is a path in which the flying object is planned to move. Based on the plan information, the plan path is based on the acquisition unit that acquires the plan information indicating In, a transmission control that specifies a fluctuation prediction region in which attitude fluctuation of the air vehicle is predicted to occur, and stops transmission of the radio signal to the radio communication device when the air vehicle is located in the fluctuation prediction region. An air vehicle is provided with a section and.

The planning information may include waypoint information indicating one or more moving waypoints, and the fluctuation prediction region may include moving waying points indicated by the waypoint information.

The acquisition unit may acquire region information indicating a region in which the attitude of the aircraft is likely to fluctuate, and the fluctuation prediction region may include a region indicated by the region information.

Further, in order to solve the above problems, according to another aspect of the present invention, the computer is a flying object, and the planning information indicating the planned route which is the route on which the flying object is planned to move. An acquisition unit that calculates a complex weight for giving directivity to the transmission of a radio signal from the array antenna to the wireless communication device, and an attitude of the flying object in the planned path based on the planned information. A transmission control unit that identifies a fluctuation prediction region in which fluctuations are expected to occur and stops transmission of the radio signal to the radio communication device when the flying object is located in the fluctuation prediction region. A program is provided to make it function as an air vehicle.

According to the present invention described above, it is possible to more effectively reduce interference with other wireless systems.

It is explanatory drawing which shows the structural example of the wireless system by one Embodiment of this invention. It is explanatory drawing which shows the specific example of the directivity of the radio signal transmitted by the aircraft body 20. It is explanatory drawing which shows the structure of the flying object 20 by one Embodiment of this invention. It is explanatory drawing which shows the structure of the communication control unit 300. It is a flowchart which shows the operation outline of the flying object 20. It is a flowchart which shows the transmission process. It is a flowchart which shows the fluctuation prediction of the posture by the 1st operation example. It is explanatory drawing which shows the change example of the angular spread of a beam and a null. It is explanatory drawing which shows an example of the planned route 50 indicated by the movement plan information. It is a flowchart which shows the fluctuation prediction of the posture by the 2nd operation example. It is a flowchart which shows the fluctuation prediction of the posture by the 3rd operation example.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the present specification and the drawings, components having substantially the same functional configuration are designated by the same reference numerals, and duplicate description will be omitted.

Further, in the present specification and the drawings, a plurality of components having substantially the same functional configuration may be distinguished by adding different alphabets after the same reference numerals. However, when it is not necessary to particularly distinguish each of the plurality of components having substantially the same functional configuration, only the same reference numerals are given to each of the plurality of components.

<1. Overview of wireless system>
One embodiment of the present invention relates to a wireless system, and more particularly to an air vehicle constituting the wireless system. Hereinafter, with reference to FIG. 1, an outline of a wireless system and an air vehicle according to an embodiment of the present invention will be described.

FIG. 1 is an explanatory diagram showing a configuration example of a wireless system according to an embodiment of the present invention. FIG. 1 shows an interference wave source 30A and an interference wave source 30B, which are other radio systems, in addition to the radio base station 10 and the flying object 20 constituting the radio system according to the embodiment of the present invention.

The wireless base station 10 is an example of a wireless communication device installed on the ground. The radio base station 10 wirelessly communicates various data with the aircraft 20 as shown by the solid double-headed arrow in FIG. For example, the radio base station 10 may receive sensor data detected by the flying object 20, image data obtained by imaging with the flying object 20, and the like.

The flying object 20 is a device that flies in the air. The vehicle 20 may be, for example, a multicopter, a manned vehicle, or an unmanned aerial vehicle (UAV). The aircraft 20 flies according to, for example, a control signal received from the radio base station 10 or according to a preset movement plan. Further, the flying object 20 has an array antenna. The aircraft body 20 can wirelessly communicate with the radio base station 10 via the array antenna.

Wireless communication is also performed between the interference source 30A and the interference source 30B, as shown by the solid double-headed arrow in FIG. The radio signals transmitted by the interference wave source 30A and the interference wave source 30B can reach the flying object 20 as interference waves. Similarly, when the flying object 20 transmits a radio signal to the radio base station 10 without any special ingenuity, the radio signal becomes an interference wave to the interference source 30A and the interference source 30B as an interference wave, as shown by the arrow of the broken line in FIG. Can be reached.

Therefore, the flying object 20 imparts directivity to the radio signal transmitted from the array antenna to the radio base station 10 in order to reduce the interference given to other radio systems such as the interference wave source 30A and the interference wave source 30B. A specific example of the directivity will be described with reference to FIG.

FIG. 2 is an explanatory diagram showing a specific example of the directivity of the radio signal transmitted by the flying object 20. As shown in FIG. 2, the beam is directed to the direction of the radio base station 10 in the radio signal transmitted by the flying object 20, and the directions of the interference wave source 30A and the interference wave source 30B (the interference wave source 30A and the interference wave source 30A when viewed from the flying object 20). The directivity toward which null is directed is given to the direction in which the interference wave source 30B is located). Null is a direction in which the gain is greatly reduced. According to such a configuration, the interference given by the flying object 20 to the interference wave source 30A and the interference wave source 30B is reduced while realizing smooth wireless communication with the radio base station 10.

Here, the flying object 20 forms a directivity that directs null to the direction of the interference wave source 30A based on the estimated values of the position of the interference wave source 30A and the attitude angle of the flying object 20. However, if the attitude variation of the flying object 20 is large, an error may occur between the estimated value of the attitude angle of the flying object 20 and the actual attitude angle of the flying object 20. As a result, the null is not actually directed to the direction of the interference source 30A accurately, and there is a possibility that the interference wave reaches the interference source 30A. Similarly, if the attitude fluctuation of the flying object 20 is large, the interference wave may reach the interference wave source 30B.

The inventor of the present invention has come to create an embodiment of the present invention with the above circumstances as a point of view. According to one embodiment of the present invention, it is possible to more effectively reduce interference with other wireless systems such as the interference wave source 30A and the interference wave source 30B. Hereinafter, the configuration and operation of the flying object 20 according to the embodiment of the present invention will be sequentially described in detail.

<2. Aircraft composition>
FIG. 3 is an explanatory diagram showing the configuration of the flying object 20 according to the embodiment of the present invention. As shown in FIG. 3, the flight body 20 according to the embodiment of the present invention includes a flight control device 220, a drive device 230, a battery 240, and a wireless control device 250.

(Flight control device)
The flight control device 220 has a sensor group 222 and a flight control unit 224. The sensor group 222 is a set of various sensors. The sensor group 222 may include, for example, a GPS sensor (GPS: Global Positioning System), a gyro sensor (angular velocity sensor), an acceleration sensor, a pressure sensor, a magnetic sensor, an ultrasonic sensor, or the like.

The flight control unit 224 is a set of a general-purpose processor and a main memory device, and has a function as an information processing device. Further, the flight control unit 224 has an input / output interface function for acquiring sensor data output from the sensor group 222. Further, the flight control unit 224 has a function of acquiring and storing the movement plan information from the outside and controlling the drive device 230 so that the flight body 20 autonomously navigates according to the stored movement plan information. Known techniques may be used for aviation control by the flight control unit 224. Further, the flight control unit 224 wirelessly controls data such as sensor data acquired from the sensor group 222, attitude angle information indicating the attitude angle of the flying object 20 calculated by calculation using the sensor data, or movement plan information. Provided to device 250.

(Drive)
The drive device 230 is a device that generates a driving force for the flight of the flying object 20. The drive device 230 is composed of, for example, a motor for flying the flying object 20, a propeller, and an ESC (ESC: Electric Speed Controller) that controls the rotation speed thereof.

(Battery)
The battery 240 powers the flight control device 220, the drive device 230, and the wireless control device 250. The flight control device 220, the drive device 230, and the wireless control device 250 operate using the electric power supplied from the battery 240. The battery 240 may be, for example, a lithium ion polymer secondary battery or a lithium ion secondary battery.

(Wireless control device)
The wireless control device 250 is configured to perform wireless communication. As shown in FIG. 3, the radio control device 250 includes an array antenna 252, an RF receiving circuit 254, an RF transmitting circuit 258, and a communication control unit 300.

The array antenna 252 has a plurality of (N) element antennas 1n (n = 1, 2, ..., N), and these element antennas are arranged on the antenna surface. The array antenna 252 is connected to the RF receiving circuit 254 and the RF transmitting circuit 258. The array antenna 252 converts the radio signal into an electrical high frequency reception signal and outputs it to the RF reception circuit 254. Further, the array antenna 252 converts the high frequency transmission signal supplied from the transmission processing unit 390 into a radio signal and transmits it.

The RF reception circuit 254 performs high frequency processing such as down conversion and AD conversion of the high frequency reception signal input from the array antenna 252. The RF reception circuit 254 outputs the reception signal obtained by down-conversion and AD conversion to the communication control unit 300.

The RF transmission circuit 258 performs high-frequency processing such as DA conversion and up-conversion of the transmission signal input from the communication control unit 300. The RF transmission circuit 258 outputs the high frequency transmission signal obtained by DA conversion and up-conversion to the RF transmission circuit 258.

The communication control unit 300 is a set of a general-purpose processor and a main memory device, and has a function as an information processing device. The communication control unit 300 may be an FPGA (FPGA: Field Programmable Gate Array) in which a part or the whole is a programmable logic device (PLD). Further, the communication control unit 300 may be a functional block that shares one piece of hardware with the flight control unit 224.

The communication control unit 300 controls processing using the reception signal input from the RF reception circuit 254, processing for generating a transmission signal to be output to the RF transmission circuit 258, and the like. Hereinafter, a detailed configuration of the communication control unit 300 will be described with reference to FIG.

<3. Communication control unit configuration>
FIG. 4 is an explanatory diagram showing the configuration of the communication control unit 300. As shown in FIG. 4, the communication control unit 300 includes an arrival direction estimation unit 310, a reception directivity calculation unit 320, a reception processing unit 330, an arrival wave source position estimation unit 340, a storage unit 350, a transmission direction calculation unit 360, and a variation. It has a prediction unit 370, a transmission directivity calculation unit 380, and a transmission processing unit 390.

(Arrival direction estimation unit)
The arrival direction estimation unit 310 has a function of estimating the arrival direction of the radio signal from the received signal from each element antenna. For example, the arrival direction estimation unit 310 uses a high-resolution algorithm such as the MUSIC (Multiple Signal Classication) method or the ESPrit (Estimation of Signal Parameters via Rotation Technology Technologies) method to estimate the direction of a radio signal. The arrival direction estimated by the arrival direction estimation unit 310 is represented by a local coordinate system with respect to the flying object 20.

(Reception directivity calculation unit)
The reception directivity calculation unit 320 calculates a complex weight for forming a directivity in which the beam is directed toward the radio base station 10 and the null is directed toward the interference wave source 30. The complex weight is a weight that adjusts the phase and amplitude of the received signal from each element antenna. For the directivity operation, for example, the DCMP (Directivity Constrained Minimization of Power) method is used. The reception directivity calculation unit 320 can be used for position information of the radio base station 10 and the interference wave source 30 stored in the storage unit 350, attitude angle information and position information of the flying object 20 supplied from the flight control unit 224, and the like. Based on this, the direction of the radio base station 10 and the direction of the interference wave source 30 may be specified.

(Reception processing unit)
The reception processing unit 330 has a function of synthesizing the complex weight obtained by the reception directivity calculation unit 320 with the reception signal from each element antenna by multiplication, and a function of decoding the combined reception signal according to the communication protocol. The reception processing unit 330 outputs the reception data obtained by decoding to the flight control unit 224.

(Arrival wave source position estimation unit)
The arrival wave source position estimation unit 340 estimates the position of the arrival wave source which is the source of the radio signal received by the flying object 20. Specifically, the arrival wave source position estimation unit 340 converts the arrival direction estimated by the arrival direction estimation unit 310 into an absolute coordinate system based on the center of gravity of the earth, and the radio signal determines the arrival direction after the conversion. It is stored in the storage unit 350 in association with the position information indicating the position of the flying object 20 at the time of reception. Further, the arrival wave source position estimation unit 340 estimates the position of the arrival wave source by, for example, the interaction method, using the arrival direction of the absolute coordinate system obtained based on the radio signals received by the flying object 20 at a plurality of different positions. Then, the estimation result is stored in the storage unit 350. The arrival wave source position estimation unit 340 may estimate the position of the arrival wave source by using the information in the arrival direction acquired from the radio base station 10.

(Memory)
The storage unit 350 stores various information used for the operation of the flying object 20. For example, the storage unit 350 is a position indicating the arrival direction of the absolute coordinate system obtained by the arrival wave source position estimation unit 340 based on the reception of the radio signal, and the position of the flying object 20 at the time when the radio signal is received. Associate and store information. Further, the storage unit 350 stores the arrival wave source position information indicating the position of the arrival wave source estimated by the arrival wave source position estimation unit 340. The incoming wave source may include an interference wave source 30A and an interference wave source 30B in addition to the radio base station 10.

(Transmission direction calculation unit)
The transmission direction calculation unit 360 calculates the direction in which the communication partner is located (transmission direction) and the direction in which the interference wave source is located (target direction). For example, when the transmission request to the radio base station 10 is input from the flight control unit 224, the transmission direction calculation unit 360 acquires the position information of the radio base station 10, the interference wave source 30A, and the interference wave source 30B from the storage unit 350. Based on these position information and the position information and attitude angle of the flying object 20 input from the flight control unit 224, the direction of the radio base station 10, the direction of the interference wave source 30A, and the direction of the interference wave source 30B are calculated. Here, the transmission direction calculation unit 360 may estimate the position and attitude angle of the flying object 20 at the time of transmission of the radio signal, and calculate each direction based on the position and attitude angle. The transmission direction calculation unit 360 can estimate the position and attitude angle of the air vehicle 20 at the time of transmission of the radio signal based on the movement speed data and the angular velocity data of the air vehicle 20.

(Fluctuation prediction unit)
The fluctuation prediction unit 370 functions as an acquisition unit for acquiring attitude change information regarding the attitude change of the flying object 20, and a transmission control unit for controlling directional transmission according to the attitude change information. When the attitude fluctuation of the aircraft 20 is large, the estimation accuracy of the position and attitude angle of the aircraft 20 at the time of transmitting the radio signal becomes low as described above, and as a result, the error of the calculation result in each direction may become large. .. Therefore, the fluctuation prediction unit 370 may calculate an adjustment weight for increasing the angle spread of the beam to the transmission direction and the angle spread of the null to the target direction based on the attitude change information. Alternatively, the fluctuation prediction unit 370 may stop the transmission of the radio signal based on the attitude fluctuation information. There are various control methods for directional transmission by such a fluctuation prediction unit 370, and some control methods will be described in detail later.

(Transmission directivity calculation unit)
The transmission directivity calculation unit 380 is a calculation unit that calculates a complex weight for giving directivity to a radio signal from the array antenna 252 to the radio base station 10. The transmission directivity calculation unit 380 acquires the transmission direction in which the radio base station 10 is located and the target direction in which the interference wave source 30 is located from the transmission direction calculation unit 360, the beam is directed to the transmission direction, and the target direction is null. Compute the complex weights so that the directivity is oriented. Here, when the adjustment weight for adjusting the angular spread of the beam and the null is supplied from the fluctuation prediction unit 370, the transmission directivity calculation unit 380 calculates the complex weight in consideration of the adjustment weight.

(Transmission processing unit)
The transmission processing unit 390 modulates the transmission data according to the communication protocol to create a baseband signal. Then, the transmission processing unit 390 multiplies the complex weight calculated by the transmission directivity calculation unit 380 to the baseband signal, and outputs the transmission signal obtained by the multiplication to the RF transmission circuit 258.

<4. Outline of operation of the aircraft>
The configuration of the flying object 20 according to the embodiment of the present invention has been described above. Subsequently, with reference to FIGS. 5 and 6, the outline of the operation of the flying object 20 is organized.

FIG. 5 is a flowchart showing an outline of the operation of the flying object 20. When the flying object 20 is activated, the radio control device 250 acquires the initial value of the position information of the incoming wave source and stores it in the storage unit 350 (S1). The initial value of the position information may be the position information of the arrival wave source estimated in the past, or may be the position information of the known arrival wave source provided by the radio base station 10.

Then, the flight control unit 224 determines whether or not the initial sequence is being executed (S2). When the initial sequence is being executed (S2 / Yes), the flight control unit 224 controls the drive device 230 so that the position of the flying object 20 is changed in order to acquire the surrounding radio wave environment (S3). At this time, at each position of the flying object 20, the arrival direction estimation unit 310 estimates the arrival direction of the radio signal, and the arrival wave source position estimation unit 340 estimates the position of the arrival wave source. Since three or more positioning points are required to estimate the position from the arrival direction, the flying object 20 repeats the estimation of the arrival direction of the radio signal while changing the altitude or the position stepwise to estimate the position. Get the information you need. After the initial sequence is completed (S2 / No), the flight control unit 224 controls the flight of the flight body 20 according to the movement plan information (S17). The movement plan information may be updated in response to a command from the radio base station 10.

When there is a data transmission request from the flight control unit 224 (S4 / Yes), the communication control unit 300 executes a transmission process described later (S5).

Further, the communication control unit 300 receives the input of the received signal from the RF receiving circuit 254 (S6), and determines whether or not the radio signal is received (S7). If no wireless signal is received, the process from S2 is repeated (S7 / No). When the radio signal is received, the processes S8 to S12 and the processes S13 to S16 are performed in parallel, and then the processes from S2 are repeated (S7 / Yes).

Regarding the processing of S8 to S12, specifically, the arrival direction estimation unit 310 estimates the arrival direction of the radio signal from the received signal from each element antenna (S8). Since the arrival direction estimated here is the direction in the relative coordinate system with respect to the flying object 20, the arrival wave source position estimation unit 340 converts the arrival direction into an absolute coordinate system with reference to the center of gravity of the earth ( S9). Then, the arrival wave source position estimation unit 340 estimates the position of the arrival wave source by, for example, an association method or the like, using the arrival direction of the absolute coordinate system obtained based on the radio signals received by the flying object 20 at a plurality of different positions. (S11). Further, the arrival wave source position estimation unit 340 updates the position information of the arrival wave source stored in the storage unit 350 with the position information of the arrival wave source estimated in S11 (S12).

Regarding the processing of S13 to S16, specifically, when the received radio signal is a radio signal transmitted from the radio base station 10 (S13 / Yes), the reception directivity calculation unit 320 sets the radio base station 10 to the process. The complex weight for forming the directivity in which the beam is directed with respect to the interference wave source 30 and the null is directed with respect to the interference wave source 30 is calculated (S14). Then, the reception processing unit 330 synthesizes the complex weight obtained by the reception directivity calculation unit 320 with the reception signal from each element antenna by multiplication, and decodes the combined reception signal according to the communication protocol (S15). The received data obtained by decoding is output to the flight control unit 224 (S16).

Subsequently, the transmission process shown in S5 will be described with reference to FIG.

FIG. 6 is a flowchart showing the transmission process. In the transmission process, first, the fluctuation prediction unit 370 predicts the posture fluctuation (S17). When the transmission of the radio signal is stopped (S18 / No) in the process of predicting the fluctuation, the process of S17 is looped until the radio signal can be transmitted. When it is determined that the radio signal can be transmitted (S18 / Yes), the transmission direction calculation unit 360 acquires the position information of each incoming wave source from the storage unit 350 (S19), and the flying object 20 to each incoming wave source. The direction of is calculated (S20). Since the direction calculated here is the direction in the absolute coordinate system, the transmission direction calculation unit 360 also converts the direction into the direction in the relative coordinate system with respect to the flying object 20.

Then, the transmission directivity calculation unit 380 calculates the complex weight so that the directivity is formed so that the beam is directed to the radio base station 10 and the null is directed to the interference wave source 30 based on the direction of each incoming wave source (S21). .. Subsequently, the transmission processing unit 390 modulates the transmission data according to the communication protocol to create a baseband signal. Then, the transmission processing unit 390 multiplies the complex weight calculated by the transmission directivity calculation unit 380 to the baseband signal, and outputs the transmission signal obtained by the multiplication to the RF transmission circuit 258 (S22).

<5. Posture fluctuation prediction>
The operation outline of the flying object 20 has been described above. Subsequently, some operation examples related to posture fluctuation prediction will be sequentially described in detail.

(First operation example)
At the start and end of the movement of the flying object 20, the attitude change of the flying object 20 becomes large. In the first operation example, when the attitude fluctuation of the flying object 20 is large, the interference from the flying object 20 is caused by increasing the angular spread of the null to the interference wave source 30 or by stopping the transmission of the radio signal. The arrival of the interference wave to the wave source 30 is suppressed.

Here, the fluctuation prediction unit 370 has a function as an acquisition unit that acquires angular acceleration data by differential calculation of the angular velocity data of the flying object 20, and changes the attitude of the flying object 20 based on the angular acceleration indicated by the angular acceleration data. Judge the size. If the angular velocity is constant even if the angular velocity is large, it is unlikely that an error will occur between the estimated value of the attitude angle of the flying object 20 and the actual attitude angle of the flying object 20, but if the angular velocity is indefinite, that is, the angular acceleration. This is because it is considered that the above error is likely to occur when there is. Hereinafter, such a first operation example will be specifically described with reference to FIG. 7.

FIG. 7 is a flowchart showing posture fluctuation prediction according to the first operation example. As shown in FIG. 7, first, the fluctuation prediction unit 370 acquires the angular velocity data of the flying object 20 from the flight control unit 224 (S101), and acquires the angular acceleration data by the differential calculation of the angular velocity data (S102). Then, the fluctuation prediction unit 370 compares the angular acceleration indicated by the angular acceleration data with the first threshold value (threshold value 1) (S103). When the angular acceleration is equal to or less than the first threshold value, the fluctuation prediction unit 370 does not perform any particular control (S103 / No).

On the other hand, when the angular acceleration exceeds the first threshold value (S103 / Yes), the fluctuation prediction unit 370 compares the angular acceleration with the second threshold value (threshold value 2) (S104). Here, the second threshold value is larger than the first threshold value. When the angular acceleration exceeds the second threshold value (S104 / Yes), the risk of interference is considered to be high, so the fluctuation prediction unit 370 stops the transmission of the radio signal as the transmission control unit (S105). On the other hand, when the angular acceleration exceeds the first threshold value but is equal to or less than the second threshold value (S104 / No), the fluctuation prediction unit 370 spreads the angle of the beam to the radio base station 10 and nulls the interference wave source 30. The adjustment weight for increasing the angular spread of is calculated (S106).

FIG. 8 is an explanatory diagram showing an example of changes in the angular spread of the beam and the null. In FIG. 8, the alternate long and short dash line shows the angular spread of the beam and null in normal times, and the solid line shows the angular spread of the beam and null when the adjustment weight is applied.

As shown in FIG. 8, when the adjustment weight is applied, the angular spread of the null to the interference source 30 becomes large. Therefore, even if there is an error in the estimated value of the attitude angle of the flying object 20, it is possible to suppress the interference wave from reaching the interference wave source 30 by actually continuing to direct the null to the interference wave source 30. .. Further, when the adjustment weight is applied, the angle spread of the beam to the radio base station 10 also becomes large, so that the radio signal can be more reliably reached to the radio base station 10.

Further, in the first operation example, when the angular acceleration exceeds the second threshold value, the transmission of the radio signal is stopped, thereby suppressing the deterioration of the communication quality in other wireless systems such as the interference wave source 30. It is possible.

(Second operation example)
As described above, the aircraft body 20 moves according to the planned route indicated by the movement plan information. In the second operation example, the fluctuation prediction unit 370 includes an acquisition unit that acquires movement plan information from the flight control unit 224, and a fluctuation prediction region in which the attitude variation of the flight body 20 is predicted to be large from the movement path. It has a function as a transmission control unit that specifies and stops transmission of a radio signal when the flight object 20 is located in the fluctuation prediction region.

FIG. 9 is an explanatory diagram showing an example of the planned route 50 indicated by the movement plan information. As shown in FIG. 9, the planned route 50 includes waypoints 51 to 55, which are waypoints for movement. The movement plan information includes information such as position coordinates, numbers, and operations of the flying object 20 as waypoint information for each of the waypoints 51 to 55. When the aircraft 20 moves between each waypoint, it executes the operation indicated by the movement plan information. For this reason, control such as acceleration / deceleration or turning may occur in the vicinity of each waypoint, so that errors due to attitude fluctuations and attitude fluctuations are likely to occur. The fluctuation prediction unit 370 specifies the vicinity of such a waypoint as the fluctuation prediction region.

Further, the area shown by the broken line in FIG. 9 is the designated area 60, which is an area where the airflow is likely to be turbulent due to the influence of the terrain and buildings, or an area where statistical fluctuations are likely to occur from the past flight data. The fluctuation prediction unit 370 acquires the area information indicating the designated area 60, and also specifies the designated area 60 as the fluctuation prediction area. Hereinafter, such a second operation example will be specifically described with reference to FIG.

FIG. 10 is a flowchart showing posture fluctuation prediction according to the second operation example. As shown in FIG. 10, the fluctuation prediction unit 370 first acquires movement plan information from the flight control unit 224 (S201), and acquires area information indicating the designated area 60 (S202). The area information may be provided by the radio base station 10.

After that, the fluctuation prediction unit 370 acquires the position information of the flight object 20 from the flight control unit 224, and compares the current position of the flight object 20 indicated by the position information with the waypoint (S204). When the current position of the aircraft 20 is near the waypoint, for example, when the current position of the aircraft 20 is within a predetermined distance from the waypoint (S204 / Yes), the fluctuation prediction unit 370 transmits a radio signal. Is stopped (S206).

On the other hand, when the current position of the flying object 20 is far from the waypoint (S204 / No), the fluctuation prediction unit 370 compares the current position of the flying object 20 with the designated area 60 (S205). When the current position of the aircraft 20 is within the designated area 60 (S205 / Yes), the fluctuation prediction unit 370 stops the transmission of the radio signal (S206). When the current position of the flying object 20 is outside the designated area 60, the radio signal can be transmitted, so that the process of predicting the fluctuation is terminated.

As described above, according to the second operation example, the flying object 20 stops the transmission of the radio signal in the region where the error due to the attitude change may occur, so that the interference wave source 30 or the like is used. It is possible to suppress deterioration of communication quality in a wireless system.

(Third operation example)
In the third operation example, the fluctuation prediction unit 370 acquires a control value for controlling the drive device 230 from the flight control unit 224. The control value may be, for example, a control value related to a movement of the flying object 20 accompanied by a change in attitude, such as a movement speed and a change speed (angular velocity) of the attitude angle. The fluctuation prediction unit 370 predicts the attitude fluctuation of the flying object 20 from the control value, and controls the directional transmission. Hereinafter, such a third operation example will be specifically described with reference to FIG.

FIG. 11 is a flowchart showing posture fluctuation prediction according to the third operation example. As shown in FIG. 11, the fluctuation prediction unit 370 first acquires a control value for controlling the drive device 230 from the flight control unit 224 (S301). Then, the fluctuation prediction unit 370 performs a differential operation of the control value (S302).

Then, the fluctuation prediction unit 370 compares the result of the differential calculation of the control value with the first threshold value (threshold value 1) (S303). When the result of the differential operation is equal to or less than the first threshold value, the fluctuation prediction unit 370 does not perform any particular control (S303 / No).

On the other hand, when the result of the differential operation exceeds the first threshold value (S303 / Yes), the fluctuation prediction unit 370 compares the result of the differential operation with the second threshold value (threshold value 2) (S304). Here, the second threshold value is larger than the first threshold value. When the result of the differential calculation exceeds the second threshold value (S304 / Yes), the risk of interference is considered to be large, so the fluctuation prediction unit 370 stops the transmission of the radio signal as the transmission control unit (S305). On the other hand, when the result of the differential calculation exceeds the first threshold value but is equal to or less than the second threshold value (S304 / No), the fluctuation prediction unit 370 spreads the angle of the beam to the radio base station 10 and to the interference wave source 30. The adjustment weight for increasing the angular spread of the null is calculated (S306).

In this way, the fluctuation prediction unit 370 predicts the attitude fluctuation of the flying object 20 in advance from the result of the differential calculation of the control value, and controls the directional transmission of the radio signal. For example, when the result of the differential calculation of the control value exceeds the first threshold value, the fluctuation prediction unit 370 increases the angular spread of the null to the interference wave source 30, so that the interference wave reaches the interference wave source 30. It is possible to prevent it from being stored. Further, the fluctuation prediction unit 370 stops the transmission of the radio signal when the result of the differential calculation of the control value exceeds the second threshold value, thereby reducing the communication quality in other wireless systems such as the interference wave source 30. It can be suppressed.

In addition, all of the above-mentioned first operation example to the third operation example control the directivity transmission from the air vehicle 20 based on the information regarding the attitude change of the air vehicle 20, which is common to the prior art. It has the technical features of.

<6. Supplement>
Although the preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, the present invention is not limited to these examples. It is clear that a person having ordinary knowledge in the field of technology to which the present invention belongs can come up with various modifications or modifications within the scope of the technical ideas described in the claims. , These are also naturally understood to belong to the technical scope of the present invention.

For example, the embodiment of the present invention may be realized by a combination of two or more operation examples of the first operation example to the third operation example described above. In the combination of the first operation example and the second operation example, the fluctuation prediction unit 370 uses the fluctuation prediction unit 370 when the angular acceleration exceeds the second threshold value and when the current position of the flying object 20 is near the waypoint or in the designated area. In any case, the transmission of the radio signal is stopped.

Further, it is possible to create a computer program for causing the hardware such as the CPU, ROM, and RAM built in the flying object 20 to exhibit the same functions as the above-mentioned configurations of the flying object 20. A storage medium for storing the computer program is also provided.

10 Radio base station 20 Aircraft 220 Flight control device 222 Sensor group 224 Flight control unit 230 Drive device 240 Battery 250 Wireless control device 252 Array antenna 254 RF reception circuit 258 RF transmission circuit
300 Communication control unit 310 Arrival direction estimation unit 320 Reception directivity calculation unit 330 Reception processing unit 340 Arrival wave source position estimation unit 350 Storage unit 360 Transmission direction calculation unit 370 Fluctuation prediction unit 380 Transmission directivity calculation unit 390 Transmission processing unit 30 Interference wave source

Claims (4)

It ’s an air vehicle,
An array antenna that communicates with a wireless communication device,
An acquisition unit that acquires planning information indicating a planned route, which is a route on which the flying object is planned to move, and an acquisition unit.
An arithmetic unit that calculates a complex weight for giving directivity to the transmission of a wireless signal from the array antenna to the wireless communication device, and
Based on the plan information, a fluctuation prediction region in which the attitude change of the flying object is predicted to occur in the planned route is specified, and when the flying object is located in the fluctuation prediction region, the said to the wireless communication device. A transmission control unit that stops the transmission of wireless signals,
A flying object. The planning information includes waypoint information indicating one or more moving waypoints.
The flying object according to claim 1, wherein the fluctuation prediction region includes a moving waypoint indicated by the waypoint information. The acquisition unit acquires area information indicating a region in which the attitude of the aircraft is likely to change, and obtains region information.
The flying object according to claim 1 or 2, wherein the fluctuation prediction region includes a region indicated by the region information. Computer,
It ’s an air vehicle,
An acquisition unit that acquires planning information indicating a planned route, which is a route on which the flying object is planned to move, and an acquisition unit.
An arithmetic unit that calculates complex weights to give directivity to the transmission of wireless signals from the array antenna to the wireless communication device,
Based on the plan information, a fluctuation prediction region in which the attitude change of the flying object is predicted to occur in the planned route is specified, and when the flying object is located in the fluctuation prediction region, the said to the wireless communication device. A transmission control unit that stops the transmission of wireless signals,
A program to function as an air vehicle.

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