JPH0465351B2 - - Google Patents

Description

[Detailed Description of the Invention] (Field of Industrial Application) This invention relates to a two-dimensional active phased array radar that performs monopulse angle measurement in both azimuth (AZ) and elevation (EL) to detect targets. It is.

(Prior art) Figure 1 is a system diagram showing a basic two-dimensional active phased array radar. An element antenna, 2 is connected to the element antenna 1 and is a large number of transmitting/receiving modules for transmitting and receiving radio waves, 3 is a vertical distributor connected to the transmitting/receiving module 2 and collects or distributes radio waves in the vertical direction, 4 is a vertical distributor 3 5 is a hybrid connected to the horizontal distributor 4 and performs monopulse reception; 6 is a circulator that switches between the transmitting/receiving wave TX and the receiving wave Σ; 7 is the transmitting/receiving module 2
This is a transmitting/receiving module controller that controls the

FIG. 4 is a system diagram showing the individual transmitting and receiving modules 2 of a conventional two-dimensional active phased array radar. In the figure, 8 is a transmitting module, 9 is a receiving module, 10 is a phase shifter, 11 is transmitting module 8 and receiving module 9
A TX/RX changeover switch 18 is a circulator that connects the element antenna 1 to the transmitting module 8 and receiving module 9.

Next, the operation of the conventional two-dimensional active phased array radar shown in FIGS. 1 and 4 will be explained. The transmitted wave TX passes through the circulator 6 and is input to the hybrid 5, where it is divided into four parts. Each of the four divided transmission waves TX is further distributed by a horizontal distributor 4 and a vertical distributor 3, and is inputted to a transmitting/receiving module 2, respectively.
In the transmitting/receiving module 2, the transmitted wave is
TX is phase controlled. The phase value at this time is controlled by the transmitting/receiving module controller 7. Next, the phase-controlled transmission wave TX is transferred to the TX/RX switching switch 11.
The signal is input to the transmitting module 8 and radiated into space from the element antenna 1. Since the phase shifter 10 of each transmitting/receiving module 2 is centrally and optimally controlled by the transmitting/receiving module controller 7,
The antenna beam can be directed in any desired direction.

Next, the received wave reflected from the target is received by the element antenna 1, inputted to the receiving module 9 of the transmitting/receiving module 2, passed through the TX/RX changeover switch 11, and phase-controlled by the phase shifter 10. At this time, the phase values of the TX/RX switch 11 and the phase shifter 10 are determined by the transmitting/receiving module controller 7.
More controlled. The received wave received by the transmitting/receiving module 2 is sent to a vertical distributor 3 and a horizontal distributor 4.
Σ by hybrid 5,
Received waves of ΔAZ and ΔEL are generated. Using these received waves, monopulse angle measurement is performed for both AZ and EL, and target detection is performed.

(Problem to be solved by the invention) Since the conventional two-dimensional active phased array radar is configured as described above,
In order to perform monopulse angle measurement for both AZ and EL using a hybrid, the arrangement of each element antenna 1 must be
It is necessary to have point symmetry with respect to the center of the antenna array surface formed by a large number of element antennas 1, but if any of the transmitter/receiver modules 2 fails, the point symmetry will not be achieved and the AZ However, there was a problem in that EL monopulse angle measurement was no longer possible.

This invention was made to solve the above problems, and is a two-dimensional active system that can continue to perform AZ, EL, and monopulse angle measurement even if some of the many transmitting and receiving modules fail. - The purpose is to obtain a phased array radar.

(Means for Solving the Problems) A two-dimensional active phased array radar according to the present invention includes a monitor circuit for monitoring the operating status in the transmitter/receiver module, and when the transmitter/receiver module fails, the monitor circuit detects the failure. In addition to detecting and disconnecting a faulty transmitter/receiver module, the system also forcibly disconnects a normal transmitter/receiver module that is located symmetrically with respect to the center of the antenna array plane formed by a large number of element antennas. . At that time, if the transmitter/receiver module is equipped with an ON/OFF switch that turns off the transmitter/receiver module, the transmitter/receiver module is controlled by the monitor signal from the monitor circuit via the transmitter/receiver module control circuit.
Control the ON/OFF switch to turn it off, or if you do not have an ON/OFF switch
The TX/RX changeover switch is controlled to effectively turn it off.

(Function) The monitor circuit of the transmitter/receiver module in the present invention constantly monitors the operating status of the transmitter/receiver module, and uses the monitor signal from the monitor circuit to control the arrangement of element antennas in the transmitter/receiver module control circuit even if any of the transmitter/receiver modules fails. Since the antenna is always controlled to be symmetrical with respect to the center of the antenna array surface, monopulse angle measurement of AZ and EL can be continued even in the event of a failure.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings. FIG. 1 shows the overall configuration of a two-dimensional active phased array radar according to an embodiment of the present invention. In the figure, 1 emits radio waves in space;
Also, a large number of element antennas that receive radio waves from space, 2 are connected to the element antenna 1 and are a number of transmitting/receiving modules that transmit and receive radio waves, and 3 is a vertical antenna that is connected to the transmitting/receiving module 2 and collects or distributes radio waves in the vertical direction. A distributor, 4 is a horizontal distributor that is connected to the vertical distributor 3 and collects or distributes radio waves in the horizontal direction, 5 is a hybrid that is connected to the horizontal distributor 4 and performs monopulse reception, 6 is a transmitted wave TX
7 is a transmitting/receiving module controller that controls the transmitting/receiving module 2.

In addition, in this embodiment, the transmitter/receiver module 2 is the second
The configuration is as shown in the figure. In FIG. 2, 8 is a transmitting module, 9 is a receiving module, 10 is a phase shifter, 11 is a TX/RX changeover switch that switches between the transmitting module 8 and the receiving module 9, and 12
13 is a monitor circuit that monitors the operating status of the transmitter/receiver module, and 13 is a circuit that turns off the transmitter/receiver module.
ON/OFF switch, 18 is a circulator.

Next, the operation will be explained. First, a case will be described in which all transmitter/receiver modules are operating normally. The transmitted wave TX passes through the circulator 6 and is input to the hybrid 5, where it is divided into four parts.
The four divided transmission waves TX are further distributed by a horizontal divider 4 and a vertical divider 3, and are respectively input to the transmitter/receiver module 2 in FIG. At this time, the ON/OFF switch 13 is on, and the phase of the transmitted wave TX is controlled by the phase shifter 10 in the transmitting/receiving module 2. At this time, the phase value is controlled by the transmitting/receiving module controller 7. Next, the phase-controlled transmission wave TX passes through the TX/RX changeover switch 11, is input to the transmission module 8, and is radiated into space from the element antenna 1. Since the phase shifter 10 of each transceiver module 2 is optimally controlled centrally by the transceiver module controller 7, the antenna beam can be directed in a desired direction.

Next, the received wave reflected from the target is received by the element antenna 1, inputted to the receiving module 9 of the transmitting/receiving module 2 in FIG.
The signal passes through the RX changeover switch 11, is phase-controlled by the phase shifter 10, passes through the ON/OFF changeover switch 13, which is in an on state, and is output to the distributor. At this time,
The phase values of the TX/RX changeover switch 11, the ON/OFF changeover switch 13, and the phase shifter 10 are controlled by the transmission/reception module controller 7. The received waves received by the transmitting/receiving module 2 are collected by a vertical distributor 3 and a horizontal distributor 4, and the hybrid 5 generates received waves of Σ, ΔAZ, and ΔEL.
Using these received waves, monopulse angle measurement is performed for both AZ and EL, and targets are detected.

Next, a case will be described in which a part of a large number of transmitting/receiving modules 2 fails. The transmitted wave TX passes through circulator 6 and is input to hybrid 5.
distributed. Each transmitted wave TX divided into 4
is further distributed by a horizontal distributor 4 and a vertical distributor 3, and is input to the transmitter/receiver module 2, respectively. In the transmitting/receiving module 2, the operating status is constantly monitored by the monitor circuit 12, and a monitor signal is output to the transmitting/receiving module controller 7, and the ON/OFF control signal from the transmitting/receiving module controller 7 is used as shown in FIG. A malfunctioning transmitting/receiving module 14 and a normal transmitting/receiving module 15 located symmetrically with respect to the center of the antenna array surface 20.
Turn off both ON/OFF switch 13.
As a result, only the remaining transmitting/receiving modules are phase-controlled by the phase shifter 10. At this time, the phase value is controlled by the transmitting/receiving module controller 7 as in the normal case. The transmitted wave TX passes through the TX/RX changeover switch 11 of the remaining transmitting/receiving module, is input to the transmitting module 8, and is radiated into space from the element antenna 1. Since the phase shifter 10 of each transmitter/receiver module 2 is optimally controlled centrally by the transmitter/receiver module controller 7 as in the normal case, the antenna beam can be directed in a desired direction.

Next, the received wave reflected from the target is received by the element antenna 1, inputted to the receiving module 9 of the transmitting/receiving module 2, passed through the TX/RX changeover switch 11, and phase-controlled by the phase shifter 10. Here, as shown in FIG. 5, the malfunctioning transmitting/receiving module 14 and the normal transmitting/receiving module 15 located symmetrically with respect to the center of the antenna array surface.
Since the ON/OFF switch 13 is turned off, the received wave is not transmitted to the subsequent distributor. In the remaining transmitting/receiving modules, the signal passes through the ON/OFF switch 13, which is in the on state, and is output to the distributor. At this time, TX/RX selector switch 1
1. ON/OFF switch 13 and phase shifter 10
The phase value of is controlled by the transmitter/receiver module controller 7. The received waves received by the transmitter/receiver module 2 are collected by a vertical distributor 3 and a horizontal distributor 4 and input to a hybrid 5. At this time, since the element antenna arrangement is controlled by the transmitting/receiving module controller 7 to be point symmetrical with respect to the center of the antenna array surface, the hybrid 5 can control the received waves of Σ, ΔAZ, and ΔEL. generated,
As a result, monopulse angle measurement is performed for both AZ and EL, and target detection is performed.

In the above embodiment, the transmitting/receiving module 2 is provided with an ON/OFF switch 13 as shown in FIG.
Although the one that turns off the OFF switch 13 is shown, as shown in FIG. 3 (the same parts as in FIG. If the transmitter/receiver module 2 is not installed and the transmitter/receiver module 2 fails, the TX/RX of the defective transmitter/receiver module and the normal transmitter/receiver module located symmetrically with respect to the center of the antenna array plane.
The changeover switch 11 may be controlled to be forcibly turned to the TX side, and the same effect as in the above embodiment can be achieved.

Further, in the above embodiment, when the transmitting/receiving module 2 fails, only the normal transmitting/receiving module 15 located symmetrically with respect to the transmitting/receiving module 14 and the antenna center is disconnected, as shown in FIG. However, as shown in FIG. 6, the transmitting/receiving module group 16 including the failed transmitting/receiving module 14 and the normal transmitting/receiving module group 17 located symmetrically with respect to the center of the antenna array surface 20 are cut off. It may be controlled to do so, and the same effects as in the above embodiment can be obtained.

(Effects of the Invention) As described above, according to the two-dimensional active phased array radar according to the present invention, the operating status of the transmitting and receiving module is constantly monitored,
This monitor signal is used to turn on/off the transmitter/receiver module or a group of transmitter/receiver modules so that the element antenna arrangement is always point symmetrical with respect to the center of the antenna array surface. Even if the transmitter/receiver module fails, AZ and EL monopulse angle measurement can be continued, making it possible to detect targets.

[Brief explanation of the drawing]

FIG. 1 is a system diagram of a two-dimensional active phased array radar showing the overall configuration of an embodiment of the present invention, FIG. 2 is a system diagram of a transmitting/receiving module according to an embodiment of the invention, and FIG. Systematic diagram showing another example of the transmitting/receiving module according to the invention, No. 4
The figure shows a system diagram of a conventional transmitting/receiving module, and FIGS. 5 and 6 show an antenna according to an embodiment of the present invention.
FIG. 3 is a perspective view showing an array surface. 1...Element antenna, 2...Transmission/reception module, 3...Vertical distributor, 4...Horizontal distributor, 5...
...Hybrid, 6...Circulator, 7...
Transmission/reception module controller, 8...Transmission module, 9...Reception module, 10...Phase shifter, 1
1...TX/RX selection switch, 12...Monitor circuit, 13...ON/OFF selection switch, 14...
...Failed transmitting/receiving module, 15... Transmitting/receiving module that is forcibly disconnected, 16... Transmitting/receiving module group including the failed transmitting/receiving module, 17
... Forced disconnection of transmitting/receiving module group, 18
...Circulator, 20...Antenna array surface.

Claims (1)

[Scope of Claims] 1. A large number of element antennas that radiate radio waves into space and receive radio waves from space; a large number of transmitting and receiving modules connected to the element antennas and transmitting and receiving radio waves; and a number of transmitting and receiving modules that are connected to the transmitting and receiving modules. Equipped with a vertical distributor, a horizontal distributor, a hybrid that performs monopulse reception in the horizontal and vertical directions, a circulator that switches between the transmitting wave (TX) and the receiving wave (Σ), and a transmitting and receiving module controller that controls the transmitting and receiving module. In a two-dimensional active phased array radar that performs monopulse angle measurement for both azimuth and elevation angles, each transmitting/receiving module has a monitor circuit that monitors the operating status of the transmitting/receiving module and outputs a monitor signal to the transmitting/receiving module controller. and when a transmitter/receiver module fails, the failed transmitter/receiver module is disconnected, and a normal transmitter/receiver module located at a point symmetrical position with respect to the center of the antenna array plane formed by the plurality of element antennas is also forcibly disconnected. A two-dimensional active phased array radar that is characterized by the ability to 2. A large number of element antennas that radiate radio waves into space and receive radio waves from space, a large number of transmitting and receiving modules connected to the element antennas and transmitting and receiving radio waves, and a vertical distributor and horizontal distributor connected to the transmitting and receiving modules. A hybrid device that performs monopulse reception in the horizontal and vertical directions, a circulator that switches between the transmitting wave (TX) and the receiving wave (Σ), and a transmitting and receiving module controller that controls the transmitting and receiving module. In a two-dimensional active phased array radar that performs monopulse angle measurement, a monitor circuit is installed in each transmitter/receiver module to monitor the operating status of the transmitter/receiver module and output a monitor signal to the transmitter/receiver module controller. When this occurs, the transmitting/receiving module group including the failed transmitting/receiving module is disconnected, and the normal transmitting/receiving module group located at a point symmetrical position with respect to the center of the antenna array plane formed by the multiple element antennas is also forcibly disconnected. A two-dimensional active phased array radar that is characterized by its ability to cut into pieces. 3 ON/OFF in which the transmitting/receiving module turns ON/OFF the transmitting/receiving module based on an ON/OFF control signal from the transmitting/receiving module controller.
3. The two-dimensional active phased array radar according to claim 1, further comprising a changeover switch.