JP3222823B2 - Reflector antenna device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a reflector antenna device.

[0002]

2. Description of the Related Art Phased array antennas, particularly active phased array antennas, are widely used because they can easily adjust directivity and form beams. FIG. 6 shows a configuration of a conventional active phased array antenna. This active phased array antenna includes a plurality of transmitting / receiving modules 201 to 20m connected to a plurality of antenna elements 101 to 10m, respectively. Then, at the time of transmission, the transmission signal from the transmitter 61 is distributed and supplied to the respective transmission / reception modules 201 to 20m by the power distribution / combiner 4 via the transmission / reception switch 51.

On the other hand, at the time of reception, each antenna element 101
The received signal from the transmission / reception module 201
The signal is combined by the power distribution / combiner 4 through ２０20 m, and received by the receiver 71 via the transmission / reception switch 51.

By the way, in a phased array antenna, it is generally important to make the transmission and reception wavefronts uniform, and therefore, it is necessary to correct the amplitude and phase of each antenna element of the array. Therefore, in the above configuration, the monitor antenna 10 is provided in the antenna aperture, and a dedicated transmission / reception system (the monitor transmission / reception switch 5
2, a monitor transmitter 62, a monitor receiver 72, a transmission correction coefficient calculation setting unit 82), and a receiver 71 are connected to a reception correction coefficient calculation setting unit 81.

[0005] In order to correct the transmission of the active phased array antenna, a transmitter 61 outputs a transmission signal for correction. Then, the correction radio waves from the antenna elements 101 to 10 m are sequentially monitored by the antenna 1.
0, and a transmission correction coefficient is calculated by the transmission correction coefficient calculation setting unit 82 based on the received signal.
Set every 10 m.

[0006] In order to make corrections relating to reception, a transmission signal for correction is radiated from the monitor transmitter 62 via the antenna 10 for monitoring, and this is transmitted to each of the antenna elements 101 to 10.
m, and the reception correction coefficient calculation / setting unit 8
1 to calculate a reception correction coefficient, which is calculated for each antenna element 10
It is set every 1 to 10 m.

However, in the above configuration, the monitor antenna 1
0 and the distance between the antenna elements 101 to 10 m are unequal. For this reason, when performing the correction work, the variation in transmission / reception power for each of the antenna elements 101 to 10 m increases.

[0008] In other words, the correction regarding transmission will be described. The radiated radio wave from the antenna element closest to the monitor antenna 10 is received by the monitor antenna 10 with large power, and the radiated radio wave from the farthest antenna element is received with small power. You. The situation is the same for the correction for reception.

As a result, an error occurs in the measurement result at the time of correction, and accurate correction cannot be performed. To make matters worse, the dynamic range of the receiver 71 and the monitor receiver 72 must be widened according to the degree of the difference in the received power. For this reason, many problems such as an unnecessary increase in price occur.

[0010]

As described above, the conventional active phased array antenna is difficult to perform accurate correction, and requires a wide dynamic range of the receiver, so that the cost is unnecessarily increased. There was a defect.

The present invention has been made in view of the above circumstances,
An object of the present invention is to provide a reflector antenna device that can accurately perform correction with a simple configuration without increasing the price.

[0012]

In order to achieve the above object, the present invention provides a primary radiator having a plurality of antenna elements arranged in an array, and a primary radiator connected to each of the plurality of antenna elements. A plurality of phase shifters that can individually set the amount of phase shift, and a reflector that reflects radio waves radiated from the primary radiator and directs it to an observation range, reflects an incoming radio wave and guides the primary radiator to the primary radiator, The power of this reflector
A monitoring antenna attached to the wave reflecting surface , and a correction radio wave radiated from the monitor antenna, the correction radio wave is received via the plurality of antenna elements, and the phase shift is performed based on the received signals. A phase correction amount to be set for each of the phase shifters, and a reception correction means for correcting the shape of the wavefront of the reception radio wave to the primary radiator by setting each of these phase shift amounts for each of the phase shifters, It is characterized by having.

With this configuration, the phase correction at the time of reception is performed using the monitoring antenna attached to the radio wave reflecting surface of the reflector. The reflector is usually installed at a certain distance from the antenna element in view of its function. For this reason, the variation in the distance between the monitoring antenna and each antenna element can be reduced, thereby reducing the variation in the reception intensity at the time of correction.

Accordingly, the correction error can be reduced, and
It is possible to narrow the dynamic range of the correction receiver
As a result, cost can be reduced. In addition to this, riffs
I am trying to attach a monitor antenna to the collector
Therefore, it is necessary to provide a new column to support the antenna for monitoring.
There is no. As a result, the weight due to the provision of a monitor antenna is
Increased volume and complications can be minimized
In addition, eliminate the risk of radio wave blocking
Can be.

Further, according to the present invention, in the receiving correction means,
Correction regarding the amplitude at the time of reception is also performed. As a result, the shape of the wavefront can be more finely corrected.

Further, according to the present invention, a transmission correcting means is provided to correct the phase or amplitude at the time of transmission. This makes it possible to correct the shape of the wavefront of the transmission radio wave with the same effect as described above.

The present invention also provides a plurality of first antenna elements arranged in an array and a plurality of first antenna elements respectively connected to each of the plurality of first antenna elements, each of which can individually set a phase shift amount. Primary radiator including a plurality of second phase shifters, and a plurality of second antenna elements respectively connected to the plurality of phase shifters, and transmission / reception means for transmitting and receiving radio waves via the primary radiator A so-called passive phased array antenna comprising a reflector that reflects a radio wave radiated from the primary radiator and directs the radio wave to an observation range, and reflects an incoming radio wave to guide the primary radiator to the primary radiator. An antenna for monitoring is attached to the radio wave reflecting surface of the antenna, and wavefront correction relating to transmission and reception is performed using the antenna for monitoring. Even in this case, the same effect as described above can be obtained.

According to the present invention, there is provided a beam scanning type active phased array antenna further comprising beam scanning means for performing beam scanning by electrically varying a phase shift amount of each of the plurality of phase shifters. Correction is performed by adjusting the amount of phase shift related to beam scanning. With this, not only the same effects as described above can be obtained, but also the correction operation becomes easier.

The present invention also provides a plurality of transmission / reception switches respectively provided on paths leading to each of the plurality of antenna elements for switching between transmission and reception, and a plurality of transmission / reception switches respectively connected to these transmission / reception switches. And a plurality of analog / digital converters for performing analog / digital conversion of the received signal via the analog / digital converter, and performing arithmetic processing on the phase and amplitude of the received signal with respect to the digital signal from the analog / digital converter. A so-called (Digital Beam Form) further comprising a calculation means for forming a beam.
ing) In the reflector antenna device of the radar, the correction is performed by setting a coefficient relating to the arithmetic processing. As a result, the correction work becomes simpler, and the convenience for the operator can be achieved. This effect will be described in detail in the following embodiment.

Further, the present invention is directed to a monopulse system.
It can also be applied to adjust the amplitude and phase balance in a so-called monopulse horn antenna that performs tracking with respect to .

[0021]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is a functional block diagram showing a configuration of a reflector antenna device according to an embodiment of the present invention. In FIG. 1, the same portions as those in FIG. 6 are denoted by the same reference numerals, and only different portions will be described here.

The reflector antenna device shown in FIG. 1 includes a reflector 9 in addition to the configuration shown in FIG. And
A monitor antenna 10 is provided on a radio wave reflecting surface of the reflector 9. In the above configuration, the antenna elements 101 to 10 m and the transmission / reception modules 201 to 20 m are collectively referred to as a primary radiator 3 for convenience of the following description.

Now, a procedure for correcting the shapes of the transmission and reception beams in the above configuration will be described. When correcting the transmission beam shape, first, a transmission seed signal is generated in the transmitter 61 and the transmission seed signal is transmitted to the transmission / reception switch 5.
1 and the transmission / reception module 201 via the power distributor 4
Lead to ~ 20m. At this time, the transmission / reception modules 201 to 201
One of the 20 m, for example, only the transmission / reception module 201 is driven to amplify the transmission seed signal and rotate its phase little by little.

The transmission seed signal thus processed is radiated from the antenna element 101 as a radio wave. This radio wave is received by the monitor receiver 72 from the monitor antenna 10 via the monitor transmission / reception switch 52, and the amplitude and phase of the received signal are measured by the transmission correction coefficient calculation setting unit 82.

By repeating the above operation by the number of transmission / reception modules, the amplitude and phase of the radiated radio wave are finally measured for all of the antenna elements 101 to 10 m. Then, based on the measurement data, the transmission correction coefficient for each of the transmission / reception modules 201 to 20m is calculated by the transmission correction coefficient calculation setting unit 82.

The transmission correction coefficient is stored in each transmitting / receiving module 2
By setting every 01 to 20 m, the antenna element 10
Wavefronts of radiated radio waves from 1 to 10m can be aligned,
The correction of the transmission beam shape is completed.

On the other hand, when correcting the reception beam shape, the monitor transmitter 62 generates a monitor transmission signal. The monitor transmission signal is transmitted to the monitor transmission / reception switch 5.
2 to the monitor antenna 10 and the monitor antenna 10
To the primary radiator 3 as a radio wave.

Radio waves radiated from the monitoring antenna 10 are received by the antenna elements 101 to 10 m and guided to the transmission / reception modules 201 to 20 m. At this time, only one of the transmission / reception modules 201 to 20m, for example, the transmission / reception module 201 is driven to amplify the received signal and rotate the phase thereof little by little.

The received signal processed as described above is led to the receiver 71 via the power distribution / synthesizer 4 and the transmission / reception switch 51, and the reception correction coefficient calculation / setting unit 81 determines the amplitude and phase of the received signal. Measure.

By repeating the above operation by the number of transmission / reception modules, the amplitude and phase of the received signal are finally measured for all of the antenna elements 101 to 10 m. Then, based on the measurement data, each transmission / reception module 20
The reception correction coefficients for 1 to 20 m are calculated by the reception correction coefficient calculation setting unit 81.

By setting the reception correction coefficient for each of the transmission / reception modules 201 to 20 m, the reception wavefronts of the antenna elements 101 to 10 m can be aligned, and the correction of the transmission beam shape is completed.

Through the above-described steps, transmission and reception can be corrected. Next, the advantages of the present invention will be described by simple quantitative considerations with reference to FIG. In FIG.
A monitor antenna 10-1 is provided on the same plane as the antenna elements A1 and A2, and a monitor antenna 10-2 is provided at a position separated by a distance b from this plane. The intervals between the monitor antenna 10-1 and the antenna elements A1 and A2 are a and 2a, respectively.

[0033] Generally, since the radio wave power radiated from the antenna is inversely proportional to the square of the distance, when the reception intensity when receiving the radio wave radiated from the antenna element A1 on the monitor antenna 10-1 and k / a ^2, it radiating radio waves from the antenna element A2 becomes k / 4a ^2. These differences are 3k
/ 4a is ^2.

On the other hand, when the radio wave radiated from the antenna element A1 is received by the monitor antenna 10-2, the reception intensity is k /
(A ² + b ² ), that of the radio wave radiated from the antenna element A2 is k / (4a ² + b ² ). These differences are 3k
/ [{1+ (b / a) ² } × (4a ² + b ² )].

The magnitude of the difference between the two is clear,
That is, the latter case is smaller. That is, b is 0
The difference becomes smaller as the value becomes larger.

That is, as shown in the present embodiment, by providing the monitor antenna 10 at a position away from the antenna aperture, each antenna element 101 to
It is possible to reduce the variation in transmission / reception power every 10 m. As a result, the measurement error can be reduced, and an accurate transmission correction coefficient can be easily calculated. further,
Even if the dynamic range of each of the transmission / reception modules 201 to 20m is narrowed (of course, within a necessary range), there is no problem, so that not only the price is not increased but also the cost can be reduced compared with the conventional one.

In the present embodiment, the monitor antenna 10
Is provided on the side facing the primary radiator 3 of the reflector 9. FIG. 3 shows an overview of the reflector antenna device of the present embodiment. In this way, not only is the configuration simple, but there are further advantages. That is,
For example, in a case where a support is extended from the primary radiator 3 and the monitor antenna 10 is supported by the support, the primary radiator 3
There is a possibility that the radio wave radiated from the antenna may be blocked (blocked) by the support, but the configuration of the present embodiment does not cause such a concern.

Thus, in the present embodiment, the monitor antenna 10 is provided at a position away from the plane on which the antenna elements 101 to 10 m for transmitting and receiving radar radio waves are arranged. Thereby, each antenna element 101-
Variation in the distance between 10 m and the monitor antenna 10 can be reduced. Therefore, at the time of the correction operation, it is possible to reduce the variation in the transmission / reception power for each of the antenna elements 101 to 10 m, and to reduce the measurement error relating to the correction. In the present embodiment, the monitor antenna 10 is reflected by the reflector 9 from the radio wave.
The structure is simplified because the device is attached to the surface .

In the present embodiment, the monitor antenna 10
Is attached to the reflector 9 on the side of the radio wave reflecting surface, so that the configuration is simplified.

The present invention is not limited to the above embodiment. For example, in the above embodiment, the reception correction coefficient and the transmission correction coefficient are
In the scanning phased array antenna, each correction coefficient can be set by adding a coefficient to a phase shift value for beam scanning. By doing so, the phase setting can be particularly simplified.

In the above embodiment, the primary radiator 3 has an active phased array, but the present invention can be applied to a passive phased array.
For example, when the present invention is applied to a passive phased array antenna as shown in FIG.
(Sign is 3-2).

The primary radiator 3-2 is connected to the antenna element 1
It includes m phase shifters 301 to 30 m connected to 01 to 10 m and antenna elements 401 to 40 m, respectively, and mediates transmission and reception of radio waves in the sub-antenna element 11. The changeover switch is not shown, but each phase shifter 3
01 to 30 m, and each phase shifter 30
The amount of phase shift at 1 to 30 m will be set. In this configuration, a high power type transmitter is used (reference numeral 61-2).

Further, in the above embodiment, the received power from each of the transmission / reception modules 201 to 20m is directly combined by the high frequency power distribution / synthesizer 4 and then guided to the receiver 71. However, in addition to this, for example, a so-called DBF (Division) that includes a transmission / reception switch, a receiver, and an A / D (analog / digital) converter for each of the transmission / reception modules 201 to 20 m and performs reception beam synthesis in the digital domain
gital Beam Forming) The present invention can be applied to radar.

When the present invention is applied to this type of radar apparatus, when calculating the reception correction coefficient, each of the transmission / reception modules 201 to 20m is driven simultaneously instead of one by one.
The amplitude and phase of the received signal can be measured simultaneously. For this reason, work efficiency can be further improved, and a greater advantage can be enjoyed.

As a further advantage when the present invention is applied to a DBF radar, a reception correction coefficient is not provided as a hardware setting for each of the transmission / reception modules 201 to 20m, but in a calculation processing stage after digital conversion. Is given as a coefficient. This allows
The phase setting operation can be further simplified.

Further, the present invention can be applied to an angle measuring radar device using a monopulse horn antenna as a primary radiator. FIG. 5 shows a configuration in such a case. The monopulse horn antenna shown in FIG. 5 includes four horn antenna elements 501 to 504, and guides signals from the three power distribution combiners 4-2 to 4-4 to each of these antenna elements. Element 50
The received signals from the power supply devices 1 to 504 are divided into three and guided to the power distribution / combiners 4-2 to 4-4, respectively.

The signals from the power distribution combiners 4-2 to 4-4 are guided to receivers 71-2 to 71-4, respectively.
Here, the signal from the power distribution / combiner 4-2 passes through the transmission / reception switch 51. The transmission signal from the high power transmitter 61-2 is transmitted to the power distribution / combiner 4-2 via the transmission / reception switch 51.
Only led to.

The present invention is applied to the above monopulse horn antenna, and each horn antenna element 501 to 504
If the amplitude and phase balance of the data can be corrected, the angle measurement performance can be further improved, and a great advantage can be obtained.

In addition, various modifications may be made without departing from the spirit of the present invention, such as the configuration of the primary radiator, the arrangement of antenna elements (such as a linear array), and the number of monitor antennas (not limited to one). It is possible to do.

[0050]

As described above in detail, according to the present invention, the antenna for monitoring is provided on the radio wave reflecting surface of the reflector. It can be provided by.

[Brief description of the drawings]

FIG. 1 is a functional block diagram showing a configuration of a reflector antenna device according to an embodiment of the present invention.

FIG. 2 is a diagram used to explain an advantage of the present invention.

FIG. 3 is a schematic view of a reflector antenna device according to the embodiment of the present invention.

FIG. 4 is a diagram showing a configuration when the present invention is applied to a passive phased array antenna.

FIG. 5 is a diagram showing a configuration when the present invention is applied to a monopulse horn antenna.

FIG. 6 is a functional block diagram showing a configuration of a conventional active phased array antenna.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 3 ... Primary radiator 4 ... Power distribution synthesizer 51 ... Transceiver switch 52 ... Monitor transmit / receive switch 61 ... Transmitter 62 ... Monitor transmitter 71 ... Receiver 72 ... Monitor receiver 81 ... Reception correction coefficient calculation setting Device 82: Transmission correction coefficient calculation setting device 9: Reflector 10: Monitor antenna 101 to 10m ... Antenna element 201 to 20m ... Transmission / reception module A1, A2: Antenna element 10-1, 10-2 ... Monitor antenna 301 to 30m: Phase shift Device 401 to 40 m Antenna element 61-2 High power transmitter 3-2 Primary radiator 11 Secondary antenna element 3-3 Primary radiator 4-2 to 4-4 Power distribution combiner 501 to 504 Horn antenna element 71-2 to 71-4 ... Receiver

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-7-297634 (JP, A) JP-A-9-138270 (JP, A) JP-A-62-11305 (JP, A) JP-A 8-118 256008 (JP, A) JP-A-9-27712 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) H01Q 3/26-3/46 H01Q 19/17 H01Q 25/00- 25/04

Claims (11)

(57) [Claims] A primary radiator having a plurality of antenna elements arranged in an array; and a primary radiator connected to each of the plurality of antenna elements.
A plurality of phase shifters that can individually set the amount of phase shift, and a reflector that reflects radio waves radiated from the primary radiator and directs it to an observation range, reflects an incoming radio wave and guides the primary radiator to the primary radiator, A monitor antenna attached to the radio wave reflecting surface of the reflector, and a correction radio wave is radiated from the monitor antenna, the correction radio wave is received via the plurality of antenna elements, and the correction signal is received based on the received signal. The amount of phase shift to be set for each phase shifter is obtained, and the phase shift amount is set for each of the phase shifters to correct the wavefront shape of the radio wave received by the primary radiator. A reflector antenna device, comprising: a correction unit. 2. The apparatus according to claim 1, further comprising a plurality of amplitude adjusters connected to each of the plurality of phase shifters, each of which is capable of individually setting an amplitude adjustment amount. Then, the amplitude adjustment amounts to be set for each of the amplitude adjusters are obtained, and the wavefront shape of the radio wave received by the primary radiator is corrected by setting these amplitude adjustment amounts for each of the amplitude adjusters. The reflector antenna device according to claim 1, wherein 3. The apparatus according to claim 1, further comprising: a beam scanning unit that performs beam scanning by electrically varying a phase shift amount of each of the plurality of phase shifters; The coefficients to be set for each of the phase shifters are calculated at the same time, and these coefficients are added to the amount of phase shift related to the beam scanning for each of the phase shifters, so that the received radio wave to the primary radiator is added. 3. The reflector antenna device according to claim 1, wherein the shape of the wavefront is corrected. 4. A transmission / reception switch provided on a path leading to each of the plurality of antenna elements for switching between transmission and reception, and an analog / digital converter for performing analog / digital conversion of a signal received via the transmission / reception switch. An arithmetic unit for forming a receive beam by performing an arithmetic process on the phase and amplitude of the received signal on the digital signal from the analog / digital converter. At the time of arithmetic processing on the phase and amplitude in the arithmetic means based on the received signal,
3. The wavefront shape of a radio wave received by said primary radiator is corrected by obtaining coefficients to be set for each antenna element and setting each of these coefficients in said calculating means. The reflector antenna device according to any one of the above. 5. A primary radiator having a plurality of antenna elements arranged in an array, and a plurality of phase shifters each connected to each of the plurality of antenna elements and capable of individually setting a phase shift amount. A reflector that reflects radio waves radiated from the primary radiator and directs it to the observation range, reflects an incoming radio wave and guides the primary radiator to the primary radiator, and a monitoring antenna attached to a radio wave reflecting surface of the reflector, A correction radio wave is radiated from each of the plurality of antenna elements, the correction radio wave is received via the monitor antenna, and a phase shift amount to be set for each of the phase shifters based on the received signal. And transmission correction means for correcting the shape of the wavefront of the transmission radio wave from the primary radiator by setting each of these phase shift amounts for each of the phase shifters. The antenna device. 6. The apparatus further comprises a plurality of amplitude adjusters respectively connected to each of the plurality of phase shifters, each of which can individually set an amplitude adjustment amount, and wherein the transmission correction unit also includes a control unit that controls the reception signal. Then, the amplitude adjustment amounts to be set for each of the amplitude adjusters are obtained, and the wavefront shape of the radio wave received by the primary radiator is corrected by setting these amplitude adjustment amounts for each of the amplitude adjusters. The reflector antenna device according to claim 5, wherein 7. The apparatus according to claim 1, further comprising a beam scanning unit configured to electrically vary a phase shift amount of each of the plurality of phase shifters to perform beam scanning. The coefficients to be set for each of the phase shifters are calculated at the same time, and these coefficients are added to the amount of phase shift related to beam scanning for each of the phase shifters, so that the transmission radio wave from the primary radiator is obtained. 7. The reflector antenna device according to claim 5, wherein the shape of the wavefront is corrected. 8. A transmission / reception switch provided on a path leading to each of the plurality of antenna elements for switching between transmission and reception, and an analog / digital converter for performing analog / digital conversion of a signal received via the transmission / reception switch. An arithmetic unit for forming a reception beam by performing an arithmetic process on a phase and an amplitude of the reception signal with respect to the digital signal from the analog / digital converter. At the time of arithmetic processing on the phase and amplitude in the arithmetic means based on the received signal,
7. The wavefront shape of a transmission radio wave from the primary radiator is corrected by obtaining coefficients to be set for each antenna element and setting these coefficients in the calculation means. The reflector antenna device according to any one of the above. 9. A plurality of first antenna elements arranged in an array, and a plurality of phase shifters each connected to each of the plurality of first antenna elements and capable of individually setting a phase shift amount. A primary radiator including a plurality of second antenna elements, each of which is connected to each of the plurality of phase shifters; a transmitting / receiving unit that transmits and receives radio waves via the primary radiator; A reflector that reflects radio waves radiated from the primary radiator and directs it to the observation range, reflects the arriving radio waves and guides the primary radiator to the primary radiator; an antenna for monitoring attached to the radio wave reflecting surface of the reflector; A radio wave for correction is radiated from the antenna, the radio wave for correction is received via the primary radiator, a phase shift amount to be set for each of the phase shifters is determined based on the received signal, and each of these Before phase shift Reflector antenna apparatus characterized by comprising a reception correcting means for correcting the received radio wave of the wavefront shape of the to the primary radiator by setting for each phase shifter. 10. A plurality of first antenna elements arranged in an array, and a plurality of phase shifters respectively connected to each of the plurality of first antenna elements and capable of individually setting a phase shift amount. Radiator, which is connected to each of the plurality of phase shifters, and a plurality of second antenna elements, and a transmitting / receiving means for transmitting and receiving radio waves via the primary radiator; A reflector that reflects radio waves radiated from the radiator and directs it to the observation range, reflects an incoming radio wave and guides the primary radiator to the primary radiator, a monitoring antenna attached to a radio wave reflecting surface of the reflector, and the transmitting and receiving means. The correction radio wave is emitted via the primary radiator, the correction radio wave is received via the monitor antenna, and the phase shift amount to be set for each of the phase shifters based on the received signal is determined. Ask, this A reflector antenna device comprising: transmission correction means for correcting the shape of the wavefront of the transmission radio wave from the primary radiator by setting each of these phase shift amounts for each of the phase shifters. . 11. The reflector antenna device according to claim 1, wherein a target is tracked by a monopulse method using the plurality of antenna elements.