JPH06104623A - Phased array antenna system - Google Patents

Abstract

PURPOSE:To suppress intermodulation noise caused at transmission due to the nonlinear characteristic of a PIN diode phase shifter used for the phased array antenna system for transmission/reception operation. CONSTITUTION:A transmission/reception branching device 2 is provided on each of element antennas 1 of the phased array antenna system, a transmission band exclusive phase shifter 3 is provided between the transmission/reception branching device 2 and a transmission wave distribution circuit 5, and a reception band exclusive phase shifter 4 is provided between the transmission/ reception branching deice 2 and a reception wave distribution circuit 6, then a bypassed intermodulation noise caused at transmission due to a nonlinear characteristic of the PIN diode phase shifters used for the phased array antenna system into a reception system is suppressed by the transmission/reception branching device 2.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a phased array antenna device applied to mobile communication.

[0002]

2. Description of the Related Art In recent years, satellite communication for mobile objects has been
It is developing from those targeting ships to those targeting aircraft and land mobiles. As an example, for example, Inmarsat (International Maritime Satelli
te Organization: INMARSAT) mobile satellite communication systems not only target ships but also enable communication between aircraft flying over the sea and the ground, or in areas where base stations are not provided. It is planned to use maritime satellites to expand communication service areas in order to enable mobile phone calls.

As an antenna device applied to these moving bodies, attention has been paid to a phased array antenna device which can be integrated with the moving body and which can obtain a relatively high gain.

FIG. 3 is a block diagram of a conventional phased array antenna device. In the figure, 1 is an element antenna forming an array antenna, 14 is a received signal by the element antenna 1 or a transmitted signal to the element antenna,
A phase shifter that gives a required phase, 15 is a distribution / combining circuit that distributes a transmission signal to each element antenna and combines reception signals from each element antenna, and 16 is a distribution / combination circuit 15 that distributes a transmission signal from a power amplifier. And a duplexer for outputting the received signal from the distribution / synthesis circuit 15 to the low noise amplifier, 7
Is a power amplifier that power-amplifies the transmission signal from the transmission terminal 9 and outputs the amplified signal to the transmission / reception demultiplexer 16. Reference numeral 8 amplifies the reception signal from the transmission / reception demultiplexer 16 while suppressing an increase in noise.
It is a low noise amplifier that outputs to.

Next, the operation of this conventional phased array antenna device when applied to satellite communication will be described. For example, Inmarsat (International Maritime
In a mobile satellite communication system using Satellite Organization (INMARSAT), frequencies in the L band are used, the transmission band is 1.6 GHz, and the reception band is 1.5 GHz.
Thus, both the transmission band and the reception band are operated with the same circular polarization, that is, right-handed circular polarization. The transmission signal is input to the transmission terminal 9, is amplified by the power amplifier 7, passes through the duplexer 16, and is sent to the distribution / synthesis circuit 15. The transmission wave is distributed in the distribution / combining circuit 15 and is fed to each element antenna 1 through the phase shifter 14.

At this time, the beam can be directed to a target satellite by setting the phase shifter 14 to an appropriate value. The received wave from the satellite is received by each element antenna 1, passes through the phase shifter 14, is combined by the distribution / combining circuit 15, and is then separated by the transmission / reception demultiplexer 16, and the low noise amplifier 8
It is amplified by and is output from the reception terminal 10.

The conventional phased array antenna device is constructed as described above, but it is not a radar antenna in which transmission and reception are alternately performed, but is applied as a general communication antenna. Therefore, the waves in both the transmission and reception bands pass through the phase shifter 14 at the same time.

By the way, a digital phase shifter using a PIN diode is usually used as the phase shifter of the phased array antenna device. For example, in the operation using two or more frequencies like the Inmarsat aircraft station. P
Intermodulation noise due to the non-linear characteristics of the IN diode may be a problem.

That is, when two or more channels are simultaneously used to transmit signals of two or more waves at the same time, the transmission power is large and the frequency interval is very close to, for example, about 10 KHz. And this is P
When passing through the IN diode, due to its nonlinear characteristics,
f1-f2, 2f1-f2, 3f1-f2, ..., Mf1
Intermodulation noise having a frequency component of −nf2, ... (m and n are positive integers and f1 and f2 are frequencies of two transmission waves) is generated. Then, of those, those having a frequency component in the reception band are output to the reception terminal through the duplexer, and the magnitude thereof is, for example, 10 or more than a general white noise level.
It is about 20 dB higher, which is a level at which the signal from the satellite is buried, and thus seriously hinders communication.

[0010]

By the way, the duplexer is usually designed to attenuate the noise in the reception band input from the transmission terminal by a predetermined amount. Since the phase shifter is provided between the duplexer and the element antenna, the intermodulation noise in the reception band generated by the phase shifter is output to the receiving terminal with almost no attenuation in the duplexer. However, there is a drawback in that the above problems occur.

The present invention has been made to solve the above problems, and in applications where transmission and reception are performed simultaneously, the intermodulation noise generated in the phase shifter is output to the reception terminal. It is an object of the present invention to obtain a phased array antenna device that can suppress the occurrence of such a situation.

[0012]

In a phased array antenna apparatus according to the present invention, a transmission / reception demultiplexer is provided for each element antenna, and a phase shifter composed of a PIN diode is provided for a transmission band and a reception band. The phase shifters are independently provided, and each phase shifter is arranged between the transmission / reception duplexer and the low noise amplifier and between the transmission / reception duplexer and the power amplifier.

In the phased array antenna apparatus according to the present invention, the transmission / reception branching filter is composed of a circulator, a transmission bandpass filter and a reception bandpass filter.

[0014]

According to the present invention, as described above, the transmission / reception demultiplexer is provided for each element antenna, and the phase shifter composed of the PIN diode is provided independently for the transmission band and the reception band, and each of the phase shifters is provided. By arranging the phase shifter between the duplexer and the low noise amplifier and between the duplexer and the power amplifier, the signal in the transmission band and the signal in the reception band are separated from each other.
Since it passes through the IN diode, it is possible to suppress the intermodulation noise generated in the PIN diode from flowing into the receiving system in the transmission / reception branching filter.

Further, according to the present invention, as described above, the transmission / reception branching filter is composed of the circulator, the transmission band pass filter and the reception band pass filter, so that the device can be constructed easily and can be provided at a low cost.

[0016]

【Example】

Example 1. An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows a phased array antenna device according to an embodiment of the present invention. In the figure, 1 is an element antenna that constitutes an array antenna, 2 is a transmission / reception demultiplexer provided for each element antenna, and outputs the transmission wave phase-shifted by the transmission band dedicated phase shifter 3 to the element antenna. , And outputs the reception signal from the element antenna to the phase shifter 4 dedicated to the reception band. Reference numeral 3 is a transmission band dedicated phase shifter provided between the transmission / reception demultiplexer 2 and the transmission wave synthesizing circuit 5, and imparts a required phase to the output of the transmission wave synthesizing circuit 5. Reference numeral 4 is a transmission / reception demultiplexer 2 and a reception wave synthesis circuit 6
It is a phase shifter dedicated to the reception band provided between the two and adds a required phase to the output of the transmission / reception demultiplexer 2.

Next, the operation will be described. In the present embodiment, the transmission wave input to the transmission terminal 9 is amplified by the power amplifier 7, distributed by the power distributor 5 in correspondence with each element antenna, and sent to the phase shifter 3 dedicated to the transmission band. Further, an appropriate phase is set by the phase shifter 3, and the power is supplied to each element antenna 1 through the transmission / reception duplexer 2. At this time, the beam can be directed to the target satellite by setting the phase shifter 3 to an appropriate value.

Further, the received wave received by each element antenna 1 is demultiplexed into the receiving terminal of the transmitting / receiving demultiplexer 2, and after being set to a predetermined phase by the phase shifter 4 dedicated to the receiving band, the received wave synthesizing circuit 6
Are combined with each other, amplified by the low noise amplifier 8, and output to the receiving terminal 10.

According to this embodiment, two or more transmission waves are input to the transmission terminal 9 and, after being distributed by the synthesizing circuit 5, pass through the phase shifter 3 dedicated to the transmission band. Modulation noise is generated, of which noise in the reception band can be attenuated by the transmission / reception duplexer 2. That is, it is possible to suppress the influence of the noise on the received signal by designing the transmission / reception branching filter so that the attenuation amount becomes equal to or more than a predetermined value of about 60 dB.

Further, according to this embodiment, since the phase shifter is provided independently for transmission and reception, it is not necessary to cover the entire transmission / reception band with one phase shifter as in the conventional configuration. Also, since the phase shifter dedicated to the reception band does not have to have power resistance, it is not necessary to select the characteristics of the PIN diode when configuring the phase shifter.

In the above embodiment, each element antenna is provided with a transmission / reception demultiplexer. However, instead of the transmission / reception demultiplexer, a circulator, a transmission band bandpass filter and a reception band bandpass filter are used. Also, it is possible to obtain the same effect as that of the above embodiment.

Example 2. FIG. 2 shows another embodiment of the present invention configured as described above. In FIG. 2, 11 is a circulator provided for each element, 12 is a transmission band band-pass filter provided between the circulator 11 and the transmission band dedicated phase shifter 3, and 13 is a circulator 11 and the reception band dedicated shifter. A reception band bandpass filter provided between the phase shifters 4 is a transmission / reception demultiplexer composed of the circulator 11, the transmission band bandpass filter 12 and the reception band bandpass filter 13.

According to this embodiment, even if the intermodulation noise occurs in the phase shifter 3 in the reception band, it is attenuated by the directivity of the transmission band bandpass filter 12 and the circulator 11, and is output to the reception terminal. The amount can be suppressed. Further, it is possible to give a predetermined attenuation to the transmission wave reflected by the element antenna by the reception band-pass filter 13 so that the transmission wave does not adversely affect the low noise amplifier.

Further, according to this embodiment, since the circulator whose structure is simpler than that of the transmission / reception duplexer of FIG. 1 is used, the apparatus becomes much cheaper and moreover, compared with the embodiment of FIG. The effect is that it can be made slightly smaller.

[0025]

As described above, according to the phased array antenna device of the present invention, a phase shifter composed of a PIN diode is provided for each of the transmission band and the reception band, and each phase shifter is provided. Since the phase shifter is arranged between the transmission / reception demultiplexer and the transmission wave synthesizing circuit and between the transmission / reception demultiplexer and the reception wave synthesizing circuit, the intermodulation noise generated in the PIN diode by two or more transmission waves. There is an effect that the amount output to the receiving terminal can be suppressed to a predetermined value or less.

Further, according to the phased array antenna apparatus of the present invention, the transmission / reception duplexer is composed of the circulator, the transmission band pass filter and the reception band pass filter, so that the configuration of the apparatus is simple and inexpensive. There is an effect that can be provided to.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing a configuration of a phased array antenna device according to an embodiment of the present invention.

FIG. 2 is a circuit diagram showing a configuration of a phased array antenna device according to another embodiment of the present invention.

FIG. 3 is a circuit diagram showing a configuration of a conventional phased array antenna device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 element antenna 2 duplexer 3 phase shifter for transmission band 4 phase shifter for reception band 5 transmission wave synthesis circuit 6 reception wave synthesis circuit 7 power amplifier 8 low noise amplifier 9 transmission terminal 10 reception terminal 11 circulator 12 transmission band Band pass filter for reception 13 Band pass filter for reception band 20 Transmission / reception duplexer

Claims (2)

[Claims] 1. A phased array antenna apparatus having a plurality of element antennas for operating a transmission / reception band with the same polarization, wherein a transmission / reception demultiplexer is provided for each element antenna, and a transmission / reception demultiplexer and a transmission wave distribution circuit are provided. A phased array antenna device characterized in that a phase shifter dedicated to the transmission band is disposed between and a phase shifter dedicated to the reception band is disposed between the transmission / reception demultiplexer and the reception wave combining circuit. 2. The phased array antenna apparatus according to claim 1, wherein the transmission / reception duplexer comprises a circulator, a transmission band pass filter, and a reception band pass filter.