JPS62195944A - Transmission power inspection equipment for active array antenna - Google Patents

Abstract

PURPOSE:To prevent the deterioration in the basic performance by fitting freely attachably and detachably an inspection waveguide device to the irradiation face of an active array antenna. CONSTITUTION:A fitting metal fixture 14 fitting freely attachably and detachably the inspection waveguide device 12 to the radiation face of an array antenna 5 is fitted to the inspection waveguide device 12 comprising the array antenna 5 consisting of the arrangement of element antennas 51...5n and waveguide lines 101...10n. The array antenna 5 is in use by removing the inspection waveguide device 12 from its radiation face by using the fitting metal fixture 14 normally. In requiring to check the output, the inspection waveguide device 12 is mounted by using the fitting metal fixture 14 as shown in figure.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a method of transmitting power for checking the output of an element amplifier in an active array antenna formed by arranging a plurality of element antennas each having a built-in element amplifier. Regarding inspection equipment.

[Prior Art] FIG. 5 is a block diagram showing an example of a conventional transmission power inspection device for an active array antenna described on page 99 of the NARDA product catalog. machine, (2) is the power supply circuit, (3□) (3□)...(
3.) is an element amplifier, (4 engineering) (4□)... (4m)
is a directional coupler, (5,) (5,)... (5o) is an element antenna, and (6) is a detector.

Next, its operation will be explained. The electromagnetic waves generated by the transmitter (1) are divided into n element amplifiers (3,) (3X)...(
3,). The electromagnetic waves amplified here are sent to the element antennas (5□) (52)...(5,) via the main lines of the directional couplers (4□) (4□)... (4). is,
There it is radiated into space. Directional coupler (4□) (4,
)...The coupling terminal of (4,) is connected to an element amplifier (3t) (
32)...(3a) appears, so assuming that the degree of coupling is known, the transmitted power can be checked using the detector (6) connected to these coupling terminals.

Furthermore, as conventional devices for branching transmission power without using a directional coupler, there are devices shown in FIGS. 6 and 7. Figure 6 shows, for example, TRANSCSO's antenna catalog number 42.
FIG. 7 is a perspective view showing an array antenna in which a large number of these element antennas are arranged. In the figure (5)
is a horn antenna which is an element antenna, (7) is a feeder line, (
8) is a coupling output connector connected to a detector (6) (not shown), and (8a) is a coupling probe.

In this configuration, electromagnetic waves sent from the transmitter are transmitted to the horn antenna (5) via the feed line (7). Assuming that the direction of the electric field vector of the electromagnetic wave at this time is the direction shown by the arrow in Fig. 6, the electromagnetic wave is connected to the coupling output connector ( A part of the transmission power is taken out from 8), and the output can be inspected by reading it with a detector.

This horn antenna (5) is connected to the element aerial 11 (5□) (5□
)...(5,), it becomes as shown in FIG.

That is, each element antenna (5,) (5□)... (5,) is arranged in a straight line with an element interval d, and the power supply connector (5a
□) (Sat)...(5a,) is not shown in the figure,
1! (7□) (72)...(7o), the combined output connector (8□) (8□)...(shi) is connected to the power supply tlA(
9□) (92)... (-) are respectively connected to a detector (6) not shown.

In an array antenna, the optimum value of the element spacing d of the array is determined from the shape of the radiation pattern and the design target value of the gain. Setting the element spacing d larger than the allowable value is undesirable from a design point of view because it causes generation of unnecessary beams and decreases in gain.

When the element antenna is a waveguide-based horn antenna, its fundamental mode cutoff frequency fc is related to the waveguide H-plane width a, so depending on the lower limit frequency used by the array antenna, the waveguide H-plane width a is It is required that it be above a certain tolerance value. In order to satisfy both this condition and the above-mentioned condition regarding the allowable maximum value of the element spacing d, the arrangement direction of the antennas is aligned with the E-plane direction of the waveguide, as shown in FIG. Therefore, the combined output connector (8□) (82)...(8
, ) will match the arrangement direction of the array antenna, and the height of this, the feeder line (9□) (92)...
It becomes necessary to secure a space h for the wiring (9,) in the arrangement direction.

[Problems to be Solved by the Invention] Since the conventional array antenna transmission power inspection device is configured as described above, the directional coupler (4
, ) (4,) ... (4,), the same number of directional couplers as element antennas are always built in, and these are used even during normal operation when there is no need to check the output. Since the loss caused by this is added as a power supply loss, there are problems in that the gain of the array antenna is reduced and the device becomes large and expensive. In addition, in the case of using the combined output connectors (8□) (8□)...(shi) as shown in Figures 6 and 7, in addition to the above problems, there are Since it is necessary to secure a space h in the arrangement direction, there is a problem in that the element spacing d is increased to a value exceeding a permissible value which is undesirable from the viewpoint of radiation pattern and gain.

This invention was made in order to solve the above-mentioned problems and to increase the scale of the array antenna, and to improve the basic performance such as radiation pattern and gain. An object of the present invention is to provide a transmission power inspection device for an active array antenna, which allows transmission power to be easily inspected without deteriorating the antenna.

[Means for Solving the Problems] The transmission power type inspection device according to the present invention has a plurality of conductors separated by conductor partitions, one end facing each element antenna and an output connector provided at the other end. An inspection waveguide device consisting of a wave tube line is detachably attached to the radiation surface of the array antenna, and an inspection output is taken out from the output connector.

[Function] In this invention, an inspection waveguide device is attached to the array antenna radiation surface only when transmitting power is inspected, and the radiated electromagnetic waves from each element antenna enter into each waveguide line facing therein. If necessary, the signal is attenuated to a power level that can be measured with a general-purpose measuring device, and then taken out from the output connector, and the transmitted power is measured with a detector. Since the inspection waveguide device consisting of these waveguide lines is removed except during inspection, there is no possibility that the basic performance of the array antenna will be degraded by this.

[Example] An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a perspective view showing an embodiment of the present invention.

In the figure, (5) is an array antenna, (10□) (10, )
...(1(1)...(10,) is a waveguide line separated by a conductor partition and one end facing each element antenna, (1
1□) (11□)...(U;)...(11,) is the output connector provided at the other end of each waveguide line, (12) is
Waveguide line (10 pieces) (10□)...Dot)...(1
An inspection waveguide device configured by 0,).

(13) is a radiation fin provided on the outer wall of this inspection waveguide device (12), and (14) is a radiator fin for detachably attaching the inspection waveguide device (12) to the radiation surface of the array antenna (5). Mounting is with metal fittings.

Fig. 2 is a vertical cross-sectional view of the i-th waveguide line Dot ) as seen from Fig. 3 ■-■;
3 is a plan cross-sectional view of the same as seen from (2). In the figure, (15
) is a radio wave absorber that acts as an attenuator, (16a)
(16b) is the fundamental mode TE construction of the waveguide line. The ridge (17) is for converting the mode to the fundamental mode TEM mode of the coaxial line, and the ridge (16b) and the output connector (
(tilB-0) (18t) is the conductor that isolates the adjacent waveguide line (tot-i) (tot, , ). It is a bulkhead. Although not shown, the element antenna (51) is connected to the i-th element amplifier, and the output connector (11t) is connected to a detector (not shown), which is a general-purpose power measuring instrument. .

Next, its operation will be explained. During normal use of the array antenna (5), the inspection waveguide (12) is removed from its radiation surface using a metal fitting (14). When you need to check the output, use the waveguide bag for inspection! (12) is attached as shown in the figure using the metal fittings (14).

Then, when the transmitter is operated, the electromagnetic waves that are amplified by the element amplifier and reach the opening of the element antenna (51) are transmitted to the waveguide line (101) in the inspection waveguide (12) opposite thereto. incident.

There is a radio wave absorber (15) on the E side wall of the waveguide line (1 (1))
is installed, the incident electromagnetic wave' gradually attenuates as it propagates in the direction of the arrow, passes through the ridge waveguide section and the pseudo TEM line section, and then reaches the output connector (111).
reach. Output connector (ll
The amount of attenuation determined by the shape of the radio wave absorber (14) is set in order to keep the input power below the maximum input power of the general purpose measuring instrument for power measurement, which is the detector connected to i), but the heat generated in this part is dissipated. For this purpose, radiation fins (13) are provided on the E-plane wall of the waveguide line.

In addition, in the above embodiment, the radio wave absorber (15) and the radiation fin (13) were provided, but the output of the element amplifier,
If these are not necessarily necessary due to differences in inspection methods, etc., they may be omitted.

Further, in the above embodiment, the case of a waveguide array antenna was explained, but as shown in FIG. 4, it is also possible to apply the output inspection of other types of active array antennas such as a dipole array antenna. .

That is, FIG. 4 is a perspective view showing a schematic configuration of another embodiment of the present invention. In FIG. 1, (19) is a dipole array antenna, each element antenna is constituted by a dipole, and the inspection waveguide device I (12) is a space in which electromagnetic waves radiated from each element antenna of the dipole array antenna (19) is propagated, which is separated by the conductive partition wall 1, and an inspection dipole (20) that is coupled to this electromagnetic wave and connected thereto. It consists of an output connector (21).

[Effects of the Invention] As described above, according to the present invention, since the single-inspection waveguide device is detachably attached to the active array antenna radiation surface, it can be used only when one inspection is necessary, and the array It is possible to prevent the deterioration of basic performance, which is a problem in the method of incorporating the antenna device itself, and also has the effect that the entire device can be constructed at a low cost.

[Brief explanation of drawings]

FIG. 1 is a perspective view showing an embodiment of the present invention, FIG. 2 is a vertical sectional view showing the internal structure of a waveguide line that is a part of this embodiment, and FIG. 3 is a plan sectional view thereof. FIG. 4 is a perspective view showing a schematic configuration of another embodiment of the present invention, FIG. 5 is a block diagram showing an example of a conventional active array antenna transmission power inspection device, and FIG. 6 is another conventional example. FIG. FIG. 7 is a perspective view showing a case where the element antenna constitutes an array antenna. (5) is an array antenna, (5□)(5□)...(55
) is the element antenna, (101) (to, )...(1
0,) is a waveguide line, (11□)(11□)...(1
1,) is the output connector, (12) is the inspection waveguide device, (
13) is a heat dissipation fin, (14) is a mounting bracket, (15)
) is a radio wave absorber, (18 layers) (18t-z) is a conductor partition, (19) is a dipole array antenna, (20) is a dipole for inspection, and (21) is an output connector. The same reference numerals in the drawings indicate the same or corresponding parts.

Claims (4)

[Claims] (1) On the radiation surface of an active array antenna consisting of a plurality of element antennas arranged, one end faces each of the element antennas, and an output connector is provided at the other end, and each is separated by a conductor partition. A transmission power inspection device for an active array antenna, characterized in that an inspection waveguide device consisting of a plurality of waveguide lines is detachably attached, and an inspection output is taken out from the output connector. (2) The inspection waveguide device is an active array antenna according to claim 1, wherein the inspection waveguide device is provided with a radiation fin on the outside and a radio wave absorber for attenuation in each waveguide line inside. transmission power inspection device. (3) Each of the above-mentioned element antennas is a fan-shaped horn, the above-mentioned waveguide line is equipped with a ridge waveguide section that converts electromagnetic waves in TE mode into electromagnetic waves in TEM mode, and the above-mentioned output connector is for coaxial lines. Claim 1 which is a connector
Or the transmission power inspection device for an active array antenna according to item 2. (4) Each of the above-mentioned element antennas is a dipole antenna element, and each of the above-mentioned waveguide lines is provided with a space for propagating electromagnetic waves from each of these dipole antenna elements, and an inspection dipole that couples to this electromagnetic wave. 2. The transmission power inspection device for an active array antenna according to claim 1, wherein the output connector is connected to each of the inspection dipoles.