JP4021600B2 - Active antenna - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an active antenna in which an antenna element and a semiconductor device are integrated, and in particular, an information transmission device from a moving body having an electronic tracking function, a multi-beam or spatially beamable satellite broadcast receiving antenna, Or, it is used for a transmission / reception antenna for a satellite.
[0002]
[Prior art]
4 and 5 are diagrams showing the structure of a conventional active antenna. In each figure, (a) and (b) show a side sectional view and a plan view seen from above of each active antenna structure. The first conventional example is an example in which a MMIC (Monolithic Microwave Integrated Circuit) amplifier circuit is mounted on a microstrip-fed slot antenna (reference: Shinseikai '99 Society Conference C-2-14). As shown in FIG. 4, the slot antenna 45 is fed by electromagnetic coupling from a microstrip line composed of a strip conductor 42, a dielectric substrate 43 and a ground 44 connected to the input / output side of the MMIC amplifier 41. ing. A dielectric substrate 46 is laminated in order to increase the radiation efficiency of the antenna. In this structure, since the ground surface of the microstrip line is a slot antenna, the amplifier circuit and the antenna surface are integrated to form an extremely thin active antenna.
[0003]
The second conventional example is an example in which an MMIC amplifier circuit 51 is mounted on an electromagnetically coupled microstrip antenna using a triplate line (reference: Shinseikai '99 Society Conference B-1-109). As shown in FIG. 5, the triplate line for feeding power to the antenna is composed of a strip conductor 52, a dielectric rest substrate 53 and grounds 54 and 59, and a metal patch 56 and a dielectric substrate 57 via a slot 55. In addition, power is supplied to the antenna by electromagnetically coupling to a microstrip patch antenna 56 composed of the ground plane 54.
[0004]
Further, in order to suppress the parallel plate mode (unnecessary mode) generated in the slot portion, the two ground plane surfaces are connected using via holes 58. Also in this structure, a very thin active antenna can be configured by integrating the MMIC, and in the case of a transmission amplifier, a heat dissipation mechanism can also be disposed on the ground plane.
[0005]
[Problems to be solved by the invention]
In the first conventional example (see FIG. 4), the operation is unstable because the amplifier is not included in the case. In the case of a transmitting active antenna, the heat dissipation mechanism must be disposed on the ground plane of the amplifier circuit. However, in this structure, since the antenna surface is on the same plane as the ground surface of the microstrip line, there is a problem that the heat dissipation mechanism cannot be arranged on this surface.
In the second conventional example (see FIG. 5), a heat dissipation mechanism can be arranged on the ground surface. However, since the antenna is formed of a multilayer substrate as in the first conventional example, the amplifier circuit and the antenna can be easily arranged. There is a problem that it cannot be integrated. In addition, there is a problem that via holes must be manufactured in the multilayer substrate in order to suppress the parallel plate mode, and in the case of arranging as an array on a plane, a complicated process is required for manufacturing and costs are increased.
Accordingly, an object of the present invention is to provide a low-cost active antenna that can be obtained with high accuracy by simple adjustment even when the frequency is high.
[0006]
[Means for Solving the Problems]
In order to achieve this object, an active antenna of the present invention is an active antenna that amplifies a predetermined high-frequency signal and radiates it to space, and has an input terminal for inputting the high-frequency signal, and a high-frequency signal output from the input terminal. A microstrip line for feeding for propagating a signal, a first microstrip line for propagating electromagnetically coupled high-frequency signals propagating through the microstrip line for feeding, and propagating through the first microstrip line An amplifier for amplifying a high-frequency signal to be transmitted; a second microstrip line for propagating the high-frequency signal amplified by the amplifier; the input terminal and the feeding microstrip line; and the first microstrip line. , The amplifier and the second microstrip line are physically connected A metal plate having grooves for holding the first microstrip line, the amplifier and the second microstrip line, and a high frequency signal propagating through the second microstrip line. A metal plate with a radiating slot for radiating into the space; and a first dielectric substrate provided on a surface on the electromagnetic wave radiation side of the metal plate with the radiating slot, wherein the power supply microstrip line includes the input A first strip conductor connected to a terminal, the metal plate, and a second dielectric substrate provided between the first strip conductor and the metal plate; The line includes a second strip conductor connected to the input portion of the amplifier, the metal plate, and the second strip conductor and the metal plate. The second microstrip line includes a third strip conductor connected to the output of the amplifier, the metal plate, and the third strip conductor. The power supply microstrip comprising a fourth dielectric substrate provided between the metal plate and the metal plate extending in a direction substantially orthogonal to the second microstrip line. A power feeding slot for propagating a high-frequency signal propagating through the line to the first microstrip line by electromagnetic coupling, and the metal plate with the slot for radiation is a high-frequency signal propagating through the second microstrip line It has a radiation slot for radiating to a space by electromagnetic coupling .
In the active antenna of the present invention, a distance between the third strip conductor and the metal plate with a slot for radiation is a position where at least the third strip conductor and the slot for radiation intersect spatially. Thus, the distance between the amplifier and the metal plate with the slot for radiation is shorter than the distance.
Furthermore, it can also be characterized as an active array antenna having a structure in which active antennas are arranged on a metal flat plate .
[0007]
DETAILED DESCRIPTION OF THE INVENTION
Active array antennas for material transmission devices for mobile objects and satellites must be as small and light as possible and have good cost performance, and must be able to be manufactured with high precision even at higher frequencies. In the present invention, a rectangular groove is formed on a planar metal plate, and an amplification turning circuit is mounted therein. Simply by mounting a metal plate with a slot on the upper side of the groove and a feeder board on the lower side, the feeder line and slot antenna element can be connected to the amplifier circuit by electromagnetic coupling, so it can be easily integrated. it can. Further, the parallel plate mode (unnecessary mode) can be suppressed by appropriately selecting the distance between the side walls of the amplifier circuit. Furthermore, the antenna characteristics can be obtained with high accuracy by appropriately selecting the length of the output line of the amplifier circuit and the position of the slot.
[0008]
【Example】
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 shows an example of an active antenna structure according to the first embodiment of the present invention. Fig. 1 (a) is an exploded side view of the active antenna, showing the radiating antenna, amplifier circuit, and feed line from the top, respectively, and Fig. 1 (b) shows the integrated side FIG. 1 (c) is a cross-sectional view, and FIG. 1 (c) is a plan view seen from above the active antenna with the radiating antenna portion removed. However, the relative position of the radiation slot 7 of the metal plate 8 is indicated.
FIG. 1 shows an example of a structure in which a grooved metal plate (ground) 6 for fixing an amplifier circuit, a feed microstrip line 15 composed of a strip conductor 10, a dielectric substrate 11, and a ground 6, and an electromagnetic wave in the amplifier circuit. Power supply slot 12 opened in metal plate 6 for coupling, MMIC transmission power amplifier 1 for amplifying power, strip conductor 4 and alumina substrate 5 used for amplifier input line, and ground 6 Microstrip line 13, microstrip line 14 composed of strip conductor 2 and alumina substrate 3 and ground 6 used in the output line of the amplifier, metal plate 8 with a slot 7 for radiating electromagnetic waves, and slot And a dielectric substrate 9 for making the length L shorter than the interval W between the side walls of the amplifier circuit.
[0009]
The signal flow will be described below. The high-frequency signal input from the input terminal T is transmitted through the feeding microstrip line 15 and is electromagnetically coupled to the input-side microstrip line 13 via the feeding slot 12 opened in the metal plate. The combined high frequency signal is transmitted through the microstrip line 13 and input to the MMIC amplifier 1. The signal amplified by the amplifier 1 is transmitted through the microstrip line 14 on the output side, and is electromagnetically coupled to the radiation slot 7 and radiated to the space. This is an example of an active antenna using an MMIC chip power amplifier.
[0010]
As the output line substrate 3 of the amplifier circuit, an alumina substrate is usually used. A high dielectric constant material such as an alumina substrate is rarely used in an antenna circuit because electromagnetic wave energy is confined in the substrate and radiation efficiency deteriorates. However, when the height is very small like an MMIC amplifier, the radiating slot surface can be brought close to the strip surface of the output line, so that the electromagnetic wave transmitted through the microstrip line 14 composed of the high dielectric constant substrate can be reduced. It can be efficiently coupled to the slot. Further, the parallel plate mode (unnecessary mode) can be suppressed by selecting the interval W between the groove sidewalls (see FIG. 1C) so as to transmit only the dominant mode of the microstrip line.
[0011]
An example of the structure of an active antenna according to a second embodiment of the present invention is shown in FIG. 2, the same components as those in FIG. 1 are denoted by the same reference numerals, and FIG. 2 (a) is an exploded side view of the active antenna as in FIG. Fig. 2 (b) is a side sectional view showing the amplifier circuit portion and the feed line portion in an integrated manner. Fig. 2 (c) is a plan view of the active antenna from which the radiation antenna portion is removed. Show. However, the relative position of the radiation slot 7 of the metal plate 8 is indicated.
An example of the structure of the active antenna according to the second embodiment is a feed microstrip line 15 comprising a grooved metal plate (ground) 6 for fixing an amplifier circuit, a strip conductor 10, a dielectric substrate 11 and a ground 6. A power supply slot 12 opened in a metal plate 6 for electromagnetic coupling with an amplifier circuit, a package-type transmission power amplifier 1 for amplifying power, a strip conductor 4 used in an amplifier input line, and an alumina substrate 5 and the microslip line 13 composed of the ground 6, the strip conductor 2 used in the output line of the amplifier, the microstrip line 14 composed of the alumina substrate 3 and the ground 6, and the strip conductor 16 and the microstrip line 14. A micros consisting of a low dielectric constant substrate 17 and a ground 6 that are thicker than the substrate. A trip line 18, a metal plate 8 with a radiation slot 7 that radiates electromagnetic waves, and a dielectric substrate 9 for making the slot length L shorter than the interval W between the side walls of the amplifier circuit.
[0012]
The signal flow will be described below in the second embodiment. The high-frequency signal input from the input terminal T is electromagnetically coupled to the input-side microstrip line 13 through the power supply microstrip line 15 and the power supply slot 12 opened in the metal plate. The combined high frequency signal is transmitted through the microstrip line 13 and input to the package type amplifier 1. The amplified signal is converted from the microstrip line 14 on the output side to the microstrip line 18, and is electromagnetically coupled to the radiation slot 7 and radiated to the space. This is an example of an active antenna using a package type power amplifier. The package type amplifier is thicker than the MMIC amplifier, and the radiation slot surface cannot be brought closer to the strip surface of the microstrip line 14 on the output side than the antenna of the first embodiment, so that the coupling efficiency is not so good. .
[0013]
Therefore, the thickness of the substrate is converted from the microstrip line 14 to the microstrip line 18 so that the strip surface can be brought close to the radiation slot surface. With such a configuration, even when the radiation slot surface cannot be brought close to the strip surface of the output line due to the thickness of the amplifier, the radiation slot surface can be efficiently coupled to the radiation slot.
[0014]
FIG. 3 shows a structural example of an active antenna according to a third embodiment of the present invention. In FIG. 3, (a) is a side sectional view of this structural example, and (b) is a plan view thereof. This structural example is shown in the metal plate 30 for fixing the amplifier circuit with grooves arranged in an array on a two-dimensional plane, and the first or second embodiment arranged in the groove. An amplifier 31, a metal plate 39 with a slot array 32 for radiating electromagnetic waves from each amplifier circuit, a dielectric substrate 33 for making the slot length L shorter than the interval W between the side walls of the amplifier circuit, and strip conductors 34, a dielectric substrate 35, and a ground 38, and a power supply microstrip line 37 arranged in an array, and a power supply slot opened in an array on the metal plate 30 for electromagnetic coupling with an amplifier circuit. Consists of 36. This is an example of operating as a 16-element planar active array antenna in which electromagnetic waves are radiated from each slot by electromagnetic coupling from an amplifier circuit disposed in each groove.
[0015]
As described above, the amplifier circuit is fixed in the groove dug in the metal plate, the slotted metal plate is arranged on the upper side of the amplifier circuit, and the feeder board is arranged on the lower side, so that the amplifier circuit and the antenna can be easily arranged. Can be integrated. The heat dissipation mechanism for transmission can be easily attached to the back side of the ground plane 30. Further, by appropriately taking the size of the groove, it is possible to easily suppress the occurrence of the parallel plate mode (unnecessary mode) caused by the discontinuity of the slots. Furthermore, the antenna characteristics can be obtained with high accuracy by appropriately selecting the length of the output line of the amplifier circuit and the position of the slot. The first embodiment, the second embodiment, and the third embodiment are the case of the active antenna for transmission, but in the case of reception, the amplifier may be configured in the reverse direction.
Although the embodiments of the present invention have been described above with reference to some examples, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the invention defined in the claims. It will be obvious.
[0016]
【The invention's effect】
According to the active antenna of the present invention, since the amplifier circuit and the antenna circuit can be easily integrated and mounted, the manufacturing process of the active array antenna is simplified and a low-cost active array antenna can be realized. In addition, since the structure is simple, the antenna characteristics can be obtained with high accuracy by selecting the length of the feed line and the position of the slot appropriately, and the distance between the metal grooves in which the amplifier circuits are arranged can be appropriately set. It is possible to suppress the occurrence of the parallel plate mode, which has been a problem in the prior art.
[Brief description of the drawings]
FIG. 1 is a structural diagram according to a first embodiment of the active antenna of the present invention. FIG. 2 is a structural diagram according to a second embodiment of the active antenna of the present invention. FIG. 4 is a diagram showing a configuration of a first conventional example of an active antenna. FIG. 5 is a diagram showing a configuration of a second conventional example of an active antenna.
1,31,41,51 Power amplifier for transmission
2,4,10,16,34,42,52 Strip conductor
3,5 Alumina substrate
6,30 grooved metal plate
7,45,55 Radiation slot
8,54 Radiation slotted metal plate
3,5,9,11,17,33,35,43,46,53,57 Dielectric substrate
12,36 Power supply slot
13,14,15,18,37 Microstrip line
32 Slot array for radiation
38 Substrate with microstrip lines for power feeding arranged in an array
39 Metal plate with slot array for radiation
56 Metal patch for radiation
58 Beer Hall
44, 59 Metal plate for ground

Claims (3)

An active antenna that amplifies a predetermined high-frequency signal and radiates it to space,
An input terminal for inputting the high-frequency signal;
A power supply microstrip line for propagating a high-frequency signal output from the input terminal;
A first microstrip line for electromagnetically coupling a high frequency signal propagating through the feeding microstrip line;
An amplifier for amplifying a high-frequency signal propagating through the first microstrip line;
A second microstrip line for propagating a high-frequency signal amplified by the amplifier;
The input terminal and the feeding microstrip line are physically separated from the first microstrip line, the amplifier, and the second microstrip line, and the first microstrip line and the amplifier are separated from each other. And a metal plate in which a groove for holding the second microstrip line is formed,
A metal plate with a slot for radiation for radiating a high-frequency signal propagating through the second microstrip line into space;
A first dielectric substrate provided on the electromagnetic wave radiation side surface of the metal plate with slots for radiation,
The power supply microstrip line includes a first strip conductor connected to the input terminal, the metal plate, and a second dielectric substrate provided between the first strip conductor and the metal plate. Has been
The first microstrip line includes a second strip conductor connected to the input section of the amplifier, the metal plate, and a third dielectric provided between the second strip conductor and the metal plate. Consists of a substrate,
The second microstrip line includes a third strip conductor connected to the output portion of the amplifier, the metal plate, and a fourth dielectric provided between the third strip conductor and the metal plate. Consists of a substrate,
The metal plate has a feeding slot for propagating a high-frequency signal propagating through the feeding microstrip line to the first microstrip line by electromagnetic coupling,
The radiating slotted metal plate extends in a direction substantially orthogonal to the second microstrip line and radiates a high-frequency signal propagating through the second microstrip line to space by electromagnetic coupling. An active antenna having a radiating slot . 2. The active antenna according to claim 1, wherein a distance between the third strip conductor and the metal plate with a slot for radiation is a position where at least the third strip conductor and the slot for radiation intersect spatially. 3. The active antenna is configured to be shorter than a distance between the amplifier and the metal plate with a slot for radiation . An active array antenna having a structure in which the active antenna according to claim 1 or 2 is arrayed on a metal flat plate.

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