JP3625155B2 - Multidirectional antenna - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a multidirectional antenna that can receive radio waves coming from different directions.
[0002]
[Prior art]
In general, an omnidirectional antenna may be used for an antenna mounted on a moving body such as a vehicle, for example, an antenna for receiving a television broadcast so as to be able to receive radio waves coming from any direction. . As this omnidirectional antenna, for example, there is an alhode loop antenna, a clover leaf antenna, and the like.
[0003]
[Problems to be solved by the invention]
However, the alhode loop antenna and the clover leaf antenna are both large. Therefore, for example, when these antennas are used for each of the VHF band and the UHF band, the number of parts is increased, the manufacturing is troublesome, and the size is increased. Furthermore, the omnidirectional antenna easily receives unnecessary radio waves, and when used for receiving television broadcasts, a ghost is easily generated on the reception screen.
[0004]
An object of the present invention is to provide a multidirectional antenna that is small in size and can satisfactorily receive radio waves coming from any direction.
[0005]
[Means for Solving the Problems]
The first aspect of the present invention has a flat main body, and the first and second Yagi antennas are arranged to receive radio waves arriving from opposite directions in the first plane in the main body. Each of the first and second Yagi antennas has a radiator and a reflector, and the radiators of the first and second Yagi antennas are formed in an eight-shape, and the first and second The radiators of the first and second Yagi antennas are arranged so that the tips of the Yagi antennas are close to each other, and the first and second Yagi antennas are disposed between the radiators of the first and second Yagi antennas. The reflector of the first Yagi antenna has a curved portion that is convexly curved on the radiator side of the first Yagi antenna, and the reflector of the second Yagi antenna. The reflector has a curved portion that is convexly curved toward the radiator side of the second Yagi antenna, In the second plane at a height position different from the plane, the third and fourth radio waves are received so as to be orthogonal to the first and second Yagi antennas and from opposite directions. The Yagi antenna is disposed, the third and fourth Yagi antennas both have a radiator and a reflector, and the radiators of the third and fourth Yagi antennas are formed in an eight-letter shape. The radiators of the third and fourth Yagi antennas are arranged so that the tips of the third and fourth Yagi antennas are close to each other, and between the radiators of the third and fourth Yagi antennas. , The reflectors of the third and fourth Yagi antennas are arranged, the reflector of the third Yagi antenna has a curved portion that is convexly curved on the radiator side of the third Yagi antenna, The reflector of No. 4 Yagi antenna was convexly curved toward the radiator side of the No. 4 Yagi antenna. It has a curved portion, the radiator of the first and second Yagi Antenna intersects with radiator and part of the third and fourth Yagi Antenna.
[0006]
In addition, each of the first to fourth Yagi antennas can be connected to a matching unit. In this case, the matching unit of the first to fourth Yagi-shaped antennas has selection means for selecting the output of each matching unit of the adjacent Yagi-shaped antennas alone or by combining the outputs. First and second output terminals are provided. In each matching unit, the first output terminal is connected to a reference potential, and the second output terminal is connected to the selection means.
[0007]
According to a second aspect of the present invention, four or more even-numbered rod antennas arranged radially on substantially the same plane, and two rod antennas derived from the inner end of each rod antenna, a total of the even-numbered rod antennas. A total of V-shaped antennas having the same number as the even-numbered antennas, each of which is composed of two rod antennas adjacent to each other. Are V-shaped antennas, which are feed terminals derived from two adjacent rod antennas, respectively, and matching units provided in the same number as the even number, and the feed terminals of each V-shaped antenna And selecting means for selecting the outputs of these matching devices alone or the combined output of the matching devices of two adjacent V-shaped antennas, and only the selected matching device. Energizing means to energize and , It has been provided.
[0008]
A third aspect of the present invention is a plurality of dipole antennas configured by disposing two rod antennas along each of a plurality of straight lines radially arranged on substantially the same plane, and these dipole antennas A plurality of dipole antennas each having two pairs of feeding terminals derived therefrom, and a matching unit provided in the same number as the rod antennas, to which the feeding terminals of the dipole antennas are respectively connected, and from the same dipole antenna The derived feeding terminals are connected in opposite phases, and a matching unit that uses the same dipole antenna as two dipole antennas whose directional characteristics are opposite to each other and an output of these matching units alone are selected or directed. Selecting means for selecting a combined output of two dipole antenna matching units adjacent to each other, and a matching unit of the selected matching unit And a biasing means for urging the, it is provided.
[0009]
In the second and third aspects, each of the matching units has first and second output terminals. In each matching unit, the first output terminal is connected to a reference potential, and the second output terminal is connected to the reference potential. It can be connected to the selection means.
[0010]
A fourth aspect of the present invention has a flat main body, and the first and second Yagi antennas are arranged so as to receive radio waves coming from opposite directions in the first plane in the main body. Each of the first and second Yagi antennas has a radiator and a reflector, and the radiators of the first and second Yagi antennas are formed in an eight-shape, and the first and second The radiators of the first and second Yagi antennas are arranged so that the tips of the Yagi antennas are close to each other, and the first and second Yagi antennas are disposed between the radiators of the first and second Yagi antennas. The reflector of the first Yagi antenna has a curved portion that is convexly curved on the radiator side of the first Yagi antenna, and the reflector of the second Yagi antenna. The reflector has a curved portion that is convexly curved toward the radiator side of the second Yagi antenna, In the second plane at a height position different from the plane, the third and fourth radio waves are received so as to be orthogonal to the first and second Yagi antennas and from opposite directions. The Yagi antenna is disposed, the third and fourth Yagi antennas both have a radiator and a reflector, and the radiators of the third and fourth Yagi antennas are formed in an eight-letter shape. The radiators of the third and fourth Yagi antennas are arranged so that the tips of the third and fourth Yagi antennas are close to each other, and between the radiators of the third and fourth Yagi antennas. , The reflectors of the third and fourth Yagi antennas are arranged, the reflector of the third Yagi antenna has a curved portion that is convexly curved on the radiator side of the third Yagi antenna, The reflector of No. 4 Yagi antenna was convexly curved toward the radiator side of the No. 4 Yagi antenna. Has a curved portion, the radiator of the first and second Yagi type antenna intersects with radiator and part of the third and fourth Yagi Antenna,
The first to fourth Yagi antennas are respectively connected to a matching device for Yagi antennas, and the first to fourth Yagi antennas are arranged in a third plane parallel to the first and second planes in the main body. 4 rod antennas arranged radially along the antenna, and a total of 8 feed terminals derived from the inner end of each rod antenna, and 2 adjacent The rod antennas constitute a total of four V-shaped antennas, and the feed terminals of these V-shaped antennas are feed terminals derived one by one from two adjacent rod antennas. Each of the character-shaped antennas has a feeding terminal connected to a V-shaped antenna matching unit, and the corresponding Yagi-shaped antenna matching unit and the V-shaped first to fourth Yagi antennas and the V-shaped antennas. Antenna matching Are combined, and the combined output of these matching units is selected alone, or the matching unit for the V-shaped antenna of the two adjacent V-shaped antennas and the corresponding Yagi-shaped antenna of the two Yagi-shaped antennas. An energizing means is provided for selecting the combined output of the matching unit for the V-shaped antenna by the selecting unit and energizing only the matching unit for the V-shaped antenna that produces the selected output.
[0011]
A fifth aspect of the present invention has a flat main body, and the first and second Yagi antennas are arranged so as to receive radio waves coming from opposite directions in the first plane in the main body. Each of the first and second Yagi antennas has a radiator and a reflector, and the radiators of the first and second Yagi antennas are formed in an eight-shape, and the first and second The radiators of the first and second Yagi antennas are arranged so that the tips of the Yagi antennas are close to each other, and the first and second Yagi antennas are disposed between the radiators of the first and second Yagi antennas. The reflector of the first Yagi antenna has a curved portion that is convexly curved on the radiator side of the first Yagi antenna, and the reflector of the second Yagi antenna. The reflector has a curved portion that is convexly curved toward the radiator side of the second Yagi antenna, In the second plane at a height position different from the plane, the third and fourth radio waves are received so as to be orthogonal to the first and second Yagi antennas and from opposite directions. The Yagi antenna is disposed, the third and fourth Yagi antennas both have a radiator and a reflector, and the radiators of the third and fourth Yagi antennas are formed in an eight-letter shape. The radiators of the third and fourth Yagi antennas are arranged so that the tips of the third and fourth Yagi antennas are close to each other, and between the radiators of the third and fourth Yagi antennas. , The reflectors of the third and fourth Yagi antennas are arranged, the reflector of the third Yagi antenna has a curved portion that is convexly curved on the radiator side of the third Yagi antenna, The reflector of No. 4 Yagi antenna was convexly curved toward the radiator side of the No. 4 Yagi antenna. The radiators of the first and second Yagi antennas have curved portions and partially intersect with the radiators of the third and fourth Yagi antennas, and the first to fourth Yagi antennas are The first and second Yagi antennas and the third and fourth Yagi antennas are respectively connected to a matching unit for Yagi antennas and in a third plane parallel to the first and second planes in the main body. In total, two dipole antennas are formed by two rod antennas located on the same straight line, and two pairs of feeding terminals are provided from each of these dipole antennas. A total of four dipole antenna matching units connected to the pair of feeding terminals are provided, and the dipole antenna matching units are derived from the same dipole antenna. The connected feed terminals are connected in opposite phases, and the same dipole antenna is used as two dipole antennas whose directivity characteristics are opposite to each other, and the first to fourth Yagi antennas The outputs of the matching unit for the Yagi antenna and the matching unit for the dipole antenna, which have the corresponding directivity among the dipole antennas, are combined, and the combined output of these matching units is selected independently or adjacent to each other. The selection means selects the combined output of the two dipole antenna matching units having directivity and the two Yagi antenna matching units corresponding to the two dipole antennas, and generates the selected output. A biasing means for biasing only the matching unit for the dipole antenna is provided.
[0012]
Each selection unit described above can be controlled by a selection control signal supplied from the control unit. Alternatively, the selecting means can be constituted by an amplifying means that takes an energized state and a non-energized state.
[0025]
DETAILED DESCRIPTION OF THE INVENTION
The multi-frequency band multi-directional antenna of one embodiment of the present invention is for receiving television broadcast signals in, for example, the UHF band and the VHF band, and has a main body 2 as shown in FIG. The main body 2 is a flat one formed in an approximately octagonal shape. As shown in an enlarged view in FIG. 1, the main body 2 has convex edge portions 4 a to 4 d that are slightly convex at intervals of 90 degrees. Furthermore, the main body 2 has concave edge portions 6a to 6d that are concavely curved so as to connect the convex edge portions 4a to 4d.
[0026]
In the main body 2, a plurality of sets, for example, four sets of first frequency bands, for example, UHF band Yagi antennas 8 a to 8 d are arranged. Of these Yagi-shaped antennas 8a to 8d, two Yagi-shaped antennas 8a and 8c are arranged along a straight line 10a that connects the two protruding edge portions 4a and 4c facing each other on one plane, for example, a horizontal plane. . The remaining two Yagi antennas 8b and 8d are arranged along a straight line 10b orthogonal to the straight line 10a on a horizontal plane at a height position different from the horizontal plane, for example, a lower position. This state is schematically shown in FIG.
[0027]
As shown in FIG. 1, the Yagi antennas 8a and 8c have waveguides 12a and 12c in the main body 2 in the vicinity of the convex edges 4a and 4c. The directors 12a and 12c are both formed in a flat plate shape of the same size, and are disposed on the straight line 10a so as to be orthogonal to the surface thereof.
[0028]
Radiators 14a and 14c are arranged at positions further inside than the directors 12a and 12c. These radiators 14a have feeding points on both sides of the straight line 10a. The radiator 14a extends outward from each of the feeding points so as to be substantially orthogonal to the straight line 10a, and is curved inward in the vicinity of the concave edges 6a and 6d. It is extended to the vicinity of the convex edge parts 4b and 4d along. The radiator 14c is similarly configured. That is, the radiators 14a and 14c are substantially in the shape of an eight. By curving in this way, each radiator 14a, 14c ensures a predetermined length even within the narrow main body 2. These radiators 14a and 14c are also flat, and the surfaces of the directors 12a and 12c are arranged horizontally, whereas the surfaces thereof are arranged vertically. However, as shown in FIG. 2 (b), the upper edge is at the same height as the directors 12a and 12c. The reason why the directors 12a and 12c are arranged in such a manner that their surfaces are vertical is to facilitate bending of the directors 12a and 12c.
[0029]
Reflectors 16a and 16c are disposed further inside than the radiators 14a and 14c. These reflectors 16a have straight portions on both sides of the straight line 10a, and have curved portions that are curved from the inward ends of the straight portions toward the waveguide 12a. The reflector 16c is similarly configured. As described above, since the central portion is curved toward the waveguides 12 a and 12 c, a predetermined length can be secured even in the narrow main body 2. These reflectors 16a and 16c are also formed in a flat plate shape, and are arranged at the same height as the waveguides 12a and 12c, as shown in FIG.
[0030]
Similarly to the Yagi antennas 8a and 8c, the Yagi antennas 8b and 8d also have directors 12b and 12d, radiators 14b and 14d, and reflectors 16b and 16d. However, they are arranged in a non-contact state so as to be orthogonal to the Yagi antennas 8a and 8c, and as shown in FIG. 3, they are arranged at positions below the Yagi antennas 8a and 8c.
[0031]
In this case, as shown in FIG. 1A, the radiators 14a and 14b, 14b and 14c, 14c and 14d, and 14d and 14a partially cross each other in a non-contact state. Similarly, the reflector 16a partially intersects the reflectors 16b and 16d in a non-contact state, the reflector 16b partially intersects with the reflectors 16a and 16c, and the reflector 16c is a reflector. 16b and 16d partially intersect with each other in a non-contact state, and the reflector 16d 16a, 16c And partially intersects with no contact. Further, the reflector 16a partially intersects with the radiators 14b and 14d and the directors 12b and 12d in a non-contact state, and the reflector 16b does not contact the radiators 14a and 14c and the directors 12a and 12c. The reflector 16c partially intersects with the radiators 14b and 14d and the waveguides 12b and 12d in a non-contact state, and the reflector 16d is non-contacted with the radiators 14c and 14a and the waveguides 12c and 12a. Partially intersect in contact.
[0032]
In this way, four sets of Yagi antennas 8a to 8d are installed in the main body 2 in a narrow space. However, since the Yagi antennas 8a, 8c and 8b, 8d are arranged at different heights, the Yagi antennas 8a to 8d do not interfere with each other, and the characteristics are not greatly disturbed. . Furthermore, since adjacent Yagi antennas, for example, Yagi antennas 8a and 8b, are provided at different heights, adjacent Yagi antennas hardly interfere with each other.
[0033]
Further, since the Yagi antennas 8a to 8d are arranged as described above, these Yagi antennas mainly receive radio waves arriving from different directions, for example, directions of the convex edges 4a to 4d. Each Yagi antenna 8a to 8d constitutes one UHF band combination antenna.
[0034]
In the main body 2, four or more even numbers, for example, four rod antennas 18 a to 18 d are arranged. These rod antennas 18a to 18d are arranged in one horizontal plane between the surface where the Yagi antennas 8a and 8c are provided and the surface where the Yagi antennas 8b and 8d are provided. Rod antennas 18a and 18c are arranged along a straight line 10a in this plane. Rod antennas 18b and 18d are arranged along a straight line 10b orthogonal to the straight line 10a. These rod antennas 18a to 18d can extend outward from the respective convex edges 4a to 4d as shown in FIG.
[0035]
Using these rod antennas 18a to 18d, the same number of V-shaped antennas as the number of rod antennas is configured. That is, two feeding terminals 20a-1 and 20a-2 are provided at the inner end of the rod antenna 18a as shown in FIGS. 5 (a) and 5 (b). Similarly, two power supply terminals 20b-1, 20b-2, 20c-1, 20c-2, 20d-1, and 20d-2 are also provided for the other rod antennas 18b to 18d. As shown in FIG. 5A, power is supplied to the rod antennas 18a and 18b using one power supply terminal 20a-1 and 20b-2 of the adjacent rod antennas 18a and 18b. Similarly, power is supplied to the rod antennas 18b and 18c by using one power supply terminal 20b-1 and 20c-2 of each of the adjacent rod antennas 18b and 18c. Hereinafter, similarly, power is supplied to the rod antennas 18c and 18d, and power is supplied to the rod antennas 18d and 18a.
[0036]
Alternatively, as shown in FIG. 5B, one dipole antenna is constituted by rod antennas, for example, rod antennas 18a and 18c, which are located on the same straight line, and another dipole antenna is constituted by rod antennas 18b and 18d. .
[0037]
Since each of the rod antennas 18a to 18d is provided with two power supply terminals, two pairs of power supply terminals are derived from one dipole antenna. For example, in the case of a dipole antenna composed of rod antennas 18a and 18c, there are power supply terminals 20a-1 and 20c-1 and power supply terminals 20a-2 and 20c-2. By using these two pairs of feeding terminals, one dipole antenna can be used as two dipole antennas having opposite directivity characteristics. In the end, even when each rod antenna is used as a dipole antenna, it can be equivalent to using the same number of dipole antennas as rod antennas. These rod antennas 18a to 18d constitute one combination antenna for the VHF band.
[0038]
Hereinafter, the four V-shaped antennas or dipole antennas constituted by the rod antennas 18a to 18d are denoted as VHF band antennas 22a to 22d. The Yagi antennas 8a to 8d are denoted as UHF band antennas 8a to 8d.
[0039]
FIG. 6 shows a reception system using the VHF band antennas 22a to 22d and the UHF band antennas 8a to 8d. The VHF band antenna 22a and the UHF band antenna 8a are connected to the filter 24a. The other VHF band antennas 22b to 22d and UHF band antennas 8b to 8d are also connected to the filters 24b to 24d, respectively.
[0040]
These filters 24a have input terminals 26a and 27a to which the UHF band antenna 8a is connected as shown in FIG. 7, and these input terminals 26a and 27a are connected to a UHF band matching unit 28a. The UHF band matching unit 28a has two output terminals 29a and 30a, and the output terminal 29a is connected to a reference potential, for example, ground. The output terminal 30a is connected to the output terminal 32a via a high-pass filter 31a whose pass band is adjusted so that a UHF band television broadcast signal can pass therethrough.
[0041]
The filter 24a has input terminals 33a and 34a to which the VHF band 22a is connected, and these are connected to the VHF band matching unit 35a. The VHF band matching unit 35a also has two output terminals 36a and 37a. The output terminal 36a is connected to a reference potential, for example, ground. The output terminal 37a is connected to the input side of the low-pass filter 39a via switching means, for example, a unidirectional element, specifically, a PIN diode 38a. The output side of the low-pass filter 39a is connected to the output terminal 32a. The PIN diode 38a has a cathode connected to the output terminal 37a of the matching unit 35a, and an anode connected to the input side of the low-pass filter 39a whose pass band has been adjusted so that a television broadcast signal in the VHF band can be passed. ing. The anode side of the PIN diode 38a is connected to the power supply terminal 41a via the current limiting resistor 40a. A bypass capacitor 42a is connected between the power supply terminal 41a and the ground.
[0042]
Since the other filters 24b to 24d are also configured in the same manner as the filter 24a, detailed description of the configurations of the filters 24b to 24d is omitted. However, the constituent elements of the filters 24b to 24d are indicated by using the reference numerals in which the subscripts indicating the constituent elements of the filter 24a are changed to b to d.
[0043]
As shown in FIG. 8, each of the matching devices 28a to 28d in the filters 24a to 24d has output terminals 29a to 29d and 30a to 30d. The output terminals 29a to 29d are connected to the ground, and the output terminals 30a to 30d are connected to the high-pass filters 31a to 31d. Similarly, in the matching units 35a to 35d, the output terminals 36a to 36d are connected to the ground, and the output terminals 37a to 37d are connected to the PIN diodes 38a to 38d. This is because the phases of the received signals in the UHF band or the VHF band generated at the output terminals 32a to 32d are aligned.
[0044]
When the rod antennas 18a to 18d are used as dipole antennas, 20a− of the pair of output terminals 20a-1 and 20c-1 of two rod antennas arranged on the same straight line, for example, the rod antennas 18a and 18c, When 1 is connected to the input terminal 33a of the matching unit 35a and 20c-1 is connected to the input terminal 34a, 20a-2 is the matching unit of the other pair of output terminals 20a-2 and 20c-2 of the rod antennas 18a and 18c. The input terminal 34c of 35c and 20c-2 are connected to the input terminal 33c of the matching unit 35c.
[0045]
Returning to FIG. 6, the output signals of the filters 24a to 24d are respectively supplied to amplification means, for example, amplifiers 44a to 44d capable of amplifying signals in the VHF band and the UHF band. The output signals of these amplifiers 44a and 44b are supplied to the combiners 46 and 47. The output signals of these synthesizers 46 and 47 are amplified by amplifiers 48 and 49 similar to the amplifiers 44 a to 44 d and synthesized by the synthesizer 50.
[0046]
The output signal of the synthesizer 50 is transmitted to the home via a DC blocking capacitor 52 and a transmission line, for example, a coaxial cable 54, and is supplied to a supply terminal 58 to the television receiver via a DC blocking capacitor 56.
[0047]
In the above-described filters 24a to 24d, when DC power is supplied to the power supply terminals 41a to 41d from the control circuit 60, the PIN diodes 38a to 38d are turned on, and the matching devices 35a to 35d are connected to the low-pass filters 39a to 39d. 39d. Similarly, the amplifiers 44a to 44d operate when DC power is supplied from the control circuit 60. When the DC power is supplied to at least one of the amplifiers 44a and 44b, the amplifier 48 is supplied via the output terminal E of the OR circuit 62 and operates. When the DC power is supplied to at least one of the amplifiers 44c and 44d, the amplifier 49 is supplied with the DC power via the output terminal F of the OR circuit 64 and operates.
[0048]
The control circuit 60 has an output terminal A for the filter 24a and the amplifier 44a, an output terminal B for the filter 24b and the amplifier 44b, an output terminal C for the filter 24c and the amplifier 44c, and an output terminal D for the filter 24d and the amplifier 44d. doing. The control circuit 60 is supplied with DC power from a DC power supply device 61 provided in the home via a high frequency blocking coil 63, a coaxial cable 54, and a high frequency blocking coil 66. A pulse signal is supplied from the directivity control pulse generator 68 through a similar path. The above-described filters 24a to 24d, amplifiers 44a to 44d, synthesizers 46 and 47, amplifiers 48 and 49, OR circuits 62 and 64, synthesizer 50, DC blocking capacitor 52, and control circuit 60 are provided in the main body 2. it can.
[0049]
The directivity control pulse generator 68 includes a power switch 70 and a directivity changeover switch 72 as shown in FIG. 9, and each time the directivity changeover switch 72 is operated, as shown in FIG. A simple pulse signal is supplied to the control circuit 60. On the side of the directivity changeover switch 72, eight light emitting elements on the circumference, for example, LEDs 74a to 74h, are arranged. When the power switch 70 is turned on, the LED 74a is turned on. When the directivity changeover switch 72 is operated, the LED 74a is turned off and the LED 74b is turned on. Hereinafter, similarly, each time the directivity changeover switch 72 is operated, the LEDs to be lit are sequentially switched.
[0050]
For example, when the power switch 70 is turned on at time t1, the control circuit 60 generates a DC power supply at the output terminal A as shown in FIG. As a result, the PIN diode 38a in the filter 24a becomes conductive, and the amplifier 44a operates. At the same time, as shown in FIG. 10E, a DC power supply is generated at the output terminal E of the OR circuit 62, and the amplifier 48 operates.
[0051]
Therefore, signals received by the UHF band antenna 8a and the VHF band antenna 22a are passed through the filter 24a, the amplifier 44a, the combiner 46, the amplifier 48, the combiner 50, the DC blocking capacitor 52, the coaxial cable 54, and the DC blocking capacitor 56. This is supplied to the input terminal 58.
[0052]
When the directivity changeover switch 72 of the directivity control pulse generator 68 is operated at time t2, a pulse signal is generated as shown in FIG. 10 (g), and as shown in FIGS. 10 (a) and 10 (b), DC power is generated at the output terminals A and B of the control circuit 60, the PIN diodes 38a and 38b of the filters 24a and 24b are turned on, and the amplifiers 44a and 44b are operated. At the same time, as shown in FIG. 10E, a DC power supply is also generated at the output terminal E of the OR circuit 62, and the amplifier 48 operates. As a result, the signals received by the UHF band antennas 8a and 8b are amplified by the amplifiers 44a and 44b through the filters 24a and 24b, and synthesized by the synthesizer 46. Similarly, the signals received by the VHF band antennas 22a and 22b are also amplified by the amplifiers 44a and 44b through the filters 24a and 24b, and synthesized by the synthesizer 46. The output of the synthesizer 46 is amplified by the amplifier 48 and supplied to the input terminal 58 via the synthesizer 50, the DC blocking capacitor 52, the coaxial cable 54, and the DC blocking capacitor 56.
[0053]
When the directivity selector switch 72 is operated at time t3, a pulse signal is generated as shown in FIG. 10 (g), and a DC power source is generated only at the output terminal B of the control circuit 60 as shown in FIG. 10 (b). Similarly to the time t1, signals received by the UHF band antenna 8b and the VHF band antenna 22b are amplified by the amplifiers 44b and 48b and supplied to the input terminal 58.
[0054]
When the directivity selector switch 72 is operated at time t4, a pulse signal is generated as shown in FIG. 10 (g), and the output terminals B and C of the control circuit 60 are applied to the control circuit 60 as shown in FIGS. A DC power supply is generated, and signals received by the UHF band antennas 8b and 8c and the VHF band antennas 22b and 22c are supplied to the amplifiers 44b and 44c through the filters 24b and 24c, and are amplified therein. Outputs of these amplifiers 44b and 44c are supplied to amplifiers 48 and 49 via combiners 46 and 47, respectively. Since direct current power is supplied to the output terminals E and F of the OR circuits 62 and 64, the amplifiers 48 and 49 operate, and the output signals of the combiners 46 and 47 are amplified by the amplifiers 48 and 49. The outputs of these amplifiers 48 and 49 are combined by a combiner 50 and supplied to an input terminal 58 via a DC blocking capacitor 52, a coaxial cable 54, and a DC blocking capacitor 56.
[0055]
When the directivity selector switch 72 is operated at time t5, a pulse signal is generated as shown in FIG. 10 (g), and DC power is supplied only to the output terminal C of the control circuit 60 as shown in FIG. 10 (c). The signals received by the UHF band antenna 8 c and the VHF band antenna 22 c are amplified by the amplifier 44 c and supplied to the amplifier 49 via the combiner 47. Since a DC power source is also generated at the output terminal F of the OR circuit 64, the amplifier 49 operates, and the output of the synthesizer 47 is amplified by the amplifier 49, and the synthesizer 52, the DC blocking capacitor 52, the coaxial cable 54, the DC blocking. The voltage is supplied to the input terminal 58 via the capacitor 56.
[0056]
When the directivity changeover switch 72 is operated at time t6, a pulse signal is generated as shown in FIG. 10 (g), and is output to the output terminals C and D of the control circuit 60 as shown in FIGS. 10 (c) and 10 (d). A DC power supply is generated, and signals received by the UHF band antennas 8 c and 8 d and the VHF band antennas 22 c and 22 d are amplified by the amplifiers 44 c and 44 d and supplied to the amplifier 49 via the combiner 47. Since a DC power supply is also generated at the output terminal F of the OR circuit 64, the amplifier 49 operates, and the output of the synthesizer 47 is amplified by the amplifier 49, and the synthesizer 50, the DC blocking capacitor 52, the coaxial cable 54, the DC blocking. The voltage is supplied to the input terminal 58 via the capacitor 56.
[0057]
When the directivity selector switch 72 is operated at time t7, a pulse signal is generated as shown in FIG. 10 (g), a DC power supply is generated at the output terminal D of the control circuit 60 as shown in FIG. 10 (d), and the filter The signals received by the UHF band antenna 8d and the VHF band antenna 22d are supplied to the amplifier 44d via 24d. Since DC power is also generated at the output terminal F of the OR circuit 64, these signals are amplified by the amplifier 44 d and supplied to the amplifier 49 via the synthesizer 47. The output signal of the amplifier 49 is supplied to the input terminal 58 via the synthesizer 50, the DC blocking capacitor 52, the coaxial cable 54, and the DC blocking capacitor 56.
[0058]
When the directivity selector switch 72 is operated at time t8, as shown in FIG. 10 (g), a DC power source is generated at the output terminals D and A of the control circuit 60 as shown in FIGS. 10 (a) and 10 (d), and the filter The signals received by the UHF band antennas 8d and 8a and the VHF band antennas 22d and 22a are supplied to the amplifiers 44d and 44a via 24d and 24a. Since DC power is also generated at the output terminals E and F of the OR circuits 62 and 64, the signals amplified by the amplifiers 44d and 44a are supplied to the amplifiers 49 and 48 via the combiners 47 and 46, respectively. Amplified. The outputs of the amplifiers 49 and 48 are synthesized by the synthesizer 50 and supplied to the input terminal 58 via the DC blocking capacitor 52, the coaxial cable 54 and the DC blocking capacitor 56.
[0059]
When the directivity selector switch 72 is operated at time t9, a DC power supply is generated at the output terminal A of the control circuit 60, and the same operation as at time t1 is performed.
[0060]
Each time the directivity changeover switch 72 is operated in this way, as shown in FIGS. 11A to 11H, the directivities of the UHF band antennas configured by combining the UHF band antennas 8a to 8d are respectively It changes in order. The directivity of the VHF band antenna configured by combining the VHF band antennas 22a to 22d also changes in the same manner. This change is obtained by changing the outputs of the antennas selected in order, such as a single antenna output, a combination of the outputs of two antennas, and a single antenna output. Since the directivity is changed in this way, it is possible to satisfactorily receive the VHF band and UHF band television broadcast signals coming from any direction.
[0061]
In each of the filters 24a to 24d, matching is performed by switching one of the PIN diodes 38a to 38d to be conducted by changing the DC voltage of the output terminals A to D of the control circuit 60 and connecting to the low-pass filters 39a to 39d. The device is switched. This is because the VHF band antennas 22a to 22d and the rod antennas 18a to 18d each have two pairs of feeding terminals. For example, as described above, of the pair of output terminals 20a-1 and 20c-1 of the rod antennas 18a and 18c, when 20a-1 is connected to the input terminal 33a of the matching unit 35a and 20c-1 is connected to the input terminal 34a, Of the other pair of output terminals 20a-2 and 20c-2 of the rod antennas 18a and 18c, 20a-2 is connected to the input terminal 34c of the matching unit 35c, and 20c-2 is connected to the input terminal 33c of the matching unit 35c. Yes. Therefore, when the output terminal of each matching device is directly connected to the low-pass filter without providing the PIN diodes 38a to 38d, each matching device is connected to the other matching device via a commonly connected rod antenna. to be influenced. In order to prevent this, at present, only the matching device connected to the rod antenna receiving the radio wave is connected to the corresponding low-pass filter.
[0062]
Further, in order to change the directivity of the combined antenna of the UHF band and the VHF band as described above, the amplifier 44a to 44d to which the signals from the antennas constituting both the combined antennas are supplied is selected. ing. Therefore, the directivity of both the UHF band and the VHF band can be changed at the same time, and it is not necessary to provide a switch for switching the antenna output other than the amplifier. Further, for example, when the control circuit 60 is provided in the home, the output terminals A to D of the control circuit 60 must be connected to the amplifiers 44a to 44d in the main body 2 using individual lines, respectively. A lot of tracks are needed. However, since the control circuit 60 is provided in the main body 2, the directivity can be changed only by supplying a pulse signal through one coaxial cable 54, and many wirings are unnecessary. .
[0063]
In the above embodiment, the antenna for the VHF band and the antenna for the UHF band is provided, but only one of them can be provided. In this case, the signal supplied to the amplifiers 44a to 44d is also only one of the outputs of the VHF band antenna and the UHF band antenna. In addition, although the amplifier 48 is configured to operate when at least one of the amplifiers 44a and 44b is operating, the amplifier 48 may be operated constantly. Similarly, the amplifier 49 may be always operated. In the above embodiment, a flat plate is used for each element of the Yagi antenna, but a rod-shaped device can also be used.
[0064]
【The invention's effect】
As described above, according to the present invention, it is possible to obtain a multidirectional antenna that is small in size and can satisfactorily receive radio waves coming from any direction.
[Brief description of the drawings]
1A is a partially omitted plan view of a multi-directional antenna for a multi-frequency band according to one embodiment of the present invention, FIG. 1B is a front view, and FIG. 1C is a right side view.
2A is a partially omitted plan view of the multi-frequency antenna for multi-frequency bands in FIG. 1; FIG. (B) is sectional drawing which follows the bb line of (a), (c) is sectional drawing which follows the cc line of (a).
3 is an assembly diagram of an antenna for UHF band in the multi-directional antenna for multi-frequency band in FIG. 1. FIG.
4 is a perspective view of the multi-frequency antenna for multi-frequency band in FIG. 1. FIG.
5A is a perspective view of a V-shaped antenna constituted by a rod antenna of a multidirectional antenna for multi-frequency bands in FIG. 1, and FIG. 5B is a perspective view of a rod antenna of the multi-directional antenna for multi-frequency bands in FIG. It is a perspective view of the comprised dipole antenna.
6 is a block diagram of a rod antenna of the multi-frequency antenna for multi-frequency band in FIG. 1. FIG.
7 is a block diagram of the filter shown in FIG.
FIG. 8 is a diagram showing a matching unit in each filter shown in FIG. 6;
9 is a front view of the directivity control pulse generator shown in FIG. 6. FIG.
10 is a diagram for explaining the operation of the directivity control pulse generator shown in FIG. 6; FIG.
11 is a diagram showing a state where the directivity of the UHF band in the multi-directional antenna for multi-frequency band in FIG. 1 changes.
[Explanation of symbols]
2 body
8a to 8d Yagi antenna (first antenna)
18a to 18d Rod antenna (second antenna)
28a to 28d matcher
44a to 44d Amplifier (selection means)
60 Control circuit (control means)

Claims (9)

Has a flat body,
First and second Yagi antennas are arranged to receive radio waves arriving from opposite directions in a first plane in the main body, and both the first and second Yagi antennas are radiators. And the reflectors of the first and second Yagi antennas are formed in an eight-letter shape so that the tips of the radiators of the first and second Yagi antennas are close to each other. A radiator of the first and second Yagi antennas is disposed, and a reflector of the first and second Yagi antennas is disposed between the radiators of the first and second Yagi antennas, and the first The reflector of the Yagi antenna has a curved portion that is convexly curved on the radiator side of the first Yagi antenna, and the reflector of the second Yagi antenna is a radiator of the second Yagi antenna. It has a curved part that curves convexly on the side,
So as to receive radio waves coming from directions opposite to each other in a second plane at a height different from the first plane in the main body so as to be orthogonal to the first and second Yagi antennas. Third and fourth Yagi antennas are arranged, each of the third and fourth Yagi antennas has a radiator and a reflector, and the radiators of the third and fourth Yagi antennas are: The radiators of the third and fourth Yagi antennas are arranged so that the tips of the radiators of the third and fourth Yagi antennas are close to each other, and the third and fourth Yagi antennas are disposed. The reflectors of the third and fourth Yagi antennas are arranged between the radiators of the Yagi antenna, and the reflectors of the third Yagi antenna are convex on the radiator side of the third Yagi antenna. The reflector of the fourth Yagi antenna has a curved curved portion, and the reflector of the fourth Yagi antenna Has a curved portion which is curved convexly toward the morphism-side,
The radiators of the first and second Yagi antennas are multidirectional antennas that partially intersect with the radiators of the third and fourth Yagi antennas. 2. The multidirectional Yagi antenna according to claim 1, wherein the first to fourth Yagi antennas are respectively connected to the matching units, and are adjacent to or adjacent to outputs of the first to fourth Yagi antenna matching units. The Yagi-type antenna has selection means for combining and selecting the outputs of each matching unit, each matching unit having first and second output terminals, and in each matching unit, the first output terminal is a reference A multidirectional antenna connected to a potential and having a second output terminal connected to the selection means. Four or more even number rod antennas arranged radially on substantially the same plane, and two lead antennas derived from the inner end of each rod antenna, and a total of twice as many feed terminals as the even number , And a total of the same number of V-shaped antennas configured by the two rod antennas adjacent to each other, and the feed terminals of these V-shaped antennas are adjacent to the two rod antennas. A V-shaped antenna that is a feed terminal derived from each of the
A matching unit provided in the same number as the even number, and a matching unit connected to a feeding terminal of each V-shaped antenna;
Selecting means for selecting the outputs of these matching devices alone or selecting the combined output of the matching devices of two adjacent V-shaped antennas;
Energizing means for energizing only the selected matching unit;
A multidirectional antenna. A plurality of dipole antennas configured by arranging two rod antennas along a plurality of straight lines that are radially located on substantially the same plane, and two pairs of feeding terminals are derived from each of these dipole antennas. A plurality of dipole antennas,
Matching units that are provided in the same number as the rod antennas and to which the feeding terminals of the dipole antennas are respectively connected, and the feeding terminals derived from the same dipole antenna are connected in opposite phases, and the same dipole antenna is connected. A matching unit used as two dipole antennas having opposite directivity characteristics;
Selecting means for selecting the outputs of these matchers alone, or selecting the combined output of two dipole antenna matchers whose directivities are adjacent;
Energizing means for energizing only the selected matching unit;
A multidirectional antenna. 5. The multidirectional antenna according to claim 3, wherein each matching unit includes first and second output terminals, wherein the first output terminal is connected to a reference potential in each matching unit, and the second output is provided. A multidirectional antenna whose terminals are connected to the selection means. Has a flat body,
First and second Yagi antennas are arranged to receive radio waves arriving from opposite directions in a first plane in the main body, and both the first and second Yagi antennas are radiators. And the reflectors of the first and second Yagi antennas are formed in an eight-letter shape, and the first and second Yagi antennas are arranged so that the tips of the first and second Yagi antennas are close to each other. A radiator of the second Yagi antenna is disposed, and reflectors of the first and second Yagi antennas are disposed between the radiators of the first and second Yagi antennas, and the first Yagi antenna is disposed. The reflector of the antenna has a curved portion that is convexly curved on the radiator side of the first Yagi antenna, and the reflector of the second Yagi antenna is convex on the radiator side of the second Yagi antenna. Has a curved portion curved,
So as to receive radio waves coming from directions opposite to each other in a second plane at a height different from the first plane in the main body so as to be orthogonal to the first and second Yagi antennas. Third and fourth Yagi antennas are arranged, each of the third and fourth Yagi antennas has a radiator and a reflector, and the radiators of the third and fourth Yagi antennas are: The radiators of the third and fourth Yagi antennas are arranged so that the tips of the third and fourth Yagi antennas are close to each other, and the third and fourth Yagi antennas are formed. The reflectors of the third and fourth Yagi antennas are arranged between the radiators of the third Yagi antenna, and the reflectors of the third Yagi antenna are curved so as to be convex toward the radiator side of the third Yagi antenna. The reflector of the fourth Yagi antenna is on the radiator side of the fourth Yagi antenna Has a curved portion curved convexly,
The first and second Yagi antenna radiators partially intersect with the third and fourth Yagi antenna radiators,
The first to fourth Yagi antennas are respectively connected to a matching device for Yagi antennas,
Four rod antennas arranged radially along the first to fourth Yagi antennas in a third plane parallel to the first and second planes in the main body, and for each rod antenna A total of eight feeding terminals led out from the inner end, and a total of four V-shaped antennas are constituted by the two adjacent rod antennas, and these V-shaped antennas Are feed terminals that are each led out from two adjacent rod antennas,
Each V-shaped antenna has a feeding terminal connected to a V-shaped antenna matching unit,
The outputs of the matching unit for Yagi antenna and the matching unit for V-shaped antenna corresponding to the first to fourth Yagi antennas and the respective V-shaped antennas are combined, and the combined output of these matching units is independently obtained. The selection means selects the combined output of the matching unit for the V-shaped antenna of the two adjacent V-shaped antennas and the matching unit for the Yagi-shaped antenna of the two corresponding Yagi-shaped antennas. And
A multidirectional antenna provided with biasing means for biasing only a V-shaped antenna matching unit that produces a selected output. Has a flat body,
First and second Yagi antennas are arranged to receive radio waves arriving from opposite directions in a first plane in the main body, and both the first and second Yagi antennas are radiators. And the reflectors of the first and second Yagi antennas are formed in an eight-letter shape, and the first and second Yagi antennas are arranged so that the tips of the first and second Yagi antennas are close to each other. A radiator of the second Yagi antenna is disposed, and reflectors of the first and second Yagi antennas are disposed between the radiators of the first and second Yagi antennas, and the first Yagi antenna is disposed. The reflector of the antenna has a curved portion that is convexly curved on the radiator side of the first Yagi antenna, and the reflector of the second Yagi antenna is convex on the radiator side of the second Yagi antenna. Has a curved portion curved,
So as to receive radio waves coming from directions opposite to each other in a second plane at a height different from the first plane in the main body so as to be orthogonal to the first and second Yagi antennas. Third and fourth Yagi antennas are arranged, each of the third and fourth Yagi antennas has a radiator and a reflector, and the radiators of the third and fourth Yagi antennas are: The radiators of the third and fourth Yagi antennas are arranged so that the tips of the third and fourth Yagi antennas are close to each other, and the third and fourth Yagi antennas are formed. The reflectors of the third and fourth Yagi antennas are arranged between the radiators of the third Yagi antenna, and the reflectors of the third Yagi antenna are curved so as to be convex toward the radiator side of the third Yagi antenna. The reflector of the fourth Yagi antenna is on the radiator side of the fourth Yagi antenna Has a curved portion curved convexly,
The first and second Yagi antenna radiators partially intersect with the third and fourth Yagi antenna radiators,
The first to fourth Yagi antennas are respectively connected to a matching device for Yagi antennas,
Four radially disposed along the first and second Yagi antennas and the third and fourth Yagi antennas in a third plane parallel to the first and second planes in the body. Among the rod antennas, two dipole antennas in total are constituted by two rod antennas located on the same straight line, and two pairs of feeding terminals are derived from each of these dipole antennas,
A total of four dipole antenna matching units connected to the respective pair of feeding terminals are provided. Among these dipole antenna matching units, the feeding terminals derived from the same dipole antenna are connected to the feeding terminals. Using the same dipole antenna connected in opposite phases as two dipole antennas whose directional characteristics are opposite to each other,
Of the first to fourth Yagi antennas and each of the dipole antennas, the outputs of the Yagi antenna matching unit and the dipole antenna matching unit having the corresponding directivity are combined. The selection means selects the combined output of two dipole antenna matching units having adjacent directivities and the two Yagi antenna matching units corresponding to the two dipole antennas. Selected,
A multidirectional antenna provided with biasing means for biasing only a dipole antenna matching unit that generates a selected output. 8. The multidirectional antenna according to claim 2, 4, 6, or 7, wherein the selection unit is controlled by a selection control signal supplied from a control unit. The multidirectional antenna according to claim 2, 4, 6, or 7, wherein the selecting means is constituted by an amplifying means that takes an energized state and a non-energized state.

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