JP2558773B2 - Monopole antenna - Google Patents

Description

Description: TECHNICAL FIELD OF THE INVENTION The present invention relates to a monopole antenna attached to a small television receiver for automobiles and used as an antenna for receiving television broadcasting.

[Prior Art and Its Deficiencies] Generally, a retractable rod antenna is often used as a monopole antenna attached to a television receiver. Since this rod antenna is used by expanding and contracting its length according to the reception frequency, the length of the antenna is expanded and contracted one by one, for example, when receiving 1 channel of VHF television broadcasting and when receiving 12 channels. There is a drawback that it must be variable.

In addition, in the antenna for receiving television broadcasting in automobiles, three rod antennas for VHF low-frequency reception, VHF high-frequency reception, and UHF reception are spatially arranged so that they do not affect each other. Is not only complicated, but also has the drawback that vibration or wind noise is likely to occur as the vehicle travels.

FIG. 8 shows a conventional automobile television broadcast receiving antenna. In FIG. 8, 1 is a VHF low band receiving rod antenna, 2 is a VHF high band receiving rod antenna, 3
Is a UHF receiving rod antenna, 4 is a feeding cable, and 5 is a mounting base.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned drawbacks, and an object of the present invention is to provide a monopole antenna having a small size and a simple structure without the need to adjust the length of the antenna each time the reception frequency is different. And

[Points of the Invention] That is, the monopole antenna according to the present invention has a total length corresponding to a quarter wavelength of the VHF low-frequency reception frequency, and one end of the antenna serves as a feeding point on the other end side of the VHF high-frequency reception frequency. A VHF high-frequency stub having a length of a quarter wavelength is provided, and a UHF stub having a length of a quarter wavelength of the UHF reception frequency is provided at the one end side, and high impedance is provided at each stub position. As a result, unnecessary antenna portions are apparently separated at each reception frequency.

Further, the antenna main body portion from the VHF high frequency stub to the other end side tip, the antenna main body portion between the VHF high frequency stub and the UHF stub, the VHF high frequency stub portion, the UHF stub portion is selectively formed into a wavy shape, This enables further miniaturization.

In addition, the feeding point on one end of the above antenna body is the UHF feeding terminal, and the open terminal of the UHF stub is the VHF feeding terminal.

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

FIG. 1 shows its configuration. In FIG. 1, 11 is a monopole antenna.
The total length of VHF low frequency reception frequency (90 to 108MHz) is, for example, 9
It is composed of a quarter wavelength of 9MHz. A UHF stub 12 and a VHF high frequency stub 13 are branched and formed on the monopole antenna 11. The UHF stub 12 has a length of a quarter wavelength of, for example, 620 MHz of the UHF reception frequency (470 to 770 MHz), and is close to one end side of the monopole antenna 11 (for example, about half of the UHF reception frequency). It is branched from one point (corresponding to one wavelength) toward one end of the antenna 11. In this case, the UHF stub 12 has a length of a quarter wavelength of its reception frequency, so that from the point A, that is, the point corresponding to approximately a quarter wavelength of the UHF reception frequency from one end of the antenna 11. Since the impedance Z _A of the other end of the antenna 11 when viewed from the other end has a very large value, the characteristics of the monopole antenna 11 as a monopole antenna for receiving UHF are substantially equal to the monopole antenna 11 separated from the point A. . Here, since the UHF stub 12 is very short with respect to the wavelength of the VHF reception frequency, its influence on the VHF reception characteristic can be ignored. Further, the VHF high frequency stub 13 has a length of a quarter wavelength of, for example, 196 MHz of the VHF high frequency reception frequency (170 to 222 MHz), and the antenna is located near the other end of the monopole antenna 11. It is branched toward one end of 11. In this case, the VHF high frequency stub 13 has a wavelength length of 4 minutes of its reception frequency, so that the point B, that is,
Approximately 1/4 of the VHF high frequency reception frequency from one end of the antenna 11.
Since the impedance Z _B looking at the other end of the antenna 11 from the point corresponding to the wavelength has a very large value, it is practically a monopole antenna for VHF high frequency equal to the monopole antenna 11 separated from the point B. Will show the characteristics of. Here, the VHF high-frequency stub 13 is about 1/2 of the quarter wavelength of the VHF low-frequency receiving frequency, but the effect on the VHF low-frequency receiving characteristic is very small.

Here, the monopole antenna 11 is a UHF stub 12
The side end is the power supply terminal 14.

FIG. 7 (A) is a Smith chart showing the impedance characteristic of the monopole antenna 11 of FIG. 1 and is adjusted to VSWR = 6 or less.

That is, in the mono-ball antenna 11 having the above configuration, the VHF low band is received with the length from one end to the other end of the antenna 11, and the VHF high band corresponds to the open position of the VHF high band stub 13 from one end of the antenna 11. Received up to point B,
UHF is received at the length from one end of the antenna 11 to the point A corresponding to the open position of the UHF stub 12, so even if the received frequency band changes to VHF low range, VHF high range, UHF, It is not necessary to adjust the length, and each broadcast band can be easily received. In addition, one end of the monopole antenna 11 is a power supply terminal 14 dedicated to UHF, and the open end of the UHF stub 12 is VH.
If used independently as a power supply terminal for F only, the demultiplexer for UHF and VHF becomes unnecessary, and the attenuation of the received signal by the demultiplexer can be eliminated, and the independent wiring for the VHF terminal and the UHF terminal of the television receiver is possible. It will be possible. In this case, the VHF low band is received with the length from the open end of the UHF stub 12 to the other end of the antenna 11, and the VHF high band is received with the length from the open end of the UHF stub 12 to the point B of the antenna 11. Therefore, the receiving antenna length is slightly shorter than the case where one end of the antenna 11 is used as the UHF / VHF common feeding terminal 14, but the shortened length is equal to one end of the antenna 11. Is shorter than the length from point A to point A and is extremely short with respect to the wavelength of the VHF reception frequency, the influence on the VHF reception characteristics can be ignored.

FIG. 2 shows another embodiment of the monopole antenna of the present invention, which is different from the monopole antenna in FIG. 1 in that the antenna section between the UHF stub 12 and the VHF high frequency stub 13 and the VHF are shown. The antenna parts extending from the high frequency stub 13 to the tip side of the other end are formed as wavy parts 15 and 16, respectively. In this case, the external dimensions can be shortened and downsized while the electrical dimensions of the monopole antenna 11 are maintained.

Also, connect one end of the monopole antenna 11 to the UHF feeding terminal 1
4, if the open terminal of the UHF stub 12 is independently used as the VHF power supply terminal 17, the demultiplexer between VHF and UHF becomes unnecessary, and the attenuation of the received signal by the demultiplexer can be eliminated, and the television receiver Independent wiring for VHF and UHF terminals is possible. In this case, the VHF low frequency band is received from the VHF power supply terminal 17 to the other end of the antenna 11, and the VHF high frequency band corresponds to the open position of the VHF high frequency stub 13 in the antenna 11 from the VHF power supply terminal 17. However, the length of the receiving antenna is slightly shorter than that of the case where one end of the antenna 11 is used as the UHF / VHF common power supply terminal 14, but the length is shortened. UHF from one end of antenna 11
Shorter than the length to the point corresponding to the open position of the stub 12,
Since it is extremely short with respect to the wavelength of the VHF reception frequency, the influence on the HF reception characteristics can be ignored.

Further, as shown in FIG. 3, with respect to the monopole antenna in FIG. 2, the tip of the monopole antenna 11 is bent at a length of a quarter wavelength of the UHF reception frequency, and U
A monopole antenna 18 for the HF band may be provided. In this case, the bent portion serves as the UHF feeding terminal 19, and the outer dimensions of the monopole antenna 11 can be further shortened and downsized. That is, the VHF low band is received with the length from the VHF feeding terminal 17 to the other end of the antenna 11, and the VHF high band is
VHF high frequency stub from the same VHF feeding terminal 17 to the antenna 11
The signal is received up to the point corresponding to the open position of 13, and the UHF is received by the monopole antenna 18 for the UHF from the UHF power supply terminal 19. In this case, the length of each receiving antenna in the VHF low-high range is slightly shorter than the quarter wavelength, but the shortened length is shorter than the quarter wavelength of the UHF reception frequency. Since it is extremely short with respect to the wavelength of the reception frequency, its influence on the VHF reception characteristics can be ignored.

FIG. 7 (B) is a Smith chart showing the impedance characteristic of the monopole antenna 11 of FIG. 3 described above, which is adjusted to VSWR = 6 or less.

FIG. 4 shows a state in which the monopole antenna 11 shown in FIG. 3 is formed on an insulating base 20 such as a printed circuit board or a polyester film. In this case, the monopole antenna 11 is an insulating base. 20 is formed by using a metal foil such as aluminum or copper. In this embodiment, the antenna pattern is formed by etching a 15 μm aluminum foil which is rolled and adhered on a 125 μm thick polyester film. When a printed circuit board is used, the antenna pattern is formed by etching the copper foil. Further, a conductive material such as a silver paste or an aluminum paste may be used instead of the metal foil, and the antenna pattern may be formed by printing. Further, the antenna pattern may be formed by depositing a metal oxide such as gold or titanium indium. in this case,
Experimental results have shown that an antenna pattern having a light transmittance of about 60% can be sufficiently used as an antenna.

That is, when a polyester film is used,
The antenna itself can be rolled up and made smaller, which is very effective for packaging and transportation. Further, when a transparent polyester film is used, even if it is attached to the glass surface of an automobile, for example, the field of view is not significantly obstructed.

FIG. 5 shows the VH of the monopole antenna shown in FIG.
A resonance circuit including a coil 21 and a capacitor 22 instead of the F high frequency stub 13 is provided from the other end of the monopole antenna 11
The figure shows the case where it is inserted and used at a position of a length of about a quarter wavelength of the VHF high frequency reception frequency corresponding to the length of the VHF high frequency stub 13, and in this case, the coil 21 and the capacitor 22 The resonance frequency of the parallel resonance circuit is set to, for example, 196 MHz which is the VHF high frequency reception frequency. That is, the impedance at the VHF high-frequency reception frequency becomes a very large value, and the monopole antenna 11 operates substantially as if it were separated in the resonant circuit section. On the other hand, at the VHF low frequency reception frequency, the influence can be ignored by selecting the value of the coil 21 so that the resonance circuit exhibits a small impedance. Here, the values of the capacitor 22 and the coil 21 of the resonance circuit are "3 pF" from the experimental results, respectively.
It is set to "0.22μH". A large value is set when only the coil 21 is used. That is, VHF low frequency is VHF
The length from the power supply terminal 17 to the other end of the antenna 11 is received, and the high frequency band of VHF is received at the length from the VHF power supply terminal 17 to the resonance circuit insertion position in the antenna 11.
F is a monopole antenna 18 for UHF from the UHF power supply terminal 19
Received by. In this case, the length of each receiving antenna in the VHF low-high range is slightly shorter than the quarter wavelength, but the shortened length is shorter than the quarter wavelength of the UHF reception frequency. Since it is extremely short with respect to the wavelength of the reception frequency, its influence on the VHF reception characteristics can be ignored.

FIG. 7 (C) is a Smith chart showing the impedance characteristics of the monopole antenna 11 of FIG. 5 described above, which is adjusted to VSWR = 6 or less.

Next, FIG. 6 shows a case where the VHF high frequency stub 13 portion of the monopole antenna 11 of FIG. 3 is formed in a wave shape. In this case, the outer dimensions of the monopole antenna 11 should be further shortened and downsized. Is possible. If the UHF band stub 18 is also formed in a corrugated shape, further downsizing is possible.

Therefore, according to the monopole antenna having the above-described configuration, the U pole is mainly used for the VHF low-frequency monopole antenna 11 and U
It has HF stub 12 and VHF high frequency stub 13, and since each of them operates independently, it is not necessary to adjust the antenna according to the reception frequency, but also with a film-like insulating base 20 made of aluminum foil or the like. It can also be used by forming an antenna pattern and attaching it to the glass surface of an automobile.

Further, by selectively forming the monopole antenna 11 and the stubs 12 and 13 in a wave shape, the antenna itself can be further downsized. That is, in the monopole antenna 11 constructed in each of the above-mentioned embodiments, the antenna length in FIG. 1 is 830 mm, whereas the antenna length in FIG. 3 is 520 mm, and a size reduction of 63% can be realized. Moreover, one end of the monopole antenna 11 or the bent portion is connected to the UHF feeding terminal 1
4 (or 19), if the open terminal of the UHF stub 12 is independently used as the VHF power supply terminal 17, the demultiplexer for UHF and VHF is unnecessary, and the attenuation of the received signal by the demultiplexer can be eliminated and the television Independent wiring is possible for the VHF and UHF terminals of the receiver.

[Effects of the Invention] As described above, according to the present invention, the total length corresponds to a quarter wavelength of the VHF low-frequency reception frequency, and the VHF high-frequency reception frequency is provided on the other end side of the antenna whose one end is the feeding point. A VHF high-frequency stub having a length of a quarter wavelength of the UHF is provided, and a U having a length of a quarter wavelength of the UHF reception frequency is provided on the one end side.
HF stubs are provided so that high impedance can be obtained at each stub position, and unnecessary antenna parts are apparently separated at each reception frequency, so the antenna length is adjusted each time the reception frequency differs. It is possible to provide a monopole antenna having a small size and a simple structure without the need to perform it.

Also, by selectively corrugating the antenna main body section from the VHF high frequency stub to the other end side tip, the antenna main body section between the VHF high frequency stub and the UHF stub, the VHF high frequency stub, and the UHF stub section. , Further miniaturization is possible.

In addition, use one end of the above antenna body as a UHF power supply terminal
By using the open terminal of the HF stub as the VHF power supply terminal, the demultiplexer becomes unnecessary and the power supply cable can be independently wired.

[Brief description of drawings]

FIG. 1 is a block diagram showing a monopole antenna according to an embodiment of the present invention, and FIGS. 2 to 6 are block diagrams showing other embodiments of the monopole antenna, respectively, and FIG.
(C) is a Smith chart showing the impedance characteristics of the monopole antenna in each of the embodiments shown in FIGS. 1, 3 and 5, and FIG. 8 is a diagram showing a conventional automobile television broadcast receiving antenna. . 11 …… Monopole antenna, 12 …… UHF stub, 13 …… V
HF high-frequency stubs, 14, 17, 19 ... Power supply terminals, 15, 16 ... Wavy forming part, 18 ... UHF band stubs, 20 ... Insulating base, 2
1 …… coil, 22 …… capacitor.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-62-31203 (JP, A) real-open Sho-49-2242 (JP, U) real-open Sho-57-152805 (JP, U) real-open Sho-62- 133409 (JP, U)

Claims (3)

(57) [Claims] 1. A main body of a monopole antenna having a length of about a quarter wavelength of a VHF low frequency reception frequency, and a length of about a quarter wavelength of a UHF reception frequency near one end of the main body of the monopole antenna. A UHF stub that is branched and formed, and a VHF that is branched and formed near the other end of the monopole antenna body at a length of about a quarter wavelength of the VHF high-frequency reception frequency.
A high-frequency stub is provided, and one end of the monopole antenna body is used as a UHF feeding terminal, and the UHF band is received at a length from the UHF feeding terminal to a point corresponding to the open position of the UHF stub, and UHF
The open end of the stub is used as the VHF feeding terminal, and the VHF low range is received from the VHF feeding terminal to the other end of the monopole antenna body, and the VHF high range is received from the VHF feeding terminal in the monopole antenna body. A monopole antenna characterized by receiving up to the point corresponding to the open position of the VHF high frequency stub and feeding the UHF / VHF band with independent coaxial cables. 2. A VHF low-frequency receiving frequency which is bent at one end and has a length of a quarter wavelength of a UHF receiving frequency.
The length of the wavelength of the monopole antenna body and the other end side near the bent end of this monopole antenna body
A UHF stub branched and formed with a length of about a quarter wavelength of the UHF reception frequency, the open end of which is set at a position corresponding to the bent end of the monopole antenna body; VHF branched near the edge with a length of about one-quarter wavelength of the VHF high-frequency reception frequency
A high-frequency stub is provided, and the bent end of the monopole antenna body is used as a UHF feed terminal, and the UHF band is received at a length from the UHF feed terminal to the tip of the bent side of the monopole antenna body, and , The above
The open end of the UHF stub is used as the VHF feeding terminal, and the VHF low range is
While receiving at the length from the power feeding terminal to the other end of the monopole antenna body, the VHF high frequency is measured from the VHF power feeding terminal to the point corresponding to the open position of the VHF high frequency stub in the monopole antenna body. A monopole antenna that receives and feeds the UHF / VHF band with independent coaxial cables. 3. A VHF low-frequency reception frequency, which is formed by bending one end at a length of a quarter wavelength of the UHF reception frequency, is approximately a quarter of the VHF reception frequency.
The length of the wavelength of the monopole antenna body and the other end side near the bent end of this monopole antenna body
A UHF stub branched and formed with a length of about a quarter wavelength of the UHF reception frequency, the open end of which is set at a position corresponding to the bent end of the monopole antenna body; Inserted near the end side,
A resonance circuit having high impedance at a VHF high frequency reception frequency is provided, and the bent end of the monopole antenna body is used as a UHF feeding terminal, and the UHF band from the UHF feeding terminal to the bending side of the monopole antenna body. Receiving at the length to the tip,
The open end of the UHF stub is used as the VHF feeding terminal, and the VHF low range is
Receives at the length from the feeding terminal to the other end of the monopole antenna main body, and receives the VHF high frequency at the length from the VHF feeding terminal to the insertion position of the resonance circuit in the monopole antenna main body, UHF / VHF A monopole antenna characterized in that each band is fed by an independent coaxial cable.