JP4188884B2 - Broadcast reception system - Google Patents

Description

The present invention relates to a broadcast receiving system provided with a UHF antenna for receiving terrestrial digital broadcasting and terrestrial analog broadcasting .

The terrestrial broadcast receiving system is built with UHF antennas and VHF antennas facing each broadcasting station, and each received signal received by each antenna is mixed by a mixer and transmitted to a television receiver via a transmission line. It was. At this time, an optimum antenna was selected for each receiving antenna at the receiving point.
For example, the VHF antenna can obtain the maximum reception operation gain in each reception frequency band such as low band (ch1-3), high band (ch4-12), and allband (ch1-12). Designed to. Further, the UHF antenna can obtain the maximum reception operation gain in each reception frequency band such as low band (ch13-44), high band (ch30-62), allband (ch13-62). Designed to. (For example, refer nonpatent literature 1).

Published by Maspro Electric Co., Ltd., General Catalog 2002.3, p. 43-56

However, the technique proposed in Non-Patent Document 1 has a problem that when a digital terrestrial broadcast is newly started, a receiving antenna must be added or replaced. This is because terrestrial digital broadcasting has been started in the three major metropolitan areas, but terrestrial digital broadcasting is broadcast in the UHF band, and most of it is concentrated in the low frequency band of Ch13 to Ch32. There is no problem if an antenna is used, but if an antenna other than the low band is used, it is necessary to add or replace an antenna capable of receiving this band. At the start of digital terrestrial broadcasting, transmission is performed with a transmission power as low as about 1/100 of the steady-state output in consideration of interference with existing terrestrial analog broadcasting. For this reason, the operational gain of the antenna becomes important in order to stably receive terrestrial digital broadcasting. Therefore, it is necessary to replace the antenna with a high operating gain in the frequency band of terrestrial digital broadcasting.
Conventionally, when an antenna is selected, an antenna for the entire band (all bands) is often selected in anticipation of the possibility of adding a broadcasting station in the future. However, when an all-band antenna is used, the reception band is matched, but the operation gain is low because of the wide band, and the number of elements (especially the number of waveguides) is required to obtain the required reception level. There was a problem that the antenna would become large because it had to be replaced with many high gain antennas. In addition, with the increase in size of antennas, aesthetics have become a problem.

Therefore, the present application has been made to solve these problems, and its purpose is to receive a terrestrial digital broadcast that can receive a stable terrestrial digital broadcast even when transmitted at a power lower than the rated power. Is to provide a system.
Another object is to provide a terrestrial digital broadcast receiving system that can be miniaturized and easily installed.

In order to achieve this object, the invention according to claim 1 is provided with a UHF antenna for receiving terrestrial digital broadcast and terrestrial analog broadcast , and a received signal from the UHF antenna is transmitted to a terminal device via a transmission line. A broadcast receiving system for transmission,
The UHF antenna is
A radiator,
A plurality of waveguides having the same length as one set, and a plurality of sets of waveguides having different waveguide lengths for each set;
The plurality of sets of waveguides are arranged such that the length of the waveguide elements is longer toward the radiator side.

2. The broadcast receiving system according to claim 1, wherein the UHF antenna used for receiving the terrestrial digital broadcast and the terrestrial analog broadcast includes a plurality of waveguide elements, and the length of the waveguide element for each set. Are provided so that the length of the waveguide element becomes longer toward the radiator side.
For this reason, among the frequency bands that can be received by the UHF antenna, the operating gain of the UHF antenna is higher in the low frequency band, which is the terrestrial digital broadcasting band, than the terrestrial analog broadcasting band, and the terrestrial digital broadcasting is more than the rated power. Even if it is transmitted with low power , terrestrial digital broadcasting can be stably received.

Furthermore, the UHF antenna, a plurality of waveguide elements of the same length and a set, since it is only by providing a plurality of sets of waveguides, the antenna can be miniaturized, provides easy broadcast receiving system installed can do.

Hereinafter, an example of an embodiment embodying the present invention will be described in detail with reference to the drawings.

FIG. 1 shows a block diagram of a digital terrestrial broadcast receiving system 100 to which the present invention is applied. Moreover, FIG. 2 has shown explanatory drawing of the UHF antenna 1 used with the said system, FIG. 1a is a front view, FIG. 1b is a side view.
Reference numeral 1 denotes a UHF antenna, which is a UHF antenna for receiving the terrestrial digital broadcasts of ch13 to ch32 that have been started in the three metropolitan areas and the existing terrestrial analog broadcasts being broadcast on ch13 to ch36.
Reference numeral 31 denotes a VHF antenna, which is an antenna for receiving terrestrial analog broadcasts of ch1 to ch12 in this embodiment.
Reference numeral 32 denotes a mixer, which mixes the terrestrial digital broadcast signal and analog terrestrial broadcast signal received by the UHF antenna 1 and the VHF band terrestrial analog broadcast signal received by the VHF antenna 31 into one transmission line 33. It is for output.
Reference numeral 34 denotes a distributor. In this embodiment, two distributors are used for outputting to two terminal terminals (also referred to as TV terminals) 35a and 35b.
Reference numeral 36 denotes a terminal device such as a TV receiver or an STB (set top box).

Next, the UHF antenna 1 used in the present invention will be described in detail with reference to FIG. As shown in FIG. 2, the UHF antenna 1 includes a reflector 4, a radiator 3, and a waveguide 2 fixed to the boom 6 at predetermined intervals. Further, the boom 6 is provided with an antenna support bracket 5 for fixing the UHF antenna 1 to a mast or the like. Reference numeral 7 denotes a feeding portion, and 20 and 21 are waveguide elements.

The director 2 includes a plurality of sets of directors 2A and 2B. The waveguides 2A and 2B are arranged on the boom 6 so that a plurality of waveguide elements 20 and 21 having different lengths are arranged at a predetermined interval.
The length of the director is formed so as to be shorter than the length of the radiator described later, and the length on the radiator side is increased.

In this embodiment, six waveguide elements 20 and 21 are used. However, the number of the waveguide elements 20 and 21 is not limited to this.

Further, as means for fixing the waveguide 2 (specifically, the waveguide elements 20 and 21) to the boom 6, a well-known screw tightening or caulking fixing method may be employed. As the material of the waveguide element, an aluminum pipe having a diameter of about 8 mm and a thickness of about 0.5 mm is preferably used. For example, a conductive material may be plated or evaporated on the surface of a synthetic resin material. good.

As shown in FIG. 2, the radiator 3 includes a power feeding unit 7 and is connected to a coaxial cable (not shown). The radiator 3 is formed as a beam dipole antenna and has a unidirectional characteristic only by the radiator. The length is set to about one half of the wavelength of the received radio wave. The power feeding unit 7 is provided with a matching circuit in a case formed of a synthetic resin material, and efficiently supplies a received signal received by the half-wave dipole antenna to a coaxial cable as a transmission line.
The power feeding unit 7 also functions as a fixing member to the boom 6 and is fixed to the boom 6 by a known fixing means.

The reflector 4 is fixed to the end of the boom by a known fixing means. The length of the reflector is set to be longer than the length of the radiator.
As the material for the radiator 3 and the reflector 4, an aluminum pipe having a diameter of about 8 mm and a thickness of about 0.5 mm is preferably used as in the waveguide element material. A conductive material may be used by plating or vapor deposition.

Next, specific dimensions and frequency characteristics of the waveguide 2, the radiator 3 and the reflector 4 of the UHF antenna 1 shown in FIG. 2 will be described with reference to FIGS.
The length L31 of the first element of the radiator 3 is 250 mm, and is set to one half of the wavelength at the approximate center frequency 600 MHz of the reception band. The length L32 of the second element is set to 380 mm, which is a value longer than the length L31 of the first element.

Next, the length L20 of the first set of waveguides 2A is 210 mm, the length L21 of the second set of waveguides 2B is 220 mm, and is set to a value shorter than the length of the elements of the radiator 3. It is.

Next, the length L4 of the reflector 4 is 310 mm, which is set to a value longer than the length of the element of the radiator 3.

Each element is arranged on the boom with the following dimensions. D1 to D12 are set to 1/3 to 1/5 of the wavelength at the center frequency 600 MHz of the reception band. Specifically, D1 = 90 mm, D2 = 80 mm, D3 = 80 mm, D4 = 80 mm, D5 = 80 mm, D6 = 80 mm, D7 = 70 mm, D8 = 70 mm, D9 = 60 mm, D10 = 50 mm, D11 = 40 mm, D12 = 40 mm. D13 is set to about one third of the wavelength at the center frequency 600 MHz of the reception band, and specifically, D13 = 160 mm.

Next, each frequency characteristic of the operation gain in the UHF antenna of the present invention and the conventional all-band UHF antenna will be described in detail with reference to FIG. As shown in FIG. 4, in the antenna of the present invention, an operation gain of 9 dB or more is obtained in ch13 to ch32 which are terrestrial digital broadcasting bands (first predetermined bands) in the three metropolitan areas. It can be seen that it is improved by 2-3 dB from the antenna. It can also be seen that the channel 13 to ch 36, which are analog terrestrial broadcasting bands (second predetermined bands) in the three metropolitan areas, have an operational gain equal to or higher than that of the conventional all-band antenna.

As described above, since the operation gain of the terrestrial digital broadcasting band is improved, the service area can be expanded by about 1.6 times compared to the area where the conventional all-band antenna is used. In addition, in the process in which the transmission output of digital terrestrial broadcasting gradually increases, stable reception is possible even when the output is lower than the rated output.

Next, the operation of the terrestrial digital broadcast receiving system will be described.
As described in detail, the signal output from the UHF antenna 1 is 2 to 3 dB higher in the frequency band (ch13 to ch32) of digital terrestrial broadcasting than the conventional all-band UHF antenna. In the process of gradually increasing the transmission output, even if the output level is lower than the rated output, an output level that is 2-3 dB higher is obtained. On the other hand, among the frequency bands (ch13 to ch36) of the terrestrial analog broadcast signal, the frequency bands (ch33 to ch36) that do not overlap the frequency band (ch13 to ch32) of the terrestrial digital broadcast are the output levels of the conventional all-band UHF antenna. Output at the same level.

Then, the terrestrial digital broadcast signal and terrestrial analog broadcast signal output from the UHF antenna 1 and the VHF band terrestrial analog broadcast signal output from the VHF antenna 31 are mixed by a mixer 32, and a single transmission line 33 is mixed. Is output. Each broadcast signal transmitted through the transmission line 33 is taken into the dwelling unit 37 and divided into two by the distributor 34. And it is transmitted to the terminal terminals 35a and 35b installed in each room. A terminal device 36 is connected to each terminal terminal 35, and each broadcast signal is processed by each terminal device 36 (TV receiver, STB, etc.), and images / sounds can be reproduced to enjoy the service.

It should be noted that the present invention is not limited to the above-described embodiment, and can be implemented by appropriately changing each part without departing from the spirit of the present invention, as exemplified below.
For example, in the above embodiment, two sets of directors are used, and six waveguide elements are used. However, the present invention is not limited to this. If the required specifications are satisfied, the number may be more than this. May be. In this embodiment, a beam dipole antenna is used as the radiator, but a normal half-wave dipole antenna may be used. In this embodiment, four reflecting elements are used as reflectors, but a net-like plate material may be used instead.
In the present embodiment, the reception system using only terrestrial waves has been described. However, as long as at least UHF band digital terrestrial broadcasting and terrestrial analog broadcasting are included, there is no problem even if other services are included. For example, satellite (BS) broadcast, CS broadcast, satellite digital broadcast broadcast in 2.6 GHz band, and the like.

It is a block diagram of a terrestrial digital broadcast receiving system to which the present invention is applied. It is explanatory drawing of a UHF antenna. (A) is a front view, (b) is a side view. It is a dimensional drawing of a UHF antenna. It is explanatory drawing which showed the frequency characteristic of the UHF antenna.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... UHF antenna, 2 ... Waveguide, 3 ... Radiator, 4 ... Reflector, 5 ... Antenna support metal fitting, 6 ... Boom, 7 ... Feeding part, 20.21 ... Waveguide element, 31 ... VHF antenna, 32 ... Mixer, 33 ... Transmission line, 34 ... Distributor, 35 ... Terminal terminal (TV terminal), 36 ... Terminal device (TV receiver), 100 ... Digital terrestrial broadcast receiving system.

Claims (1)

A broadcast receiving system having a UHF antenna for receiving digital terrestrial broadcasting and analog terrestrial broadcasting, and transmitting a reception signal from the UHF antenna to a terminal device via a transmission line,
The UHF antenna is
A radiator,
A plurality of waveguides having the same length as one set, and a plurality of sets of waveguides having different waveguide lengths for each set;
The broadcast receiving system is characterized in that the plurality of sets of waveguides are arranged such that the length of the waveguide elements becomes longer toward the radiator.

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