KR101248392B1 - Antenna system for receiveing broadcasting - Google Patents

Abstract

An antenna system for receiving a terrestrial DTV broadcast according to an embodiment of the present invention includes an antenna for receiving a terrestrial DTV broadcast frequency full band (UHF) with a wideband logarithmic antenna; And a low noise amplifier (LNA) attached to the antenna itself to minimize signal transmission loss and amplifying a low power level signal of the antenna and using a solar cell as a power source. Position the antenna and the low noise amplifier in the.

Description

Antenna system for terrestrial DTV broadcasting reception {ANTENNA SYSTEM FOR RECEIVEING BROADCASTING}

The present invention relates to a small high-performance antenna for terrestrial digital broadcasting reception installed on the roof of a building, so that anyone can easily install it through the construction of a single body or a built-in enclosure in consideration of aesthetics and aesthetics of a low noise amplifier using a solar cell. It is.

According to the present invention, a small power can be obtained by synthesizing several antennas to obtain a high gain, such as a large antenna, and a power source using a solar cell and a charger. It is designed to compensate for the power loss generated during the transmission process, to make the antenna look beautiful by mounting it in the enclosure, and to make it safe and durable by making the related modules into a single body to be protected from wind, snow, rain and solar heat. It features.

Existing rooftop antennas have a length of about 1m in the form of Yagi antennas, and in the case of Yagi antennas, the bandwidth is narrow enough to receive broadcast signals in the 470-800MHz band and two or more antennas should be used. In addition, when the location of the broadcasting station transmission station or the relay station is different, as in Korea, there is a inconvenience in that multiple antennas must be used. And the intensity of the radio wave varies depending on the position even within one wavelength range. It is not easy to be in a good place with just one antenna.

In addition, the signals received from the antenna are amplified by a separately installed amplifier and delivered to the receiver. At this time, the power of the amplifier must be supplied separately from the constant power of the building.

In addition, the existing roof antenna system is not aesthetically beautiful and is not protected from wind, snow, rain, and solar heat, and becomes messy and functionally deteriorated over time.

In order to receive the broadcast signal, the Yagi antenna shown in FIG. 1A and the V-dipole antenna shown in FIG. 1B are frequently used. The Yagi antenna 100 is located at the front of the waveguide 120 and the rear of the half-wavelength dipole antenna. The reflector 140 is arranged to have a unidirectional directivity, and the V-dipole antenna 200 also receives a broadcast signal by configuring a dipole element in a V shape.

However, since the above-mentioned Yagi antenna and V-dipole antenna have to match the transmission antenna of the broadcasting station with the angle of direction of 30 degrees, the antenna can be received when the position of the antenna is shaken or shaken due to the external natural environment. Or there is a problem that the characteristics of the antenna is easily changed, such as image quality or sound is degraded when viewing.

That is, Yagi antennas are sensitive and difficult to maintain antenna characteristics due to external environment, and V-dipole antennas have a narrow bandwidth, making it difficult to stably receive broadcast signals.

In addition, in the case of the Yagi antenna, the gain is different for each receiving channel, but there is a problem that it is impossible to use it in an area having a low transmission level because the antenna gain is generally low, such as 0 to 10 dB.

The present invention has been made to improve the prior art as described above, and as the DTV broadcasting spread nationwide, the antenna of the VHF band becomes unnecessary, and thus, there is a need to replace or maintain the existing antenna system installed on the roof. .

In the present invention, to overcome the shortcomings of the conventional antenna system, a wide bandwidth logarithmic antenna is selected and the number of elements of the antenna is reduced so that the front length of the antenna is similar to the element length (half wavelength), and if necessary, several antennas are separated by half wavelength intervals. Vertically or horizontally, and synthesize the received power of each antenna.

In addition, in synthesizing the reception power, the synthesis and amplification are simultaneously performed using an amplification device, thereby increasing the reception gain of the antenna, widening the reception azimuth angle, and enabling ultrashort amplification so that it can be used without a separate amplifier. In addition, when the transmitting station or the relay station of the broadcasting station is different from each other, the individual antennas can be directed in different directions so that the reception can be performed without installing additional antennas.

The rooftop dirt of the existing antenna system is made by mounting small antennas, power supply and related modules in the enclosure or by making it as a single body to make it look beautiful and to protect the antenna system from wind, snow, rain and the sun. It is intended to be safe and durable and to be installed simply by the user even without the expert knowledge.

In order to achieve the above object and to solve the problems of the prior art, the antenna system for receiving a terrestrial DTV broadcast according to an embodiment of the present invention, to receive a terrestrial DTV broadcast frequency full band (UHF) with a broadband logarithmic antenna An antenna and a low noise amplifier (LNA) attached to the antenna itself to amplify the signal transmission loss to amplify a low power level signal of the antenna, including the antenna and the low noise amplifier in one radome or Adjacent to one body is characterized in that attached.

In addition, in the antenna system for receiving terrestrial DTV broadcasting according to an embodiment of the present invention, the antenna may be implemented as a small flat antenna.

In addition, in the antenna system for receiving terrestrial DTV broadcasting according to an embodiment of the present invention, the antennas are arranged at half wavelength intervals and are arranged in a direction in which a broadcast signal arrives.

In the antenna system for receiving terrestrial DTV broadcasting according to an embodiment of the present invention, the low noise amplifier may amplify and synthesize an electric field induced in the antenna.

In addition, the antenna system for terrestrial DTV broadcasting reception according to an embodiment of the present invention is a solar cell panel attached to the upper portion of the radome to generate power supplied to any one of the antenna and low noise amplifier; And a charger attached to a lower portion of the radome and charging a power generated by the solar cell panel.

According to the antenna system for receiving terrestrial DTV broadcasting according to an embodiment of the present invention, an antenna having a shorter antenna length, a wider bandwidth, a higher gain, and a wider azimuth angle and receiving multiple directions can be received than conventional antenna systems. This makes it possible to receive multiple channels well and adopts the concept of an active antenna, economically functional and simple to install, including amplifier capability without a separate amplifier.

Power is supplied by using solar cells without extra power, so electrical safety is good and users can install it easily.

The rooftop dirt of the existing antenna system is equipped with small antennas, power supplies and related modules in the enclosure to make it look beautiful and safe and durable by protecting the antenna system from wind, snow, rain and solar heat. Even if the user does not have the expertise, it can be installed simply by the manual.

1A and 1B show a conventional antenna;
2A and 2B are diagrams illustrating an antenna system for receiving terrestrial DTV broadcasting according to an embodiment of the present invention.
Figures 3a, 3b, and 4 is a schematic view of the radome enclosure according to an embodiment of the present invention.

The present invention relates to a small high-performance antenna for terrestrial digital broadcasting reception installed on the roof of a building, so that anyone can easily install the antenna by miniaturizing the antenna and attaching a low noise amplifier using a solar cell and a built-in enclosure considering aesthetics.

The present invention has a low-noise amplifier for synthesizing several small antennas to obtain a high gain, such as a large antenna, there is a device for generating power using a solar cell and storing it in a charger and providing power from the charger to the antenna It relates to a system that is equipped with small antennas, power supplies and related modules in an enclosure to make it look beautiful and to make the antenna system protected from wind, snow, rain and solar heat, thereby making it safe and durable.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2A, 2B and 4 are diagrams illustrating the configuration of an antenna system for receiving terrestrial DTV broadcasting according to an embodiment of the present invention.

In the present invention, the solar cell panel 40 for making a power source as shown in Figures 2a and 2b is attached to the lid of the radome housing, or as shown in Figure 4 to install the antenna and the solar cell, LNA module separately to charge the power obtained here The charger 50 is attached to the lower portion of the lid so that charging and power supply occur at the same time so that power can be supplied even at night or when power cannot be obtained.

The radome lid is manufactured to be inclined at an angle suitable for standing and attaching the solar cell panel 40 and to be rotated so that it can be adjusted to the direction of the sun. The individual antenna 10 is made of a logarithmic antenna having a wide bandwidth, etc., but is made flat and not to be large because the size is within the horizontal and vertical half-wavelength. The individual antenna 10 is inputted to the passive power synthesizer and then amplified or amplified using the antenna active element (LNA1) 20 to synthesize power.

Since the signal output from the antenna active element (LNA1) 20 has a constant impedance, it is obtained by using the antenna active element (LNA2) 60 through the N: 1 power synthesis element 60 to obtain the necessary amplification factor. do. The spacing between the antennas 10 is preferably half wavelength (30 cm) vertically or horizontally.

In the case of a power synthesizer, when an antenna amplifier is used as an active element for antenna (LNA2) 60, two or more antennas 10 may be directly attached and synthesized without a separate circuit. In general, a separate power synthesis circuit is manufactured. The input / output impedance is made constant so that the input / output impedance is matched with the antenna active element (LNA2) 60.

The overall gain of gain is about 10-30dB. The lengths from the respective antennas 10 to the power combining points must be the same to match the phases in order to achieve power combining. The shorter the length, the lower the power loss and the lower the noise figure.

At this time, since the noise induced in each antenna 10 is different from each other, the noise is not added even when synthesized, but the signals are added in the same phase to have a synthesis effect.

The radome should be able to pass radio waves well, be strong and protected from ultraviolet rays, and it is advantageous to have a cylindrical shape so that resistance from wind and the like is low.

As described above, the present invention provides a wideband planar antenna capable of receiving both UHF bands (470-800 MHz) in a television broadcasting antenna 10 installed on the roof of a building, having a length and width of about half the wavelength. After placing two or more at half wavelength intervals vertically or horizontally, amplifying and synthesizing the electric field induced in each antenna 10 using the low noise amplifiers 20, 30, and 60 for the antennas, and then antenna gain is obtained by wideband frequency. Achieve high in the range, widen the receiving azimuth angle of the antenna, and arrange the individual antennas 10 in accordance with the direction in which the broadcast signal arrives so that multiple broadcast signals can be received by one antenna system and obtain the necessary amplification gain without a separate amplifier. The noise figure can be lowered by implementing and attaching a low noise amplifier capability directly to the antenna 10.

The power is obtained from the solar panel 40 and stored in the charger 50, so that the stored electricity can be supplied at night as well as low.

Power supply, antenna, and power synthesis and amplifier using solar cell are put into the enclosure to be protected from wind, snow, rain and solar heat as shown in Figs. It can be easy for users to install.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above-described embodiments, which can be variously modified and modified by those skilled in the art to which the present invention pertains. Modifications are possible. Accordingly, the spirit of the present invention should be understood only in accordance with the following claims, and all equivalents or equivalent variations thereof are included in the scope of the present invention.

Claims (5)

An antenna for receiving terrestrial DTV broadcasting frequency full band (UHF) with a wideband logarithmic antenna;
A low noise amplifier (LNA) attached to the antenna itself to minimize signal transmission loss and amplifying a low power level signal of the antenna;
A radome in which the antenna and the low noise amplifier are embedded;
A solar cell panel attached to an upper portion of the radome to generate power supplied to any one of the antenna and the low noise amplifier; And
A charger attached to a lower portion of the radome to charge power generated by the solar cell panel; An antenna system for terrestrial DTV broadcasting reception, comprising: a. The method of claim 1,
The antenna system for receiving a terrestrial DTV broadcast, characterized in that implemented as a small flat antenna. delete The method of claim 1,
And the low noise amplifier amplifies and synthesizes an electric field induced by the antenna. delete

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