KR980009775U - Elevation Indicator for Parabolic Antenna - Google Patents

Abstract

The present invention relates to an elevation display device for a parabolic antenna, wherein the reflection plate 11 is connected to the support rod 16 and the pivot 14, and the azimuth angle and elevation angle so that the reflection plate 11 faces the satellite of the broadcast. In the parabolic antenna to be installed in accordance with, the elevation angle is marked by a scale or a number, and is mounted on the back of the reflecting plate is mounted on the back of the pivot (14) in accordance with the rotation of the reflecting plate to display the elevation angle ( 13) and a guide (15) rotatably attached to the pivot (14) so as to point to the earth's center at all times by the earth's gravity, and the scale or number displayed on the elevation display plate as the guide plate rotates. This point is to display the elevation angle.

Description

Elevation Indicator for Parabolic Antenna

1 is a perspective view showing a parabolic antenna for satellite broadcasting reception according to the present invention.

* Explanation of symbols for the main parts of the drawings

11: reflector 12: feed horn 13: elevation display

14 Pivot 15 Instructions 16 Reflector Support Rod

17: feed horn support 18: mounting bracket

[Purpose of designation]

The technical field to which the design belongs and the prior art in the field

The present invention relates to an elevation display device that can easily align the direction of the antenna to the elevation angle of a corresponding area when a parabolic antenna for receiving satellite broadcasting is installed on a veranda.

In general, direct satellite broadcasting (DBS) is a satellite equipped with a microwave propagation station in space, and the earth receiver receives the radio waves from the earth station and transmits them back to earth. In order to receive satellite broadcasting directly, each receiver must be equipped with a parabola antenna. Here, the satellite located on the ground orbit includes a communication repeater and a broadcast repeater. The communication repeater transmits and receives signals received from one earth station to another station, and thus is low power, whereas the broadcast repeater is received so that a wide range of receivers can receive directly. The signal must be amplified sufficiently, so it is relatively large. At this time, the satellite moves along the orbit of a certain height on the earth, which means the trajectory of the moving point of the rotating satellite according to the law of universal gravity. The closer the satellite is to Earth, the greater the gravitational force of the Earth, so the speed of rotation must be faster if the satellite is not to fall to Earth.

The satellites currently in use are shot at about 35,860 km above the Earth's orbit, allowing them to enter orbit and rotate like the Earth's rotation cycle. As the satellite rotates like the earth's rotation cycle, it appears to be stationary at any point of time when viewed from the earth. These satellites are called geostationary satellites, and these satellites are not time-limited for transmission and contain communications across the globe. The advantage is that a large number of satellites are not needed for this purpose. On the other hand, the orbits of the satellites can be divided into circular orbits and elliptical orbits by the shape of the orbits, and low earth orbit (LEO) and medium orbits (MEO) by the altitude of the orbit (height from the ground). And geostationary earth orbit (GEO). Low orbit generally has altitude of 750 ~ 1500Km, and has advantages such as satellite power reduction, antenna size reduction, short propagation delay time, use of positioning Doppler effect, and system expansion capability. Medium tracks have altitudes ranging from 10,000 km to 20,000 km.

The satellite communication system using the satellite is composed of a satellite body for receiving, amplifying the radio wave from the ground, converting the frequency, and transmitting it back to earth, a channel through which the radio waves are transmitted, and an earth station for transmitting and receiving radio waves from the earth. Satellites are generally composed of antenna groups for transmission and reception, telemeters, satellite repeaters, and power meters. The outer wall is coaxial with solar cells. The antenna group includes a Hemi / Zone beam antenna, a 14/11 GHz spot beam antenna, and the antenna group is selected depending on the frequency band used and the size of the beam.

The power of the satellite mainly uses solar energy, but for several weeks every year, the satellite's orbit passes through the shade of the earth, which causes solar power to be unavailable. Batteries can be recharged, but their life is not permanent, and the life of the batteries and the amount of fuel on board for orbital calibration will limit the life of today's satellites to 8 to 10 years.

In addition, satellites use a device called a satellite repeater to relay radio signals. A satellite repeater receives signals from a transmitting station on the earth, amplifies its size, retransmits the frequency, and can be captured by a receiving antenna on the earth. To be. Thus, larger and more powerful satellite repeaters allow for satellite communications even with smaller antennas and inexpensive ground stations. The capacity of the satellite repeater is determined according to the type of signal to be relayed. In the case of Mugunghwa-ho Satellite, three repeaters are used for broadcasting and 12 repeaters are used for communication. The communication repeater is to use 7 for video relay, 1 for inter-station relay, 3 for administrative communication and emergency communication, and 1 for low speed communication.

On the other hand, the earth station consists of an earth station antenna, a low noise amplifier, a high power amplifier, a modulator, a controller, and a transmitter. The earth station can be classified into a fixed station, a coast station, a coast station, a land mobile station, and an individual receiving station according to the form of receiving radio waves. have. In this case, the individual reception refers to a radio wave emitted from a satellite, which is directly received by a small (about 75 cm) dish-shaped antenna receiver in each home or office (DBS: direct broadcasting satellite).

On the other hand, the trajectory of the stationary satellite as described above exists on the equator plane with an inclination angle of 0 °, and has an eccentricity of 0 ° and has a circular shape. The angular velocity of the satellite is the same as the angular velocity of the earth and the same direction. The satellite's trajectory appears at a point above the equator and the satellite is permanently perpendicular to this point. Thus, from the ground, the satellite appears to be fixed in the air.

In addition, the reception antenna for DBS used in each home or office uses a parabolic reception antenna or a flat antenna, and the parabolic reception antenna has very sharp directivity. In this way, since the directivity in the microwave band is installed, the parabolic antenna cannot be received unless the antenna direction is exactly toward the satellite, and cannot be received by roughly adjusting the direction as in the case of the VHF antenna.

Therefore, in order to install the parabolic antenna for DBS as described above, it is necessary to know the elevation and azimuth in order to install the antenna to face the satellite accurately.

However, conventionally, when installing a parabolic antenna, by using a compass (compass) to position the reflector at the azimuth angle calculated according to a predetermined equation, in order to meet the elevation angle, the reflector is approximately rotated at an angle determined by the predetermined equation and then television The antenna was fixed in the direction of the best image quality while watching the broadcast received. As described above, when the parabolic antenna is installed for satellite broadcasting reception, the installer does not accurately install the antenna while looking at the TV screen and installs the direction approximately. In particular, because the DBS broadcast signal has a strong directivity, it is difficult to install an antenna because the TV screen disappears because the signal is reduced by about 3dB even if it is only 1 ° to 2 ° away from the optimum elevation angle. And when installing the antenna, the antenna is usually installed on the roof or veranda, and the TV receiver is located in the room, so it is inconvenient to have a person who monitors the TV screen and the person who installs the antenna, or the installer has to carry the portable TV. .

[Technical Challenges to be Done]

Accordingly, an object of the present invention is to provide an elevation display device that displays an elevation angle of a current reflector according to a direction of an antenna when installing an antenna in order to solve the above problems.

In order to achieve the above object, the device of the present invention has a reflector connected to a support rod and a pivot, and a parabola antenna installed at an azimuth angle and an elevation angle so that the reflector faces the satellite of the broadcasting, wherein the elevation angle is a scale or Marked by numbers, attached to the rear of the reflecting plate is rotated with respect to the pivot in accordance with the rotation of the reflecting plate to display the elevation angle, and attached to the pivot pivotally attached to the pivot at all times the earth center The guide is configured to indicate that the guide points to the scale or number displayed on the elevation display panel according to the rotation of the reflector is characterized in that to display the elevation.

As described above, since the elevation display device can display the elevation angle according to the rotation of the parabola antenna, the elevation angle can be easily adjusted when the antenna is installed.

[Configuration and Action of Design]

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

First, in order to install a parabola antenna (also called a dish antenna), as described above, the elevation angle and azimuth angle of the satellite in the region must be obtained according to the following equation.

[Equation 1]

[Equation 2]

here, △ is 'satellite longitude-receiving location longitude', ø is the latitude of receiving location.

As in the above equation, the azimuth and elevation angles vary depending on the reception position and the position of the satellite. In the case of the Mugunghwa satellite, the orbit is a stationary orbit, which is 116 ° above latitude (0 ° latitude and 116 ° longitude). As such, when the position of the broadcast satellite to be received is determined, the azimuth and elevation angles are determined according to the latitude and longitude of the reception area.

Next, the parabolic antenna according to the present invention will be described. As shown in FIG. 1, the parabolic antenna has a reflector 11 on a parabolic surface and a feed horn 12 is installed at a focal point thereof and has a dish shape. Also known as a dish antenna, it is the most used antenna in the microwave band or more microwave. Referring to FIG. 1, the feed horn 12 is positioned at the focal position of the reflecting plate 11 by the feed horn support 18, and the reflecting plate 11 is pivotally connected to the supporting rod 16 by the pivot 14. It can be rotated up and down about the axis and the support rod 16 is attached to the veranda by the mounting bracket 17. At this time, the elevation display panel 13 according to the present invention is attached to the back of the parabolic surface of the reflecting plate to rotate together with the rotation of the reflecting plate 11, the guide 15 attached to the pivot 14 to be rotatable at all times by gravity It is supposed to point to the center.

In order to install such a parabolic antenna, the antenna support rod 16 is fixed to the structure that is easy to install, such as a veranda, using a mounting bracket 17. At this time, the center of the reflective surface is directed toward the azimuth angle calculated previously.

Subsequently, after fixing the reflecting plate support bar 16, the inclination of the reflecting surface becomes the elevation angle obtained previously. In this case, when the elevation angle of the reflector is set, the elevation display device according to the present invention may point to the elevation angle so that the elevation angle can be easily adjusted. That is, since the elevation angle of the antenna is attached to the reflector 11 and rotated up and down with the reflector 11 is displayed as a number or a scale, the guide 15 indicates the elevation angle by moving the reflector 11 up and down. What is necessary is just to fix the reflecting plate 11 in the position. For example, when the elevation angle of the corresponding reception area is 40 °, the reflection plate 11 may be rotated up and down so that the guide 15 indicates the position where the scale of the elevation display plate 13 is 40 °.

[Effect of design]

As described above, according to the present invention, the reflector of the parabolic antenna is moved up and down so that the scale of the elevation plate attached to the reflector indicates the elevation of the corresponding position according to the instructions, and then the rotation of the reflector is fixed at that point. Since the elevation angle of the antenna can be easily adjusted, it is easy to install the antenna.

Claims (1)

In the parabolic antenna in which the reflector plate 11 is connected to the support rod 16 and the pivot 14, and the reflector plate 11 is installed at the azimuth angle and the elevation angle so that the reflector plate 11 faces the satellite of the broadcast, the elevation angle is a scale or a number. And an elevation display plate 13 which is attached to the rear surface of the reflection plate and rotates about the pivot 14 according to the rotation of the reflection plate to display the elevation angle, and is rotatably attached to the pivot 14. An elevation display device for a parabolic antenna comprising a guide (15) configured to point to the earth's center at all times by gravity, and indicating the elevation by indicating the scale or number displayed on the elevation display panel as the reflector rotates. ※ Note: This is to be disclosed based on the first application.