KR200181680Y1 - Antenna for satellite communication - Google Patents

Abstract

The present invention relates to an antenna for a satellite communication to mount the antenna and the communication equipment to a mobile body, such as a ship or a vehicle, to provide a two-way communication service using a communication satellite.

To this end, the present invention includes a main reflector for reflecting a transmission radio wave and a reception radio wave coming from a satellite; A mixed radiator provided on the main reflector in the axial direction of the antenna to radiate the received radio waves or to receive received radio waves; A plurality of axial displacement rotating sub-reflective plates which are displaced from the antenna axis and reflect the received radio waves reflected from the main reflecting plates to the mixed radiator; Rotate the plurality of axial displacement sub-reflection plates at high speed and track the satellite direction along the 0 axis of the equivalent monopulse wave generated by the high speed rotation of the sub-reflection plate, so that the antenna axis direction always faces the satellite direction. It characterized in that it comprises an automatic tracking motor drive means for controlling the rotation of the reflector.

Description

ANTENNA FOR SATELLITE COMMUNICATION}

The present invention is to mount the antenna for satellite communication in a mobile body such as a ship or a vehicle to automatically track the antenna direction to always be the satellite direction in communication service during movement. The present invention relates to an antenna for satellite communication that can rotate to form an equivalent monopulse waveform, and input and output it to a single horn horn copier to accurately track the antenna radiation axial direction in the satellite direction.

In the conventional antenna for satellite communication, when the ship's or moving object's horizontal, vertical, left and right rotation directions fluctuate, the antenna axial direction must always be maintained in the satellite direction, and through the motor driving means to automatically track the satellite direction. The antenna should rotate automatically.

In order to automatically track the conventional antenna, five mixed copy machines are installed, one is used for data communication, one pair is used for horizontal communication, and the other pair is vertical tracking monopulse (MONOPULSE). A wave was formed to automatically track the satellite direction.

However, when tracking the satellite direction in this way, the space occupied by the mixed copying machine is large, and the volume of the satellite communication antennas for ships and moving objects is increased, and the price is increased.

In addition, since the conventional antenna for satellite communication uses separate transmission and reception coaxial rotary joints, the installation of the rotary joint is accompanied by difficulty in installing the rotary joint and increases in price.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an antenna for a satellite communication service to the two-way communication service using a communication satellite by mounting the antenna and the communication equipment on a moving object such as a ship or a vehicle. .

In order to achieve the above object, the present invention provides a main reflector for reflecting a transmission radio wave and a reception radio wave coming from a satellite; A mixed radiator provided on the main reflector in the axial direction of the antenna to radiate the received radio waves or to receive received radio waves; A plurality of axial displacement rotating sub-reflective plates which are displaced from the antenna axis and reflect the received radio waves reflected from the main reflecting plates to the mixed radiator; Rotate the plurality of axial displacement sub-reflection plates at high speed and track the satellite direction along the 0 axis of the equivalent monopulse wave generated by the high speed rotation of the sub-reflection plate, so that the antenna axis direction always faces the satellite direction. It provides an antenna for satellite communication comprising an automatic tracking motor drive means for controlling the rotation of the reflector.

In the present invention, the V (outwardly curved) sub-reflective plate, and / or casee grain-type sub-reflective plate, and / or Gregorian-type sub-reflective plate, and / or rotational horn horn, and / or inclined surface sub-reflective plate may be used. The horn copier may be placed at a focal length of the plurality of axial displacement sub-reflection plates, and the satellite directions may be automatically tracked by rotating the plurality of axial displacement rotation sub-reflection plates at high speed.

In the present invention, in particular, the plurality of axial displacement rotating sub-reflection plate on the antenna axis inclined with respect to the axial direction, it is also possible to rotate the sub-reflection plate inclined with respect to the antenna axial direction.

In addition, in the present invention, a rotary joint and a power slip ring for rotating the horizontal rotation support of the antenna is composed of one coaxial cable, and the transmission intermediate frequency and the reception intermediate frequency are different from each other by transmitting upward and downward through the same coaxial cable. Can be received.

In the present invention, the plurality of axial displacement rotation sub-reflection plate, a four-way sensor, true north sensor, horizontal gyro sensor and each of the rotary axis sensor is attached; The automatic tracking motor driving means receives all and / or some of the sensors and the difference signal of the equivalent monopulse with respect to the received high frequency signal, and vertical, horizontal and horizontal rotation for rotating the antenna so that the antenna direction is the satellite direction. It is characterized by controlling the motor.

1 is a front view showing an antenna configuration according to an embodiment of the present invention

2 is a side view for explaining the antenna driving part of FIG.

3 is a reference diagram showing an example of an axial displacement rotation sub-reflection plate that can be used in the present invention

4 is a plan view of the antenna when the antenna faces in the vertical air direction

<Explanation of symbols for main parts of the drawings>

1: Mixed copy machine 2: Main reflector

3, 3 ': Axial displacement V (outward bending) type rotating sub-reflective plate

4, 4 ': Axial displacement case grain type rotary sub-reflective plate

5, 5 ': Axial displacement Gregorian rotary sub-reflective plate

6, 6 ': Axial displacement rotary horn

7, 7 ': Inclined reflector rotating sub-reflective plate

8: diplexer 9: frequency conversion and high power amplifier

10: frequency conversion and low noise amplifier 11: divider

12: Coaxial Rotary Joint and Power Slip Ring

13: transmit / receive intermediate frequency diplexer

14: intermediate frequency transmitter 15: intermediate frequency receiver

16a: vertical rotation motor and gear 16b: vertical rotation support

17a: horizontal rotation motor and gear 17b: horizontal rotation support

18a: left and right rotation motor and gear 18b: left and right rotation support

19: automatic tracking motor drive means 20: antenna pedestal

21: snow cover (rainproof) A: antenna radiation axis 4-way sensor

B: True North Sensor C: Horizontal Sensor (Gyro)

D: axis sensor

These objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description.

The present invention below proposes a satellite communication antenna mounted on a mobile body such as a ship or a vehicle as a preferred embodiment. In addition, in the present specification, the antenna for satellite communication is described, but the technical idea of the present invention is not limited thereto, but may be variously modified and modified by those skilled in the art.

1 is a front view showing an antenna configuration according to an embodiment of the present invention, Figure 2 is a side view for explaining the antenna driving portion of FIG.

1 and 2, an intermediate frequency transmitter 14, a transmission and reception intermediate frequency diplexer 13, an antenna pedestal 20 for rotating a horizontal rotation support, and the center of the antenna pedestal A coaxial rotary joint and a power slip ring 12 attached thereto, a frequency conversion and high output amplifier 9 for high-frequency conversion and amplification of a signal coming from the coaxial cable from the diplexer, and a reception radio wave from a radio wave and a satellite. A main reflector (2) reflecting a light source, a horn copier (1) provided on the main reflector in the antenna axial direction, radiating the transmitted radio wave or receiving a received radio wave, and being displaced from the antenna axis, A plurality of axial displacements attaching a four-way sensor, a true north sensor, a horizontal gyro sensor, and respective rotation axis sensors, and reflecting the received radio wave reflected from the main reflector to the mixed copy machine. I reflector portion (in the drawing that shows a case of a V-type (??) reflecting plate portion (3, 3 ') bent outward mounting example) and; Rotate the plurality of axial displacement sub-reflection plates at high speed, receive all and / or some of the sub-reflection plate sensors, and receive a high frequency signal (equivalent monopulse difference signal), and generate the equivalent by the high speed rotation of the sub-reflection plate. Automatic tracking motor driving means for tracing the satellite direction along the zero axis of the monopulse wave, and controlling the vertical, horizontal and horizontal rotating motors for rotating the antenna so that the antenna axis always faces the satellite direction. (19), a frequency conversion and low noise amplifier (10) for processing signals received from the mixed copy machine and transmitted through a diplexer, a divider (11), an intermediate frequency receiver (15), rainproof or snowproofing And a dragon cover 21. At this time, the rotary joint and the power slip ring for rotating the horizontal rotation support for the horizontal rotation of the antenna is composed of one coaxial cable, the transmission intermediate frequency and the reception intermediate frequency is different from each other by transmitting upward and downward through the same coaxial cable Can be received. When the motor driving power is drawn out from the antenna pedestal 20 and supplied when the antenna rotates, a power supply rotary slip ring attached to the coaxial rotary joint is attached to the motor driving power using the slip ring. By supplying power, it is possible to simultaneously supply power to motors, frequency conversion and high power amplifiers, frequency conversion and low noise amplifiers, and motor drives for automatic antenna tracking.

3 is a reference view showing an example of an axial displacement rotating sub-reflection plate that can be used in the present invention, Figure 4 is a plan view of the antenna when the antenna is directed in the vertical air direction.

Referring to FIG. 3, the plurality of axial displacement rotating sub-reflection plates are convex downward, such as V (outward bending) type sub-reflection plates 3, 3 ′, which are bent outwards, and / or reference figure (a). Case-shaped sub-reflection plates 4, 4 ', and / or up-convex Gregorian-type sub-reflection plates 5, 5', and / or rotatable, such as reference diagram (c). The horn horn 6, 6 ', and / or the inclined surface sub-reflective plate (7), such as reference diagram (d) may be of any one form. In particular, the plurality of axial displacement rotating sub-reflection plates may be inclined with respect to the axial direction on the antenna axis to rotate the sub-reflection plates inclined with respect to the antenna axial direction to automatically track the mono pulse wave.

Referring to FIG. 4, the auto-tracking motor driving means for each of the axial displacement rotating sub-reflection plates 3, 3 ′ (4, 4 ′), 5, 5 ′, 6, 6 ′ (7, 7 ′). According to (19), the shape of the main reflector and the sub-reflective plate appearing in the vertical air direction can be seen. At this time, in order to rotate the plurality of axial displacement rotating sub-reflection plate or axial displacement feed horn at high speed, it is preferable to install a rotary motor on each of the axial displacement sub-reflection plate or the feed horn.

Referring to the operation of the antenna for satellite communication according to the present invention configured as described above and the action and effects derived therefrom are as follows.

First, the transmission intermediate frequency transmitted from the intermediate frequency transmitter 14 passes through the transmission / reception intermediate frequency diplexer 13, and then a coaxial rotary joint and a power source attached to the center of the antenna pedestal 20 by a coaxial cable. It is transmitted via the slip ring 12 to the frequency conversion and the high power amplifier 9. In this frequency conversion and high output amplifier 9, the intermediate frequency band propagation is frequency converted and high output amplified into a signal of a high frequency band and then radiated in the mixed copying machine 1. At this time, the radiated high frequency is first reflected by the axial displacement rotating V sub-reflection plates 3 and 3 ', and then reflected again by the main reflection plate 2 and transmitted to the satellite.

On the contrary, the radio waves coming from the satellites are first reflected by the main reflector 2, and are again reflected by the axial displacement rotating V subreflective plates 3 and 3 'and received by the mixed copying machine 1. Direct attachment is also possible when an axial displacement horn copier is attached at the focal point, that is, the position of the sub-reflection plate. The received signal is passed through the diplexer 8, the frequency conversion and the low noise amplifier 10 in turn, and then frequency-converted to the receiving intermediate frequency (different from the transmitting intermediate frequency), and then partly distributed through the divider 11. And then synthesized at the input of the frequency conversion and high output amplifier 9. In this way, the reception intermediate frequency signal is transmitted in the same direction as the transmission intermediate frequency signal through the same coaxial rotary joint and power slip ring 12 through the same coaxial cable as the transmission intermediate frequency signal. After passing through 13), it is received by the intermediate frequency receiver 15.

In the transceiving process, when the ship or the moving object changes in the horizontal, vertical, left and right rotation directions, the antenna should rotate while automatically tracking the satellite direction to maintain the satellite direction.

The present invention installs only one horn copying machine and rotates the sub-reflection plate at high speed after the shaft change, so that an equivalent MONOPULSE wave similar to a horizontal / vertical tracking monopulse wave is generated and inputted to the automatic tracking motor driving device 19, and the equivalent mono Motor rotation is possible, which automatically tracks the zero point (ie satellite axis direction) on the pulse wave.

That is, by receiving the radio wave coming from the satellite, the splitter 11 distributes the received signal so that the frequency conversion attached to the horn copier 1 and the output of the low noise amplifier 10 become the 0-axis, The motor driving power of the automatic tracking and motor driving device 19 is sent to the tracking motor driving device 19, respectively, to the vertical rotating motor and gear 16a, the horizontal rotating motor and gear 17a, the left and right rotating motor and gear 18a. Rotate each to rotate the vertical rotation support 16b, the horizontal rotation support 17b, and the left and right rotation support 18b, respectively, so that the antenna radiation axis direction H is automatically tracked so as to be the communication satellite direction. In addition, the cover 21 is installed in order to prevent rain or snow.

In addition, when the motor driving power is drawn out from the antenna pedestal 20 and supplied when the antenna rotates, the slip slip is attached to the coaxial rotary joint and the power slip ring 12 provided in the power slip ring 12. By using the ring to supply the motor driving power, the motor, frequency conversion and high power amplifier, frequency conversion and low noise amplifier, and motor driving device for antenna auto tracking can be simultaneously supplied.

In addition, by using the coaxial cable at the same time by differently transmitting the intermediate frequency and the receiving intermediate frequency, it is possible to improve the price competitiveness and solve the installation difficulties.

The present invention is not limited to the embodiments described above, it can be various modifications and changes by those skilled in the art, which is included in the spirit and scope of the present invention defined in the appended claims.

Therefore, the present invention makes it possible to form the equivalent monopulse waveform required for satellite tracking using a single mixed radiator and multiple sub-reflection plates axially displaced from the antenna radiation axis and rotating at high speed. Since the antenna radiation axis can be automatically tracked in the satellite direction through the input and output through the antenna, it is possible to implement an antenna for satellite communication that can accurately track the satellite position while improving the price competitiveness with a simple configuration.

Claims (6)

A main reflector reflecting a transmission radio wave and a reception radio wave coming from the satellite; A mixed radiator provided on the main reflector in the axial direction of the antenna to radiate the received radio waves or to receive received radio waves; A plurality of axial displacement rotating sub-reflective plates which are displaced from the antenna axis and reflect the received radio waves reflected from the main reflecting plates to the mixed radiator; Rotate the plurality of axial displacement sub-reflection plates at high speed and track the satellite direction along the 0 axis of the equivalent monopulse wave generated by the high speed rotation of the sub-reflection plate, so that the antenna axis direction always faces the satellite direction. And an automatic tracking motor driving means for controlling the rotation of the reflector. The method of claim 1, wherein the plurality of axial displacement sub-reflection plate, An antenna for satellite communication, characterized in that it comprises a V-shaped sub-reflection plate, and / or a casein-type sub-reflection plate, and / or a Gregorian-type sub-reflection plate, and / or a rotating whid horn, and / or an inclined sub-reflection plate. The method according to claim 1 or 2, And the mixed radiator is positioned at a focal length of the plurality of axial displacement sub-reflection plates, and the satellite directions are automatically tracked by rotating the plurality of axial displacement rotation sub-reflection plates at high speed. According to claim 1 or 2, wherein the rotary joint and the power slip ring for rotating the horizontal rotation support for the horizontal rotation of the antenna consisting of one coaxial cable, the same as the transmission intermediate frequency and the reception intermediate frequency respectively different An antenna for satellite communication, characterized in that uplink transmission, downlink reception via a coaxial cable. The method of claim 1, wherein the plurality of axial displacement rotating sub-reflection plate is installed on the antenna axis inclined with respect to the axial direction, and the sub-reflection plate is rotated inclined with respect to the antenna axial direction to automatically track the mono pulse wave. Satellite communication antenna, characterized in that. The method of claim 1, In the plurality of axial displacement sub-reflection plate, Attaching a four-way sensor, a true north sensor, a horizontal gyro sensor, and respective rotation axis sensors; The automatic tracking motor driving means, Receiving all and / or some of the sensors and the difference signal of the equivalent monopulse to the received high frequency signal, characterized in that for controlling the vertical, horizontal, left and right rotation motor for antenna rotation so that the antenna direction is the satellite direction Satellite communications antenna.