KR20100127045A - 3 band tracking antenna for satellite communication - Google Patents

Abstract

PURPOSE: A 3-band tracking antenna for a satellite communication is provided to improve design efficiency by using a selective reflective plate with low frequency. CONSTITUTION: An antenna body is comprised of a main reflection mirror and a sub reflection mirror. A motor driving unit rotates the antenna body. A sensor unit senses the angle of the antenna body. A frequency selection type reflector(110) transmits 3X band electric wave and reflects Ku/Ka band electric wave. A total reflection plate(112) totally reflects Ku / Ka band electric wave. An X-band feed horn(120) transmits and receives the transmitted X band electric wave. The Ku / Ka band multi feed horn(140) transmits and receives the reflected Ku/Ka band electric wave. An antenna control unit generates a control signal for tracking a satellite.

Description

3 BAND TRACKING ANTENNA FOR SATELLITE COMMUNICATION}

The present invention relates to a tracking antenna device for satellite communication, and more particularly, to selectively transmit and receive frequencies in a low loss frequency selective reflector in an automatic tracking antenna that simultaneously transmits and receives triple bands for satellite communication (X band, Ku band, Ka band band). The present invention relates to a three-band satellite communication tracking antenna for improving efficiency by reflecting and separating a frequency band and transmitting and receiving a transmitted signal through a feed horn for an X band and a reflected signal through a multi feed horn for a Ku / Ka band.

Also, depending on the application, the Ku band may be reflected and the X and Ka bands may be transmitted, or only the Ka band may be reflected and the X and Ku bands may be transmitted.

In general, satellite communication refers to launching a satellite at a certain altitude above the earth to perform a communication or broadcasting service, which is advantageous for communication between books, wallpaper, and mobile devices, and in the case of satellite broadcasting, TV difficulties in mountain walls or urban building areas. It can solve the problem, and can provide various services of high quality. The satellite communication system is divided into space parts related to satellites, ground parts such as earth stations and control stations installed on the ground, and signals parts of signals, that is, methods of transmitting or processing radio waves.

A satellite communication earth station is a ground facility that transmits and receives communication satellites and is basically composed of a transmitter, a receiver, and an earth station antenna. Generally, the antenna for satellite communication includes a king post antenna, a yoke & tower antenna, a wheel on track antenna, a beam wave guide antenna, Vehicle-mounted main reflector sub-reflective plate Off Set antenna. In addition, a large-caliber parabola is used as the main reflector, and a case-cable antenna composed of a sub-reflection mirror and a primary radiator of a rotation hyperbolic line is mainly used. The reflector plate of the satellite communication antenna is divided into small plates and large segments into multiple segments It was.

Meanwhile, the conventional triple band tracking antenna for satellite communication uses an X band or a Ka band or a Ku band feed horn behind the sub-reflector, so that the main reflector cannot be manufactured with a parabolic curved surface, and thus the efficiency cannot be increased by more than 50%. Moreover, since the sub-reflector is used as the frequency selective type, subtracting the loss, the efficiency is reduced to 40% or less, which causes inefficiency.

The present invention has been proposed to solve the above problems, and an object of the present invention is to install a three-band feed horn in the hub of the antenna base, and at the same time using the low-loss frequency selective reflection plate, the main reflector and the sub-reflector By developing the parabolic type instead of the parabolic type, it provides a tracking antenna device for three-band satellite communication that increases the design efficiency by 90% and enables high efficiency of more than 75% without subtracting various losses.

In order to achieve the above object, the antenna of the present invention is, for example, in the three-band satellite communication tracking antenna for transmitting and receiving the X-band and Ku-band, and Ka-band radio waves with the satellite, the main reflector and the sub-reflection mirror An antenna body portion formed; A motor driver for tracking the satellite by rotating the antenna body; A sensor unit for sensing an angle of the antenna body unit; A frequency selective reflector that transmits X-band radio waves and reflects Ku and Ka band radio waves during transmission and reception of triple bands; A total reflection reflector for total reflection of the Ku and Ka band radio waves of the triple band transmission and reception radio waves; An X band feed horn for transmitting and receiving the transmitted X band radio waves; Ku / Ka band multi feed horn for transmitting and receiving reflected Ku / ka band radio waves; An X-band processing unit for processing the X-band signal input and output through the X-band feed horn; A Ku band signal processor for processing Ku band signals inputted and outputted through the Ku / Ka band multi-feed horn; A Ka band signal processor for processing Ka band signals input and output through the Ku / Ka band multi feed horn; A selection switch for selecting one of the X band processor, the Ku band processor, and the Ka band processor; A beacon receiver for receiving a beacon signal of the band processor selected by the selection switch; An antenna control unit for generating a control signal for tracking satellites by adjusting the azimuth, elevation, and polar of the antenna from the beacon signal received by the beacon receiver and the angle signal detected by the sensor unit; And a power control unit for driving the motor driving unit according to a control signal of the antenna control unit, wherein the frequency selective reflector and the total reflection reflector, the X band feed horn, and the Ku / Ka band multi feed horn are all the main reflectors. Located in the hub of the base side is to modify the curved surface of the main reflector and the sub-reflective mirror to increase the efficiency by more than 90% is characterized by having a high efficiency of 75% or more even after subtracting the loss rate after design.

The tracking antenna device for the triple band satellite communication according to the present invention installs the feed horn of the three bands to the hub of the antenna base and at the same time, the main reflector and the sub reflector are not parabolic type by using the low loss frequency selective reflector. Developing with improved crystal efficiency improves design efficiency by nearly 90% and enables high efficiency of more than 75% without the loss of losses. In addition, according to the present invention, the frequency selective reflection plate has a honeycomb cell structure, a flat type, a concave surface, a convex surface, and the like, and various tuning patterns are formed on one surface to facilitate selection of a desired frequency band, and permits air and dielectric constant. Similarly, transmission loss can be greatly reduced.

The technical problems achieved by the present invention and the practice of the present invention will be more clearly understood by the preferred embodiments of the present invention described below. The following examples are merely illustrative of the present invention and are not intended to limit the scope of the present invention.

First, the tracking antenna device for three-band satellite communication according to the present invention can be applied to various kinds of antennas, for example, horizontal ± 60 ° rotatable kingpost antenna, horizontal ± 360 ° rotatable yoke antenna, horizontal ± 360 ° rotation It can be applied to a vehicle-mounted double reflector offset antenna or the like.

In addition, the present invention can be applied to a casee grain antenna or a Gregorian antenna, a dual reflector offset antenna, etc. Figure 1 is a side view of an example in which the present invention is applied to a casein antenna with a small reflector, Figure 2 is a casein antenna with a large reflector 3 is a side view of an example applied to the present invention, and FIG. 3 is a diagram illustrating an example of the present invention applied to a dual reflector plate Gregorian antenna (which may be fixed).

1 to 3, the tracking antenna device 100 for the triple band satellite communication of the present invention is X band and Ku in various types of satellite communication antenna device including the main reflector 102 and the sub-reflector 104 The frequency selective reflector 110, the total reflection reflector 112, and the triple band feed horns 120 and 140 for separating and receiving the signals of the band and the Ka band are installed in the hub 108 of the central base of the main reflector 102. Therefore, by developing the main reflector 102 and the sub-reflector 104 in the form of a curved surface rather than a parabolic type, the design efficiency is increased to near 90%, so that high efficiency can be obtained at about 75% or more without removing various losses.

And the casein-type triple band satellite communication antenna 100 according to the present invention, as shown in Figure 1, the sub-reflector 104 and the main reflector 102 is supported through the support 106 on the main reflector 102 ) Is facing each other, and the hub 108 located at the base of the center of the main reflector 102 is installed to have an inclination of approximately 45 degrees with respect to the central axis penetrating through the center, and is reflected from the sub-reflector 104 and is incident. The frequency selective reflector 110 transmits the X-band signal and reflects the Ku-band and Ka-band signals laterally, and a planar metal material that totally reflects the signals of the Ku-band and Ka-band incident in the lateral direction to the rear. An X-band feed horn 120 for receiving the X-band signal transmitted through the total reflection reflector 112, the frequency selective reflector 110, and a Ku-band and Ka-band signals reflected by the total reflection reflector 112. Ku / Ka It located DE multi-feed horn 140. And the antenna shaft supported by the pedestal support 30 is rotated in the horizontal direction ± 60 ° by the horizontal rotation reducer motor 10, the rod connected to the antenna hub through the vertical rotation reducer motor 20 and the hinge 44 ( 22, it is possible to rotate up and down about the white paper 42.

In case 2 of the casein-type triple band satellite communication antenna of FIG. 2, the reflector is large, and the feed horns 120 and 140, the frequency selective reflector 110, and the total reflection reflector 112 protrude from the center of the main reflector 102. Since the remaining configuration is the same as that of FIG. 1 and attached to the filled horn horn enclosure 109, further description thereof will be omitted.

As shown in FIG. 3, the mobile-mounted triple band satellite communication antenna 100 according to the present invention has a frequency on the front side after attaching the sub-reflector 104 through the support 106 to the offset main reflector 102. Optional reflector 110, total reflection reflector 112, 3-band feed horn (120, 140) is attached, the horizontal rotation angle of ± 360 ° rotation by vertically tracking the satellite by the reducer motor (vertical rotation of 0 to 90 degrees vertical tracking) It is an omnidirectional rotary type that is mainly used for moving objects such as ships and vehicles. And the main reflector 102 and the support shaft 107 is coupled through the hinge 105 to fold the main reflector 102 at the time of movement, and to install the main reflector 102 to be used again when installed and automatic tracking deceleration motor installed If it does not need to be folded when used for ships, it may be protected by a snow cover (not shown).

As described above, the triple band feed horn attachment positions in the various kinds of antennas to which the present invention is applied are all built in the hub 108 provided at the center of the main reflector, and the X, Ku, and Ka band radio waves coming from the satellites are provided. Is totally reflected at the main reflector 102 to reach the sub-reflector 104, it is again totally reflected at the sub-reflector 104 to arrive at the hub 108. At this time, the main reflecting mirror 102 is implemented as a single plate shape if it is small, it consists of a number of panels.

In addition, the hub 108 has a frequency selective reflector 110 which transmits an X-band signal among radio waves reflected from the sub-reflector 104 and enters the Ku-band and Ka-band signals laterally. The total reflection reflector 112 of the flat metal plate for totally reflecting the signals of the Ku band and the Ka band to the rear, the X band feed horn 120 for receiving the X band signal transmitted through the frequency selective reflector 110, and the total reflection reflector Ku / Ka band multi-feed horn 140 for receiving the Ku-band and Ka-band signal reflected at 112 is located, so the Ku, Ka band radio waves are reflected by the low-loss frequency selective reflector 110, and the X-band radio waves are Transmitting and entering the X-band feed horn 120. In addition, the reflected Ka and Ku band radio waves are totally reflected by the total reflection reflector 112 and input to the Ku / Ka band multi feed horn 140, and the Ka / Ka band multi feed horn 140 is again Ka and Ku band signals. To be separated.

4 is a view showing an automatic tracking system of a three-band antenna according to the present invention, the automatic tracking system according to the present invention is an antenna body 101 consisting of the main reflector 102 and the sub-reflector 104, The motor driver for tracking the satellite by rotating the antenna body 101, the sensor unit for detecting the angle of the antenna body 101, and transmits the X-band radio waves during transmission and reception of the triple band Ku and Ka A frequency selective reflector 110 reflecting the band radio waves, a total reflection reflector 112 reflecting the Ku and Ka band radio waves of the triple band transmission and reception radio waves, and an X band feed horn 120 for transmitting and receiving the transmitted X band radio waves. ), Ku / Ka band multi-feed horn 140 for transmitting and receiving the reflected Ku / ka band radio wave, X band signal processing unit 130 for processing the X band signal, and Ku for processing the Ku band signal Band signal processing unit 150, Ka band signal K a selection switch (SW) for selecting any one of a band signal processor 160, an X band signal processor 130, a Ku band signal processor 150, and a Ka band signal processor 160, and a select switch Antenna from the beacon receiver 170 for receiving the beacon signal of the band selected by (SW), the beacon signal received by the beacon receiver 170 and the angle signal detected by the sensor unit (S1, S2, S3) The antenna control unit 180 to generate a control signal for tracking the satellite by adjusting the azimuth and altitude of the polarity and the polarity of the motor, and the motor driving unit (M1, M2, M3) according to the control signal of the antenna control unit (ACU) 180 It consists of a power control unit (PCU) 190 for driving.

Referring to FIG. 4, the antenna body portion 101 has three directions (X-band, Ku-band, Ka-band) while tracking satellites by adjusting azimuth, elevation, and polarity by motor driving units M1, M2, and M3. It consists of a main reflector 102 and a sub reflector 104 for transmitting and receiving radio waves to and from the satellite, and includes a frequency selective reflector 110 and a total reflector 112, an X-band feed horn 120, and a Ku / Ka band multifeed. Horns 140 are all located at base-side hub 108 of main reflector 102.

The motor driving units M1, M2, and M3 may be configured by the azimuth (horizontal) motor M1 for adjusting the azimuth angle of the antenna under the control of the power control unit 190, and the antenna under the control of the power control unit 190. Elevation (vertical) motor (M2) for adjusting the altitude angle, and feed horn rotation polar motor (M3) for adjusting the polarity of the antenna under the control of the power control unit 190, the sensor unit (S1) , S2 and S3 detect the azimuth angle of the antenna and transmit the azimuth (horizontal) angle sensor S1 for transmitting the antenna control unit 180 to the antenna control unit 180, and detect the altitude angle of the antenna to the antenna control unit 180. Elevation angle sensor (S2) for, and the polar angle sensor (S3) for detecting the polar angle of the antenna to transmit to the antenna control unit 180.

The X-band signal processor 130 may include a diplexer 131 for separating transmission and reception signals of the X-band feed horn 120, and a low noise amplifier (LNA) 132 for amplifying a received signal of the diplexer 131. And a down converter (D / C) 133 for downgrading the low noise amplified received signal to an intermediate frequency (IF) signal, a divider 134 for distributing the intermediate frequency signal into two signals, and a divider 134 for distribution. A data receiver 135 for receiving data from the received intermediate frequency signal, a transmitter 136 for modulating the X-band data to transmit a high frequency signal, and amplifying the signal of the transmitter 136 to the diplexer 131. And a high power amplifier (HPA) 137 for outputting.

The Ku band signal processing unit 150 includes a diplexer 151 for separating the transmission / reception signals of the Ku / Ka band multi-feed horn 140 and a low noise amplifier (LNA) for amplifying the received signal of the diplexer 151. 152, a down converter (D / C) 153 for downgrading the low noise amplified received signal to an intermediate frequency signal, a divider 154 for dividing the intermediate frequency signal into two signals, and a divider 154 for distribution. A data receiver 155 for receiving data from the received intermediate frequency signal, a transmitter 156 for transmitting a high frequency signal by modulating Ku-band data, and amplifying a signal from the transmitter 156 to the diplexer 151. And a high power amplifier (HPA) 157 for outputting.

The Ka band signal processor 160 includes a diplexer 161 for separating the transmission / reception signals of the Ku / Ka band multi-feed horn 140 and a low noise amplifier (LNA) for amplifying the received signal of the diplexer 161. 162, a down converter (D / C) 163 for downgrading the low noise amplified received signal to an intermediate frequency signal, a divider 164 for distributing the intermediate frequency signal into two signals, and a divider 164 for distribution. A data receiver 165 for receiving data from the received intermediate frequency signal, a transmitter 166 for modulating the data to transmit a Ka band high frequency signal, and amplifying the signal of the transmitter 166 to the diplexer 161. And a high power amplifier (HPA) 167 for outputting.

The selector switch SW selects any one of the X-band signal processor 130, the Ku-band signal processor 150, and the Ka-band signal processor 160, and the beacon receiver 170 is connected to the selector switch SW. Receives a beacon signal of the band selected by the antenna, the antenna control unit 180 adjusts the azimuth, elevation and polarity of the antenna from the beacon signal received by the beacon receiver 170 and the angle signal detected by the sensor unit to adjust the satellite Generates a control signal for tracking, and the power control unit 190 drives the motor drive unit (M1, M2, M3) according to the control signal of the antenna control unit (ACU) to allow the antenna to track the satellite.

Figure 5 is a schematic diagram of a multi-feed horn for Ku / Ka band according to the present invention, (A) is a side view and (B) is a rear view.

Ku / Ka band multi feed horn 140 according to the present invention, as shown in Figure 5, dually implemented as a circular waveguide feed horn for Ka band implemented on the inside and a Ku horn feed horn implemented on the outside The Ka band feed horn is composed of a TE11 mode circular waveguide 142 and a hybrid coupler 143 into which the dielectric horn 141 is inserted, and the Ku band feed horn is a corgate feed horn 144 and a Ku band waveguide 145. , 3 dB couplers 146-1 and 146-2.

Referring to FIG. 5, the Ku / Ka band combined multi feed horn 140 according to the present invention includes a Ku band corgate horn 144 and a Ka band dielectric horn 141 embedded in the center thereof. The Ku-band feed horn is configured as a corgate and passes through the slot in four directions at the midpoint and is transmitted to the waveguide 145 for the Ku-band, where the horizontal 0 degree and 180 degree slots are combined in the 3 dB coupler 146-1. Ku-band horizontal polarization is drawn out, and the vertical 0 degree and 180 degree direction slots are combined in the 3dB coupler 146-2 with a waveguide to draw out the vertical polarization. The Ka band feed horn reduces the space by using a dielectric horn to reduce the space, transmits the circular waveguide TE11 mode to the back of the Ku band feed horn, and separates and draws the circular polarization horizontally and vertically in the OMT. 143) to output. In addition, a diplexer is additionally attached to each output to enable transmission and reception by connecting a transmitting HPA and a receiving LNA.

6 is a schematic view showing a flat frequency selective reflector according to the present invention, where (A) is a side view and (B) is a front view.

Referring to FIG. 6, in the planar low loss frequency selective reflector 110 according to the present invention, two low dielectric constant thin films 115 and 116 are prepared on both sides (two planes), and then a plurality of low dielectric constant support thin films 117 are provided between the two sides. When inserted and glued together, a large amount of space is formed, and the overall dielectric constant is close to air, and the dielectric constant 1 is close, so that the radio wave transmission loss is close to air, so that the transmission loss is 0.1 to 0.2 dB or less. In addition, a plurality of thin film copper plate resonating elements 118 that resonate at a frequency that requires reflection on either side of the two surfaces are attached at close intervals to selectively transmit or reflect only a specific resonance frequency.

7 is a schematic view showing a concave frequency selective reflection plate according to the present invention, (A) is a side view, (B) is a front view, and FIG. 8 is a schematic view showing a convex frequency selective reflection plate according to the present invention, (A ) Is a side view and (B) is a front view.

7 and 8, the concave curved frequency selective reflector 210 according to the present invention forms a honeycomb space with an insulating support 217 between the concave double-sided films 215 and 216. A plurality of patterns of the resonator element 218 are formed, and the convex curved frequency selective reflector 310 forms a honeycomb space with an insulating support 317 between the convex double-sided films 315 and 316, and then resonates on the convex surface. A large number of patterns of the element 318 are formed. The concave-convex and convex-convex frequency selective reflectors 210 and 310 are somewhat different in shape, but the principles of operation are the same as the planar frequency selective reflectors described above. However, it is possible to design various required surfaces according to the use. 7 and 8 may also be used instead of the conventional sub-reflective plate to transmit and focus the radio waves to the feed horn located in the main reflector focus.

9 is a view showing the shape of the resonant elements applied to the frequency selective reflector according to the present invention.

 As shown in FIG. 9, the resonant element of the frequency selective reflector according to the present invention has a metal thin film type (A, B, C, D, etc.) and can be used by selecting one of several types such as a cross type and a square. Types A and C are broadband and B is resonant. Select wide band type or high resonant Q type according to the frequency selection difference. D-type is also used as the double resonance type. The dual resonant type can transmit or reflect two frequency bands. Types A and C should be about 1/2 of the length and width, and type B will be resonant. Type D resonates at high frequency, while the internal angle resonates at low frequency and transmits or reflects.

Next, the operation of the tracking antenna for the triple band satellite communication according to the present invention configured as described above is as follows.

1. X-band signal transmission / reception path

The X-band transmitter 136 modulates the transmission data into the X-band signal, amplifies the high-power amplifier 137 to high power, and transmits the amplified data to the diplexer 131. The diplexer 131 transmits the X-band transmission signal to the X-band feed horn 120, and the transmission signal of the X-band feed horn 120 passes through the frequency selective reflector 110 and the sub-reflector 104 and the main beam. It is radiated to the satellite side via the reflector 102.

The triple-band satellite signal arriving from the satellite to the hub 108 via the main reflector 102 and the sub reflector 104 is transmitted to the X band feed horn 120 by transmitting only the X band signal from the frequency selective reflector 110. It is pulled in. The X-band received signal introduced into the X-band feed horn 120 is amplified by the LNA 132 after passing through the diplexer 131, converted to IF by the down-converter 133, and then 2 by the divider 134. One IF signal is distributed and input to the communication data receiver 135, and the other is connected to the selection switch SW and transmitted to the beacon receiver 170. The beacon receiver 170 receives a beacon signal (70/140 Hz) included in the received signal of the selected band, and the output of the beacon receiver 170 is input to the antenna control unit (ACU) 180. The antenna control unit 180 generates a control signal for tracking satellites with the beacon signal and the angle signal detected from the angle sensors S1, S2, and S3, and the power control unit 190 (PCU) is an antenna control unit ( The direction of the antenna is automatically controlled by rotating the horizontal driving motor M1, the vertical driving motor M2, and the polar driving motor M3 according to the control signal of 180). In addition, the direction angle of the antenna is sensed again through the azimuth angle sensor (S1), altitude angle sensor (S2), polar angle sensor (S3) attached to the rotating shaft is transmitted to the ACU (180), accordingly in the ACU (180) The direction angle can be monitored.

Polar drive motor (M3) is the horizontal polarization or vertical polarization, left-turned or right-turned polarized wave coming from the satellite is deformed during transmission. Automatic tracking to this maximum.

2. Ku band's transmit and receive path

The Ku-band transmitter 156 modulates the transmission data into a Ku-band signal and amplifies the Ku-band transmitter to a high output in the high output amplifier 157 and transmits it to the diplexer 151. The diplexer 151 transmits the Ku band transmission signal to the Ku / Ka band multi feed horn 140, and the transmission signal of the Ku / Ka band multi feed horn 140 is a total reflection reflector 112 and a frequency selective reflector ( Reflected by the 110 is emitted to the satellite via the sub-reflector 104 and the main reflector 102.

The triple-band satellite signal arriving from the satellite through the main reflector 102 and the sub reflector 104 to the hub 108 is a total reflection reflector after the Ku band signal and the Ka band signal are reflected by the frequency selective reflector 110. The total reflection at 112) is introduced into the Ku / Ka band multi feed horn 140. The Ku-band received signal introduced into the Ku / Ka band multi-feed horn 140 is received by the corgate feed horn 144 on the outside of the multi-feed horn and passes through the four slots and the waveguide 145 to the 3dB coupler 146-. 1,146-2), and are extracted as a vertical polarization signal and a horizontal polarization signal, passed through the diplexer 151, amplified by the LNA 152, converted to IF in the down converter 153, and then the divider 154 The IF signal is divided into two and one IF signal is input to the communication data receiver 155, and the other is connected to the selection switch SW and transmitted to the beacon receiver 170. The beacon receiver 170 receives a beacon signal (70/140 Hz) included in the received signal of the selected band, and the output of the beacon receiver 170 is input to the antenna control unit (ACU) 180. The antenna control unit 180 generates a control signal for tracking satellites by the beacon signal and the angle signal detected from the angle sensors S1, S2, and S3, and the power control unit 190 generates the antenna control unit 180. The direction of the antenna is automatically controlled by rotating the horizontal drive motor M1, the vertical drive motor M2, and the polar drive motor M3 in accordance with the control signal. In addition, the direction angle of the antenna is sensed again through the azimuth angle sensor (S1), altitude angle sensor (S2), polar angle sensor (S3) attached to the rotating shaft is transmitted to the ACU (180), accordingly in the ACU (180) The direction angle can be monitored.

3. Ka band signal transmission / reception path

The Ka-band transmitter 166 modulates the transmission data into a Ka-band signal, and then amplifies the Ka-band transmitter to high output by the high power amplifier 167 and transmits the same to the diplexer 161. The diplexer 161 transmits the Ka band transmission signal to the Ku / Ka band multi feed horn 140, and the transmission signal of the Ku / Ka band multi feed horn 140 is a total reflection reflector 112 and a frequency selective reflector ( Reflected by the 110 is emitted to the satellite via the sub-reflector 104 and the main reflector 102.

The triple-band satellite signal arriving from the satellite through the main reflector 102 and the sub reflector 104 to the hub 108 is a total reflection reflector after the Ku band signal and the Ka band signal are reflected by the frequency selective reflector 110. The total reflection at 112) is introduced into the Ku / Ka band multi feed horn 140. The Ka-band received signal introduced into the Ku / Ka band multi feed horn 140 is received by the dielectric feed horn 141 inside the multi feed horn and is coupled in the hybrid 143 via the circular waveguide 142 to a circular polarization. Withdrawal, polarized in polarizer 161, then amplified in LNA 162, converted to IF in downconverter 163, and then divided in divider 164 so that one IF signal is transmitted to communication data receiver 165. ), And the other is connected to the selection switch (SW) and transmitted to the beacon receiver (170). The beacon receiver 170 receives a beacon signal (70/140 Hz) included in the received signal of the selected band, and the output of the beacon receiver 170 is input to the antenna control unit (ACU) 180. The antenna control unit 180 generates a control signal for tracking satellites by the beacon signal and the angle signal detected from the angle sensors S1, S2, and S3, and the power control unit 190 generates the antenna control unit 180. The direction of the antenna is automatically controlled by rotating the horizontal drive motor M1, the vertical drive motor M2, and the polar drive motor M3 in accordance with the control signal. In addition, the direction angle of the antenna is sensed again through the azimuth angle sensor (S1), altitude angle sensor (S2), polar angle sensor (S3) attached to the rotating shaft is transmitted to the ACU (180), accordingly in the ACU (180) The direction angle can be monitored.

The above description has been given in the case where one transmitter and one receiver are connected to the X, Ku, and Ka bands, respectively, but a large amount of communication is possible by connecting multiple transmitters and receivers in parallel according to communication capacity. Can be implemented.

And the above explanation was explained by resonating the resonator element of the frequency selective reflector in the Ku / Ka broadband band, but if the efficiency is reduced only the Ka band resonating to replace the Ku / Ka 2 frequency band horn, instead of the Ku band dedicated horn, The X band and the Ka band can also be configured to be fed into X, Ka band dual frequency band horns. The coupling method of the X band is first drawn out to the X band feed horn and four-way slots among the Ka band coupling method, and the coupling method may be configured in the same manner as the Ku band type.

Only the Ku band is reflected and the detailed description of the X and Ka band transmission methods is the same as the above detailed description, and thus the additional description is omitted.

The present invention has been described above with reference to one embodiment shown in the drawings, but those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom.

1 is a side view of a small case mirror antenna to which the present invention is applied;

Figure 2 is a side view of a large reflector casee antenna applied to the present invention,

3 is a side view of a Gregorian antenna to which the present invention is applied;

4 is an automatic tracking system of a triple band antenna according to the present invention;

5 is a schematic diagram of a feed horn for a Ku / Ka band according to the present invention;

6 is a schematic view showing a flat frequency selective reflector according to the present invention;

7 is a schematic view showing a concave frequency selective reflector according to the present invention;

8 is a schematic diagram showing a convex frequency selective reflector according to the present invention;

9 is a view showing the shape of the resonant elements applied to the frequency selective reflector according to the present invention.

DESCRIPTION OF THE REFERENCE NUMERALS

101: antenna body portion 102: the main reflector

104: sub-reflector 106: support

108: Hub 109: Feedhorn Enclosure

110: frequency selective reflector 112: total reflection reflector

120: X-band feed horn 130: X-band signal processing unit

140: Ku / Ka band multi feed horn 150: Ku band signal processing unit

160: Ka band signal processing unit SW: selection switch

170: beacon receiver 180: ACU

Claims (9)

In the tracking antenna for three-band satellite communication for transmitting and receiving the X band, Ku band, and Ka band radio waves with the satellite, An antenna body part comprising a main reflector and a sub-reflector; A motor driver for tracking the satellite by rotating the antenna body; A sensor unit for sensing an angle of the antenna body unit; A frequency selective reflector that transmits X-band radio waves and reflects Ku and Ka band radio waves during transmission and reception of triple bands; A total reflection reflector for total reflection of the Ku and Ka band radio waves of the triple band transmission and reception radio waves; An X band feed horn for transmitting and receiving the transmitted X band radio waves; Ku / Ka band multi feed horn for transmitting and receiving reflected Ku / ka band radio waves; An X-band processing unit for processing the X-band signal input and output through the X-band feed horn; A Ku band signal processor for processing Ku band signals inputted and outputted through the Ku / Ka band multi-feed horn; A Ka band signal processor for processing Ka band signals input and output through the Ku / Ka band multi feed horn; A selection switch for selecting one of the X band processor, the Ku band processor, and the Ka band processor; A beacon receiver for receiving a beacon signal of the band processor selected by the selection switch; An antenna control unit for generating a control signal for tracking satellites by adjusting the azimuth, elevation, and polar of the antenna from the beacon signal received by the beacon receiver and the angle signal detected by the sensor unit; And Including a power control unit for driving the motor driving unit according to the control signal of the antenna control unit, The frequency selective reflector, total reflection reflector, X band feed horn, and Ku / Ka band multi feed horn are all located at the base side hub of the main reflector. A three-band satellite communication tracking antenna device, characterized in that to improve the efficiency of more than 90% by modifying the curved surface of the main reflector and the sub-reflector to have a high efficiency of more than 75% even after subtracting the loss rate. The method of claim 1, wherein when the resonator element is a Ku band on the frequency selective reflector, the Ku band radio waves are reflected to feed the Ku band independent feed horn instead of the Ku / Ka band multi feed horn. Three-band satellite communication tracking antenna device characterized in that the transmission through the feed power of the dual feed horn of Ka / X band. The method of claim 1, wherein the frequency selective reflector Glue the space between the films on both sides with an adhesive to form a flat plate, a concave plate, or a convex plate, and close the air and the dielectric constant to minimize the loss of transmission waves, and attach a large number of resonant copper foils to one side of the resonance frequency. The tracking antenna device for three-band satellite communication characterized in that for reflecting. According to claim 1, wherein the X-band processing unit A diplexer for separating transmission and reception signals of the X-band feed horn, a low noise amplifier for amplifying the output reception signal of the diplexer, and a down converter for downgrading the low noise amplified reception signal to an intermediate frequency (IF) signal. A divider for dividing the intermediate frequency (IF) signal into two signals, a data receiver for receiving data from the intermediate frequency signal distributed by the divider, a transmitter for modulating the data and transmitting the data as an X-band signal, A high output amplifier for amplifying the X band signal of the transmitter and output to the diplexer, The ku band processing unit A diplexer for separating transmission / reception signals of the Ku / Ka band multi-feed horn, a low noise amplifier for amplifying the reception signal of the diplexer output, and a down converter for downgrading the low noise amplified reception signal to an intermediate frequency signal A divider for dividing the intermediate frequency signal into two signals, a data receiver for receiving data from the intermediate frequency signal distributed by the divider, a transmitter for modulating the data to transmit a Ku band signal, and a signal of the transmitter A high output amplifier for amplifying the output to the diplexer, The Ka band processing unit A diplexer for separating transmission / reception signals of the Ku / Ka band multi-feed horn, a low noise amplifier for amplifying the received signal of the diplexer, a down converter for downgrading the low noise amplified received signal to an intermediate frequency signal, A divider for dividing the intermediate frequency signal into two signals, a data receiver for receiving data from the intermediate frequency signal distributed by the divider, a transmitter for modulating the data to transmit a Ka band signal, and amplifying the signal of the transmitter Consists of a high output amplifier for outputting to the diplexer 3. A tracking antenna device for three-band satellite communication, characterized in that only one of the three tracking signals distributed among the transmission / receiving device and the receiving IF output of the three bands is selected as a switching device to perform the tracking by performing only one tracking device. The method of claim 1, wherein the multi feed horn, A three-band satellite communication tracking antenna consisting of an internal Ka band feed horn consisting of a circular waveguide in TE11 mode with a dielectric horn inserted therein, and a Ku band feed horn consisting of an external corgate feed horn and a Ku band waveguide. Device. The method of claim 1, wherein the multi feed horn, It consists of an internal Ka band feed horn consisting of a circular waveguide of TE11 mode with a dielectric horn inserted therein and an X band feed horn consisting of an external corgate feed horn and an X band waveguide. Device. The method of claim 1, The motor drive unit An azimuth motor for adjusting the azimuth angle of the antenna under the control of the power control unit, an elevation motor for adjusting the altitude angle of the antenna under the control of the power control unit, and an antenna feed under the control of the power control unit Consists of a polar motor for rotating the polar of the horn, The sensor unit Azimuth angle sensor for detecting the azimuth angle of the antenna and transmitting to the antenna control unit, Elevation angle sensor for detecting the altitude angle of the antenna and transmitting to the antenna control unit, and Polar angle of the antenna feed horn to detect the antenna Tracking antenna device for a three-band satellite communication, characterized in that consisting of a polar angle sensor for transmitting to the control unit. The reflector for frequency selection is composed of flat or curved surface and the honeycomb for thin film insulation to attach double-sided thin film insulator with adhesive, and to attach broadband or resonant metal film A, B, C, D, etc. to the radio wave reflecting surface. Tracking antenna device for triple-band satellite communication, characterized in that using the frequency selective reflector. 10. The method of claim 8, wherein the curved type is used as a sub-reflection plate of the dual reflector antenna, and the transmission frequency focuses on the feed horn attached to the parabolic focus of the main reflection plate and has a low loss characteristic. Tracking antenna device.

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