KR101153747B1 - Low noise block down converter and apparatus for slow noise block down converter and apparatus for satellite antenna with the same atellite antenna with the same - Google Patents

Abstract

PURPOSE: A low-noise-amplification converter and a satellite antenna apparatus including the same are provided to confirm the intensity of a satellite signal through a low-noise-amplification converter. CONSTITUTION: An antenna selecting unit(108) passes through one satellite signal. A polarized wave selecting unit passes through a signal having first polarization and second polarization of the selected satellite signal. A tracing filter(116) filters a TP signal from the satellite signal. A signal converter(118) converts the TP signal into a DC(Direct Current). A control unit generates an antenna selection control signal.

Description

LOW NOISE BLOCK DOWN CONVERTER AND APPARATUS FOR SATELLITE ANTENNA WITH THE SAME}

An embodiment of the present invention relates to a low noise block down converter (LNB) and a satellite antenna device including the same, and more particularly, a low noise amplifying converter for detecting and displaying the strength of a satellite signal and a satellite including the same. An antenna device.

The low noise block down converter is installed at the rear end of the satellite antenna (more specifically, the horn antenna located at the center of the satellite antenna) to reduce noise of the satellite signal received by the satellite antenna and then amplify the satellite signal. It converts satellite signals into intermediate frequencies and delivers them to satellite broadcast receivers.

Specifically, the low noise amplifying converter reduces noise included in the satellite signal received by the satellite antenna. At this time, since the satellite signal transmitted from the satellite has a weak signal, the satellite signal is amplified. In addition, since the frequency of the satellite signal is a high frequency band of 11.7 to 12.75 GHz, the low-noise amplifying converter is a low frequency, or intermediate frequency (intermediate frequency) that can use the satellite signal in a satellite broadcast receiver (e.g., set-top box). ). Satellite signals whose frequency is lowered to intermediate frequencies are input to the satellite broadcasting receiver through a cable or the like.

Conventionally, when installing a satellite antenna, whether or not the satellite antenna is installed in accordance with the direction and position of the target satellite (that is, well pointing with the target satellite) is checked through a separate instrument or through a satellite broadcast receiver. Confirmed. That is, in the prior art, when the satellite antenna is installed, the operator adjusts the orientation angles such as azimuth and elevation of the satellite antenna while checking the strength of the satellite signal transmitted from the target satellite through a separate instrument. There is an inconvenience that the operator should have a separate measuring instrument, and should be familiar with how to use the measuring instrument.

Or, in the related art, when the satellite antenna is installed, the operator checks whether the satellite signal is well received through the satellite broadcasting receiver, and then adjusts the direction of the satellite antenna. However, in general, the satellite antenna is installed on the roof of the apartment porch or house, and the satellite broadcast receiver is located indoors. In this case, the operator has to go back and forth between the satellite antenna and the satellite broadcasting receiver several times in order to check whether the satellite signal is well received by the satellite broadcasting receiver, and thus, it is very cumbersome and inconvenient to adjust the orientation angle of the satellite antenna. have.

In addition, conventionally, in order to receive the satellite signal of the second target satellite while receiving the satellite signal of the first target satellite, the direction of the satellite antenna has to be changed from the first target satellite to the second target satellite, where the orientation of the satellite antenna To change the angle, as described above, it is inconvenient to adjust the direction of the satellite antenna while checking whether the target antenna is pointing to the target satellite by using a separate instrument or a satellite broadcast receiver.

An embodiment of the present invention is to provide a low noise amplification converter and a satellite antenna device including the same that can determine whether the pointing to the target satellite without a separate instrument.

An embodiment of the present invention is to provide a low noise amplifying converter that can receive both satellite signals without changing the direction angle of the satellite antenna and a satellite antenna device including the same.

The low noise amplifier according to an embodiment of the present invention, the antenna selection unit for passing any one of the satellite signal received by the first satellite antenna and the satellite signal received by the second satellite antenna according to the antenna selection control signal ; A polarization selection unit configured to pass a signal having any one of a first polarization and a second polarization of the selected satellite signal according to a polarization selection control signal; A tracking filter which moves a frequency band of the filter window according to a filter control signal and filters and passes a TP (Transponder) signal corresponding to the polarization of the satellite signal from the satellite signal passing through the polarization selector; A signal converter converting the TP signal passing through the tracking filter into DC; A display unit displaying the strength of the TP signal converted into DC; And a controller configured to receive an operation control signal from an external source, generate the antenna selection control signal, the polarization selection control signal, and the filter control signal, and detect and display an intensity of the TP signal converted into DC. do.

According to another embodiment of the present invention, a low noise amplifying converter may include: a polarization selector configured to pass a signal having any one of a first polarization and a second polarization of a satellite signal received by a satellite antenna according to a polarization selection control signal; An intermediate frequency converter for converting a frequency of the satellite signal passing through the polarization selector into an intermediate frequency; A tracking filter which moves a frequency band of the filter window according to a filter control signal and filters and passes a TP (Transponder) signal suitable for polarization of the satellite signal in the satellite signal whose frequency is converted into the intermediate frequency; A signal converter converting the TP signal passing through the tracking filter into DC; A display unit displaying the strength of the TP signal converted into DC; And a controller configured to receive an operation control signal from an external source, generate the polarization selection control signal and the filter control signal, and detect and display an intensity of the TP signal converted into DC.

According to an embodiment of the present invention, since the operator installing the satellite antenna can work while visually confirming the strength of the satellite signal currently received from the satellite antenna through the low noise amplifying converter 100, it is easy without any additional measurement equipment. It is possible to point the satellite antenna to the target satellite. In addition, in order to confirm whether the satellite antenna is correctly pointed to the target satellite, it is possible to avoid the hassle of checking between the satellite broadcasting receiver and the satellite antenna.

In addition, after the first satellite antenna and the second satellite antenna are arranged to be directed to each target satellite, one of the satellite signal received by the first satellite antenna and the satellite signal received by the second satellite antenna through the antenna selection unit. By selectively passing only the satellite signal, if it is necessary to change the target satellite, it is easy to receive satellite signals transmitted from the changed target satellite without moving the satellite antenna to change the satellite antenna's directivity angle to the changed target satellite. Will be.

1 is a view showing the configuration of a low noise amplifying converter according to an embodiment of the present invention.
2 is a view showing TP signals in BS and CS bands of Mugunghwa No. 3;
3 is a view illustrating a state in which a frequency band of a filter window moves when receiving a satellite signal of Mugunghwa 3 in a low noise amplifying converter according to an embodiment of the present invention.
4 is a view illustrating a state in which a frequency band of a filter window moves when receiving a satellite signal of Mugunghwa 3 and Mugunghwa 5 in a low noise amplifying converter according to an embodiment of the present invention.

Hereinafter, a specific embodiment of a low noise amplifying converter and a satellite antenna device including the same according to the present invention will be described with reference to FIGS. 1 to 4. However, this is only an exemplary embodiment and the present invention is not limited thereto.

In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intention or custom of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

The technical spirit of the present invention is determined by the claims, and the following embodiments are merely means for effectively explaining the technical spirit of the present invention to those skilled in the art to which the present invention pertains.

1 is a view showing the configuration of a low noise amplifying converter according to an embodiment of the present invention.

Referring to FIG. 1, the low noise amplifying converter 100 includes an input circuit 102, a first polarization selector 104, a second polarization selector 106, an antenna selector 108, and a band pass filter. Filter 110, an intermediate frequency converter 112, a directional coupler 114, a tracking filter 116, a signal converter 118, a display 120, and a controller 122.

The input circuit 102 may be formed between the output terminal 160 and the controller 122 of the low noise amplifying converter 100. Here, the output terminal 160 is connected to a satellite broadcast receiver (eg, set top box, etc.) (not shown). The input circuit 102 receives an operation control signal for controlling the operation of the low noise amplifying converter 100 from the satellite broadcasting receiver (not shown) through the output terminal 160 and transmits it to the controller 122. In this case, the operation control signal may include at least one of a power source DC (eg, 13V or 18V) and a 22 KHz tone signal input from a satellite broadcasting receiver (not shown).

Here, the input circuit 102 may be a choke circuit in order not to affect the satellite signal input to the satellite broadcast receiver (not shown) through the output terminal 160. In this case, the choke circuit is a low pass filter that filters only signals having a very low frequency, such as a power supply DC (for example, 13V or 18V) and a 22 KHz tone signal input from a satellite broadcasting receiver (not shown). Is implemented.

The controller 122 checks the polarization of the satellite signal to be received by the satellite broadcasting receiver (not shown) through the voltage value of the power source DC among the operation control signals transmitted from the input circuit 102, and then applies the polarization selection control signal to the first polarization selection control signal. The polarization selector 104 and the second polarization selector 106 are respectively generated. For example, when the power source DC input from the satellite broadcasting receiver (not shown) is 13 V, the controller 122 may perform a first polarization in the satellite signals received by the first satellite antenna 151 and the second satellite antenna 154. A polarization selection control signal for selecting a signal of vertical polarization or left circle polarization, for example, is generated to the first and second polarization selection sections 104 and 106, respectively.

In addition, when the power DC input from the satellite broadcasting receiver (not shown) is 18V, the controller 122 may perform a second polarization (eg, a second polarization) in the satellite signals received by the first satellite antenna 151 and the second satellite antenna 154. For example, a polarization selection control signal for selecting a signal of horizontal polarization or right polarization is generated to the first polarization selection unit 104 and the second polarization selection unit 106, respectively. In this case, the power source DC input from the satellite broadcasting receiver (not shown) not only supplies power to the low noise amplifying converter 100 but also serves as an operation control signal for polarization selection.

Here, the first satellite antenna 151 and the second satellite antenna 154 may respectively receive satellite signals transmitted from satellites neighboring each other over the earth. For example, the first satellite antenna 151 receives a satellite signal transmitted from Mugunghwa No. 3 (located at 116 degrees long east), and the second satellite antenna 154 is located at Mugunghwa No. 5 (113 degrees east long). Each satellite signal can be received from At this time, the first satellite antenna 151 and the second satellite antenna 154 are arranged to be mutually arranged so that the azimuth angle is 3 degrees apart. Here, although the first satellite antenna 151 receives the satellite signal transmitted from Mugunghwa 3 and the second satellite antenna 154 has been described as receiving the satellite signal transmitted from Mugunghwa 5, the present invention is not limited thereto. The first satellite antenna 151 and the second satellite antenna 154 may further be spaced apart from various satellites adjacent to each other (eg, the first satellite antenna 151 and the second satellite antenna 154 over the earth). Satellite signals transmitted from satellites spaced apart from each other by an azimuth angle corresponding to a distance may be simultaneously received. In this case, the first satellite antenna 151 and the second satellite antenna 154 include a horn antenna installed in front of the low noise amplifying converter 100.

In addition, the controller 122 checks the satellite antenna receiving the satellite signal through the operation control signal transmitted from the input circuit 102 through the presence or absence of a 22 KHz tone signal, and then transmits the antenna selection control signal to the antenna selection unit 108. To occur. For example, if the 22 KHz tone signal is not included in the operation control signal transmitted from the input circuit 102, the controller 122 may receive a satellite signal received from the first satellite antenna 151. An antenna selection control for selecting a satellite signal received by the first satellite antenna 151 from a satellite signal transmitted) and a satellite signal received by the second satellite antenna 154 (that is, a satellite signal transmitted from Mugunghwa No. 5). A signal is generated by the antenna selector 108.

When the 22 KHz tone signal is included in the operation control signal transmitted from the input circuit 102, the controller 122 receives the satellite signal received by the first satellite antenna 151 and the second satellite antenna 154. The antenna selector 108 generates an antenna selection control signal for selecting a satellite signal received by the second satellite antenna 154 among the satellite signals.

For example, referring to a case in which a satellite broadcast receiver (not shown) selects a KBS 2 broadcast channel, the KBS 2 broadcast channel uses a satellite signal transmitted from Mugunghwa No. 3, and since the polarization of the satellite signal is vertically polarized, A power supply DC of 13 V is input as an operation control signal from a broadcast receiver (not shown). At this time, the 22 KHz tone signal is not included in the operation control signal.

Then, the controller 122 transmits a polarization selection control signal for selecting a signal of vertical polarization from the satellite signals received by the first and second satellite antennas 151 and 154. Each of them is generated by the second polarization selector 106. In addition, the controller 122 controls the satellite signals received by the first satellite antenna 151 (that is, the satellite signals transmitted by Mugunghwa No. 3) and the satellite signals received by the second satellite antenna 154 (ie, Mugunghwa No. 5). The antenna selector 108 generates an antenna selection control signal for selecting the satellite signal received by the first satellite antenna 151 from among the satellite signals transmitted by the.

The first polarization selector 104 is installed at the rear end of the first satellite antenna 151 and has a predetermined polarization among satellite signals received by the first satellite antenna 151 according to the polarization selection control signal of the controller 122. Pass the signal selectively. The first polarization selector 104 passes through a signal having a first polarization (eg, vertical polarization) among the satellite signals received by the first satellite antenna 151. ) And a 1-2 polarization selector 104-2 for passing a signal having a second polarization (eg, horizontal polarization) among satellite signals received by the first satellite antenna 151. In this case, the 1-1 polarization selector 104-1 is connected to the vertical polarization edge of the first satellite antenna 151, and the 1-2 polarization selector 104-2 is connected to the first satellite antenna 151. Is connected to the horizontal polarization end of

At this time, when the polarization selection control signal is a signal for passing only vertical polarization of the satellite signals received by the first satellite antenna 151, the first polarization selection unit 104 is the 1-1 polarization selection unit 104-1. ) Is turned on, and the 1-2 polarization selector 104-2 is turned off to selectively pass only vertical polarization of the satellite signals received by the first satellite antenna 151.

In addition, when the polarization selection control signal is a signal for passing only horizontal polarization of the satellite signals received by the first satellite antenna 151, the first polarization selection unit 104 may include a 1-1 polarization selection unit 104-1. ) Is turned off, and the 1-2 polarization selector 104-2 is turned on to selectively pass only horizontal polarization of the satellite signals received by the first satellite antenna 151.

Here, although the first polarization selector 104 selectively passes vertical polarization or horizontal polarization among the satellite signals received by the first satellite antenna 151 according to the polarization selection control signal, the present invention is not limited thereto. The first polarization selector 104 may be configured to selectively pass left circular polarization or right circular polarization among the satellite signals received by the first satellite antenna 151.

The second polarization selector 106 is installed at the rear end of the second satellite antenna 154 and has a predetermined polarization among satellite signals received by the second satellite antenna 154 according to the polarization selection control signal of the controller 122. Pass the signal selectively. The second polarization selector 106 transmits a second-first polarization selector 106-1 through which a signal having a first polarization (eg, vertical polarization) is passed among satellite signals received by the second satellite antenna 154. And a 2-2 polarization selector 106-2 that passes a signal having a second polarization (eg, horizontal polarization) among the satellite signals received by the second satellite antenna 154. In this case, the 2-1 polarization selector 106-1 is connected to the vertical polarization end of the second satellite antenna 154, and the 2-2 polarization selector 106-2 is the second satellite antenna 154. Is connected to the horizontal polarization end of

At this time, when the polarization selection control signal is a signal for passing only vertical polarization of the satellite signals received by the second satellite antenna 154, the second polarization selection unit 106 is a 2-1 polarization selection unit 106-1. ) Is turned on, and the 2-2 polarization selector 106-2 is turned off to selectively pass only vertical polarization of the satellite signals received by the second satellite antenna 154.

When the polarization selection control signal is a signal for passing only horizontal polarization of the satellite signals received by the second satellite antenna 154, the second polarization selection unit 106 may include the 2-1 polarization selection unit 106-1. ) Is turned off, and the 2-2 polarization selector 106-2 is turned on to selectively pass only horizontal polarization of the satellite signals received by the second satellite antenna 154.

Here, although the second polarization selector 106 selectively passes vertical polarization or horizontal polarization among the satellite signals received by the second satellite antenna 154 according to the polarization selection control signal, the present invention is not limited thereto. The second polarization selector 106 may be implemented to selectively pass left circular polarization or right circular polarization of the satellite signals received by the second satellite antenna 154.

The antenna selector 108 is connected to output terminals of the first polarization selector 104 and the second polarization selector 106, respectively. The antenna selector 108 selectively passes one of the satellite signals received by the first satellite antenna 151 and the satellite signal received by the second satellite antenna 154 according to the antenna selection control signal. The antenna selector 108 is connected to an output terminal of the first polarization selector 104 to pass the satellite signals received by the first satellite antenna 151 and the second antenna selection 108-1. And a second antenna selector 108-2 connected to an output terminal of the unit 106 to pass satellite signals received by the second satellite antenna 154.

For example, when the antenna selection control signal is a signal for passing only the satellite signal received by the first satellite antenna 151, the antenna selector 108 may turn on the first antenna selector 108-1. The second antenna selector 108-2 turns off and passes only the satellite signal received by the first satellite antenna 151. When the antenna selection control signal is a signal for passing only the satellite signal received by the second satellite antenna 154, the antenna selector 108 turns off the first antenna selector 108-1. The second antenna selector 108-2 is turned on to pass only the satellite signal received by the second satellite antenna 154.

A low noise amplifier (LNA) may be used as the first antenna selector 108-1 and the second antenna selector 108-2. In this case, the first antenna selector 108-1 reduces the noise of the satellite signal received by the first satellite antenna 151 and amplifies the satellite signal from which the noise is reduced. The second antenna selector 108-2 reduces the noise of the satellite signal received by the second satellite antenna 154 and amplifies the satellite signal from which the noise is reduced.

Here, the controller 122 may simultaneously generate a polarization selection control signal and an antenna selection control signal. At this time, the polarization selection control signal is input to the first polarization selection unit 104 and the second polarization selection unit 106, respectively. In this case, the first polarization selector 104 and the second polarization selector 106 selectively select signals having a predetermined polarization among the satellite signals received by the first satellite antenna 151 and the second satellite antenna 154, respectively. After passing through, the antenna selector 108 may select and pass one of the satellite signals received by the first satellite antenna 151 and the satellite signals received by the second satellite antenna 154. .

In addition, the controller 122 may sequentially generate a polarization selection control signal and an antenna selection control signal. For example, the controller 122 generates an antenna selection control signal to the antenna selector 108 so that only one of the first antenna selector 108-1 and the second antenna selector 108-2 is turned on. ON), and then polarization selection control of the first polarization selector 104 and the second polarization selector 106 connected to the ON-operated antenna selector 108-1 or 108-2. A signal may be generated to selectively pass a signal having a predetermined polarization among satellite signals received by the satellite antenna.

As such, after the first satellite antenna 151 and the second satellite antenna 154 are disposed to face each target satellite (for example, Mugunghwa 3 and Mugunghwa 5), the antenna selection unit 108 is arranged. By selectively passing only one of the satellite signals received by the first satellite antenna 151 and the satellite signals received by the second satellite antenna 154, it is necessary to change the target satellite. It is possible to easily receive the satellite signal transmitted from the changed target satellite without moving the satellite antenna to change the direction angle to the changed target satellite.

That is, when receiving the satellite signal of Mugunghwa 3 (for example, KBS 2) and trying to receive the satellite signal of Mugunghwa 5 (for example, MBC), the satellite signal passed by the antenna selector 108 is first transmitted. Since only the satellite signal received by the satellite antenna 151 is changed from the satellite signal received by the second satellite antenna 154, the satellite signal transmitted from the changed target satellite even if the target satellite desired to be received by the satellite broadcasting receiver is changed. Can be easily received.

Meanwhile, although the antenna selector 108 is illustrated as being connected to the respective output terminals of the first polarization selector 104 and the second polarization selector 106, the present invention is not limited thereto. The first satellite antenna 151 and the second satellite antenna 154 may be connected to respective rear ends, and the polarization selector may be connected to the output terminal of the antenna selector 108. In this case, the antenna selector 108 selects one of the satellite signals received by the first satellite antenna 151 and the satellite signal received by the second satellite antenna 154 according to the antenna selection control signal. The polarization selector selects and passes a signal having a predetermined polarization among the satellite signals passed through the antenna selector 108 according to the polarization selection control signal.

The band pass filter 110 is connected to an output terminal of the antenna selector 108. The band pass filter 110 filters the satellite signal passing through the antenna selector 108 and passes only a signal corresponding to a predetermined frequency band (for example, 11.7 to 12.75 GHz) of the satellite signals.

The intermediate frequency converter 112 is connected to the output terminal of the band pass filter 110. The intermediate frequency converter 112 converts the frequency band of the satellite signal passing through the band pass filter 110 into an intermediate frequency (IF) band. That is, since the frequency of the satellite signal passing through the band pass filter 110 is high, for example, from 11.7 to 12.75 GHz, the intermediate frequency converter 112 converts the frequency of the satellite signal into a satellite broadcast receiver (for example, Lower the frequency to the usable frequency of the set-top box.

The intermediate frequency converter 112 may include a first amplifier 112-1, a local oscillator 112-2, a mixer 112-3, and a second amplifier 112-4. Here, the first amplifier 112-1 amplifies the satellite signal passing through the band pass filter 110. Next, the local oscillator 112-2 generates an oscillation signal having a predetermined frequency band (for example, 10.75 GHz), and then amplifies and outputs the generated oscillation signal. Next, the mixer 112-3 combines the satellite signal amplified by the first amplifier 112-1 and the oscillation signal output from the local oscillator 112-2 to output a satellite signal having an intermediate frequency. Next, the second amplifier 112-4 amplifies the satellite signal having an intermediate frequency.

In this case, the satellite signal output from the mixer 112-3 (that is, the satellite signal having an intermediate frequency) is output from the local oscillator 112-2 and the frequency of the satellite signal amplified by the first amplifier 112-1. It has a frequency corresponding to the difference of the frequency of the oscillation signal. That is, the intermediate frequency = the original frequency of the satellite signal-the frequency of the oscillation signal. For example, when the frequency of the satellite signal amplified by the first amplifier 112-1 is 11.7 to 12.75 GHz, and the frequency of the oscillation signal output from the local oscillator 112-2 is 10.75 GHz, the mixer ( The intermediate frequency of the satellite signal output from 112-3) is 0.95 ~ 2 GHz. In this case, by adjusting the frequency of the oscillation signal output from the local oscillator 112-2, it is possible to adjust the intermediate frequency of the satellite signal output from the mixer 112-3.

The directional coupler 114 may be installed between the intermediate frequency converter 112 and the output terminal 160. The directional coupler 114 branches the satellite signal (ie, the satellite signal having the intermediate frequency) output from the intermediate frequency converter 112 to the output terminal 160 and the tracking filter 116, respectively. That is, a part of the satellite signal output from the intermediate frequency converter 112 is input to the satellite broadcast receiver through the output terminal 160, and another part of the satellite signal output from the intermediate frequency converter 112 is a tracking filter ( 116).

Here, the satellite signal inputted to the tracking filter 116 is input to the signal conversion unit 118 by filtering only a predetermined TP (Transponder) signal from the tracking filter 116, the signal conversion unit 118 to the strength of the satellite signal Is converted into the form of a detectable DC signal. As described above, in the exemplary embodiment of the present invention, a part of the satellite signal output from the intermediate frequency converter 112 is input to the tracking filter 116 through the directional coupler 114 to detect the strength of the satellite signal. A detailed description thereof will be described later.

On the other hand, here, the directional coupler 114 is installed between the intermediate frequency converter 112 and the output terminal 160, the satellite signal output from the intermediate frequency converter 112, the output terminal 160 and the tracking filter 116. Although illustrated as branching to each other), the present invention is not limited thereto, and may be provided between the band pass filter 110 and the intermediate frequency converter 112. In this case, the directional coupler 114 branches the satellite signal filtered by the band pass filter 110 to the intermediate frequency converter 112 and the tracking filter 116, respectively.

The tracking filter 116 shifts the frequency band of the filter window according to the filter control signal of the control unit 122 and diverts from the directional coupler 114 to the TP (Transponder) signal corresponding to the polarization of the satellite signal. Filter it through.

Specifically, the controller 122 checks the polarization of the satellite signal to be received by the satellite broadcasting receiver (not shown) through the voltage value of the power supply DC among the operation control signals transmitted from the input circuit 102, and then the directional coupler 114. A tracking signal is generated by the tracking filter 116 to filter a TP (Transponder) signal corresponding to the polarization of the satellite signal from the satellite signal branched and inputted at the Rx.

For example, when the power supply DC received from the input circuit 102 is 13V, the controller 122 outputs any one TP (Transponder) signal having vertical polarization in the satellite signal branched from the directional coupler 114. A filter control signal is generated to the tracking filter 116 for filtering. When the power supply DC received from the input circuit 102 is 18 V, the controller 122 filters the TP (Transponder) signal having horizontal polarization from the satellite signal branched from the directional coupler 114. A filter control signal to the tracking filter 116.

In general, satellite signals are divided into a broadcasting satellite (BS) band and a communication satellite (CS) band, and each satellite uses a plurality of TPs in the BS band and the CS band, respectively. For example, in the case of Mugunghwa 3, as shown in FIG. 2, 6 TPs having left circle polarization are used in the BS band (a in FIG. 2), 2 TPs having vertical polarization in the CS band, and Nine TPs with horizontal polarization are used (b of FIG. 2). For the BS band, the bandwidth of each TP is 27 MHz, and for the CS band, the bandwidth of each TP is 36 MHz. Here, since a wide bandwidth CS band is easy to design the tracking filter 116, the operation of the tracking filter 116 in the CS band will be described below. However, the present invention is not limited thereto, and the tracking filter 116 may be designed to operate in the BS band.

For example, if the power supply DC delivered by the input circuit 102 is 18V, and the operation control signal does not include a 22 KHz tone signal, the satellite signal input to the tracking filter 116 is transmitted in Mugunghwa 3 and is horizontal. Satellite signal with polarization. In this case, the satellite signal input to the tracking filter 116 includes nine TPs having horizontal polarization as shown in FIG. 2. At this time, the tracking filter 116 filters and passes any one of the nine TP signals having horizontal polarization.

In addition, when the power supply DC transmitted by the input circuit 102 is 13V, and the operation control signal does not include the 22 KHz tone signal, the satellite signal input to the tracking filter 116 is transmitted from Mugunghwa No. 3 and receives vertical polarization. Having satellite signals. In this case, the satellite signal input to the tracking filter 116 includes two TPs with vertical polarization as shown in FIG. 2. At this time, the tracking filter 116 filters and passes any one of two TP signals having vertical polarization.

Here, the tracking filter 116 may be any one having a TP signal or a horizontal polarization having a vertical polarization according to the voltage value of the power supply DC transmitted by the input circuit 102 (that is, according to the polarization of the satellite signal). It should be possible to filter the TP signal. In this case, since each TP signal has a different frequency band, the tracking filter 116 should be implemented such that the frequency band of the filter window moves according to the filter control signal.

3 is a view illustrating a state in which a frequency band of a filter window moves in a low noise amplifying converter according to an embodiment of the present invention. Here, the case of receiving the satellite signal of Mugunghwa 3 is shown. In addition, the satellite signal input to the tracking filter 116 has an intermediate frequency (IF) band (for example, 0.95 to 2 GHz, when the frequency of the oscillation signal is 10.75 GHz), but for convenience of description, the original frequency of the satellite signal Bands (11.7-12.75 GHz).

Referring to FIG. 3, the filter window W of the tracking filter 116 may be preset to filter a TP signal CS 14 having a center frequency of 12.530 GHz among TP signals having horizontal polarization. That is, the filter window W of the tracking filter 116 may have a center frequency of 12.530 GHz and a bandwidth of 36 MHz.

Here, the controller 122 determines whether the frequency band of the filter window W of the tracking filter 116 needs to be shifted by checking the polarization of the satellite signal, and then generates a filter control signal to the tracking filter 116. .

For example, when the satellite signal is a satellite signal transmitted from Mugunghwa No. 3 and has a horizontal polarization, the controller 122 does not need to move the frequency band of the filter window W of the tracking filter 116, so that the control unit 122 may use the filter window ( A filter control signal is generated to the tracking filter 116 to maintain the frequency band of W). Then, the tracking filter 116 filters and passes the TP signal CS 14 among the input satellite signals.

On the other hand, if the satellite signal is a satellite signal transmitted from Mugunghwa 3 and has a vertical polarization, to filter the TP signal having vertical polarization (ie, CS 5 or CS 13) from the satellite signal input to the tracking filter 116, The frequency band of the filter window W should be moved to 12.350 GHz, which is the center frequency of the TP signal CS 5, or 12.523 GHz, which is the center frequency of the TP signal CS 13.

Here, since the center frequency of the current filter window (W) is 12.530 GHz, it is preferable to move the center frequency of the filter window (W) to 12.523 GHz rather than to 12.350 GHz. Accordingly, the controller 122 generates a filter control signal to the tracking filter 116 to move the frequency band of the filter window W such that the center frequency of the filter window W is 12.523 GHz. The tracking filter 116 then shifts the frequency band of the filter window W to filter the TP signal CS 13 with a center frequency of 12.523 GHz. That is, the tracking filter 116 moves the frequency band of the filter window W from the TP signal CS 14 (horizontal polarization) to the TP signal CS 13 (vertical polarization) in accordance with the filter control signal.

In addition, when the satellite signal transmitted from Mugunghwa 3 and having a horizontal polarization is input again, the controller 122 shifts the frequency band of the filter window W such that the center frequency of the filter window W is 12.530 GHz. Generate a filter control signal to the tracking filter 116. The tracking filter 116 then shifts the frequency band of the filter window W to filter the TP signal CS 14 with a center frequency of 12.530 GHz. That is, the tracking filter 116 shifts the frequency band of the filter window W from the TP signal CS 13 (vertical polarization) to the TP signal CS 14 (horizontal polarization) in accordance with the filter control signal.

Here, the shift of the frequency band of the filter window (W) can be easily implemented using a variable capacitor. That is, the tracking filter 116 includes a variable capacitor, and shifts the frequency band of the filter window W to the corresponding frequency by changing the capacitance value of the variable capacitor according to the filter control signal.

On the other hand, when the center frequency of the filter window (W) of the tracking filter 116 is already set to 12.530 GHz, a satellite signal transmitted from Mugunghwa No. 5 and having horizontal polarization is input to the tracking filter 116. Looking at it as follows.

As shown in FIG. 4, in the case of Mugunghwa 5, eight TPs having horizontal polarizations exist in the CS band, and no TPs having vertical polarizations exist. In the case of the TP signal CS 10, it can be seen that the center frequency is 12.530 GHz. Therefore, it is possible to filter and pass only the TP signal CS 10 without shifting the frequency band of the filter window of the tracking filter 116.

Here, only the case of receiving satellite signals of Mugunghwa 3 and Mugunghwa 5 is described as an embodiment, and when receiving satellite signals transmitted from other satellites, the TP of each satellite, the center frequency and polarization of each TP The design can be changed according to the type.

The signal converter 118 converts the satellite signal passing through the tracking filter 116 into a DC signal and inputs it to the controller 122. That is, the signal converter 118 rectifies the satellite signal passing through the tracking filter 116, and then smoothes the rectified satellite signal to convert it into a DC signal. As such, when the satellite signal, which is an RF signal, is converted into a DC signal by the signal converter 118 and input to the controller 122, the controller 122 can detect the strength of the satellite signal.

The display unit 120 displays the strength of the satellite signal received from the first satellite antenna 151 or the second satellite antenna 154 under the control of the controller 122. That is, the controller 122 detects the strength of the satellite signal converted into the DC signal by the signal converter 118, and then displays the strength of the satellite signal on the screen through the display unit 120. In this case, the display unit 120 may include, for example, a plurality of LEDs (Light Emitting Diodes), and may display the strengths of the satellite signals with LEDs of different colors according to the strengths of the satellite signals. In this case, through the strength of the satellite signal it is possible to determine whether the satellite antenna pointing well with the target satellite.

Here, the low-noise amplifying converter 100 can immediately check the strength of the satellite signal received by the first satellite antenna 151 and the second satellite antenna 154, and thus the first satellite antenna 151 and the second satellite It is possible to point the satellite antenna 154 with Mugunghwa 3 and Mugunghwa 5, respectively. After pointing the first satellite antenna 151 and the second satellite antenna 154 with Mugunghwa 3 and Mugunghwa 5, respectively, the first satellite antenna 151 and the second satellite antenna 154 through an antenna selection control signal. Only one satellite signal of the received satellite signals can be selected.

As described above, according to an embodiment of the present invention, the operator installing the satellite antenna can work while visually confirming the strength of the satellite signal currently received from the satellite antenna through the low noise amplification converter 100, so that the measurement equipment is separate. Without this, the satellite antenna can be easily pointed to the target satellite. In addition, in order to confirm whether the satellite antenna is correctly pointed to the target satellite, it is possible to avoid the hassle of checking between the satellite broadcasting receiver and the satellite antenna.

On the other hand, above, the input circuit 102 supplies power from a satellite broadcast receiver (not shown) to a power supply DC (eg, 13V or 18V) (i.e., serves as an operation control signal for polarization selection) and 22 Although it has been described as receiving a KHz tone signal (that is, an operation control signal for antenna selection), the present invention is not limited thereto. The input circuit 102 receives power only from a satellite broadcasting receiver (not shown), and the operation control signal is It may also be input via a separate external control means (for example, a remote control).

In this case, the low noise amplifying converter 100 may further include a wireless communication unit that receives an operation control signal from a separate external control means. Here, the wireless communication unit may be, for example, a short range wireless communication means such as infrared IR, Bluetooth (Blue Tooth), Wireless Local Area Network (WLAN), Ultra Wide Band (UWB), or the like.

In this case, the wireless communication unit may receive information on the type of satellite and the polarization of the satellite signal from the external control means. Then, the controller 122 checks the information on the polarization of the satellite signal received by the wireless communication unit and generates a polarization selection control signal to the first polarization selection unit 104 and the second polarization selection unit 106, respectively. The controller 122 checks information on the type of satellite received by the wireless communication unit and generates an antenna selection control signal to the antenna selection unit 108.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, I will understand. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

100: low noise amplification converter 102: input circuit
104: first polarization selector 104-1: first-1 polarization selector
104-2: 1-2nd polarization selector 106: Second polarization selector
106-1: 2-1 polarization selector 106-2: 2-2 polarization selector
108: antenna selector 108-1: first antenna selector
108-2: second antenna selector 110: band pass filter
112: intermediate frequency converter 112-1: first amplifier
112-2: Local Oscillator 112-3: Blender
112-4: second amplifier 114: directional coupler
116: tracking filter 118: signal conversion unit
120: display unit 122: control unit
151: first satellite antenna 154: second satellite antenna
160: output terminal

Claims (12)

An antenna selection unit configured to pass one of the satellite signals received by the first satellite antenna and the satellite signals received by the second satellite antenna according to the antenna selection control signal;
A polarization selection unit configured to pass a signal having any one of a first polarization and a second polarization of the selected satellite signal according to a polarization selection control signal;
A tracking filter which moves a frequency band of the filter window according to a filter control signal and filters and passes a TP (Transponder) signal corresponding to the polarization of the satellite signal from the satellite signal passing through the polarization selector;
A signal converter converting the TP signal passing through the tracking filter into DC;
A display unit displaying the strength of the TP signal converted into DC;
A wireless communication unit for receiving an operation control signal including polarization information and satellite type information of a satellite signal from an external control means; And
The antenna selection control signal, the polarization selection control signal, and the filter control signal are generated using the operation control signal received by the wireless communication unit, and the strength of the TP signal converted into DC is detected and displayed on the display unit. A low noise amplifying converter comprising a control unit.
The method of claim 1,
The operation control signal,
A low noise amplifying converter input from a satellite broadcast receiver connected to the output terminal of the low noise amplifying converter and including at least one of a power DC and a 22 KHz tone signal.
The method of claim 2,
The control unit,
And generating the antenna selection control signal in accordance with whether the 22 KHz tone signal is included in the operation control signal, and generating the polarization selection control signal in accordance with the voltage value of the power source DC.
The method of claim 2,
The control unit,
After checking the polarization of the satellite signal through the voltage value of the power source DC, and shifting the frequency band of the filter window to filter the TP (Transponder) signal corresponding to the polarization of the satellite signal from the satellite signal passing through the polarization selection unit , Low noise amplification converter.
The method of claim 1,
The low noise amplification converter,
An intermediate frequency converting unit converting the frequency of the satellite signal passing through the polarization selecting unit into an intermediate frequency; And
And a directional coupler for branching the satellite signal passing through the polarization selector into the tracking filter and the intermediate frequency converter, respectively.
delete The method of claim 1,
The first satellite antenna and the second satellite antenna,
A low noise amplifying converter which is installed spaced apart from each other corresponding to the azimuth difference between the target satellites.
A polarization selection unit configured to pass a signal having any one of a first polarization and a second polarization of the satellite signal received by the satellite antenna according to the polarization selection control signal;
An intermediate frequency converter for converting a frequency of the satellite signal passing through the polarization selector into an intermediate frequency;
A tracking filter which moves a frequency band of the filter window according to a filter control signal and filters and passes a TP (Transponder) signal suitable for polarization of the satellite signal in the satellite signal whose frequency is converted into the intermediate frequency;
A signal converter converting the TP signal passing through the tracking filter into DC;
A display unit displaying the strength of the TP signal converted into DC;
A wireless communication unit for receiving an operation control signal including polarization information of a satellite signal from an external control means; And
A control unit for generating the polarization selection control signal and the filter control signal by using the operation control signal received by the wireless communication unit, and detecting the strength of the TP signal converted into DC and displaying the intensity on the display unit; converter.
The method of claim 8,
The low noise amplification converter,
And a directional coupler for branching the satellite signal whose frequency is converted into the intermediate frequency into an output terminal of the low noise amplifying converter and the tracking filter, respectively.
The method of claim 8,
The low noise amplification converter,
And an input circuit formed between the intermediate frequency converter and an output terminal of the low noise amplification converter and receiving the operation control signal from a satellite broadcasting receiver connected to the output terminal and transferring the operation control signal to the control unit.
The method of claim 10,
The operation control signal,
A power source DC input from the satellite broadcasting receiver;
The control unit generates the polarization selection control signal and the filter control signal in accordance with the voltage value of the power source DC.
A satellite antenna device comprising the low noise amplifying converter according to any one of claims 1 to 5 and 7 to 11.

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