KR200405575Y1 - Satellite antenna type lnb - Google Patents

Abstract

The present invention relates to a low noise block down converter (LNB) for satellite antenna that can provide satellite signals to other external devices other than the set-top box.

A low noise block down converter for a satellite antenna according to the present invention is a low noise block down converter for a satellite antenna for converting a satellite signal applied from a satellite antenna into an intermediate frequency of a predetermined level and providing the set top box, for combining with the set top box. A first output terminal, a second output terminal for coupling with an external device, and a satellite signal converted into the intermediate frequency at a predetermined ratio to provide a satellite signal having a first ratio to the first output terminal and a satellite signal having a second ratio A line coupler provided to the second output end side and a satellite signal of a second ratio applied from the line coupler are filtered for a predetermined frequency band, and the amplified filtered satellite signal is provided to the second output end by a predetermined level. Characterized in that it comprises a signal amplification means.

Satellite Antenna

Description

SATELLITE ANTENNA TYPE LNB}

1 is a diagram showing a schematic configuration of a general satellite broadcasting system.

Figure 2 is a block diagram showing the functional separation of the internal configuration of the satellite antenna LNB according to the first embodiment of the present invention.

3 is a view for explaining the internal configuration of an LNB for a satellite antenna according to a second embodiment of the present invention;

******* Brief description of the main parts of the drawing *******

110: low noise amplifier, 120: the first filter,

130: mixer, 140: local oscillator,

150: second filter, 160: first amplifier,

170: coupler, 180: first output stage,

190: second output stage, 200: signal amplifier.

The present invention relates to a low noise block down converter (LNB) for satellite antenna that can provide satellite signals to other external devices other than the set-top box.

In general, the satellite broadcasting system includes an antenna unit 10 for receiving a broadcast signal provided through the satellite 1 and a broadcast signal provided from the antenna unit 10 as shown in FIG. It is configured with a set-top box 20 for providing to the TV receiver 30.

Here, the antenna unit 10 has a hemispherical shape of a satellite antenna 11 installed at an angle so as to direct the elevation angle of the satellite 1 and a band of about 11.7 to 12.75 GHz received from the satellite antenna 11. A low noise block down converter (LNB), which converts the signal into an intermediate frequency signal in the 950-2000 MHz band and provides the set-top box 200, is included.

In this case, in order for a user to smoothly receive a broadcast signal of a desired channel through the TV receiver 30, the satellite antenna 11 needs to always be directed to the satellite 1 providing the channel. Therefore, when watching satellite broadcasts provided by the plurality of satellites 1, it is necessary to change the direction angle of the satellite antenna 11 to face the specific satellite 1 providing the corresponding channel. In addition, even when the satellite antenna 11 is installed in the moving object, it is necessary to adjust the orientation angle of the satellite antenna 11 according to the moving direction of the moving object.

Thus, a device has been proposed and used that can automatically adjust the orientation angle of the satellite antenna 11. The device basically analyzes the broadcast signal received from the satellite 1 to appropriately adjust the orientation angle of the satellite antenna 11. That is, in order to drive the steering angle adjustment device, the broadcast signal received through the satellite antenna 11 should be provided to the steering angle adjustment device.

However, the broadcast signal received through the satellite antenna 11 may need to be separated not only for adjusting the direction angle of the satellite antenna 11 but also for other additional services using the broadcast signal received from the satellite 1 in the future.

Accordingly, the present invention was conceived in view of the above circumstances, and provides a low noise block down converter for a satellite antenna that can convert a signal received from the satellite antenna into an intermediate frequency and then separate and provide the signal to a plurality of output terminals. It has a technical purpose.

A low noise block down converter for a satellite antenna according to the present invention for achieving the above object is a low noise block down converter for a satellite antenna for providing a set-top box by converting a satellite signal applied from the satellite antenna to a predetermined level of intermediate frequency, the A first output terminal for coupling with a set-top box, a second output terminal for coupling with an external device, and a satellite signal converted to the intermediate frequency at a predetermined ratio to provide a satellite signal having a first ratio to the first output terminal; The satellite signal having a ratio of 2 is subjected to filtering processing for a predetermined frequency band with respect to the line coupler provided to the second output end and the satellite signal having a second ratio applied from the line coupler, and amplified by a predetermined level. It characterized in that it comprises a signal amplifying means for providing to the second output terminal .

In addition, the low noise block down converter for the satellite antenna further comprises a plurality of branch means for branching the satellite signal of the second ratio applied from the line coupler, a plurality of signal amplification corresponding to each branch means The means are coupled, and a plurality of second output stages are respectively coupled to correspond to the signal amplification means.

In addition, the low noise block down converter for the satellite antenna is characterized in that the signal amplifying means is configured to perform filtering processing for different frequency bands for each branch means.

In addition, the low noise block down converter for the satellite antenna is characterized in that the second output terminal is composed of different connection ports.

That is, according to the above, the satellite signal received from the satellite antenna is converted into an intermediate frequency signal, so that most of the satellite signals are provided to the set-top box, and some of the satellite signals can be provided to an external device. It can be provided.

Next, an embodiment according to the present invention will be described.

Figure 2 is a block diagram showing the functional separation of the internal configuration of a low noise block down converter for a satellite antenna according to the present invention.

As shown in FIG. 2, the LNB for a satellite antenna provides a low noise amplifier (LNA) 110 through a coupling capacitor C with a satellite signal in the 11.7 to 12.75 GHz band applied from the satellite antenna.

The low noise amplifier 110 low noise amplifies the satellite signal received from the satellite antenna and provides it to the first filter 120. Here, although not shown, the low noise amplifier 110 may be configured such that the first and second amplifiers are connected in series to perform the second amplification process.

The first filter 120 filters the signal of the corresponding reception band, for example, the 11.7 to 12.75 GHz band, from the satellite signal applied from the low noise amplifier 110 and provides it to the mixer 130. The first filter 120 is configured as a band pass filter (BPF).

The mixer 130 synthesizes the satellite signal applied from the first filter 120 and the signal applied from the local oscillator 130 to convert the satellite signal of the 11.7 ~ 12.75GHz band into an intermediate frequency. Here, the local oscillator 130 provides a mixer 130 with a frequency of, for example, 10.75 GHz. That is, the mixer 130 converts the satellite signal of the 11.7 ~ 12.75GHz band applied from the first filter 120 into a satellite signal of the intermediate frequency band of 950 ~ 2000MHz is provided to the second filter 150.

The second filter 150 filters the satellite signal of the intermediate frequency band with respect to the satellite signal applied from the mixer 130 and provides it to the first amplifier 160. The second filter 150 may be configured as a low pass filter (LPF) that filters only frequency signals below a specific frequency, for example, the highest intermediate frequency.

The first amplifier 160 amplifies the satellite signal of the intermediate frequency band applied from the second filter 150 by a predetermined level and provides it to the coupler 170. The first amplifier 160 may be configured in such a manner that two amplifiers are connected in series to perform a second amplification process.

The coupler 170 is configured to separate the satellite signal applied from the first amplifier 160 at a predetermined ratio and provide it to the first output terminal 180 and the second output terminal 190. Here, the first output terminal 180 is coupled to the set top box, the second output terminal 190 is coupled to the external device. On the other hand, the coupler 170 may be configured as a line coupler to minimize signal loss. Here, the line coupler is configured in a form in which the metallic second signal line is arranged in parallel to the metallic first signal line disposed between the first amplifier 160 and the first output terminal 180, and has one end R0. Ground through and the other end is configured to be coupled to the second output (190). That is, the induced current is induced into the second signal line by the first signal line, thereby separating the satellite signals into the first and second output terminals 180 and 190.

In addition, the coupler 170 separates the satellite signal at a ratio of 29: 1, for example, provides a signal corresponding to "29" to the first output terminal 180, and a signal corresponding to "1" to a second output terminal ( 190). In this case, a signal amplifier 200 may be coupled between the coupler 170 and the second output terminal 190 to amplify the satellite signal applied from the coupler 170 to the second output terminal 190. . In addition, the signal amplifier 200 may include a third filter 201 for filtering a frequency corresponding to an external device coupled to the second output terminal 190 in the satellite signal applied from the coupler 170, and the third filter ( And a second amplifier 202 for amplifying a predetermined level of the satellite signal applied from 201 to the second output terminal 190. The third filter 201 may be configured as a SAW filter.

On the other hand, in the present invention it is possible to configure to provide a plurality of satellite signals separated through the coupler 170, for example, N external devices.

That is, the LNB for satellite antenna according to the present invention, as shown in Figure 3, the first to N-1 branch (310: 3101) for branching the satellite signal of the second ratio applied from the line coupler 170 310N-1) is further provided, and the first to N-th signal amplifiers 320: 3201 to 320N are coupled to correspond to the branch parts, and correspond to the respective signal amplifiers 320. The twenty-first to second N output terminals 330: 3301 to 330N may be sequentially coupled. Here, the first to N-th branch portions 3101 to 310N may be parallel to the metallic main signal line coupled to the coupler 170, and one end thereof may have a resistance R1 to RN-1. And a line coupler configured to be grounded through the circuit and to receive an induced current induced by the main signal line. In addition, the first to N-th signal amplifiers 320: 3201 to 320N may include a SAW filter and an amplifier as shown in FIG. 2, wherein the filtering band of the SAW filter and the amplification degree of the amplifier are respectively The signal amplifiers may be set differently. In addition, the twenty-first to second N output terminals 330: 3301 to 330N may be configured as connection ports having different shapes. This is to enable support for various types of external devices. In this case, each output terminal 330 may be configured to perform an interface function corresponding to the corresponding connection port.

That is, according to the above embodiment, the satellite signal received from the satellite antenna is converted into an intermediate frequency signal, so that most satellite signals are provided to the set-top box, and some of the satellite signals can be provided to an external device. Can be provided. In this case, the satellite signal may be separated into a predetermined ratio and provided to a plurality of external devices, respectively.

In addition, the LNB for the satellite antenna is configured to separate the satellite signal through a line coupler to minimize attenuation due to signal separation. Therefore, it is possible for the user to watch satellite broadcasting of better quality through the TV receiver.

On the other hand, the present invention is not limited to the above embodiments and can be variously modified within the scope without departing from the technical spirit of the present invention.

As described above, according to the present invention, the satellite signal received from the satellite antenna is converted into an intermediate frequency signal, so that most of the satellite signals are provided to the set-top box, and some of the satellite signals are provided to the external device. LNB can be provided.

Claims (4)

A low noise block down converter for a satellite antenna for converting a satellite signal applied from a satellite antenna into an intermediate frequency of a predetermined level and providing the same to a set top box, A first output terminal for coupling with the set top box, A second output for coupling with an external device, A line coupler that separates the satellite signal converted into the intermediate frequency at a predetermined ratio and provides a satellite signal of a first ratio to the first output terminal and a satellite signal of a second ratio to the second output terminal; And a signal amplifying means for performing a filtering process for a predetermined frequency band on the satellite signal of the second ratio applied from the line coupler and amplifying the filtered satellite signal by a predetermined level to provide the second signal to the second output terminal. A low noise block downconverter for satellite antennas. The method of claim 1, And a plurality of branching means for branching the satellite signal of the second ratio applied from the line coupler, A plurality of signal amplifying means is coupled to correspond to each branch means, A low noise block down converter for a satellite antenna, characterized in that a plurality of second output stages are respectively coupled to correspond to the signal amplification means. The method of claim 2, The signal amplifying means is a low noise block down converter for a satellite antenna, characterized in that configured to perform a filtering process for a different frequency band for each branch means. The method of claim 2, The second output terminal is a low noise block down converter for a satellite antenna, characterized in that consisting of the connection port of the different shape.

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