KR19990005050U - Satellite tuner - Google Patents

Abstract

The present invention relates to a tuner for satellite broadcasting, comprising: a signal level comparator for measuring the electric field strength of a high frequency signal supplied from an antenna, converting the data into a data signal, and applying a data signal to the microcomputer; When the electric field strength of the high frequency signal supplied from the antenna is low by low noise amplification, the high frequency signal is low noise amplified. When the electric field strength of the high frequency signal supplied from the antenna is high, the RF tuning is performed without amplifying the high frequency signal. Since it comprises a low noise amplifier that is automatically turned off to be supplied to the negative, there is an excellent effect that the signal level of the high frequency signal is actively adjusted to maintain the optimal reception sensitivity.

Description

Satellite tuner

The present invention relates to a tuner for satellite broadcasting. In particular, a satellite having a low-noise amplifier under the control of the microcomputer is installed at the rear of the antenna so that the signal level can be actively adjusted according to the change in the electric field strength of the high frequency signal supplied from the satellite over the equator. A broadcast tuner.

The general satellite tuner includes an input filter unit 10 which removes noise components included in a signal of a high frequency band applied from an antenna ANT and passes only a desired high frequency signal, as shown in the block diagram of FIG. A high frequency amplifier 20 for amplifying the high frequency signal passed through the input filter unit 10, and an RF tuning unit 30 for selecting a desired high frequency signal from the high frequency signal amplified by the high frequency amplifier 20. ), An OSC 70 interlocked by the PLL 60 controlled by the microcomputer 50, and outputting an oscillation frequency, and a high frequency signal selected through the RF tuning unit 30 and oscillation of the OSC 70. The mixing unit 40 for mixing the frequencies and outputting the intermediate frequency, the first intermediate frequency amplifying unit 80 for amplifying the intermediate frequency of the mixing unit 40, and the first intermediate frequency amplifying unit 80 The intermediate frequency amplified By the SAW filter unit 90 for filtering, the second intermediate frequency amplifier 100 for re-amplifying the intermediate frequency filtered through the SAW filter unit 90, and the second intermediate frequency amplifier 100 The demodulator 110 demodulates the amplified intermediate frequency and outputs the low frequency signal.

Referring to the operation of the tuner for satellite broadcasting according to the prior art made of the configuration as follows.

First, when a high frequency signal of approximately 10 kHz is emitted from a satellite above the equator, the high frequency signal is integrated in a satellite antenna and then in a low noise block down convertor (not shown). It is converted into a high frequency signal and supplied to the antenna ANT of the tuner.

At this time, the high frequency signal of the 1 to 2 kHz band received through the antenna ANT is removed through the input filter unit 10, the noise component is removed only the desired high frequency signal is passed through the amplification by the high frequency amplifier 20 After that, only the desired high frequency signal is selected through the RF tuning unit 30. Thereafter, the high frequency signal selected through the RF tuning unit 30 is supplied to the mixing unit 40 to receive the channel frequency of the microcomputer 50 for inputting the data of the channel frequency to be received. The first intermediate frequency amplification unit 80 and the SAW filter unit 90 are mixed with the oscillation frequency of the OSC 70 interlocked by the output voltage of the PLL 60 for outputting the voltage, and then converted into an intermediate frequency of 480 MHz. The second intermediate frequency amplifier 100 is supplied to the demodulator 110 and output as a final low band signal.

By the way, according to the prior art satellite tuner, when a high frequency signal of approximately 10 kHz band emitted from a satellite above the equator is converted into a high frequency signal of 1 to 2 kHz band through a satellite antenna and supplied to the tuner antenna, Since the electric field strength changes and deteriorates from time to time, the reception sensitivity of the tuner is significantly reduced.

Accordingly, the present invention has been made to solve the above problems, and its purpose is to provide a low noise amplifier under the control of the microcomputer to actively adjust the signal level according to the change in the electric field strength of the high frequency signal supplied from the antenna. It is provided in the rear end of the antenna to provide a tuner for satellite broadcasting that can maintain the optimal reception sensitivity.

1 is a block diagram showing a satellite broadcast tuner according to the prior art.

Figure 2 is a block diagram showing a tuner for satellite broadcasting according to the present invention

Explanation of symbols on the main parts of the drawings

10: input filter unit 20: high frequency amplifier unit

30: RF tuning unit 40: mixing unit

50: Micom 60: PLL

70: OSC 80: first intermediate frequency amplifier

90 SAW filter 100 second intermediate frequency amplifier

110: demodulation unit 200: signal level comparison unit

300: low noise amplifier ANT: antenna

The satellite broadcast tuner according to the present invention for achieving the above object is an OSC that outputs an oscillation frequency interlocked by an RF tuning unit for selecting only a desired high frequency signal from a high frequency signal supplied from an antenna and a PLL controlled by a microcomputer. And a mixing unit for mixing the high frequency signal selected through the RF tuning unit and the oscillation frequency of the OSC to output an intermediate frequency, and a demodulation unit for demodulating the intermediate frequency of the mixing unit and outputting the low frequency signal. In the case of the electric field strength of the high-frequency signal supplied from the antenna after measuring the electric field strength of the high-frequency signal supplied from the antenna to the data level comparator and data applied to the microcomputer and the high-frequency signal supplied from the antenna by the control signal The low frequency amplification of the high frequency signal, When the electric field strength of the high frequency signal supplied from the antenna is high, a low noise amplifier is automatically turned off so that the high frequency signal can be supplied to the RF tuning unit without amplifying the high frequency signal.

Hereinafter, a preferred embodiment of the satellite broadcast tuner according to the present invention will be described with reference to FIG. 2.

2 is a block diagram showing a satellite tuner according to the present invention.

As shown in FIG. 2, the satellite tuner of the present invention includes an input filter unit 10 which removes noise components included in a signal of a high frequency band applied from an antenna ANT and passes only a desired high frequency signal; A high frequency amplifying unit 20 for amplifying a high frequency signal passing through the input filter unit 10, and an RF tuning unit 30 for selecting a desired high frequency signal from the high frequency signal amplified by the high frequency amplifying unit 20; And an OSC 70 that is linked by the PLL 60 controlled by the microcomputer 50 and outputs an oscillation frequency, and a high frequency signal selected through the RF tuning unit 30 and an oscillation frequency of the OSC 70. Mixing unit 40 for outputting the intermediate frequency by mixing, the first intermediate frequency amplifier 80 for amplifying the intermediate frequency of the mixing unit 40 and the first intermediate frequency amplifier 80 Filter Amplified Intermediate Frequency SAW filter unit 90, a second intermediate frequency amplifier 100 for re-amplifying the intermediate frequency filtered through the SAW filter unit 90, and amplified by the second intermediate frequency amplifier 100 The demodulator 110 demodulates the intermediate frequency and outputs the low frequency signal.

In this case, the signal level comparison unit 200 which measures the electric field strength of the high frequency signal supplied from the antenna ANT and converts it into data is connected to the microcomputer 50, and the front end of the input filter unit 10 is connected. The low noise amplification of the high frequency signal when the electric field strength of the high frequency signal supplied from the antenna ANT is low by the control signal of the microcomputer 50 supplied with the data signal of the signal level comparator 200. When the electric field strength of the high frequency signal supplied from the antenna ANT is high, it is automatically turned off so that the high frequency signal is supplied to the RF tuning unit 30 through the input filter unit 10 without amplifying the high frequency signal. Low noise amplifier 300 is connected.

Referring to the operation of the tuner for satellite broadcasting according to the present invention made of the configuration as follows.

First, when a high frequency signal of approximately 10 Hz band is converted to a high frequency signal of 1 to 2 Hz band by a low noise converter from an satellite above the equator, and then supplied to the antenna ANT of the tuner, the electric field strength of the high frequency signal is a signal. After being measured by the level comparator 200, it is converted into a data signal and applied to the microcomputer 50.

In this case, when the electric field strength of the high frequency signal supplied from the antenna ANT is low, it is amplified by the low noise amplifier 300 and then applied to the input filter unit 10, while being supplied from the antenna ANT. When the field strength of the high frequency signal is high, the low noise amplifier 300 is automatically turned off and is applied to the input filter unit 10 as it is with the high frequency signal having the high field strength.

Thereafter, the high frequency signal supplied through the low noise amplifier 300 has the noise component removed by the input filter unit 10 and only a desired high frequency signal is passed and amplified by the high frequency amplifying unit 20. Only the desired high frequency signal is selected through the tuning unit 30.

In this case, the high frequency signal selected through the RF tuning unit 30 is supplied to the mixing unit 40 to receive a channel frequency of the microcomputer 50 for inputting data of the channel frequency to be received, and thus the voltage is fixed in a phase-synchronizing manner. The first intermediate frequency amplifier 80 and the SAW filter unit 90 are mixed with the oscillation frequency of the OSC 70 that is interlocked by the output voltage of the PLL 60 that outputs the signal, and then converted into an intermediate frequency of 480 MHz. It is supplied to the demodulator 110 via the second intermediate frequency amplifier 100 and output as a final low band signal.

As described above, according to the satellite broadcasting tuner, a low-noise amplifier under the control of the microcomputer is installed at the rear end of the antenna so that the signal level can be actively adjusted according to the change in the electric field strength of the high frequency signal supplied from the antenna. There is an excellent effect to maintain the reception sensitivity of.

Claims (1)

An RF tuning unit for selecting only a desired high frequency signal among the high frequency signals supplied from the antenna, an OSC interlocking by a PLL controlled by a microcomputer, and outputting an oscillation frequency; a high frequency signal selected through the RF tuning unit and oscillation of the OSC In the satellite broadcasting tuner comprising a mixing unit for mixing the frequency and outputting the intermediate frequency, and a demodulation unit for demodulating the intermediate frequency of the mixing unit to output a low band signal, A signal level comparator for measuring the electric field strength of the high frequency signal supplied from the antenna and converting the data into data; When the electric field strength of the high frequency signal supplied from the antenna is low by the control signal of the microcomputer, the low frequency amplification of the high frequency signal is performed. When the field strength of the high frequency signal supplied from the antenna is high, the high frequency signal is not amplified. And a low noise amplifier which is automatically turned off to be supplied to the RF tuning unit in a state.