KR0141742B1 - Multi-lnb power supply - Google Patents

Abstract

The present invention relates to a power supply automatic selection device for a multi-LNB (Low-Noise Converter Block), in particular a multi-LN to automatically recognize the type of the LNB according to the type of multi-LNB to supply power The present invention relates to a cost power automatic selection supply device. In the related art, a user has to select an LNB type to supply power. However, the present invention detects a synchronization signal from a current state of the LNB and a composite video signal output from a tuner. It automatically selects whether or not high frequency frequency is generated according to the state, so that the user can automatically supply power according to LNB type without selecting band setting. Will be.

Description

Multi-L & C Power Automatic Selection Supply

1 is a block diagram of a general multi-lens reception for satellite broadcasting.

Figure 2 is a block diagram of a conventional multi LNB power supply.

3 is a block diagram of another conventional multi L & N power supply.

4 is a block diagram of the multi-lens power automatic selection supply of the present invention.

5 is an output waveform diagram of each stage of FIG.

* Explanation of symbols for the main parts of the drawings

400: synchronization signal detection unit 410: control unit

420: current consumption detection unit 430: LNB state determination unit

440: high frequency generator 450: switching unit

The present invention relates to a power supply automatic selection device for a multi-LNB (Low-Noise Converter Block), in particular a multi-LN to automatically recognize the type of the LNB according to the type of multi-LNB to supply power A cost power automatic selection supply device.

In general, LNB is a kind of frequency down device that allows a user to input a BS (Broadcasting Satellite) tuner by downgrading a very high frequency received from a satellite when receiving a satellite broadcast. As shown in FIG. 1, the input power PIN is input from the regulator 170 to supply constant stable power so that each part of the system can operate, and the input switch stage 110 is provided by the input power PIN. Is driven to select a high frequency applied to the input terminal 100, and the selected high frequency is applied to the amplifier 120 to be amplified low noise and input to the mixer 130.

In addition, the output of the amplifier 120 is mixed with the local oscillation frequency applied from the voltage controlled oscillator 150 in the mixer 130 is applied to the amplifier 140 in a state loaded on a DC power source and only the components of the lower band It is amplified and output (RFOUT) to down convert (high converting) the high-frequency hitting primary.

On the other hand, the voltage controlled oscillation switching stage 160 receives the input power (PIN) to select the high voltage controlled oscillator 151 or the low voltage controlled oscillator 152 of the voltage controlled oscillator 150, which is Simply select the 14 volts / 18 volts when the voltage is applied to operate as a low-band L / N, and according to the presence or absence of a 22KHz square wave high band L / N The voltage controlled oscillation switching stage 160 is mainly configured as a low pass filter and a comparator in many cases.

In the multi-LNB for satellite broadcast reception described in detail above, the conventional multi-LNB power supply device includes a microcomputer 200 for outputting a control signal for selectively supplying a voltage, as shown in FIG. And a power supply unit 210 that receives a control signal of the microcomputer 200 and outputs a voltage, and a power source that selects and outputs a voltage output from the power supply unit 210 by receiving a control signal of the microcomputer 200. It is composed of a selection unit 2200.

On the other hand, another conventional multi-lens power supply device is a microcomputer 300 for outputting a control signal for selectively supplying a high frequency and voltage, as shown in Figure 3, and the microcomputer ( A power supply unit 310 for receiving a control signal of 300 and outputting a voltage, a power selection unit 320 for receiving a control signal of the microcomputer 300 and selecting and outputting a voltage of the power supply 310; High frequency generator 330 for selectively outputting the high frequency by the control signal of the microcomputer 300, the output voltage of the power selector 320 and the high frequency output from the high frequency generator 330 It consists of a switching unit 340 for mixing the high frequency.

The power supply device of the conventional multi L & N configured as described above will be described in detail.

First, the power supply of the multi L & B of FIG.

When the power supply signal is output from the microcomputer 200, the power supply unit 210 is turned on to output a voltage of about 20 volts, and the power selector 220 outputs the voltage from the power supply unit 210 and the microcomputer. The control signal output from the 200 is applied to selectively output voltages of 14 volts or 18 volts and 16 volts to the input switch 231 of the BS tuner 230 to selectively output the multi-L & B shown in FIG. To power on.

In addition, when the first down-converted signal is input to the input switch 231 of the BS tuner 230 in a multi-L NB, the DC blocking is performed by blocking appropriately and the DC is blocked, thereby providing a pure intermediate frequency to the amplifier 232. Childbirth is input and amplified.

The output of the amplifier 232 is input to the mixer 233 and mixed with the local oscillation frequency output from the voltage controlled oscillator 234 to output the secondary intermediate frequency signal to the amplifier 235. In 235, the video signal and the audio signal are extracted from the input signal and amplified therefrom, and the baseband signal is output to the intermediate frequency processor 236. The intermediate frequency processor 236 de-emphasis energy process. After the disperasal process, the composite video signal CVBS is finally output to the TV image processing unit (not shown).

Another multi LNB power supply will be described with reference to FIG.

In general, when operating as a high-frequency power supply, it depends on the presence or absence of a 22KHz square wave. When the 22KHz square wave is not loaded, it is the same as the operation of the low-frequency power supply described above. do.

When the power supply signal is output from the microcomputer 300, the power supply unit 310 is turned on to output a voltage of about 20 volts, and the power selector 320 is the voltage output from the power supply unit 310 and the microcomputer. The control signal output from the 300 is applied to selectively output a voltage of 14 volts or 18 volts and 16 volts as needed. At this time, if the frequency generation signal is output from the microcomputer 300, high frequency generation occurs. The unit 330 receives the inputted square wave of 22 KHz to the switching unit 340, and the switching unit 340 receives the switching signal of the microcomputer 300 and the output voltage of the power selecting unit 320. It is mixed with the 22 KHz square wave of the high frequency generator 330 and input to the BS tuner 350 to supply power to the multi-LN shown in FIG.

On the other hand, if the power output of the multi-L & N power supply described above is 0 volts, the power of the L & N is turned off, and if it is 14 volts, it is a power for vertical polarity reception in polarized wave reception, and if it is 18 volts, polarization is applied. In addition to being a power source for horizontal polarity reception at reception, 16 volts is a power source for circularly polarized light reception.

However, the above-described power supply of the multi-L NB shown in FIG. 1 is suitable for the low range but difficult to use for the high-frequency, and the power supply of the multi-L NB shown in FIG. Although it can be used for both low and low range, there is an inconvenience in use that the user must select whether to use high or low pass according to the situation at the time of use.

Accordingly, the present invention has been made in view of the above-mentioned problems in the prior art, and serves as a power supply device for a high pass and a low pass, so that the user can automatically catch and receive a band without a user's selection. The present invention having will be described in detail.

4 is a block diagram of the multi-lens automatic power supply selection device of the present invention, as shown in this, the synchronization signal detection unit 400 for detecting a synchronization signal from the composite video signal (CVBS) output from the BS tuner 490 And, the current consumption detection unit 420 for detecting the current consumption state of the LNB and the output of the current consumption detection unit 420 whether the LNB is operating in the high pass or low pass operation A control unit 410 for outputting an on / off signal according to an output signal of the LNB state determination unit 430, the LNB state determination unit 430, and the synchronization signal detection unit 400, and the controller ( If the output signal is the on-signal at 410, the high frequency generator 440 for generating a frequency for operating the high frequency LNB, and if the output signal of the controller 410 is switched on the high-frequency frequency Frequency of generator 440 Constitute a switching unit 450 for determining whether power.

The operation and effects of the present invention configured as described above will be described in detail.

Since the operation state of the tuner 490 is the same as in the related art, the description of the operation is omitted.

First, a case in which the LNB shown in FIG. 1 should be operated for a low pass will be described. The synchronization signal detector 400 detects a synchronization signal from the composite image signal CVBS output from the BS tuner 490 to generate the synchronization signal. As shown in Fig. 5 (d), when there is a signal, a low potential signal and a high potential signal are output when there is no signal.

Since the current consumption detection unit 420 detects the current consumption state of the LNB, the current consumption detection unit 420 currently operates for the low band, so the LNB state determination unit 430 determines the current consumption detection state of the current consumption detection unit 420. Accordingly, as shown in FIG. 5C, a low potential signal is output.

At this time, since the output signal of the LN state determination unit 430 is in the low potential state, the control unit 410 has a low potential as shown in FIG. 5E regardless of the output signal of the synchronization signal detection unit 400. The high frequency generator 440 and the switching unit 450 are turned off by outputting a signal.

However, when a user searches for a channel and the frequency goes to a high frequency, that is, when the LNB needs to operate for a high frequency, the current consumption detected by the current consumption detector 420 increases every time the low frequency. The determination unit 430 outputs a high potential signal as shown in FIG. 5 (c), and the control unit 410 outputs a high potential signal as shown in FIG. 5 (c). The controller 410 receives the synchronization signal of the synchronization signal detection unit 400 and the output signal of the LN state determination unit 430 as shown in FIG. 4D, and outputs a control signal. When the output signal of the synchronization signal detector 400 has a high potential, that is, when there is no signal, as shown in FIG. 450), so that ENV It will output a 22KHz square wave for the purpose of operation.

In addition, the power supply unit 470 is turned on by the microcomputer 460 to output a voltage of about 20 volts to the power selector 480, and the power selector 480 is shown in FIGS. 5A and 5B. According to the control signal of the microcomputer 460 as shown in the following selects and outputs the voltage, when the signals of (a) and (b) of the signals output from the microcomputer 460 is low potential Outputs a voltage of 0 volts, and if the signal in (a) is a high potential signal and the signal in (b) is a low potential signal, a voltage of 14 volts is output, and the signal in (a) is a low potential When the signal of (b) has a high potential, a voltage of 18 volts is output. When the signals of (a) and (b) have both high potentials, a voltage of 16 volts is output.

Therefore, when the LNB operates for the high band, the 22 KHz square wave of the high frequency generator 440 is loaded on the output voltage of the power selector 480 so that the LNB is automatically set to the high band LNB.

Therefore, the present invention detects the synchronization signal from the current consumption state of the LCD and the composite video signal output from the tuner and automatically selects whether or not to generate a high-frequency frequency according to the state without the user having to select a separate band setting The power is automatically supplied according to the L & B format, which makes it easy to use and very suitable for multiplexing satellite receivers.

Claims (1)

The LNB is operated for a high frequency region by receiving the output of the synchronous signal detector which detects the synchronous signal from the composite video signal outputted from the BS tuner, the current consumption detector which detects the current consumption state of the LCD, and the output of the current consumption detector. An LNB state discrimination unit for discriminating whether a signal is generated or operating in a low range; If the ON signal is a high frequency frequency generator for generating a frequency for operating the high frequency LNB, and if the output signal of the controller is on signal switching unit for determining whether or not the frequency output of the high frequency frequency generator; Multi-lenbyl power automatic selection supply characterized in that.