KR960003992Y1 - Satellite broadcasting receiver - Google Patents

Abstract

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Description

Satellite broadcasting receiving system

1 is a schematic configuration diagram of a satellite broadcast receiving system.

2a is a block diagram of a conventional satellite broadcasting reception system.

2b is a waveform diagram of an LNB reference voltage in a conventional satellite broadcasting reception system.

Figure 3a is a block diagram of a satellite broadcast receiving system according to the present invention.

3b is an LNB voltage output waveform diagram in a satellite broadcasting receiving system according to the present invention;

4A and 4B are circuit diagrams showing an embodiment of an LNB voltage control unit in a satellite broadcasting reception system according to the present invention.

* Explanation of symbols for main parts of the drawings

2: LNB circuit 3: Tuner and audio / video discrimination circuit

4: MCU and Peripheral Circuit 6: Comparison Circuit

8 pulse / current conversion circuit 10 LNB voltage control unit

L1, L2: Inductor C1, C2: Capacitor

The present invention relates to a satellite broadcast receiving system, and more particularly, to a satellite broadcast receiving system for reducing the installation cost by reducing the number of lines connected between an indoor unit (In Door Unit) and an outdoor unit (Out Door Unit). will be.

In general, the satellite broadcasting reception system has a schematic configuration as shown in FIG. 1. The outdoor unit (ODU) is equipped with a parabolic antenna, a polar rotor, a low noise blockdown converter (LBN), and an indoor unit (IDU). ) Is equipped with a receiver and a television. In the case of receiving a broadcast in such a satellite broadcast receiving system, a polarized signal is received from the satellite in polarized form and applied to the LNB, and the frequency of the received signal is lowered by the LNB with low noise. The receiver receives the satellite broadcast by processing the received signal and applying the signal to a television.

In such a satellite broadcasting reception system, a plurality of cables are connected between an indoor unit (IDU) and an outdoor unit (ODU) to transmit a received signal from an outdoor unit (ODU) to an indoor unit (IDU) or to an indoor unit (IDU). LNB dynamic power applied from) is transmitted to the outdoor unit (ODU).

Referring to FIG. 2, the conventional satellite broadcast reception system will be described in more detail as follows.

The conventional satellite broadcasting reception system is configured as shown in FIG. 2A. The indoor unit IDU includes a tuner and an audio / video discrimination circuit 3, an MCU and a peripheral circuit 4, an LNB voltage control unit 5, and an inductor. An L1 and a capacitor C1 are provided, and the outdoor unit ODU is provided with a polar loader 1, an LNB 2, an inductor L2, and a capacitor C2.

The LNB voltage control unit 5 maintains a DC power supply for operating the LNB circuit 2 at a constant voltage as shown in FIG. 2B and outputs it to the LNB circuit 2 side through the coaxial cable a. The polar rotor 1 receives a signal applied from the satellite according to a control signal applied from the MCU and the peripheral circuit 4 through the signal line b, and outputs the polarized wave to the LNB circuit 2 side. The LNB circuit 2 operates by receiving DC power applied from the LNB voltage control unit 5 to lower the frequency of the received signal applied from the polar rotor 1 through the coaxial cable a. Output Receives the signal from the tuner and the audio / video discrimination circuit (3) through the coaxial cable (a), separates the audio signal from the video signal, and outputs it to the TV monitor and various connected devices so that the user can watch the broadcast contents. To be able. In addition, the MCU and the peripheral circuit 4 control the operation of the tuner and the audio / video discrimination circuit 3, and control signals for controlling the polar rotor 1 through the polar line 1 through the signal line b. Applied to the side.

On the other hand, the inductor (L1) is used for alternating current blocking, passing through the direct current power output from the LNB voltage control unit 5 to pass through the coaxial cable (a) to the LNB circuit (2) side, LNB circuit (2) ) Block the reception signal applied through the ipsilateral cable (a) from the LNB voltage control unit (5). The capacitor C1 is used for DC blocking. The received signal applied from the LNB circuit 2 through the coaxial cable a is passed to the tuner and the audio / video distinguishing circuit 3, and the LNB voltage controller 5) It blocks the DC power applied from the coaxial cable (a) to the tuner and the audio / video discrimination circuit (3). Similarly, the inductor L2 is used for alternating current interruption. The inductor L2 passes through a direct current power source applied from the LNB voltage control unit 5 through the coaxial cable a and inputs the LNB circuit 2 to the LNB circuit 2 side. ) And outputs through the capacitor (C2) to block the reception signal applied through the coaxial cable (a) to the LNB circuit (2) again. The capacitor C2 is used for DC blocking, and passes the received signal output from the LNB circuit 2 to the coaxial cable a side and cuts off the DC power applied through the coaxial cable a.

In the conventional satellite broadcasting reception system as described above, the signal received from the LNB dynamic DC power source and the satellite is transmitted through the coaxial cable (a), and the control signal for polarization control of the polar rotor is transmitted to a plurality of signal lines (b). Since the number of lines must be connected between the indoor unit (IDU) and the outdoor unit (ODU), the system installation work is complicated and the system installation cost is increased.

The present invention has been devised to solve the above problems, and the number of lines connected between indoor units is reduced by transmitting LNB dynamic DC power, received signal and polarization control signal through a single coaxial cable. It is an object of the present invention to provide a satellite broadcasting reception system that enables economical installation of a system.

In order to achieve the above object, the present invention operates by receiving a DC power source applied through a second inductor via a coaxial cable, and lowers the frequency of a signal applied from the polar rotor to a low noise via a second capacitor. An LNB circuit output through the coaxial cable; A tuner and an audio / video discrimination circuit which receives a signal applied from the LNB circuit via a coaxial cable via a first capacitor, separates an audio signal and a video signal, and outputs the signal to a TV monitor and various connectors; A satellite broadcast receiving system including an MCU and a peripheral circuit that controls an operation of the tuner and an audio / video discrimination circuit and outputs a polarization control signal, in accordance with a polarization control signal applied from the MCU and the peripheral circuit. An LNB voltage control unit for changing a voltage of a DC power supply to a predetermined width and outputting the voltage to the coaxial cable via a first inductor; And a comparison circuit for comparing the voltage of the DC power source applied via the second inductor via the coaxial cable with the reference voltage, and outputting a pulse signal as a control signal for polarization control according to the comparison result.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 3A, the satellite broadcasting reception system according to the present invention includes an LNB circuit 2, a tuner and an audio / video discrimination circuit 3, an MCU and a peripheral circuit 4, a comparison circuit 6, a pulse / A current conversion circuit 8, an LNB voltage control unit 10, an inductor L1, a capacitor C1, an inductor L2, and a capacitor C2 are provided. The LNB voltage controller 10 outputs a DC power for operating the LNB circuit 2 to the LNB circuit 2 through a coaxial cable. When the DC power is output through the coaxial cable, the MCU and the peripheral circuit 4 are output. According to the control signal for polarization control applied from, change the voltage of DC power and output it to the coaxial cable side. The LNB circuit 2 operates by receiving a DC power applied from the LNB voltage controller 10 through a coaxial cable. The LNB circuit 2 operates by adjusting the DC power to a predetermined voltage to operate the polarizer (not shown in the drawing). The frequency of the received signal applied from) is lowered to low noise and output through the coaxial cable. The tuner and audio / video discrimination circuit (3) receives a signal applied from the LNB circuit (2) through a coaxial cable, separates the audio signal and the video signal, and outputs it to the TV monitor and various connected devices for broadcasting by the user. Allows you to watch the content. In addition, the MCU and the peripheral circuit 4 control the operation of the tuner and the audio / video discrimination circuit 3, and apply a control signal for controlling the polarization of the polar rotor to the LNB voltage controller 10 side.

On the other hand, the inductor (L1) is used for alternating current blocking, passing through the DC power output from the LNB voltage control unit 10 to pass through the coaxial cable to the LNB (2) side, the coaxial cable from the LNB circuit (2) Blocking the reception signal applied through the LNB voltage control unit 10 side. The capacitor C1 is used for DC blocking. The received signal applied from the LNB circuit 2 through the coaxial cable is passed to the tuner and the audio / video distinguishing circuit 3, and to the LNB voltage controller 10. DC power applied through the coaxial cable is blocked from being input to the tuner and the audio / video discrimination circuit (3). Similarly, the inductor L2 is used for alternating current interruption. The inductor L2 is used to cut the AC power through the DC power applied from the LNB voltage control unit 10 through the coaxial cable and input the LNB circuit 2 and the comparison circuit 6 to the LNB circuit. Output from the capacitor (C2) from (2) to block the reception signal applied via the coaxial cable to the LNB circuit 2 and the comparison circuit (6). The capacitor C2 is used for DC blocking, and passes the received signal output from the LNB circuit 2 to the coaxial cable side, and cuts off the DC power applied through the coaxial cable. On the other hand, the comparison circuit 5 compares the voltage of the DC power source applied via the inductor L2 via the coaxial cable with the reference voltage and outputs a pulse signal as a control signal for polarization control according to the comparison result. In addition, there are mechanical type and ferrite type in the polar rotor. On the side of the mechanical type polar rotor, the pulse signal output through the output terminal PA of the comparison circuit 6 is used for polarization control. Directly applied as a control signal, the pulse signal is converted into current by the pulse / current conversion circuit 8 on the ferrite polar rotor side and applied as a control signal for polarization control through the output terminal PB.

In addition, the LNB voltage controller 10 transmits a control signal for polarization control applied from the MCU and the peripheral circuit 4 together when the DC power for operating the LNB circuit 2 is output to the coaxial cable side. The circuit can be configured in the form as shown in Figs. 4a and b.

The LNB voltage controller 10 shown in FIG. 4A is composed of a voltage regulator 11, a plurality of resistors R11 to R15, a plurality of capacitors C11 and C12, and a transistor Q1. L200 is used by SGS Thmson. A DC power source having an LNB reference voltage is applied to an input terminal Vin of the voltage regulator 11, a control signal for polarization control applied from the MCU and the peripheral circuit 4 is applied to the input terminal CP, and the transistor Q1 is applied. Is on / off according to the polarization control signal applied from the input terminal (CP) to apply a current to the voltage regulator (11). The voltage regulator 11 changes the voltage of the DC power applied from the input terminal Vin according to the current applied from the transistor Q1 and outputs it to the coaxial cable side through the output terminal Vout, as shown in FIG. 3B. As described above, the voltage is changed to a predetermined width and output according to the current applied from the transistor Q1 based on the LNB reference voltage.

In addition, the LNB voltage controller 10 shown in FIG. 4B includes a voltage regulator 12, a plurality of resistors R16 to R20, a capacitor C13, and a transistor Q2, and thus the voltage regulator 12. For example, National Semiconductor Corporation's LM 317 is used. A DC power supply having an LNB reference voltage is applied to the input terminal Vin of the voltage regulator 12, a control signal for polarization control applied from the MCU and the peripheral circuit 4 is applied to the input terminal CP, and the transistor Q2 is applied. Is on / off according to the polarization control signal applied from the input terminal (CP) to apply a current to the voltage regulator (12). The voltage regulator 12 changes the voltage of the DC power applied from the input terminal Vin according to the current applied from the transistor Q2 and outputs it to the coaxial cable side through the output terminal Vout, as shown in FIG. As described above, the voltage is changed to a predetermined width and output according to the current applied from the transistor Q2 based on the LNB reference voltage.

On the other hand, the comparison circuit 6 is composed of a plurality of resistors (R1 ~ R5) and the OP amplifier (7), divided by the resistors (R1 ~ R2) at the inverting end (-) of the OP amplifier (7) The reference voltage Vcc 'is applied, and the voltage of the DC power supply input via the inductor L2 from the coaxial cable is applied to the non-inverting terminal (+) of the OP amplifier 7. The OP amplifier 7 is compared with the voltage of the DC power source applied to the non-inverting terminal (+) and the reference voltage Vcc 'applied to the inverting terminal (-). When the voltage is higher than the reference voltage (Vcc ') applied to-), a high level signal is output, and the voltage applied to the non-inverting terminal (+) is equal to the reference voltage (Vcc') applied to the inverting terminal (-). Outputs a low-level signal. That is, the OP amplifier 7 outputs a pulse signal according to the comparison result by comparing the reference voltage Vcc 'applied to the inverting terminal (-) and the voltage of the DC power applied to the non-inverting terminal (+). The signal is used as a control signal for adjusting the polarization of the polar rotor. The reference voltage Vcc 'applied to the inverting terminal (-) of the OP amplifier 7 is preferably applied in the same manner as the LNB reference voltage.

The LNB circuit 2 is equipped with a voltage regulator (not shown in the figure) for regulating the voltage of the DC power supply to itself, and converts the voltage of the DC power supply applied via the inductor L2 from the coaxial cable to the LNB reference voltage. It is operated by adjusting it to.

The satellite broadcasting system of the present invention configured as described above operates as follows.

When the LNB voltage control unit 10 outputs a DC power source for operating the LNB circuit 2 to the LNB circuit 2 side through a coaxial cable, the MCU and the peripheral circuit 4 are used to control the polarization of the polar rotor. The control signal is applied to the LNB voltage controller 10 side. At this time, the LNB voltage controller 10 changes the voltage of the DC power supply in the form of 3b according to the polar rotor control control signal applied from the MCU and the peripheral circuit 4 to the coaxial cable side through the inductor L1. Output Accordingly, the LNB circuit 2 operates by receiving the DC power applied from the LNB voltage control unit 10 through the coaxial cable, and operates the voltage of the DC power applied via the inductor L2 from the coaxial cable. It operates by adjusting the input voltage to a predetermined voltage by the voltage regulator included in the circuit, and lowering the frequency of the received signal applied from the polar rotor to low noise and outputting the same to the coaxial cable through the capacitor C2. The tuner and the audio / video discrimination circuit 3 receive a signal applied from the LNB circuit 2 via the capacitor C1 through a coaxial cable, separate the audio signal from the video signal, and then process the TV monitor and Output to various connected device axis enables the user to watch the broadcast contents.

On the other hand, the OP amplifier 7 of the comparison circuit 6 has a reference voltage (Vcc) to which the DC power applied to the non-inverting terminal (+) is applied to the voltage and the inverting terminal (-) via the inductor L2 through the coaxial cable. ') Is compared and the pulse signal is output as the control signal for polarization control according to the comparison result.On the mechanical polar rotor side, the corresponding pulse signal is directly applied as the control signal for polarization control through the output terminal PA, and the ferrite polar On the rotor side, the pulse / current converter circuit 8 converts the pulse signal into a current and applies it as a control signal for polarization adjustment through the output terminal PB.

As described above, the present invention transmits the LNB dynamic DC power supply, the reception signal, and the control signal for polarization control through a single coaxial cable, thereby reducing the number of lines connected between the indoor unit and the outdoor unit. You can install it.

Claims (1)

It operates by receiving DC power applied through the second inductor (L2) via the coaxial cable, and lowers the frequency of the signal applied from the polar rotor to low noise to pass the coaxial cable through the second capacitor (C2). LNB circuit 2 for outputting through; Tuner and audio to receive the signal applied from the LNB circuit (2) via the coaxial cable via the first capacitor (C1) to separate the audio signal and the video signal and to output to the TV monitor and various connected devices / Video discrimination circuit 3; A satellite broadcast receiving system comprising an MCU and a peripheral circuit 4 for controlling the operation of the tuner and the audio / video discrimination circuit 3 and outputting a control signal for polarization control, to the MCU and the peripheral circuit 4. An LNB voltage control unit 10 for changing the voltage of the DC power supply to a predetermined width according to the control signal for polarization control applied from the output unit and outputting the voltage to the coaxial cable via the first inductor L1; And a comparison circuit 6 for comparing the voltage of the DC power supply applied via the second inductor L2 via the coaxial cable with the reference voltage, and outputting a pulse signal as a control signal for polarization control according to the comparison result. Characterized in a satellite broadcast receiving system.