KR100845610B1 - Circuit for protecting satellite broadcasting receiver from over current of lnb line - Google Patents

Abstract

A circuit for protecting a satellite broadcasting receiver from an overcurrent of an LNB(Low Noise Block down converter) line is provided to discriminate a normal or short-circuit state of the LNB line by connecting a pull-up resistor to an output terminal to maintain voltage even in cut-off of power due to a short-circuit uniformly. A circuit(33) for protecting a satellite broadcasting receiver from an overcurrent of an LNB line(22) includes an LNB power supply(32), a switching unit(331), a monitoring unit(332), a feedback unit(333), a control signal generating unit(334), and an auxiliary power cut off unit(335). The switching unit connects or cuts off power of the LNB power supply to/from the LNB line according to a control signal. The monitoring unit monitors the power supplied to an LNB(20) through the LNB line to generate a monitoring signal. The feedback unit feeds back the signal of the monitoring unit. The control signal generating unit controls the switching unit through AND operation of the signal of the monitoring unit and an LNB on/off signal of a control unit. The auxiliary power cut off unit cuts off auxiliary power supplied to the LNB from the LNB power supply through a pull-up resistor(R6) in cut-off of power by a user.

Description

Satellite Power Receiver Over Current Protection Device for Power Monitoring System {CIRCUIT FOR PROTECTING SATELLITE BROADCASTING RECEIVER FROM OVER CURRENT OF LNB LINE}

The present invention relates to an LNB power supply apparatus of a satellite broadcasting antenna, and more particularly, to a satellite broadcasting receiver that can protect a satellite broadcasting receiver from overcurrent when a short circuit (short) occurs due to a cable or LNB abnormality in relation to the LNB power supply. The present invention relates to a satellite broadcast receiver overcurrent protection device of an LNB power monitoring method.

In general, satellite broadcasting receives the broadcast signal transmitted through the uplink from the earth station on the earth from the satellite located on the geostationary orbit, and then amplifies it from the transponder (TP) and transmits it through the downlink again. Is to make it available to the receiver.

In order to receive satellite broadcasting in each home on the ground, the antenna is installed outdoors and receives the SHF band wireless signal from the satellite and the low noise amplifies the signal of the SHF frequency band (4 ~ 12GHz) received from the antenna. Low Noise Block Down Converter (LBN), which converts frequency into IF and transmits it indoors via coaxial cable, satellite set-top box (hereinafter referred to as 'satellite broadcast receiver') and satellite set-top installed indoors A television connected to the box STB is required.

Normally, a satellite launched on a geostationary track for satellite broadcasting has a plurality of repeaters. For example, the KOREA SAT2 includes three broadcasting repeaters and 12 communication repeaters, and the Mugunghwa 3 satellite. (KOREA SAT3) is equipped with six broadcasting repeaters and 24 communication repeaters. In addition, satellites use various types of polarization for efficient use of radio waves, for example, left circular circular polarization (LHCP), vertical polarization or horizontal polarization.

The outdoor antenna needs to adjust the elevation angle and azimuth angle according to the satellite and region to be received, and the outdoor low noise frequency converter is integrated with the feed horn located in front of the dish antenna reflector. The low-noise frequency converter is operated by the power supplied from the satellite broadcasting receiver and can select either vertical polarization or horizontal polarization according to 13V / 18V control voltage and high and low band according to 22KHz tone signal. have.

In the technique of monitoring the LNB power supply, the conventional method simply checks the voltage state of the LNB power supply terminal. When the potential difference of the power supply terminal becomes ground (or 0V) at the time of short-circuit, it is judged as a short-circuit state. Could fall out. Specifically, when a short circuit occurs due to a lightning strike or an external factor, the LNB power supply circuit is cut off once. As a result, the LNB power is continuously cut off, and thus the LNB output terminal is not powered (0V). It will recognize and fall out of control. As a result, in the related art, since there is no power applied after the power supply is cut off due to a short circuit detection, the LNB power is not continuously supplied because it is recognized as a short circuit state even after recovering to a normal state.

The present invention has been proposed to solve the above problems, and an object of the present invention is to check the state of the LNB power terminal at all times to determine whether there is a short circuit or connection and to use it as an LNB control signal to short-circuit due to a cable or LNB error. It is to provide a satellite broadcasting receiver overcurrent protection device of the LNB power monitoring method that can protect the satellite broadcasting receiver from over current in case of a short.

In order to achieve the above object, the apparatus of the present invention is a satellite broadcast receiving system in which a satellite broadcast receiver and an LNB are connected to an LNB line so that the satellite broadcast receiver can supply power to the LNB through an LNB line.

An LNB power supply, a switching unit for connecting or disconnecting the power of the LNB power supply to the LNB line according to a control signal, and a monitoring unit for monitoring a power supplied to the LNB through the LNB line and generating a monitoring signal; A feedback unit for feeding back the signal of the monitoring unit, a control signal generation unit for feeding back the signal of the monitoring unit and performing an AND operation on the LNB on / off signal inputted from the controller to control the switching unit; The auxiliary power cut-off unit for cutting off the auxiliary power provided to the LNB side through the pull-up resistor (R6) from the LNB power supply.

The switching unit includes a switching transistor Q1 connected to an output terminal of the LNB power supply, and a reverse current protection diode D1 connected between the switching transistor and the LNB line, and the monitoring unit outputs the LNB power supply. A pull-up resistor R6 for bypassing the voltage and transferring the voltage to the monitoring unit, a voltage divider resistor R3 and R4 connected to the LNB line and dividing a line voltage, and the voltage divider resistors R3 and R4. The third transistor Q3 is turned on in a normal state and outputs a low signal in response to a split voltage therebetween, and is turned off in a short circuit to output a high signal.

The feedback unit may include an inverter U2 which converts a low signal into a high signal among the monitoring signals of the monitoring unit and converts a high signal into a low signal and feeds it back to the control signal generator, wherein the control signal generator is input from the controller. An end gate U1 for performing an AND operation on the LNB on / off signal and the monitoring signal of the feedback unit, and on / off according to the output of the end gate U1 to turn on / off the switching transistor Q1 of the switching unit. Is composed of a second transistor Q2.

The LNB power monitoring type satellite broadcasting receiver overcurrent protection device according to the present invention can be distinguished from a short circuit state by connecting a pull-up resistor (R6) to the output terminal to maintain a constant voltage even when the power supply is cut off due to a short circuit detection. This feedback has the advantage that the user can directly control by connecting to the user's LNB control signal and logical product (AND operation).

In addition, the overcurrent protection device according to the present invention always checks the state of the LNB power terminal to determine whether there is a short circuit or connection, and uses it as an LNB control signal to protect the satellite broadcasting receiver from overcurrent in the event of a short circuit (short) due to a cable or LNB error. can do.

The technical problems achieved by the present invention and the practice of the present invention will be more clearly understood by the preferred embodiments of the present invention described below. The following examples are merely illustrated to illustrate the present invention and are not intended to limit the scope of the present invention.

1 is a schematic diagram showing the overall configuration of a satellite broadcasting receiving system to which the present invention is applied. Typical satellite broadcasting receiving system to which the present invention can be applied is an antenna 10 and an antenna 10 for receiving a radio signal of the SHF band (4 ~ 12GHz) from the satellite is installed outdoors, as shown in FIG. Low noise amplified frequency converter (LNB; 20) for low noise amplification of the signal received from the SHF frequency band (4 to 12 GHz) and converting it into an intermediate frequency (IF) of the 1 GHz band and transmitting it indoors through the LNB line 22 made of a coaxial cable. And a satellite broadcasting receiver 30 installed indoors, and a television (not shown) that receives a video output and an audio output of the satellite broadcasting receiver 30 so that a user can view it.

The antenna 10 is installed outdoors by adjusting the elevation angle and azimuth angle according to the satellite and region to be received, and the low noise frequency converter (LNB: 20) is integrated with the feed horn located at the front of the dish antenna reflector to form a coaxial cable. It operates in accordance with the power supplied from the satellite broadcast receiver 30 through the LNB line 22. In addition, the low-noise frequency converter (LNB) 20 can select vertical polarization or horizontal polarization by 13V / 18V voltage switching, and can select high band and low band according to tone signal on / off of 22KHz.

The satellite broadcast receiver 30 may have various structures, but the LNB power supply unit may provide a satellite broadcast receiver system 31 including a tuner for receiving satellite broadcast signals and a power supply (usually 15V DC) to the LNB 20 ( 32), the control unit 34 for controlling the overall operation, and the LNB power supply 32 via the LNB line 22 made of coaxial cable according to the LNB on / off control signal of the control unit 34; 20) the overcurrent protection device 33 for supplying or interrupting the side and monitoring the LNB line side.

The satellite broadcast receiver 30 recovers the digital broadcast program of the MPEG2 transport stream received through the antenna 10 and the LNB 20 to the original video and audio signals, and then processes the video and audio signals. An audio signal is output through a television (not shown) so that a user can watch a desired digital broadcast program.

Referring to FIG. 1, the satellite broadcasting reception system 31 includes a tuner and a decoder to receive a broadcast signal of a specific channel under the control of the controller 34, and decomposes a packet assembled into a transport stream of the broadcast signal. The video signal compressed in the MPEG2 standard is reproduced as the original video signal, and the compressed audio signal is decoded according to the corresponding standard and reproduced as the original audio signal.

The LNB power supply 32 provides a power supply, such as 15V DC, required by the LNB 20, and the overcurrent protection device 33 according to the present invention monitors the LNB on / off signal of the control unit 34 and the LNB line side. The LNB power supply 32 supplies or cuts off the power according to the signal. Although not shown in detail in the drawing, the LNB power supply system may be implemented in a tuner or may be equipped with a diesec control function.

2 is a circuit diagram showing an over-current protection device for satellite broadcast receiver of the LNB power monitoring method according to the present invention.

Referring to FIG. 2, the overcurrent protection device 33 of the present invention connects or cuts off the power of the LNB power supply 32 and the LNB power supply 32 to the LNB 20 side according to a control signal. ), A monitoring unit 332 for monitoring a power supplied to the LNB 20 through the LNB line 22 to generate a monitoring signal, a feedback unit 333 for feeding back a signal from the monitoring unit 332, A control signal generator 334 for generating a control signal for turning on / off the switching unit 331 by performing an AND operation on the feedback monitoring signal and the LNB on / off signal received from the control unit 34, and the power supply by the user. And an auxiliary power interrupter 335 for interrupting an auxiliary power provided from the LNB power supply 32 to the LNB side through the pull-up resistor R6.

The switching unit 331 includes a switching transistor Q1 and a reverse current protection diode D1 connected to an output terminal of the LNB power supply 32, and the monitoring unit 332 includes the LNB power supply 32. The voltage divider resistors R3 and R4 connected to the pull-up resistor R6 and the LNB line 22 side for bypassing the output voltage to the monitoring unit 332 to divide the line voltage, and the voltage divider resistor ( A base of the third transistor Q3 and the third transistor Q3 which is turned on in a normal state and outputs a low signal according to the division voltage (monitoring voltage) between R3 and R4 and is turned off when a short circuit is output. It is composed of bias resistors R5 and R7 connected to the collector, respectively.

The feedback unit 333 includes an inverter U2 that converts a low signal into a high signal among the monitoring signals of the monitoring unit 332 and converts the high signal into a low signal to feed back to the control signal generator 334. The control signal generator 334 includes an end gate U1 for performing an AND operation on the LNB on / off control signal LNB on / off control input from the controller 34 and the monitoring signal fed back from the feedback unit 333. The second transistor Q2 is turned on / off according to the output of the end gate U1 to turn on / off the switching transistor Q1 of the switching unit 331. The collector of the second transistor Q2 and the base of the switching transistor Q1 are connected via a resistor R1.

In addition, the auxiliary power cut-off unit 335 is composed of an inverter U3 for inverting the LNB on / off signal, a base resistor R8, and a switching transistor Q4 for shutting off the auxiliary power on the LNB line 22 side. When the power supply is cut off, the auxiliary power provided from the LNB power supply 32 to the LNB side through the pull-up resistor R6 is cut off.

Next, the operation of the overcurrent protection circuit according to the present invention configured as described above will be described in detail.

1. LNB line side is normal

First, when the satellite broadcast receiver 30 is turned on by a user's manipulation, the controller 34 outputs a high signal for turning on the LNB 20 to receive the satellite broadcast signal, thereby turning on the switching unit 331. When the LNB line 22 side is normal when the switching unit 331 is turned on, the normal voltage is applied to the LNB line 22 side, and the normal voltage on the line side is divided by the division resistors R3 and R4 to form a third transistor ( Applied to the base of Q3) with a forward bias. Accordingly, the third transistor Q3 is turned on to output a low signal to the collector side, and the low signal is inverted by the inverter U2 so that the high signal is transmitted to the end gate U1.

The end gate U1 performs an AND operation on the high signal fed back from the control unit 34 and the fed back high signal to output a high signal, and the high signal turns on the second transistor Q2 via the base resistor R2. Accordingly, the base of the switching transistor Q1 is connected to the ground through the resistor R1 and forward biased so that the switching transistor Q1 is turned on to supply the reverse current protection diode D1 to the power supply of the LNB power supply 32. It is connected to the LNB line 22 to supply power to the LNB 20. Accordingly, the LNB 20 normally transmits the satellite broadcasting reception signal to the satellite broadcasting receiving system 31 so that the satellite broadcasting receiver 30 can receive the satellite broadcasting.

On the other hand, when the user turns off the power supply to the LNB through the control unit 34, the control unit 34 outputs a low signal to turn off the switching transistor Q1 irrespective of the feedback signal to cut off the main power supply and the auxiliary power supply. The switching transistor Q4 of the blocking unit 335 is turned on to forcibly ground the LNB line 22 to bypass the auxiliary power supplied through the pull-up resistor R6. Therefore, the connection of the pull-up resistor R6 can prevent unintentional or unstable power supply to the LNB side.

2. LNB line short circuit

If the LNB line 22 is short-circuited, the line side becomes ground or a voltage of 0V, so there is no voltage divided between the division resistors R3 and R4, so that the base of the third transistor Q3 is reverse biased. Accordingly, the third transistor Q3 is turned off to output a high signal (or Vcc) to the collector side, and the high signal is inverted by the inverter 333 so that the low signal is transmitted to the end gate U1.

The end gate U1 outputs a low signal regardless of the signal of the control unit 34 by the fed back low signal, and the low signal turns off the second transistor Q2 via the base resistor R2. The base of the switching transistor Q1 becomes high and is reverse biased while the switching transistor Q1 is turned off to cut off the power supply of the LNB power supply 32. Accordingly, power cannot be supplied to the LNB line 22 side.

3. When LNB line side recovers from short circuit and becomes normal

In the related art, once the switching transistor Q1 is turned off, the voltage is not continuously applied to the LNB line 22 so that the LNB power is not supplied even if the line is restored to normal.

In the overcurrent protection device 33 according to the present invention, since the auxiliary power for monitoring is applied to the split resistors R3 and R4 through the pull-up resistor R6 even when the switching transistor Q1 is turned off and the power supply is cut off, Short circuit status can be distinguished.

That is, when the LNB line 22 side recovers from a short circuit and returns to a normal state, the monitoring auxiliary power is applied to the split resistors R3 and R4 through the pull-up resistor R6 even though the switching transistor Q1 remains in the off state. The transistor Q3 is turned on to output a low signal, which is inverted to a high signal through the inverter U2 and transmitted to the end gate U1. The end gate U1 performs an AND operation on the high signal fed back from the control unit 34 and the fed back high signal, and outputs a high signal. The high signal turns on the second transistor Q2 and accordingly switches the switching transistor ( Q1) is turned on again to connect the power of the LNB power supply 32 to the LNB line 22 through the reverse current protection diode D1 to supply the power to the LNB 20.

The present invention has been described above with reference to one embodiment shown in the drawings, but those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom.

1 is a schematic diagram showing the overall configuration of a satellite broadcasting receiving system to which the present invention is applied;

2 is a circuit diagram showing an over-current protection device for satellite broadcast receiver of the LNB power monitoring method according to the present invention.

* Explanation of symbols for main parts of the drawings

10: antenna 20: LNB

22: LNB line 30: satellite broadcasting receiver

31: Satellite broadcasting receiver system 32: LNB power supply

33: overcurrent protection device 34: control unit

331: switching unit 332: monitoring unit

333: feedback unit 334: control signal generation unit

335: auxiliary power breaker

Claims (5)

In the satellite broadcasting receiver system in which the satellite broadcasting receiver and the LNB are connected to the LNB line so that the satellite broadcasting receiver can supply power to the LNB through the LNB line. With LNB power supply, A switching unit for connecting or disconnecting the power of the LNB power supply to the LNB line side according to a control signal; A monitoring unit for monitoring a power supplied to the LNB through the LNB line and generating a monitoring signal; A feedback unit for feeding back a signal of the monitoring unit; A control signal generation unit configured to perform an AND operation on the signal of the monitoring unit fed back through the feedback unit and the LNB on / off signal input from the control unit to control the switching unit; The LNB power monitoring type satellite broadcasting receiver over-current protection device, characterized in that the auxiliary power cut-off unit for disconnecting the auxiliary power provided to the LNB side through the pull-up resistor (R6) from the LNB power supply when the user is powered off. The method of claim 1, wherein the switching unit Switching transistor (Q1) connected to the output terminal of the LNB power supply, and the reverse current protection diode (D1) connected between the switching transistor and the LNB line, the satellite broadcast receiver overcurrent of the LNB power monitoring method Protection device. The method of claim 1, wherein the monitoring unit A pull-up resistor (R6) for bypassing the output voltage of the LNB power supply to be delivered to the monitoring unit, voltage division resistors (R3 and R4) connected to the LNB line side to divide the line voltage, and the voltage division The satellite of the LNB power supply monitoring system, comprising a third transistor Q3, which is turned on in a normal state and outputs a low signal in a short state and outputs a high signal according to a divided voltage between the resistors R3 and R4. Broadcast receiver overcurrent protection device. The method of claim 1, wherein the feedback unit Overcurrent of the satellite broadcast receiver of the LNB power monitoring method comprising an inverter (U2) for converting a low signal of the monitoring signal of the monitoring unit into a high signal, and converts the high signal into a low signal to feed back to the control signal generator. Protection device. The method of claim 1, wherein the control signal generator An end gate U1 for performing an AND operation on the LNB on / off signal input from the controller and the monitoring signal fed back from the feedback unit, and a switching transistor of the switching unit being turned on / off according to an output of the end gate U1. A satellite broadcast receiver overcurrent protection device of an LNB power monitoring method, comprising a second transistor (Q2) for turning Q1) on and off.

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