JP4810755B2 - Digital satellite broadcast receiver - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a digital satellite broadcast receiver capable of receiving a plurality of satellite broadcasts such as digital satellite broadcast and CS broadcast and terrestrial broadcasts, and more particularly to a digital satellite broadcast receiver capable of receiving multiple inputs for a plasma display. It is about.
[0002]
[Prior art]
In recent years, plasma displays have attracted attention as display panels (thin display devices) with excellent visibility, and high definition and large screens are being promoted.
[0003]
This plasma display is roughly classified into AC type and DC type in terms of driving, and there are two types of discharge types, a surface discharge type and a counter discharge type, but high definition, large screen, and ease of manufacture. Therefore, at present, AC type and surface discharge type plasma displays have become the mainstream. The plasma display is a device that has a large screen and can be displayed by digital signal processing. It is ideal for displaying multiple input video signals at the same time, so it is expected to be an indispensable video display device in the network age. Yes.
[0004]
FIG. 5 shows the structure of the panel in the plasma display. As shown in FIG. 5, on a transparent front substrate 51 such as a glass substrate, a plurality of stripe-shaped display electrodes 52 that are paired with a scan electrode and a sustain electrode are formed, and covers the electrode group. Thus, a dielectric layer 53 is formed, and a protective film 54 is formed on the dielectric layer 53.
[0005]
Further, a plurality of rows of stripes covered with an overcoat layer 56 are formed on the rear substrate 55 opposite to the front substrate 51 so as to intersect the display electrodes 52 of the scan electrodes and the sustain electrodes. Address electrodes 57 are formed. On the overcoat layer 56 between the address electrodes 57, a plurality of barrier ribs 58 are arranged in parallel with the address electrodes 57, and a phosphor layer 59 is provided on the side surface between the barrier ribs 58 and on the surface of the overcoat layer 56. Yes.
[0006]
The substrate 51 and the substrate 55 are opposed to each other with a minute discharge space so that the display electrode 52 and the address electrode 57 of the scan electrode and the sustain electrode are almost orthogonal to each other, and the periphery is sealed, In the discharge space, one or a mixed gas of helium, neon, argon, and xenon is sealed as a discharge gas. The discharge space is divided into a plurality of sections by partition walls 58, thereby providing a plurality of discharge cells where the intersections of the display electrodes 52 and the address electrodes 57 are located. Each of the discharge cells has red, green and blue colors. Thus, the phosphor layers 59 are sequentially arranged for each color.
[0007]
FIG. 6 shows an electrode arrangement of this plasma display panel. As shown in FIG. 6, the scan electrode, the sustain electrode, and the address electrode have a matrix configuration of M rows × N columns, and M rows of scan electrodes SCN1 to SCNM and sustain electrodes SUS1 to SUSM are arranged in the row direction. N columns of address electrodes D1 to DN are arranged in the column direction.
[0008]
In the plasma display panel having such an electrode configuration, an address pulse is applied between the address electrode and the scan electrode by applying a write pulse between the address electrode and the scan electrode, and after selecting the discharge cell, the scan electrode By applying a periodic sustain pulse that is alternately inverted between the sustain electrode and the sustain electrode, a sustain discharge is performed between the scan electrode and the sustain electrode, and a predetermined display is performed.
[0009]
FIG. 7 shows an example of the entire configuration of a plasma display in which the panel having the structure described above is incorporated. In the figure, the housing that houses the panel 60 is composed of a front frame 61 and a metal back cover 62, and an opening of the front frame 61 is a front surface made of glass or the like that also serves as an optical filter and panel 60 protection. A filter 63 is arranged. The front filter 63 is subjected to, for example, silver deposition in order to suppress unnecessary radiation of electromagnetic waves. Further, the back cover 62 is provided with a plurality of vent holes 62a for releasing heat generated in the panel 60 and the like to the outside.
[0010]
The panel 60 is bonded to the front surface of the chassis member 64 serving as a holding plate that also serves as a heat sink made of aluminum or the like via a double-sided adhesive material or a heat conductive sheet 65 made of an acrylic, urethane, or silicon material. A plurality of circuit blocks 66 for attaching and driving the panel 60 are attached to the rear surface side of the chassis member 64. The heat conductive sheet 65 is for efficiently transferring the heat generated in the panel 60 to the chassis member 64 to dissipate heat. The circuit block 66 includes an electric circuit for driving and controlling the display of the panel 60, and extends beyond the four sides of the chassis member 64 to the electrode lead-out portion drawn to the edge of the panel 60. They are electrically connected by a plurality of extending flexible wiring boards (not shown).
[0011]
A boss portion 64a for attaching the circuit block 66 and fixing the back cover 62 is protruded from the rear surface of the chassis member 64 by integral molding such as die casting. The chassis member 64 may be configured by fixing a fixing pin to an aluminum flat plate.
[0012]
On the other hand, digital broadcasting and digital high-definition satellite broadcasting started in 2000, and digitalization of broadcasting has become serious. In addition, digitalization of terrestrial broadcasting is about to begin in 2003. These broadcasts have been improved in functionality, such as software rewriting using the broadcast as a medium, and bidirectionalization through a telephone line, etc., and multi-functionalization that combines broadcasting and communication has been made. . Indeed, digital satellite broadcast receivers have become essential devices for plasma displays.
[0013]
[Problems to be solved by the invention]
By the way, in such a digital satellite broadcast receiving apparatus, a large number of video signals and audio signal input / output means such as an external video signal transmitting apparatus such as a video apparatus and a computer apparatus, the large number of video signals and audio signal signals. It has switching means and signal processing means, and power consumption is about 50W to 70W. On the other hand, since the power consumption of the plasma display is as large as 300 W to 400 W, the power consumption of the digital satellite broadcast receiver has not been regarded as a problem so far.
[0014]
However, with the advancement of plasma display technology, the power consumption has been rapidly reduced, which has caused the problem that the power consumption of the digital satellite broadcast receiver cannot be ignored.
[0015]
SUMMARY OF THE INVENTION An object of the present invention is to solve such problems and to provide a digital satellite broadcast receiving apparatus that reduces power consumption and has a power supply protection function corresponding to the broadcast reception state.
[0016]
[Means for Solving the Problems]
In order to achieve the above object, a digital satellite broadcast receiver of the present invention includes a U / V power supply circuit unit that drives a terrestrial broadcast reception processing circuit, a DBS power supply circuit unit that drives the digital satellite broadcast reception processing circuit, and an image. A SUB power supply circuit unit that drives the signal processing circuit, and a main power supply circuit unit that supplies DC power from a commercial power supply to the U / V power supply circuit unit, the DBS power supply circuit unit, and the SUB power supply circuit unit. In a digital satellite broadcast receiving device for sending to a video display device, a U / V power protection circuit unit, a DBS power protection circuit unit, and a SUB power protection circuit are respectively provided in the U / V power circuit unit, the DBS power circuit unit, and the SUB power circuit unit. And the U / V power supply protection corresponding to the operation of turning the U / V power supply circuit part or the DBS power supply circuit part on or off according to the reception state. A digital satellite broadcast receiving apparatus, characterized in that a control means for stopping the function of the road section or DBS power protection circuit portion.
[0017]
According to the present invention, since only a necessary power source is turned on according to a reception state, it is possible to provide a digital satellite broadcast receiving apparatus that can reduce reactive power and can function only a protection circuit for a power source in an on state.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
That is, according to the first aspect of the present invention, a U / V power supply circuit unit that drives a terrestrial broadcast reception processing circuit, a DBS power supply circuit unit that drives a digital satellite broadcast reception processing circuit, and a video signal processing circuit are provided. A SUB power supply circuit unit for driving, and a main power supply circuit unit for supplying DC power from a commercial power supply to the U / V power supply circuit unit, the DBS power supply circuit unit, and the SUB power supply circuit unit, and supplying a video signal to the video display device In the digital satellite broadcast receiving apparatus to be transmitted, a U / V power supply protection circuit unit, a DBS power supply protection circuit unit, and a SUB power supply protection circuit unit are provided in each of the U / V power supply circuit unit, the DBS power supply circuit unit, and the SUB power supply circuit unit, The U / V power supply protection circuit unit or DBS corresponds to an operation for turning on or off the U / V power supply circuit unit or DBS power supply circuit unit according to the reception state. It is provided with a control means for stopping the function of the source protection circuit.
[0019]
The present invention A standby control unit is provided for receiving normal / abnormality determination outputs of the U / V power supply protection circuit unit, DBS power supply protection circuit unit, and SUB power supply protection circuit unit and controls the main power supply circuit unit. The main power supply circuit unit is turned off and the normality determination outputs of the U / V power supply protection circuit unit and the DBS power supply protection circuit unit are transmitted to the standby control means when not receiving data. The normality / abnormality determination output of the protection circuit unit, the DBS power supply protection circuit unit, and the SUB power supply protection circuit unit is transmitted to a standby microcomputer which is a standby control means having a power supply control function. The circuit unit is turned off, and the U / V power protection circuit unit and the DBS power protection circuit unit receive normal / abnormal discrimination output. Depending on the status, the normal determination output is transmitted to the standby microcomputer when not receiving, and the reactive power is reduced by turning on only the power supply in the reception state, and the main power supply circuit only when an abnormality occurs in the power supply in the reception state The part can be turned off.
[0020]
further, The present invention In this configuration, the U / V power supply protection circuit unit and the DBS power supply protection circuit unit output a normal determination output when not receiving in conjunction with the ON / OFF signal of the U / V power supply circuit unit or the DBS power supply circuit unit. The U / V power supply protection circuit unit and the DBS power supply protection circuit unit are linked to the ON / OFF signal of the U / V power supply circuit unit or the DBS power supply circuit unit according to the reception state of the normal / abnormal determination output. Thus, a normal discrimination output is output at the time of non-reception, and the reactive power is reduced by turning on only the power supply in the reception state, and the on / off signal of the U / V power supply circuit unit or the DBS power supply circuit unit is used. As a result, the function of the protection circuit of the power supply circuit unit in the non-reception state can be easily stopped in conjunction with the on / off signal.
[0021]
Also, The present invention The normal / abnormal discrimination output of the U / V power protection circuit, DBS power protection circuit, and SUB power protection circuit is transmitted to the standby microcomputer by the OR function means, and only the power supply in the receiving state is turned on. The reactive power can be reduced, and an abnormality determination output can be transmitted to the standby microcomputer through a single signal line to turn off the main power supply circuit unit.
[0022]
further, The present invention The U / V power supply protection circuit unit and the DBS power supply protection circuit unit include abnormality determination means and SOS signal on / off means for outputting a normal / abnormality determination signal SOS signal as a normal determination signal. By using the on / off signal of the U / V power supply circuit unit or the DBS power supply circuit unit, the determination signal of the abnormality determination means provided in the protection circuit of the power supply circuit unit that is in a non-reception state easily linked to the off signal The output is output as a normal discrimination signal.
[0023]
further, The present invention The digital satellite broadcast receiving apparatus includes connection means connectable to an external video signal transmission apparatus such as a video device or a computer device, and signal switching means for switching each external video signal source and transmitting a video signal. Is.
[0024]
Also, The present invention A plasma display having a panel in which a plurality of discharge cells are formed so that a discharge space is formed between a pair of substrates transparent at least on the front side, and a terrestrial broadcast reception processing circuit, digital satellite broadcast reception processing A digital satellite broadcast receiver having a circuit and a video signal processing circuit for sending a video signal to a plasma display, the digital satellite broadcast receiver having a U / V power supply circuit section for driving the terrestrial broadcast reception processing circuit; Direct current power is supplied from the DBS power supply circuit unit for driving the digital satellite broadcast reception processing circuit, the SUB power supply circuit unit for driving the video signal processing circuit, and the commercial power supply to the U / V power supply circuit unit, the DBS power supply circuit unit, and the SUB power supply circuit unit. A main power supply circuit section to be supplied, and the U / V power supply circuit section, the DBS power supply circuit section, and the SUB. Each source circuit unit has a U / V power supply protection circuit unit, a DBS power supply protection circuit unit, and a SUB power supply protection circuit unit, and turns the U / V power supply circuit unit or the DBS power supply circuit unit on or off according to the reception state. A television receiver using a plasma display provided with a control means for stopping the function of the U / V power supply protection circuit unit or the DBS power supply protection circuit unit in response to the operation.
[0025]
further, The present invention The digital satellite broadcast receiving apparatus includes connection means connectable to an external video signal transmission apparatus such as a video device or a computer device, and a signal switching means for switching each external video signal source, and a video signal is displayed on the plasma display. When the broadcast is not received, the U / V power supply circuit unit or the DBS power supply circuit unit is turned off, so this reactive power is reduced and the function of the protection circuit of the power supply circuit unit in the broadcast non-reception state is stopped. It has the effect that it can
[0026]
A digital satellite broadcast receiver according to an embodiment of the present invention will be described below with reference to FIGS.
[0027]
(Embodiment 1)
FIG. 1 shows a main configuration of a digital satellite broadcast receiving apparatus according to Embodiment 1 of the present invention. As shown in the figure, in the digital satellite broadcast receiving apparatus 100, a plasma display 1 is connected to a video display apparatus via a connector 1a. As the external video signal transmitting device 2, a video device 2a, a digital video disc (DVD) 2b, a personal computer 2c, etc. are connected as connectors 3a, 3b, 3c as multi-input connections. Yes. In addition, the U / V signal receiving antenna 4 for receiving the RF signal and the DBS signal receiving antenna 5 for receiving the DSB signal are connected to the U / V antenna terminal 4a and the BS antenna terminal 5a, respectively.
[0028]
The power supply circuit of the digital satellite broadcast receiver 100 is connected to the commercial power supply 6 and is converted into a DC voltage by the standby power supply circuit 11 and the main power supply circuit 13 connected via the relay 12. The standby power supply circuit 11 supplies power to the standby microcomputer 14 and the relay 12 which are control means, and controls on / off of the main power supply circuit 13.
[0029]
The main power supply circuit 13 supplies power to a U / V power supply circuit 151 that is a terrestrial broadcast reception processing circuit and a DBS power supply circuit 152 that is a digital satellite broadcast reception processing circuit. The signal reception processing circuit 17 is operated. Further, power is supplied to the SUB power circuit 153 to operate the PDP signal processing circuit 181 that is a video signal processing circuit, the signal switching unit 182, and the main microcomputer 19 that is a control unit.
[0030]
Further, the U / V power supply circuit 151p, the DBS power supply circuit 152, and the SUB power supply circuit 153 are connected to the U / V power supply protection circuit 151p, the DBS power supply protection circuit 152p, and the SUB power supply protection circuit 153p as protection circuits, respectively. The output of the protection circuit is transmitted to the standby microcomputer 14 so that the relay 12 is turned off and the main power circuit 13 is turned off when the power supply is abnormal.
[0031]
In such a digital satellite broadcast receiving apparatus, according to the present invention, only the power supply circuit that performs signal processing of the received signal is held in the ON state based on the ON signal of the main microcomputer 19 in response to the receiving state, An off signal is input from the main microcomputer 19 to the power supply circuit that does not perform the control so that the power supply circuit is turned off.
[0032]
For example, when only the U / V signal is received, the main microcomputer 19 turns off the DBS power supply circuit 152 and simultaneously stops the function of the DBS power supply protection circuit 152p. For example, when the video signal of the personal computer 2 c is displayed on the plasma display device 1, since the digital satellite broadcast and the terrestrial broadcast are not normally received, the main microcomputer 19 is connected to the U / V power supply circuit 151. The BS power supply circuit 152 is turned off, and at the same time, the functions of the U / V power supply protection circuit 151p and the DBS power supply protection circuit 152p are stopped.
[0033]
Therefore, for example, the power consumption of a 50 W digital satellite broadcast receiving apparatus can be reduced to about 20 W during the operation of the entire circuit, and extremely efficient power use can be achieved.
[0034]
FIG. 2 shows a main configuration of the power supply circuit according to the present embodiment.
[0035]
First, the output Vin of the main power supply circuit 13 is supplied to the U / V power supply circuit 151, and a predetermined voltage is supplied by a UVA converter 151a, a UVB converter 151b, and a UVC converter 151c, which are DC-DC converters. Output voltage V _O11 (For example, + 9V), output voltage V _O12 (Eg + 5V), output voltage V _O13 Each (for example, +3.3 V) is supplied with power by receiving a U / V power supply circuit ON signal sent from the main microcomputer 19. Each output voltage is determined by the U / V power supply protection circuit 151p for an output short circuit abnormality.
[0036]
The DBS power supply circuit 152 is supplied with the output Vin of the main power supply circuit 13, and is supplied with a predetermined output voltage V by a BSA converter 152a, a BSB converter 152b, and a BSC converter 152c which are DC-DC converters. _O21 (Eg + 5V), output voltage V _O22 (Eg + 3.35V), output voltage V _O23 Each (for example, +2.5 V) is supplied with power by receiving a DBS power supply circuit ON signal sent from the main microcomputer 19. Each output voltage is determined by the DBS power supply protection circuit 152p for an output short circuit abnormality.
[0037]
The SUB power supply circuit 153 is supplied with the output Vin of the main power supply circuit 13, and is supplied with a predetermined output voltage V by a SUBA converter 153a, a SUBB converter 153b, and a SUBC converter 153c, which are DC-DC converters. _O31 (Eg + 5V), output voltage V _O32 (Eg + 3.35V), output voltage V _O33 (For example, + 2.5V) Each power is supplied. Each output voltage is determined by the SUB power supply protection circuit 153p for an output short circuit abnormality.
[0038]
The SOS signal, which is the output signal of the U / V power protection circuit 151p, DBS power protection circuit 152p, and SUB power protection circuit 153p, is transmitted to the standby microcomputer 11 through the OR function means 21 constituted by the diodes 21a, 21b, and 21c. Is done. The SOS signal is sent to the OR function means 21 as logic of “L” at normal time and “H” at abnormal time. Therefore, even when any power supply circuit is short-circuited, the logic signal “H” at the time of abnormality can be transmitted to the standby microcomputer 11 as the SOS signal.
[0039]
On the other hand, when the digital satellite broadcast is not received, for example, the main microcomputer 19 outputs an off signal of the DBS power supply circuit 152 to the DBS power supply circuit 152 to turn off the DBS power supply circuit 152. The DBS power supply protection circuit 152p holds the SOS signal at “L” in a normal state by the OFF signal of the DBS power supply circuit 152. Therefore, the output voltage V of the DBS power supply circuit 152 _O21 , Output voltage V _O22 , Output voltage V _O23 However, since the SOS signal is kept at “L” during normal operation, the digital satellite broadcast receiving apparatus can be operated without the power source protection operation, for example, turning off the relay 12.
[0040]
3A and 3B show the configuration of the main part of the power protection circuit according to this embodiment. In the main block configuration, the U / V power protection circuit 151p and the DBS power protection circuit 152p are the same, and therefore description will be made using the DBS power protection circuit 152p.
[0041]
That is, in FIG. 3A, the DBS power supply protection circuit 152p is composed of the abnormality determination means 31 and the SOS signal output on / off means 32. Output voltage V of DBS power supply circuit 152 _O21 , Output voltage V _O22 , Output voltage V _O23 Based on the above, the abnormality determination means 31 determines normality or abnormality. The SOS signal output on / off means 32 is turned on when the DSB power supply circuit 152 is turned on by the on / off signal of the DSB power supply circuit 152, and is grounded when the DSB power supply circuit 152 is turned off.
[0042]
FIG. 3B shows an example of a specific circuit configuration of the SOS signal output on / off means 32. That is, for example, a 470Ω resistor R31 is connected in series between the SOS signal input line and the SOS signal output line, the collector of the NPN transistor Q31 is connected to the SOS signal output line, and the emitter is grounded. A DSB power circuit on / off signal is input to the base. For example, a resistor R32 having a resistance value of, for example, 10 kΩ is used as the base resistor.
[0043]
In this case, when logic “L” is input to the base of the NPN transistor Q31 as the DSB power supply circuit ON signal, the NPN transistor Q31 is turned off and the SOS signal output on / off means 32 is turned on. When logic “H” is input to the base of the NPN transistor Q31 as the DSB power supply circuit off signal, the NPN transistor Q31 is turned on and the SOS signal output on / off means 32 is turned off. That is, when the DSB power supply circuit 152 is on, the SOS signal is output to the standby microcomputer 11. However, when the DSB power supply circuit 152 is off, the SOS signal is not output to the standby microcomputer 11 and functions as a protection circuit. Can be stopped.
[0044]
(Embodiment 2)
FIGS. 4A and 4B show the configuration of the main part of the power protection circuit in the second embodiment of the present invention. In the main block configuration, the U / V power protection circuit 151p and the DBS power protection circuit 152p are the same, and therefore description will be made using the DBS power protection circuit 152p.
[0045]
That is, the DBS power protection circuit 152p is composed of the abnormality determination unit 41 and the SOS signal output on / off unit 42. The difference from the configuration shown in FIG. 3 is that the SOS signal output of the abnormality determination unit 41 is not turned on / off, but the logic of the SOS signal output of the abnormality determination unit 41 is in the case where the DSB power supply circuit on / off signal is on. This is a point held in logic “L”. A specific circuit configuration will be described below.
[0046]
The output voltage V of the DBS power supply circuit 152 is supplied to the abnormality determination unit 41. _O21 , Output voltage V _O22 , Output voltage V _O23 Is input for voltage abnormality detection, and the output voltage V of the SUB power circuit 153 _O33 Is input as a reference voltage. Output voltage V _O21 Is the output voltage V _O22 Is the reference voltage and the output voltage V _O22 Is the output voltage V _O23 Is the reference voltage and the output voltage V _O23 Is the output voltage V _O33 As a reference voltage, normal / abnormal is discriminated using the low voltage side as the reference voltage in the levels of the plurality of output voltages. That is,
V _O21 ≧ V _O22 ≧ V _O23 ≧ V _O33 The relationship.
[0047]
Output voltage V _O21 The normal / abnormal discrimination means includes a PNP transistor Q41, 1 kΩ resistors R41 and R42, a 0.1 μF capacitor C41, and a diode D41. The output voltage V is applied to the emitter of Q41. _O22 As a reference voltage, and the output voltage V _O21 Enter. In the normal state, since the base voltage is higher than the emitter voltage, the PNP transistor Q41 is turned off, and the cathode output of the diode D41 becomes the normal logic "L". On the other hand, the output voltage V _O21 For example, when + 5V decreases to 2.5V, the PNP transistor Q41 is turned on and 2.7V (abnormal logic “H”) is output.
[0048]
Similarly, the output voltage V _O22 The normal / abnormal discrimination means includes a PNP transistor Q42, 1 kΩ resistors R43 and R44, a 0.1 μF capacitor C42, and a diode D42. _O23 The normal / abnormal discrimination means includes a PNP transistor Q43, 1 kΩ resistors R45 and R46, a 0.1 μF capacitor C43, and a diode D43.
[0049]
Output voltage V _O23 For example, the normal / abnormal discrimination of + 2.5V is determined by the output voltage V _O23 When the voltage decreases to, for example, + 1.0V, the PNP transistor Q43 is turned on and 1.9V (abnormal logic “H”) is output.
[0050]
The SOS signal output on / off means 32 includes, for example, a DBS power supply circuit on / off signal (on-time logic “L”, off-time logic “H”) and the output voltage V of the SUB power supply circuit 152. _O33 And outputs an output for turning on / off the PNP transistor Q43. In order to output an output for turning on / off the PNP transistor Q43 in response to the DBS power supply circuit on / off signal, for example, from Q44 and Q45 consisting of NPN transistors, resistors R47, R48 and R49, and a diode D44 Constitute.
[0051]
When the DBS power supply circuit ON / OFF signal is ON and the logic is “L”, the NPN transistor Q44 is OFF, so that the output voltage V of the SUB power supply circuit 152 is connected to the base of the NPN transistor Q45 through the resistor R49. _O33 Is input, and the NPN transistor Q45 is turned on. Therefore, the anode side of the diode D44 is held at the collector potential of the NPN transistor Q45, for example, 0.6V. Since the base voltage of the PNP transistor Q43 provided in the abnormality determination means 41 is 2.5V, D44 does not conduct, and the abnormality determination means 41 is electrically separated from the SOS signal output on / off means 32. Yes.
[0052]
When the DBS power supply circuit on / off signal is off and the logic level is “H”, the NPN transistor Q44 is on, so that the base voltage of the NPN transistor Q45 is the collector-emitter voltage Vce of the NPN transistor Q44, eg, 0. The voltage becomes 3V, and the NPN transistor Q45 is turned off.
[0053]
Next, the output voltage V of the SUB power supply circuit 152 is passed through the resistor R48 and the diode D44. _O33 (For example, 2.5 V) is input to the base of the PNP transistor Q43 provided in the abnormality determination means 41. Since the DBS power supply circuit 152 is off, the emitter voltage of the PNP transistor Q43 is lower than the base voltage (V _O23 <V _O33 The PNP transistor Q43 is turned off.
[0054]
Also, V _O21 , V _O22 The emitter voltages of the PNP transistor Q41 and the PNP transistor Q42 that output the normal / abnormal discrimination signal are output from the cathode side of the diodes D41 and D42 at 1V or less since the DBS power supply circuit 152 is turned off. is there. Therefore, the SOS signal output becomes logic “L”, and the standby microcomputer 11 determines that it is normal.
[0055]
In the above description, the logic “H” and the logic “L” have been described as H: 1.2 V or more and L: less than 1.2 V. However, the discrimination voltages of the logic “H” and the logic “L” are described. Is not required to be 1.2 V, and is due to the specifications of the standby microcomputer to be used.
[0056]
In the above description, the example in which each power supply circuit and each protection circuit are arranged in units of each circuit block has been described. However, each circuit block is configured to have a plurality of functions, and You may comprise so that each function may be controlled similarly to the above.
[0057]
【The invention's effect】
As is apparent from the above description, according to the digital satellite broadcast receiving apparatus according to the present invention, the DBS power supply circuit or the U / V power supply circuit is turned off when the broadcast is not received, and the power supply of the power supply circuit in the broadcast non-received state. Since it is possible to stop the function of the protection circuit, only the power supply circuit in the reception state is operated to reduce reactive power, and only the power supply protection circuit of the operating power supply circuit is operated to operate the device safely. The advantageous effect of being able to be obtained is obtained.
[Brief description of the drawings]
FIG. 1 is a main part configuration diagram of a digital satellite broadcast receiving apparatus according to an embodiment of the present invention;
FIG. 2 is a detailed circuit diagram of the power supply circuit block of FIG.
FIGS. 3A and 3B are circuit diagrams showing the configuration of the DBS power supply protection circuit of FIG.
FIGS. 4A and 4B are circuit diagrams showing a configuration of a DBS power protection circuit of a digital satellite broadcast receiver according to another embodiment of the present invention.
FIG. 5 is a schematic configuration diagram showing a panel structure of a plasma display.
FIG. 6 is a configuration diagram showing an example of electrode wiring of the panel
FIG. 7 is a perspective view showing an example of the overall configuration of the plasma display.
[Explanation of symbols]
1 Plasma display
1a connector
2 External video signal transmission device
2a video
2b DVD
2c Personal computer
3 connection means
3a, 3b, 3c connector
4 U / V signal receiving antenna
4a U / V antenna terminal
5 DBS signal receiving antenna
5a BS antenna terminal
6 Commercial power supply
11 Standby power circuit
12 Relay
13 Main power circuit
14 Standby microcomputer
16 U / V signal reception processing circuit
17 DBS signal reception processing circuit
19 Main microcomputer
100 Digital satellite broadcast receiver
151 U / V power supply circuit
151p U / V power protection circuit
152 DBS power supply circuit
152p DBS power protection circuit
153 SUB power supply circuit
153p SUB power protection circuit
181 PDP signal processing circuit
182 Signal switching means

Claims (1)

A U / V power supply circuit unit for driving a terrestrial broadcast reception processing circuit, a DBS power supply circuit unit for driving a digital satellite broadcast reception processing circuit, a SUB power supply circuit unit for driving a video signal processing circuit, and the U / V power supply circuit, a main power supply circuit section for supplying DC power to the DBS power supply circuit unit and the SUB power supply circuit unit, a normal determination or an abnormal determination to determine the output short-circuit abnormality of the U / V power supply circuit unit A U / V power supply protection circuit unit for output, a DBS power supply protection circuit unit that outputs a normal determination or an abnormality determination by determining an output short circuit abnormality of the DBS power supply circuit unit, and an output short circuit abnormality of the SUB power supply circuit unit A SUB power supply protection circuit unit that outputs normality determination or abnormality determination, and the U / V power supply circuit unit when the terrestrial broadcast or the digital satellite broadcast is not received. Control means for stopping the function of the U / V power supply protection circuit unit or the DBS power supply protection circuit unit in response to an operation for turning off the DBS power supply circuit unit, the U / V power supply protection circuit unit, and the DBS power supply protection Standby control means for inputting the normality determination output or the abnormality determination output from the circuit unit or the SUB power supply protection circuit unit,
The standby control means turns off the main power supply circuit section when inputting the abnormality determination output, and the control means is the U / V power supply protection circuit when the terrestrial broadcast or the digital satellite broadcast is not received. Unit and the DBS power protection circuit unit transmit normality determination outputs to the standby control means .

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