JP4518402B2 - Backlight control device, liquid crystal television with backlight control device, and backlight control method - Google Patents

Description

  The present invention relates to a backlight control device that controls driving of a backlight composed of a plurality of fluorescent lamps, a liquid crystal television including the backlight control device, and a backlight control method.

  For example, in a direct type backlight mounted on a liquid crystal television, straight tube lamps having a length substantially equal to the screen size are arranged in parallel at an appropriate pitch in the horizontal or vertical direction with respect to the screen.

  In such a direct type backlight, when one of a plurality of lamps is not lit, only the lamp part becomes dark, which is harmful to view the liquid crystal screen. Further, if the lamp is continuously used without being lit, various problems such as heating of the circuit components and high-pressure discharge may occur and the product may be damaged.

  For this reason, when at least one lamp is not lit or abnormal, it stops driving all lamps and displays a prompt to replace the lamp, or turns off the main power of the LCD TV. By doing so, the user is made aware that lamp replacement is necessary.

  By the way, if at least one of the lamps is not lit or malfunctions, if the lamp driving is stopped or the main power of the LCD TV is turned off, the lamp replacement maintenance service is completed. , I can not watch TV.

In such a case, as shown in Patent Document 1, when at least one lamp is not lit or abnormal, the driving of only the lamp at the failure location is stopped, and the failure history is also displayed. By displaying the corresponding history information as OSD as necessary, it is possible to continue watching the television until the lamp replacement maintenance service is completed.
JP 2004-053988 A

  However, as in Patent Document 1, when at least one lamp is not lit or malfunctions, even if the driving of only the lamp at the failure location is stopped, the remaining normal lamps can be used to watch TV. Is possible.

  However, when watching the television by driving the remaining normal lamps, only the lamp part at the failure location becomes dark, and uneven brightness occurs between the lamp part where the drive is stopped and the normal lamp part on the entire liquid crystal screen, As described above, there is a problem that it is harmful to view the liquid crystal screen.

  The present invention has been made in view of such circumstances, and provides a backlight control device, a liquid crystal television including the backlight control device, and a backlight control method that can solve the above-described problems. Objective.

The backlight control device of the present invention is a backlight control device that controls driving of a plurality of light sources arranged in parallel on the back surface of the liquid crystal display unit, and includes a first driving unit that drives the odd-numbered light sources, and an even number a second driving means for driving the second of the light source, an abnormality occurs in any of said light source, and a control means for stopping the driving of the first driving means or the second driving means corresponding to the light source The first driving means monitors the driving of the odd-numbered light source, and outputs a first abnormality detection signal when an abnormality occurs in any of the light sources, and the second driving means The driving of the even-numbered light source is monitored, and if an abnormality occurs in any of the light sources, the second abnormality detection signal is output, and the control means detects the first abnormality detection signal or the second abnormality detection. The first driving means for outputting a signal Alternatively, the driving of the light source by the second driving unit is stopped, and the first driving unit detects a power required for driving the odd-numbered light source and outputs a first power detection signal, and the second driving unit outputs the first power detection signal. The driving means detects the power required for driving the even-numbered light source and outputs a second power detection signal, and the control means is configured to output the second power detection signal based on the first power detection signal and the second power detection signal. A power control signal for making the power required for driving the odd-numbered light source and the power required for driving the even-numbered light source uniform to the first drive means and the second drive means, To do.
Further, the control means can control the driving by the first driving means and the second driving means by shifting the phase.
A liquid crystal television of the present invention comprises the backlight control device according to claim 1 or 2 .
The backlight control method of the present invention is a backlight control method for controlling the driving of a plurality of light sources arranged in parallel on the back surface of the liquid crystal display unit, and includes a first driving step for driving the odd-numbered light sources, and an even number. A second driving step for driving the second light source, and a control step for stopping driving in the first driving step or the second driving step corresponding to the light source when an abnormality occurs in any of the light sources. In the first driving step, the driving of the odd-numbered light source is monitored, and when an abnormality occurs in any of the light sources, a first abnormality detection signal is output, and in the second driving step The driving of the even-numbered light source is monitored, and if an abnormality occurs in any of the light sources, a second abnormality detection signal is output. In the control step, the first abnormality detection signal or the second abnormality signal is output. Based on the abnormality detection signal, The drive of the light source by the drive system that has output the abnormality detection signal or the second abnormality detection signal is stopped, and in the first driving step, the power required for driving the odd-numbered light source is detected to detect the first power. In the second driving step, a power required for driving the even-numbered light source is detected and a second power detection signal is output. In the control step, the first power detection signal and the second power detection signal are output. Based on a power detection signal, a power control signal for making the power required for driving the odd-numbered light source and the power required for driving the even-numbered light source uniform is output .
Further, a step of controlling the driving phase of the odd-numbered light sources and the driving phase of the even-numbered light sources may be controlled.
In the backlight control device, the liquid crystal television including the backlight control device, and the backlight control method of the present invention, the odd-numbered light sources are driven by the first driving means, and the even-numbered light sources are driven by the second driving means, When an abnormality occurs in any one of the light sources, the control unit stops driving the first driving unit or the second driving unit corresponding to the light source. That is, since the plurality of light sources are driven every other by the two systems of driving means, when an abnormality occurs in any of the light sources, only the odd-numbered light source or the even-numbered light source can be driven, Although there is a decrease in the overall luminance of the liquid crystal display unit, it can be maintained in a state without luminance unevenness.

  According to the backlight control device, the liquid crystal television including the backlight control device, and the backlight control method of the present invention, a plurality of light sources can be driven every other one by two systems of driving means. When an abnormality occurs in the light source, only the odd-numbered light source or even-numbered light source is driven, so that the overall brightness of the liquid crystal display unit is reduced, but the brightness unevenness is maintained. Until the replacement maintenance service is completed, viewing can be performed in a state where there is no luminance unevenness.

  In the present embodiment, when the odd numbered light source is driven by the first driving means and the even numbered light source is driven by the second driving means, and an abnormality occurs in any of the light sources, the control means corresponds to the light source corresponding to the light source. The driving of the first driving means or the second driving means is stopped. That is, when a plurality of light sources are driven by every other two driving means and an abnormality occurs in any one of the light sources, only the odd-numbered light source or even-numbered light source is driven, thereby the liquid crystal display unit Although there is a decrease in the overall brightness, it can be maintained in a state without brightness unevenness. As a result, viewing is performed with no luminance unevenness until the maintenance service for lamp replacement is completed.

  FIG. 1 is a block diagram showing an embodiment of a backlight control device of the present invention, and FIGS. 2 and 3 are diagrams for explaining a backlight control method by the backlight control device of FIG.

  As shown in FIG. 1, the backlight control device is a first drive that drives a backlight 10 having fluorescent lamps 11 a to 11 d and 12 a to 12 d that are a plurality of light sources arranged in parallel on the back surface of a liquid crystal display unit (not shown). A system 20 and a second drive system 30 and a microcomputer 40 that controls the drive by the first drive system 20 and the second drive system 30 are provided.

  The first drive system 20 as the first drive means drives the odd-numbered fluorescent lamps 11a to 11d, and includes a drive circuit (1) 21, a voltage detection circuit (V1) 22, and a voltage detection circuit (V2) 23. , An arithmetic circuit 24 is provided.

  The drive circuit (1) 21 drives the fluorescent lamps 11a to 11d based on the ON / OFF control signal (1) and the power control signal (1) from the microcomputer 40. The drive circuit (1) 21 stops the driving of the fluorescent lamps 11a to 11d when the control signal (1) from the microcomputer 40 is OFF.

  The voltage detection circuit (V1) 22 detects the voltage provided on the drive line 26 of the fluorescent lamps 11a to 11d and the voltage (V1) at one end of the small resistor 25 for current detection. The voltage detection circuit (V2) 23 detects the voltage provided on the drive lines 26 of the fluorescent lamps 11a to 11d and the voltage (V2) at the other end of the small resistor 25 for current detection. The voltage detection circuit (V1) 22 and the voltage detection circuit (V2) 23 can be configured by a level conversion circuit, a clamp circuit, or an integration circuit.

  The arithmetic circuit 24 detects a voltage abnormality, a current abnormality, and power by calculation based on the voltages (V1, V2) detected by the voltage detection circuit (V1) 22 and the voltage detection circuit (V2) 23, and sends them to the microcomputer 40. An abnormality detection signal (1) as one abnormality signal and a power detection signal (1) as a first power detection signal are output.

  That is, the arithmetic circuit 24 compares, for example, the detected voltages (V1, V2) by comparing the voltages (V1, V2) detected by the voltage detecting circuit (V1) 22 and the voltage detecting circuit (V2) 23 with the reference voltage. ) Is below the reference voltage, it is determined that the voltage is abnormal.

  The arithmetic circuit 24 calculates the current from the calculation of the voltages (V1, V2) detected by the voltage detection circuit (V1) 22 and the voltage detection circuit (V2) 23. For example, when the current is lower than the specified current, Judged to be abnormal. If it is determined that the voltage is abnormal or the current is abnormal, an abnormality detection signal (1) is output.

  In addition, the arithmetic circuit 24 performs an operation from the detected voltage (V1, V2) and the current calculated by calculating the voltage (V1, V2) regardless of whether the voltage is abnormal or the current is abnormal. Power is calculated and a power detection signal (1) is output.

  The second drive system 30 as the second drive means drives the even-numbered fluorescent lamps 12a to 12d. The drive circuit (2) 31, the voltage detection circuit (V3) 32, and the voltage detection circuit (V4) 33 are driven. , An arithmetic circuit 34 is provided.

  The drive circuit (2) 31 drives the fluorescent lamps 12a to 12d based on the ON / OFF control signal (2) and the power control signal (2) from the microcomputer 40. The drive circuit (2) 31 stops driving the fluorescent lamps 12a to 12d when the control signal (2) from the microcomputer 40 is OFF. The voltage detection circuit (V3) 32 detects the voltage provided on the drive line 36 of the fluorescent lamps 12a to 12d and the voltage (V3) at one end of the small resistor 35 for current detection.

  The voltage detection circuit (V4) 33 detects the voltage (V4) at the other end of the voltage provided on the drive lines 36 of the fluorescent lamps 12a to 12d and the current detection micro resistor 35. The voltage detection circuit (V3) 32 and the voltage detection circuit (V4) 33 can be configured by a level conversion circuit, a clamp circuit, or an integration circuit.

  The arithmetic circuit 34 detects voltage abnormality, current abnormality, and electric power by calculation based on the voltages (V3, V4) detected by the voltage detection circuit (V3) 32 and the voltage detection circuit (V4) 33, and the microcomputer 40 2 An abnormality detection signal (2) as an abnormality detection signal and a power detection signal (2) as a second power detection signal are output.

  That is, the arithmetic circuit 34 compares the voltages (V3, V4) detected by the voltage detection circuit (V3) 32 and the voltage detection circuit (V4) 33 with the reference voltage, for example, detected voltages (V3, V4). ) Is below the reference voltage, it is determined that the voltage is abnormal.

  The arithmetic circuit 34 calculates a current from the calculation of the voltages (V3, V4) detected by the voltage detection circuit (V3) 32 and the voltage detection circuit (V4) 33. For example, when the current is below a specified current, Judged to be abnormal. When it is determined that the voltage is abnormal or the current is abnormal, an abnormality detection signal (2) is output.

  In addition, the arithmetic circuit 34 performs an operation from the detected voltage (V3, V4) and the current calculated by the operation of the voltage (V3, V4) regardless of whether the voltage is abnormal or the current is abnormal. Power is calculated and a power detection signal (2) is output.

  The microcomputer 40 as the control means is configured to control the fluorescent lamps 11a to 11d and 12a to 12d based on the power detection signals (1) and (2) from the arithmetic circuits 24 and 34 of the first drive system 20 and the second drive system 30. Power control signals (1) and (2) for making the luminance uniform are output to the drive circuit (1) 21 and the drive circuit (2) 31. Thereby, even if there are two drive systems, it is possible to prevent a large difference in the drive power between them.

  When the microcomputer 40 outputs the power control signals (1) and (2) to the drive circuit (1) 21 and the drive circuit (2) 31, the drive in the drive circuit (1) 21 and the drive circuit (2) 31 is performed. The output is made so that the phase is shifted by 90 °, for example. Thereby, it is possible to reduce the stress applied to the component due to the dispersion of the peak current phase and to reduce the fluorescent lamp noise due to the superposition of the noise power due to the deviation of the noise generation timing.

  In addition, when the microcomputer 40 receives the abnormality detection signal (1) or (2) from the arithmetic circuit 24 or the arithmetic circuit 34, the microcomputer 40 sends an OFF control signal (1) to the corresponding drive circuit (1) 21 or drive circuit (2) 31. ) Or (2) is output. Then, the drive circuit (1) 21 or the drive circuit (2) 31 stops the driving of the fluorescent lamps 11a to 11d or the fluorescent lamps 12a to 12d having an abnormality. In this case, the overall luminance of the liquid crystal display unit (not shown) is reduced, but since the fluorescent lamps 11a to 11d or the fluorescent lamps 12a to 12d are every other lamp, the maintenance service for the replacement of the lamp is completed. Viewing without uneven brightness is possible.

Next, a backlight control method will be described.
First, as shown in FIG. 2, when the backlight 10 is driven, the microcomputer 40 controls ON to the drive circuit (1) 21 and the drive circuit (2) 31 of the first drive system 20 and the second drive system 30. Signals (1) and (2) and power control signals (1) and (2) are output (steps S1 and S2).

  The power control signals (1) and (2) in this case are signals that make the luminance of the fluorescent lamps 11a to 11d and 12a to 12d uniform as described above. In addition, as described above, the power control signals (1) and (2) reduce the stress applied to the component due to the dispersion of the peak current phase, and reduce the fluorescent lamp noise due to the superposition of the noise power due to the noise generation timing shift. Therefore, the drive phases in the drive circuit (1) 21 and the drive circuit (2) 31 are output so as to be shifted by 90 °, for example.

  Thereby, the odd numbered fluorescent lamps 11a to 11d and the even numbered fluorescent lamps 12a to 12d are individually driven by the drive circuit (1) 21 and the drive circuit (2) 31, and the entire liquid crystal display unit (not shown) is driven. The brightness is made uniform.

  At this time, in the first drive system 20, the voltage detection circuit (V1) 22 detects the voltage provided on the drive lines 26 of the fluorescent lamps 11a to 11d and the voltage (V1) at one end of the current detection microresistor 25. Is done. The voltage detection circuit (V2) 23 detects the voltage (V2) at the other end of the minute resistor 25.

  When the voltage (V1, V2) is detected, the calculation circuit 24 detects voltage abnormality, current abnormality, and power by calculation based on the voltage (V1, V2) (step S3). That is, by comparing the detected voltage (V1, V2) with the reference voltage, for example, when the detected voltage (V1, V2) is lower than the reference voltage, it is determined that the voltage is abnormal.

  Further, the current is calculated from the calculation of the detected voltages (V1, V2). For example, when the current is lower than the specified current, it is determined that the current is abnormal. If the voltage or current is not abnormal, the abnormality detection signal (1) is not output. However, if it is determined that the voltage or current is abnormal (step S4), the abnormality detection signal (1) is output. (Step S5).

  Regardless of whether the voltage or current is abnormal, the power is calculated by calculation from the detected voltage (V1, V2) and the current calculated by calculating the voltage (V1, V2). The power detection signal (1) is output.

  On the other hand, in the second drive system 30, the voltage detection circuit (V 3) 32 detects the voltage provided on the drive line 36 of the fluorescent lamps 12 a to 12 d and the voltage (V 3) at one end of the small resistor 35 for current detection. The The voltage detection circuit (V4) 33 detects the voltage (V4) at the other end of the minute resistor 35.

  When the voltage (V3, V4) is detected, the calculation circuit 34 detects voltage abnormality, current abnormality, and power by calculation based on the voltage (V3, V4) (step S6). That is, by comparing the detected voltage (V3, V4) with the reference voltage, for example, when the detected voltage (V3, V4) is lower than the reference voltage, it is determined that the voltage is abnormal.

  Further, the current is calculated from the calculation of the detected voltages (V3, V4). For example, when the current is lower than the specified current, it is determined that the current is abnormal. If the voltage abnormality or current abnormality is not detected, the abnormality detection signal (2) is not output. If it is determined that the voltage abnormality or current abnormality is detected (step S7), the abnormality detection signal (2) is output. (Step S8).

  Regardless of whether the voltage or current is abnormal, the power is calculated by calculating from the detected voltage (V3, V4) and the current calculated by calculating the voltage (V3, V4). The power detection signal (2) is output.

  For example, if an abnormality detection signal (1) is output from the arithmetic circuit 24 of the first drive system 20, an OFF control signal (1) is sent from the microcomputer 40 to the drive circuit (1) 21 of the first drive system 20. Is output (step S9). Thereby, the drive of the odd-numbered fluorescent lamps 11a to 11d having an abnormality is stopped by the drive circuit (1) 21 (step S10).

  In this case, as shown in FIG. 3, even when the odd-numbered fluorescent lamps 11a to 11d are stopped, the normal even-numbered fluorescent lamps 12a to 12d are driven. Although the luminance is reduced, since every other fluorescent lamp 12a to 12d is provided, the luminance is not uneven. Thereby, it is possible to view without luminance unevenness until the lamp replacement maintenance service is completed.

  As described above, in the present embodiment, the odd-numbered fluorescent lamps 11a to 11d are driven by the first drive system 20, and the even-numbered fluorescent lamps 12a to 12d are driven by the second drive system 30, so that the fluorescent lamps 11a to 11d are driven. , 12a to 12d, when the abnormality occurs, the microcomputer 40 stops driving the first drive system 20 or the second drive system 30 corresponding to the fluorescent lamps 11a to 11d and 12a to 12d where the abnormality has occurred. I made it. That is, when a plurality of fluorescent lamps 11a to 11d and 12a to 12d are driven by every other two driving means, and an abnormality occurs in any one of the fluorescent lamps 11a to 11d and 12a to 12d, an odd number Only the fluorescent lamps 11a to 11d or even-numbered fluorescent lamps 12a to 12d are driven.

  Specifically, the first drive system 20 monitors the driving of the odd-numbered fluorescent lamps 11a to 11d, and outputs an abnormality detection signal (1) when an abnormality occurs in any of the fluorescent lamps 11a to 11d. The second drive system 30 monitors the driving of the even-numbered fluorescent lamps 12a to 12d, and outputs an abnormality detection signal (2) when any abnormality occurs in any of the fluorescent lamps 12a to 12d. The drive of the fluorescent lamps 11a to 11d or 12a to 12d by the first drive system 20 or the second drive system 30 that output the abnormality detection signal (1) or the abnormality detection signal (2) by 40 is stopped.

  Thereby, although there is a decrease in the overall brightness of the liquid crystal display unit, it can be maintained in a state without brightness unevenness, so that it is possible to perform viewing in a state without brightness unevenness until the maintenance service for lamp replacement is completed. it can.

  In the present embodiment, the first drive system 20 detects the power required to drive the odd-numbered fluorescent lamps 11 a to 11 d and outputs the power detection signal (1). The first drive system 20 is detected based on the power detection signal (1) and the power detection signal (2) by the microcomputer 40 based on the detection of the power required for driving the fluorescent lamps 12a to 12d. And a power control signal for making the power required to drive the odd-numbered fluorescent lamps 11a to 11d and the power required to drive the even-numbered fluorescent lamps 12a to 12d to the second drive system 30 uniform. Therefore, it is possible to reduce luminance unevenness due to a difference in driving power between the two driving systems.

  In the present embodiment, the microcomputer 40 controls the drive phases of the first drive system 20 and the second drive system 30 to be shifted by, for example, 90 °. , And fluorescent lamp noise can be reduced by superimposing noise power due to a shift in noise generation timing.

  In the present embodiment, the fluorescent lamps 11a to 11d or 12a to 12d are driven by the first drive system 20 or the second drive system 30 that outputs the abnormality detection signal (1) or the abnormality detection signal (2) by the microcomputer 40. Although the case of stopping is described, in conjunction with this, the microcomputer 40 may notify the display control circuit (not shown) of the lamp abnormality, and the display control circuit may cause the lamp abnormality to be OSD-displayed.

  The present invention can be applied not only to a liquid crystal television but also to a display device that displays information using a backlight.

It is a block diagram which shows one Embodiment of the backlight control apparatus of this invention. 3 is a flowchart for explaining a backlight control method by the backlight control device of FIG. 1. It is a figure for demonstrating the backlight control method by the backlight control apparatus of FIG.

Explanation of symbols

10 Backlight
11a to 11d, 12a to 12d Fluorescent lamp 20 First drive system (first drive means)
21 Drive circuit (1)
22 Voltage detection circuit (V1)
23 Voltage detection circuit (V2)
24, 34 Arithmetic circuit 25, 35 Micro resistance 26, 36 Drive line
30 Second drive system (second drive means)
31 Drive circuit (2)
32 Voltage detection circuit (V3)
33 Voltage detection circuit (V4)
34 Arithmetic circuit
40 Microcomputer (control means)

Claims (5)

A backlight control device for controlling driving of a plurality of light sources arranged in parallel on the back surface of the liquid crystal display unit,
First driving means for driving odd-numbered light sources;
Second driving means for driving the even-numbered light sources;
A control means for stopping the driving of the first driving means or the second driving means corresponding to the light source when an abnormality occurs in any of the light sources ;
The first driving means monitors the driving of the odd-numbered light source, and outputs a first abnormality detection signal when an abnormality occurs in any of the light sources,
The second driving means monitors the driving of the even-numbered light source, and outputs a second abnormality detection signal when an abnormality occurs in any of the light sources,
The control means stops driving the light source by the first driving means or the second driving means that has output the first abnormality detection signal or the second abnormality detection signal,
further,
The first driving means detects a power required for driving the odd-numbered light source and outputs a first power detection signal;
The second driving means detects power required for driving the even-numbered light source and outputs a second power detection signal;
Based on the first power detection signal and the second power detection signal, the control unit causes the first driving unit and the second driving unit to supply power required for driving the odd-numbered light source and the even-numbered light source. A backlight control device that outputs a power control signal for making the power required for driving a light source uniform . The backlight control apparatus according to claim 1 , wherein the control unit controls driving by the first driving unit and the second driving unit with a phase shift. A liquid crystal television having a backlight control device, comprising the backlight control device according to claim 1 . A backlight control method for controlling the driving of a plurality of light sources arranged in parallel on the back surface of a liquid crystal display unit,
A first driving step of driving an odd-numbered light source;
A second driving step of driving the even-numbered light sources;
A control step of stopping driving in the first driving step or the second driving step corresponding to the light source when an abnormality occurs in any of the light sources ,
In the first driving step, the driving of the odd-numbered light source is monitored, and when an abnormality occurs in any of the light sources, a first abnormality detection signal is output,
In the second driving step, the driving of the even-numbered light source is monitored, and when an abnormality occurs in any of the light sources, a second abnormality detection signal is output,
In the control step, based on the first abnormality detection signal or the second abnormality detection signal, the driving of the light source by the drive system that outputs the first abnormality detection signal or the second abnormality detection signal is stopped,
further,
In the first driving step, power required for driving the odd-numbered light source is detected and a first power detection signal is output,
In the second driving step, the power required for driving the even-numbered light source is detected and a second power detection signal is output,
In the control step, the power required for driving the odd-numbered light sources and the power required for driving the even-numbered light sources are made uniform based on the first power detection signal and the second power detection signal. A backlight control method characterized by outputting a power control signal . 5. The backlight control method according to claim 4 , further comprising a step of controlling the driving phase of the odd-numbered light sources and the driving phase of the even-numbered light sources by shifting.

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