JP2010002562A - Liquid crystal display - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid crystal display in which a liquid crystal display panel is always driven acceleratively and suitably regardless of starting patterns thereof. <P>SOLUTION: A control circuit 4 selects a correction parameter to be used for correcting a gradation signal based on the reference temperature to be detected through a temperature sensor when the liquid crystal display panel 15 is driven acceleratively. The control circuit 4 discriminates according to which pattern of two or more starting patterns the liquid crystal display is started and selects the temperature sensor for detecting the reference temperature from a plurality of temperature sensors S1, S2 mounted respectively on different substrates according to the discrimination result. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a liquid crystal display device having a function of correcting a gradation signal of an image according to the change and supplying it to a drive unit of a liquid crystal display panel.

In a liquid crystal display device, a voltage (gray scale voltage) corresponding to the level of each of the R, G, and B3 primary colors in each frame of an image signal is applied to a liquid crystal element provided in the liquid crystal display panel. The image corresponding to the image signal is displayed on the liquid crystal display panel.
The liquid crystal element has a property that response speed is relatively slow, that is, a property that a change in filter characteristics is delayed with respect to a change in applied gradation voltage.
Therefore, as shown in Patent Documents 1 to 3 and the like, the liquid crystal display device performs an acceleration driving process of correcting the gradation signal of the input image according to the change and supplying the corrected gradation signal to the driving unit of the liquid crystal display panel. Often has a function to perform. This acceleration driving process overshoots the level change of the gradation signal supplied to the driving unit of the liquid crystal display panel with respect to the level change of the gradation signal from the previous frame to the current frame in the input image signal. It is a process to make. As a result, the gradation voltage supplied to the liquid crystal element overshoots, but the filter characteristics of the liquid crystal element change quickly to the target state without overshooting, and the responsiveness of the liquid crystal display panel to display moving images is improved. .

In addition, it is known that the response speed of liquid crystal elements is strongly temperature dependent. Therefore, as disclosed in Patent Document 3, it is effective to change the correction parameter for gradation signal correction in the acceleration drive processing based on a temperature (hereinafter referred to as a reference temperature) detected through a temperature sensor. .
The temperature sensor for detecting the reference temperature is desirably provided on the liquid crystal display panel itself as disclosed in Patent Document 3, for example. However, in practice, it is difficult to provide a temperature sensor on the liquid crystal display panel, which is a transparent body for displaying an image, so as not to affect the display image. For this reason, the temperature sensor for detecting the reference temperature is generally a thermistor or the like mounted on one of electronic boards in the apparatus. Here, the temperature of the inverter circuit, the power supply circuit, and the like that adjust the power supply to the backlight behaves completely different from the temperature of the liquid crystal display panel due to its heat generation during operation. Therefore, it is desirable that the temperature sensor for detecting the reference temperature is mounted on a circuit that is relatively less affected by heat generation and whose detected temperature behaves similarly to the temperature of the liquid crystal display panel.
In general, a liquid crystal display device includes a power supply board on which a power supply circuit is mounted, an inverter circuit board on which an inverter circuit for adjusting power supplied to a light source of a backlight is mounted, a device that performs image processing, and an MPU that controls the device. A mounted main control board and the like are provided. The main control board is suitable for a temperature sensor mounting board that detects the reference temperature because the influence of heat generation is relatively small compared to the inverter circuit board, the power supply circuit board, and the like.
JP 2000-231091 A JP 2003-207761 A JP 2006-126627 A

However, the main control board may also behave significantly different from the temperature of the liquid crystal display panel. This will be described below.
In a digital broadcast-compatible liquid crystal television receiver (an example of a liquid crystal display device), a digital tuner or a device for processing an image signal (hereinafter referred to as an image signal processing device) is activated for a relatively long time (for example, 10 It is known that it takes about 20 seconds). For this reason, recent liquid crystal television receivers are divided into two types: a standby state that prioritizes power saving (hereinafter referred to as a complete standby state) and a standby state that prioritizes the speed of startup (hereinafter referred to as an intermediate standby state). The standby state can be selected. The complete standby state is a state in which energization of most devices such as an inverter circuit, a liquid crystal drive circuit, a digital tuner, and an image signal processing device is stopped. On the other hand, the intermediate standby state is a standby state in which the energization to the inverter circuit, the liquid crystal drive circuit, etc. is stopped while the energization to the devices having a long startup time such as the digital tuner and the image signal processing device is performed.
FIG. 2 is a graph showing changes in the detected temperature of the temperature sensor mounted on each substrate after the liquid crystal display device is activated. The horizontal axis of the graph is the elapsed time after starting up the device.
As shown in FIG. 2, when the liquid crystal display device is started from the complete standby state, the detected temperature T1 of the temperature sensor mounted on the main control board shows a behavior highly correlated with the temperature T0 of the liquid crystal display panel. .
Here, in the temperature sensor mounted on the main control board on which the image signal processing device is mounted, the detected temperature T1 ′ in the intermediate standby state is higher than the detected temperature T1 in the complete standby state.
Therefore, when the liquid crystal display device is activated from the intermediate standby state, the detected temperature T1 ′ of the temperature sensor mounted on the main control board has a small change width after activation, and is an appropriate index for the temperature T0 of the liquid crystal display panel. Not.
The detected temperature T2 of the temperature sensor mounted on the inverter circuit board shows a relatively high correlation with the temperature T0 of the liquid crystal display panel for a while after the start regardless of the start pattern. The behavior is completely different from the temperature T0 of the display panel.
As described above, in the conventional liquid crystal display device in which the temperature sensor for detecting the reference temperature is fixed, the correction parameter for gradation signal correction in the acceleration driving process is appropriately set depending on the start pattern. Therefore, there was a problem that a good image quality could not be obtained.
Therefore, the present invention has been made in view of the above circumstances, and an object of the present invention is to provide a liquid crystal display device that can always realize an appropriate acceleration driving process of the liquid crystal display panel regardless of the activation pattern. Is to provide.

In order to achieve the above object, the liquid crystal display device according to the present invention corrects the gradation signal of the image according to the change and supplies it to the driving unit of the liquid crystal display panel, and at the reference temperature detected through the temperature sensor. Based on this, the correction parameters used for correcting the gradation signal are changed, and each component shown in the following (1) and (2) is provided. The process of correcting the gradation signal of the image according to the change and supplying it to the driving unit of the liquid crystal display panel includes the acceleration driving process.
(1) Activation pattern determination means for determining which of a plurality of activation patterns is activated when the liquid crystal display device is activated.
(2) A temperature sensor for detecting the reference temperature from when the liquid crystal display device is activated to when a predetermined condition is satisfied is selected from a plurality of temperature sensors mounted on different substrates. Temperature sensor selection means for selecting according to the determination result of the activation pattern determination means.
In the liquid crystal display device according to the present invention, the temperature sensor that detects the temperature (the reference temperature) that is referred to when determining the correction parameter of the gradation signal to be supplied to the drive unit of the liquid crystal display panel is a startup pattern of the device. It is selected appropriately according to. Therefore, according to the present invention, an appropriate acceleration driving process for the liquid crystal display panel can be realized regardless of the activation pattern.
In addition, the temperature sensor suitable for detecting the reference temperature is fixed to a specific temperature sensor regardless of the activation pattern when the temperature in the apparatus is in a steady state.
Therefore, it is conceivable that the liquid crystal display device according to the present invention further includes the constituent elements shown in the following (3).
(3) A temperature sensor for switching the temperature sensor for detecting the reference temperature after the predetermined condition is satisfied from the temperature sensor selected by the temperature sensor selection means to the first temperature sensor determined in advance. Switching means.

More specifically, it is conceivable that the liquid crystal display device according to the present invention further has each configuration shown in the following (4) to (6).
(4) A liquid crystal display device according to the present invention includes the following first substrate and second substrate. The first substrate is a substrate on which an image signal processing device that executes image signal processing and the first temperature sensor are mounted. The second substrate is a substrate on which a power supply adjusting device for the backlight that illuminates the liquid crystal display panel and a second temperature sensor are mounted.
(5) The activation pattern determination means determines at least the next first activation pattern and the second activation pattern. The first activation pattern is an activation pattern that is activated when energization to the image signal processing device and energization to the backlight through the second substrate are both stopped. It is. The second activation pattern is an activation pattern that is activated when energization of the backlight through the second substrate is started during energization of the image signal processing device.
(6) When the temperature sensor selection means is the first start pattern when the determination result of the start pattern determination means is the first start pattern, only the first temperature sensor is the second start pattern. One or more temperature sensors including two temperature sensors are selected.
Here, when a plurality of temperature sensors are selected by the temperature sensor selection unit, for example, an average temperature (including a weighted average temperature) of the detected temperatures may be set as the reference temperature.
The first board corresponds to the main control board, and the second board corresponds to the inverter circuit board. The first activation pattern corresponds to an activation pattern activated from the complete standby state, and the second activation pattern corresponds to an activation pattern activated from the intermediate standby state.
Further, as the predetermined condition, one of the following three conditions can be considered.
A condition that the reference temperature is equal to or higher than the detected temperature of the first temperature sensor.
A condition that the reference temperature is equal to or higher than a preset temperature.
A condition that a predetermined time has elapsed since the liquid crystal display device was activated.

  According to the present invention, it is possible to provide a liquid crystal display device that can always realize an appropriate acceleration driving process of the liquid crystal display panel regardless of the activation pattern.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that the present invention can be understood. The following embodiment is an example embodying the present invention, and does not limit the technical scope of the present invention.
FIG. 1 is a block diagram showing a schematic configuration of a liquid crystal television receiver X which is an example of a liquid crystal display device according to an embodiment of the present invention, and FIG. 2 is mounted on a plurality of substrates in the liquid crystal television receiver X. FIG. 3 is a diagram showing an example of a gradation signal conversion table, and FIG. 4 is a diagram showing the detected temperatures of temperature sensors mounted on a plurality of substrates in the liquid crystal television receiver X. It is a graph showing the change of the average value.

First, the configuration of a liquid crystal television receiver X, which is an example of a liquid crystal display device according to an embodiment of the present invention, will be described with reference to the block diagram shown in FIG.
As shown in FIG. 1, a liquid crystal television receiver X includes a tuner 1, an external signal input unit 2, a demodulation / separation circuit 3, a video decoding circuit 11, a video selection circuit 12, a video processing circuit 13, a liquid crystal driver 14, a liquid crystal Display panel 15, dimmer circuit 16, backlight 17, audio decoding circuit 21, audio selection circuit 22, audio processing circuit 23, amplifier 24, speaker 25, control circuit 4, switch circuit 5, remote control light receiving unit 6, remote control 7, An energization switching circuit 8, two temperature sensors (first thermistor S1 and second thermistor S2) and the like are provided.

The tuner 1 is an electronic component that extracts a signal of content (broadcast program) being broadcast from an input television broadcast signal. More specifically, the tuner 1 extracts a carrier frequency component signal including a broadcast program signal instructed to be selected by the control circuit 4, and transmits the extracted signal to the demodulation / separation circuit 3 in the subsequent stage. To do. The tuner 1 is provided for each broadcasting medium (terrestrial wave, BS, CS, etc.).
The demodulation / separation circuit 3 demodulates a transport stream signal (Transport Stream signal: hereinafter referred to as a TS signal) from the carrier frequency component transmitted from the tuner 1. Further, the demodulation / separation circuit 3 separates and extracts a video signal and an audio signal corresponding to a broadcast program to be viewed and additional data from the extracted TS signal. Further, the demodulation / separation circuit 3 extracts a video signal and an audio signal of a broadcast program to be viewed according to a PID (Packet IDentification) received from the control circuit 4, and each signal is extracted from the video decoding circuit 11 And to each of the speech decoding circuits 21.
Further, the demodulation / separation circuit 3 extracts SI (Service Information) as additional data from the TS signal and transmits it to the control circuit 4. The SI is data in which information of an EPG (electronic program guide) (for example, information indicating a program name, a program genre, a broadcast time, etc.) is multiplexed.

The external signal input unit 2 is a signal input interface for inputting a video signal and an audio signal from an external device.
The video decoding circuit 11 decodes the video signal transmitted from the demodulation / separation circuit 3 and transmits the decoded video signal to the video selection circuit 5. Similarly, the audio decoding circuit 21 decodes the audio signal transmitted from the demodulation / separation circuit 3 and transmits the decoded audio signal to the audio selection circuit 22.
The video selection circuit 12 selects one or a plurality of video signals from a plurality of video signals input according to a control command from the control circuit 4 and transmits the selected video signals to the video processing circuit 13. The signals input to the video selection circuit 12 include the video signal of the content of the broadcast program input through the video decoding circuit 11 and the video signal of the external input content input through the external signal input unit 2. It is.

The video processing circuit 13 generates a frame image signal to be supplied to the liquid crystal driver 14 in order to display a content image on the liquid crystal display panel 15 in accordance with a control command from the control circuit 4.
For example, the video processing circuit 13 generates a frame image signal for displaying an image in which one or a plurality of content images are laid out in the entire display area in accordance with a control command from the control circuit 4.
The video processing circuit 13 corrects the gradation signal in the image signal of the input content according to the change, and supplies the frame image signal including the corrected gradation signal to the liquid crystal driver 14. Perform acceleration drive processing.
Specifically, the video processing circuit 13 includes a frame memory 13a that temporarily stores the image signal of the latest frame and the image signal of the previous (previous) frame. Then, the video processing circuit 13 refers to the signal stored in the frame memory 13a, and responds to the liquid crystal driver 14 with respect to the level change of the gradation signal from the previous (previous) frame to the current frame. Correction to overshoot the level change of the supplied gradation signal is performed.

FIG. 3 is an example of a gradation signal conversion table in the acceleration driving process.
As shown in FIG. 3, the correction parameters used in the acceleration driving process are the levels supplied to the liquid crystal driver 14 in response to the level change of the gradation signal from the previous (previous) frame to the current frame. The parameter overshoots the level change of the modulation signal. When the levels of the previous and current gradation signals are different from the levels set in the conversion table shown in FIG. 3, the corrected gradation signals are subjected to interpolation processing based on the levels set in the conversion table. And the corrected gradation signal is supplied to the liquid crystal driver 14.

The liquid crystal driver 14 controls the liquid crystal display panel 15 based on the frame image signal sequentially transmitted from the video processing circuit 13 in a predetermined cycle, and corresponds to one frame (one frame) corresponding to the frame image signal. Are sequentially displayed on the liquid crystal display panel 15.
The liquid crystal display panel 15 displays an image corresponding to the frame image signal in accordance with control by the liquid crystal driver 14.
The backlight 17 illuminates the display area of the liquid crystal display panel 15 from the back side with the light of a plurality of light sources arranged on the back side of the liquid crystal display panel 15.
The dimming circuit 16 adjusts the power supplied to the light source of the backlight 17 in accordance with a control command from the control circuit 4, thereby adjusting the brightness of the light emission of the backlight 17 by PWM control. Circuit.

The voice decoding circuit 21 decodes the voice signal transmitted from the demodulation / separation circuit 3 and transmits the decoded voice signal to the voice selection circuit 22.
The audio selection circuit 22 is a circuit that selects one audio signal from a plurality of input audio signals in accordance with a control command from the control circuit 4 and transmits the selected audio signal to the audio processing circuit 23. The audio signal input to the audio selection circuit 22 includes an audio signal of the content of the broadcast program selected by the tuner 1 (an audio signal input through the audio decoding circuit 21), and the external signal input unit 2 And an audio signal input through.
The voice processing circuit 23 performs various signal processing on the voice signal selected by the voice selection circuit 22 in accordance with an instruction from the control circuit 4. For example, equalization processing, surround processing, or the like according to the characteristics of the speaker 25 is performed.
The amplifier 24 performs a volume adjustment process for amplifying or attenuating the audio signal processed by the audio processing circuit 23 in accordance with an instruction from the control circuit 4, and outputs it to the speaker 25.

The remote control light receiving unit 6 is a signal transmission interface that receives a radio signal by infrared rays from a remote control 7 (remote controller) for operating the liquid crystal television receiver X according to a predetermined signal transmission protocol (so-called remote control protocol). is there. The remote control light receiving unit 6 extracts a signal representing operation input information for the remote control 7 from the infrared signal, and transmits the signal to the control circuit 4.
In the liquid crystal television receiver X, the demodulation / separation circuit 3, the video decoding circuit 11, the video selection circuit 12, the video processing circuit 13, and the like including the image signal processing device for processing the image signal, The control circuit 4 to be controlled and the first thermistor S1 which is one temperature sensor are mounted on a main control board B1 which is one electronic board. On the main control board B1, the audio decoding circuit 21, the audio selection circuit 22, the audio processing circuit 23, and the switch circuit 5 including devices for executing audio signal processing are mounted.
The dimming circuit 16 (inverter circuit) on which the power supply adjusting device for the backlight 17 that illuminates the liquid crystal display panel 15 is mounted and the second thermistor S2 that is the other temperature sensor are a single electronic board. It is mounted on the inverter circuit board B2.
Therefore, the detected temperature of the first thermistor S1 shows the behavior of the detected temperature T1 or T1 ′ shown in FIG. 2 according to the activation pattern of the liquid crystal television receiver X. Further, the detected temperature of the second thermistor S2 shows the behavior of the detected temperature T2 shown in FIG. 2 regardless of the activation pattern of the liquid crystal television receiver X. The activation pattern will be described later.
The circuit constituting the external signal input unit 2 is mounted on a terminal board B3, which is one electronic board, together with connection terminals for external input signals.

The energization switching circuit 8 is a circuit that switches between energization and interruption of energization to a part of the circuit included in the liquid crystal television receiver X.
Specifically, the energization switching circuit 8 can individually switch the energization presence / absence for each of the first circuit group and the second circuit group divided into two groups.
The first circuit group includes the tuner 1, the demodulation / separation circuit 3 including the image signal processing device 3, the video decoding circuit 11, the video selection circuit 12 and the video processing circuit 13, and an audio signal processing device. The speech decoding circuit 21, the speech selection circuit 22, and the speech processing circuit 23 are included.
The second circuit group includes the dimmer circuit 16 and the liquid crystal driver 14.
The energization switching circuit 8 changes the energization state of the liquid crystal television receiver X by switching the energization state to the first circuit group and the second circuit group in accordance with a control command from the control circuit 4. , Switching to three states: complete standby state, intermediate standby state, and operating state.
The complete standby state is an energized state in which energization of both the first circuit group and the second circuit group is interrupted.
The intermediate standby state is an energized state in which energization is performed on the first circuit group including an image signal processing device that requires a long start-up time, and energization is interrupted on the second circuit group.
The operating state is an energized state in which energization is performed on both the first circuit group and the second circuit group.
The switch circuit 5 is a circuit that inputs the detection signal of the first thermistor S1 and the detection signal of the second thermistor S2, and selects and outputs either of them. The selection (switching) of the output signal is performed according to the control signal from the control circuit 4. The output signal of the switch circuit 5 is transmitted to the MPU 4a included in the control circuit 4.

The control circuit 4 includes an MPU 4a that is an arithmetic means, and a ROM 4b (EPROM) and an EEPROM 4c that are storage means, and the MPU 4a controls the entire liquid crystal television receiver X by executing a control program.
The ROM 4b stores in advance a control program executed by the MPU 4a. The EEPROM 4c stores various data that is read and written (referenced or written) in the process executed by the MPU 4a.
In the following description, the processing executed by the control circuit 4 is realized by the MPU 4a executing a control program stored in the ROM 4b.
For example, the control circuit 4 acquires channel tuning and volume control information through the remote controller 7 and the remote control light receiving unit 6, and selects a tuning instruction for the tuner 1 and the amplifier 24 according to the contents of the acquired information. Outputs volume adjustment instructions.

Further, when the control circuit 4 detects through the remote control light receiving unit 6 that the operation of the power key on the remote control 7 has been performed, and when it has detected that a predetermined time has passed since the detection, The energization state of the liquid crystal television receiver X is switched by controlling the energization switching circuit 8.
Specifically, when the control circuit 4 detects the operation of the power key in the complete standby state or the intermediate standby state, the control circuit 4 switches the energized state to the operating state.
Further, when the control circuit 4 detects the operation of the power key in the operating state, the control circuit 4 switches the energized state to the intermediate standby state.
Further, the control circuit 4 switches the energized state from the intermediate standby state to the complete standby state when a predetermined time has elapsed since the energized state was switched to the intermediate standby state.
In addition, the control circuit 4 has a function of setting an intermediate standby time zone, which is a time zone for prohibiting switching to the complete standby state, in accordance with input information through the remote controller 7, and recording the setting information in the EEPROM 4c. It is also possible. In the intermediate standby time zone, a time zone in which the liquid crystal television receiver X is frequently used is set. The control circuit 4 does not switch from the intermediate standby state to the complete standby state based on the passage of time when the current time detected by a timing circuit (not shown) belongs to the intermediate standby time zone. As a result, the liquid crystal television receiver X is always activated in a short time in a time zone with high usage frequency.

In addition, the control circuit 4 is configured so that the video processing circuit 13 is based on the reference temperature detected through the first thermistor S1 or the second thermistor S2 (an example of a temperature sensor). A process of changing a correction parameter used for correcting the tone signal is executed. The reference temperature is a temperature indicated by a detection signal of either the first thermistor S1 or the second thermistor S2 output from the switch circuit 5.
The ROM 4b included in the control circuit 4 stores information of a conversion table in which correction parameters as shown in FIG. 3 are set for each temperature range of the reference temperature divided into a plurality.
The control circuit 4 selects the conversion table corresponding to the reference temperature value, and sets the selected conversion table in a register (not shown) included in the video processing circuit 13. Then, the video processing circuit 13 converts the gradation signal according to the conversion table set in the register by the control circuit 4, that is, converts the original gradation signal to the gradation signal supplied to the liquid crystal driver 14. Make corrections.

  In addition, the control circuit 4 determines which one of the two activation patterns is activated when the liquid crystal television receiver X is activated in response to the operation of the power key. Execute. Here, the first activation pattern is an activation pattern that has shifted from the intermediate standby state to the operation state. The second activation pattern is an activation pattern that has shifted from the complete standby state to the operating state. Hereinafter, the first activation pattern is referred to as a quick activation pattern, and the second activation pattern is referred to as a normal activation pattern. The activation pattern is determined based on the state of the control command to the energization switching circuit 8 at the time when the operation of the power key is detected (immediately before shifting to the operation state).

Then, the control circuit 4 controls the switch circuit 5 at the time of transition to the operation state, so that the control circuit 4 is predetermined after the liquid crystal television receiver X is activated (becomes the operation state). The thermistor for detecting the reference temperature until the sensor switching condition is satisfied is selected.
Specifically, when the start pattern determination result is the quick start pattern, the control circuit 4 controls the switch circuit 5 so that only the second thermistor S2 becomes a sensor for detecting the reference temperature. On the other hand, when the determination result of the start pattern is the normal start pattern, the control circuit 4 controls the switch circuit 5 so that only the first thermistor S1 becomes a sensor for detecting the reference temperature.
In this way, the control circuit 4 uses the thermistors for detecting the reference temperature on different substrates (the main control) from when the liquid crystal television receiver X is activated until the sensor switching condition is satisfied. A temperature sensor selection process is performed for selecting from the two thermistors S1 and S2 mounted on the board B1 and the inverter circuit board B2) according to the determination result of the startup pattern.

When the second thermistor S2 is selected as the reference temperature detection sensor at the time of start-up, the control circuit 4 determines at any time whether or not the sensor switching condition is satisfied. Then, when the sensor switching condition is satisfied, the control circuit 4 switches the sensor for detecting the reference temperature from the second thermistor S2 to the first thermistor S1. The control circuit 4 holds the selected state when the first thermistor S1 is selected as the reference temperature detection sensor at the time of activation.
As the sensor switching condition, for example, one of the following three conditions can be considered.
A first example of the sensor switching condition is a condition that the reference temperature is equal to or higher than a detected temperature of the first thermistor S1.
As shown in FIG. 2, when the liquid crystal television receiver X is activated in the quick activation pattern, the detected temperature T2 of the second thermistor S2 is a detected temperature T1 ′ of the first thermistor S1 after a while. After that, the liquid crystal display panel 15 exhibits a completely different behavior from the temperature T0. Therefore, the control circuit 4 compares the detected temperature T2 of the second thermistor S2, which is the reference temperature, with the detected temperature T1 ′ of the first thermistor S1 as needed, and when T2 ≧ T1 ′ is satisfied (FIG. 2). At the time tp in FIG. 4), the switch circuit 5 is controlled to output the detection signal of the first thermistor S1.
For example, after startup, the control circuit 4 periodically executes a process of temporarily switching the signal selection state of the switch circuit 5 and acquiring the detected temperature T1 ′ of the first thermistor S1. Further, the control circuit 4 compares the acquired detected temperature T1 ′ with the detected temperature T2 of the second thermistor S2 obtained when the signal selection state of the switch circuit 5 is restored. Determine the switching condition.

The second example of the sensor switching condition is a condition that the detected temperature T2 of the second thermistor S2, which is the reference temperature, is equal to or higher than a preset temperature.
Further, the second example of the sensor switching condition is a condition that a predetermined time has elapsed since the liquid crystal television receiver X was activated.
Even when the second example or the third example is adopted as the sensor switching condition, the reference temperature detection sensor is not changed in the process of the liquid crystal television receiver X shifting to the steady operation. The thermistor S2 is switched to the first thermistor S1.
As described above, in the liquid crystal television receiver X that selects the reference temperature detection sensor in accordance with the activation pattern, the appropriate acceleration driving process can always be realized regardless of the activation pattern.

  By the way, when the MPU 4a of the control circuit 4 inputs both the temperature detection signals of the two thermistors S1 and S2, and the start pattern is the quick start pattern, as a temperature sensor for detecting the reference temperature, It is also conceivable to select both the first thermistor S1 and the second thermistor S2. In this case, the control circuit 4 switches the conversion table (see FIG. 3) using the detected temperature T1 ′ of the first thermistor S1 and the average temperature T12 ′ of the detected temperature T2 of the second thermistor S2 as the reference temperature. I do. The average temperature T12 ′ may be a weighted average value obtained by setting different weights for each temperature in addition to a simple average value in which the weight of each temperature is equal (0.5). Conceivable.

FIG. 4 is a graph showing changes in detected temperatures and average temperatures of the thermistors S1 and S2 mounted on the substrates B1 and B2 after the liquid crystal television receiver X is started. 4 is a simple average value of the detected temperature T1 ′ of the first thermistor S1 and the detected temperature T2 of the second thermistor S2 when the start pattern is the quick start pattern. is there.
As shown in FIG. 4, when the startup pattern is the quick startup pattern, the average temperature T12 ′ shows a behavior highly correlated with the temperature T0 of the liquid crystal display panel 15 for a while after the startup. Therefore, it is also conceivable that the acceleration drive process is performed using the average value of the detected temperatures of a plurality of thermistors as the reference temperature from when the sensor is switched to when the sensor switching condition is satisfied.
Further, a configuration in which the second thermistor S2 that is a candidate for selecting a temperature sensor for detecting the reference temperature is mounted on the terminal board B3 is also conceivable.
Further, in the embodiment described above, the case where there are two types of activation patterns has been described. On the other hand, when three or more types of standby states depending on the presence / absence of energization of components mounted on three or more boards can be taken as standby states before startup (before entering the operating state), the control is performed. It is also conceivable that the circuit 4 discriminates three or more types of activation patterns and selects a temperature sensor suitable for the detection of the reference temperature according to the discrimination result.

  The present invention is applicable to a liquid crystal display device such as a liquid crystal television receiver.

1 is a block diagram illustrating a schematic configuration of a liquid crystal television receiver X that is an example of a liquid crystal display device according to an embodiment of the present invention. The graph showing the change of the detection temperature of the temperature sensor mounted in the some board | substrate in the liquid crystal television receiver X. FIG. The figure showing an example of the conversion table of a gradation signal. The graph showing the detection temperature of the temperature sensor mounted in the some board | substrate in the liquid crystal television receiver X, and the change of the average value.

Explanation of symbols

X: liquid crystal television receiver 1: tuner 2: external signal input unit 3: demodulation / separation circuit 4: control circuit 5: switch circuit 6: remote control light receiving unit 7: remote control 8: energization switching circuit 11: video decoding circuit 12: Video selection circuit 13: Video processing circuit 14: Liquid crystal driver 15: Liquid crystal display panel 16: Light control circuit (inverter circuit)
17: Backlight 21: Audio decoding circuit 22: Audio selection circuit 23: Audio processing circuit 24: Amplifier 25: Speaker S1: First thermistor S2: Second thermistor B1: Main control board B2: Inverter circuit board B3: Terminal board

Claims (6)

The gradation signal of the image is corrected according to the change and supplied to the driving unit of the liquid crystal display panel, and the correction parameter used for correcting the gradation signal is changed based on the reference temperature detected through the temperature sensor. A liquid crystal display device,
An activation pattern discriminating means for discriminating which one of a plurality of activation patterns is activated when the liquid crystal display device is activated;
A temperature sensor for detecting the reference temperature from when the liquid crystal display device is activated to when a predetermined condition is satisfied is selected from the plurality of temperature sensors mounted on different substrates. A temperature sensor selection means for selecting according to the discrimination result of the discrimination means;
A liquid crystal display device comprising:   Temperature sensor switching means for switching the temperature sensor for detecting the reference temperature after the predetermined condition is satisfied from the temperature sensor selected by the temperature sensor selection means to the first temperature sensor determined in advance; The liquid crystal display device according to claim 1. An image signal processing device that executes image signal processing, a first substrate on which the first temperature sensor is mounted, a power supply adjustment device for a backlight that illuminates the liquid crystal display panel, and a second temperature sensor are mounted. A second substrate,
The activation pattern discrimination means is
A first activation pattern that starts when energization of the image signal processing device and energization of the backlight through the second substrate are both stopped, and the image signal; Determining a second activation pattern to be activated by energizing the backlight through the second substrate while energizing the processing device;
When the determination result of the activation pattern determination unit is the first activation pattern, the temperature sensor selection unit selects only the first temperature sensor and the second temperature when the determination result is the second activation pattern. The liquid crystal display device according to claim 2, wherein one or a plurality of temperature sensors including the sensor are selected.   The liquid crystal display device according to claim 3, wherein the predetermined condition is a condition that the reference temperature is equal to or higher than a detection temperature of the first temperature sensor.   The liquid crystal display device according to claim 3, wherein the predetermined condition is a condition that the reference temperature is equal to or higher than a preset temperature.   The liquid crystal display device according to claim 3, wherein the predetermined condition is a condition that a predetermined time has elapsed since the liquid crystal display device was activated.

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