JP3699001B2 - Liquid crystal display device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a liquid crystal display device that requires a lighting device.
[0002]
[Prior art]
In a liquid crystal display device used as a display screen of a conventional notebook type personal computer or word processor, when a high-speed moving image is displayed, the display quality is deteriorated such as a blurred image or blurring.
[0003]
Therefore, in JP-A-1-082019, JP-A-8-500915, and JP-A-11-202286, the light-emitting portion of the liquid crystal display device has a constant light-out period for each frame. It is disclosed that a good display quality can be obtained in high-speed moving images.
[0004]
[Problems to be solved by the invention]
However, in the above conventional technique, a rectangular wave voltage is applied to the light emitter of the illumination unit. Thus, when a rectangular wave is applied to a light-emitting body, the following problems will be caused.
[0005]
That is, when the applied waveform is a rectangular wave, the durability of the light emitter is short, which causes a problem in practical use. For example, when a rectangular wave voltage is applied to a common cold cathode tube in a liquid crystal display device, an abrupt current flows through the cold cathode tube when light emission rises. On the other hand, when light emission falls, the current to the cold cathode tube is abruptly interrupted, and a reverse current may flow. Such current behavior significantly reduces the durability of the cold cathode tube. In addition, since the rectangular wave includes harmonic components, this causes a problem of electromagnetic interference.
[0006]
In the above description, the case where a cold cathode tube is used has been described. However, the same result can be obtained by using other light emitters such as a light emitting diode, an electroluminescence element, a hot cathode tube, a mercury lamp, a halogen lamp, and a laser.
[0007]
The present invention has been made in view of the above-mentioned problems, and its purpose is to provide a good display quality even in high-speed moving images while suppressing a decrease in the durable life of the illuminator of the illumination unit and reducing electromagnetic interference. There is to do.
[0008]
[Means for Solving the Problems]
In order to solve the above-described problem, the liquid crystal display device of the present invention is a liquid crystal display device including a light emitter that irradiates pixels with light according to a drive signal. A light emission control means for controlling the drive signal is provided so as to make the rise and fall slow.
[0009]
According to the above invention, the light emitted from the light emitter is changed according to the drive signal, and is emitted to the pixels to display desired information. At this time, when a drive signal having a rectangular waveform is applied to the light emitter, there is a light extinction period, and for the viewer, only a moment with a high contrast ratio remains as an afterimage, so that it looks as a clear screen with a good contrast ratio. .
[0010]
However, when the drive signal has a rectangular waveform, high-frequency electromagnetic radiation is observed, which adversely affects the human body. In addition, when a rectangular wave driving signal is applied to the light emitter, a sudden current flows through the light emitter when light emission rises, and when the light emission falls, the current to the light emitter is suddenly interrupted and a reverse current is applied to the light emitter. Such current behavior may significantly reduce the durable life of the light emitter.
[0011]
Therefore, according to the invention described above, the drive signal is controlled by the light emission control means so that the rise and fall of the light emission waveform of the light emitter are blunted every vertical period. In this way, since the drive signal is controlled so that the light emission waveform of the light emitter is dull near the rising edge, no sudden current flows through the light emitter, and similarly, the light emitting body is also near the falling edge of the light emitting waveform. Therefore, it is possible to prevent the reverse current from flowing through the light emitter. Therefore, it is possible to reliably and surely prevent the durability life of the luminous body from being significantly reduced by such current behavior.
[0012]
Further, since the drive signal applied to the light emitter is controlled so that the light emission waveform of the light emitter is dull in the vicinity of the rise and fall, the harmonic component can be reliably reduced / reduced. As a result, electromagnetic radiation that causes danger to the human body is greatly reduced, and the problem of electromagnetic interference can be overcome.
[0013]
In addition, since the drive signal applied to the light emitter is controlled so that the light emission waveform of the light emitter is dull near the rise and fall, there is a period in which the light emission of the light emitter is reduced every vertical period, For the viewer, only the moment with a high contrast ratio remains as an afterimage, and it appears as a clear screen with a good contrast ratio, and in particular, the display quality of high-speed moving images can be made extremely good.
[0014]
In the liquid crystal display device, the light emission control means blunts the rise and fall of the waveform of the drive signal applied to the light emitter, and gradually increases the light emission of the light emitter near the rise, Moreover, it is preferable to reduce gradually near the fall.
[0015]
In this case, since the rise and fall of the waveform of the drive signal is dull, as described above, a sudden current does not flow to the light emitter, and the current to the light emitter is suddenly cut off even near the fall of light emission. It is also possible to avoid reverse current from flowing through the light emitter. Therefore, it is possible to prolong the durable life of the illuminant, to reduce or alleviate electromagnetic interference that the harmonic component poses a danger to the human body, and to extremely improve the display quality of high-speed moving images.
[0016]
The light emission control means blunts the rise and fall of the envelope of the waveform of the drive signal applied to the light emitter, and gradually increases the light emission of the light emitter near the rise and falls. It may be gradually reduced in the vicinity.
[0017]
The light emission control means may generally make the rise and fall of the waveform of the drive signal part of a sine wave.
[0018]
The light emission control means may generally make the rise and fall of the envelope of the waveform of the drive signal part of a sine wave.
[0019]
In another liquid crystal display device of the present invention, in the liquid crystal display device including a light emitter that irradiates the pixel with light according to the drive signal, the drive signal is set so that the frequency becomes a sine wave substantially matching the reciprocal of the vertical period. It is characterized by having a light emission control means for controlling the above.
[0020]
According to the above invention, the light emitted from the light emitter is changed according to the drive signal, and is emitted to the pixels to display desired information. At this time, when a drive signal having a rectangular waveform is applied to the light emitter, there is a light extinction period, and for the viewer, only a moment with a high contrast ratio remains as an afterimage, so that it looks as a clear screen with a good contrast ratio. .
[0021]
However, when the drive signal has a rectangular waveform, high-frequency electromagnetic radiation is observed, which adversely affects the human body. In addition, when a rectangular wave driving signal is applied to the light emitter, a sudden current flows through the light emitter when light emission rises, and when the light emission falls, the current to the light emitter is suddenly interrupted and a reverse current is applied to the light emitter. Such current behavior may significantly reduce the durable life of the light emitter.
[0022]
Therefore, according to the above-described invention, the drive signal is controlled by the light emission control means so that the frequency is a sine wave whose frequency substantially coincides with the reciprocal of the vertical period. In this way, since the drive signal is controlled so that the frequency becomes a sine wave that substantially matches the reciprocal of the vertical period (since it is not a rectangular wave as in the past), no sudden current flows through the light emitter. Similarly, the light emission from the light emitter also changes so that the frequency becomes a sine wave that roughly matches the reciprocal of the vertical period. Therefore, a sudden current does not flow through the light emitter, a current with respect to the light emitter is not suddenly interrupted, or a reverse current does not flow through the light emitter. By such a current behavior, it is possible to surely and reliably avoid a significant decrease in the durable life of the light emitter.
[0023]
In addition, since the drive signal applied to the light emitter is controlled to be a sine wave whose frequency substantially matches the reciprocal of the vertical period, the harmonic component can be reliably reduced / reduced. As a result, electromagnetic radiation that causes danger to the human body is greatly reduced, and the problem of electromagnetic interference can be overcome.
[0024]
In addition, there is a period in which light emission of the light emitter is reduced every vertical period due to the drive signal applied to the light emitter, and for the viewer, only the moment with a high contrast ratio remains as an afterimage, and the contrast ratio is good. It can be seen as a clear screen, and in particular, the display quality of high-speed moving images can be made extremely good.
[0025]
The drive signal may be controlled so that the frequency of the envelope is a sine wave that roughly matches the reciprocal of the vertical period.
[0026]
The drive signal may be controlled so as to have a Gaussian distribution waveform in which the repetition period substantially coincides with the vertical period.
[0027]
The drive signal may be controlled so as to have a Gaussian distribution waveform in which the repetition period of the envelope generally matches the vertical period.
[0028]
The drive signal may be controlled so as to have a Lorentz distribution waveform in which the repetition period substantially coincides with the vertical period.
[0029]
The drive signal may be controlled so as to have a Lorentz distribution waveform in which the repetition period of the envelope substantially matches the vertical period.
[0030]
The drive signal may be controlled such that the frequency is a triangular wave that substantially matches the reciprocal of the vertical period.
[0031]
The drive signal may be controlled so that the frequency of the envelope is a triangular wave that roughly matches the reciprocal of the vertical period.
[0032]
As the light emitter, it is preferable to use a cold cathode tube, a light emitting diode element, an electroluminescence element, a hot cathode tube, a mercury lamp, a halogen lamp, or a laser.
[0033]
In order to solve the above-described problem, the light emitter driving method of the present invention is characterized in that the rise and fall of the drive signal of the light emitter included in the liquid crystal display device are blunted.
[0034]
According to said invention, the light emitted from the light-emitting body with which a liquid crystal display device is provided changes according to a drive signal. At this time, when the drive signal has a rectangular waveform, high-frequency electromagnetic radiation is observed, which adversely affects the human body. In addition, when a rectangular wave driving signal is applied to the light emitter, a sudden current flows through the light emitter when light emission rises, and when the light emission falls, the current to the light emitter is suddenly interrupted and a reverse current is applied to the light emitter. Such current behavior may significantly reduce the durable life of the light emitter.
[0035]
Therefore, according to the above invention, the rise and fall of the drive signal are blunted. As described above, when the driving signal of the light emitter is dulled in the vicinity of the rising edge, a sudden current does not flow to the light emitter. In addition, when the driving signal of the light emitter is dulled near the falling edge, similarly, the current to the light emitter is not cut off suddenly, and the reverse current can be prevented from flowing to the light emitter. Therefore, it is possible to reliably and surely prevent the durability life of the luminous body from being significantly reduced by such current behavior.
[0036]
Further, since the drive signal applied to the light emitter is controlled so that the light emission waveform of the light emitter is dull in the vicinity of the rise and fall, the harmonic component can be reliably reduced / reduced. As a result, electromagnetic radiation that causes danger to the human body is greatly reduced, and the problem of electromagnetic interference can be overcome.
[0037]
Moreover, the drive signal applied to the light emitter has a period in which the light emission of the light emitter is reduced, and for the viewer, only a moment with a high contrast ratio remains as an afterimage, and it looks as a clear screen with a good contrast ratio, Thereby, especially the display quality of a high-speed moving image can be made very favorable.
[0038]
Even if the rising and falling edges of the envelope of the driving signal are blunted instead of the driving signal, the same effect as described above can be obtained.
[0039]
In order to blunt the waveform of the drive signal, the drive signal line related to the drive signal is preferably grounded via a capacitor. In this case, an integrating circuit is formed by the resistance of the drive signal line and the capacitor. By this integration circuit, the drive signal which is a rectangular wave can be blunted according to the time constant.
[0040]
In place of the drive signal, the same operation as described above can be achieved even when the drive signal of the light emitter provided in the liquid crystal display device is synchronized with the vertical synchronization signal.
[0041]
Alternatively, the same effect as described above can be obtained by making the envelope of the drive signal of the light emitter included in the liquid crystal display device into a periodic waveform synchronized with the vertical synchronization signal.
[0042]
The rising and falling edges of the periodic waveform preferably include a part of a sine wave. Alternatively, the periodic waveform may be approximately a sine wave.
[0043]
In this case, an abrupt current does not flow to the light emitter, and light emission from the light emitter also periodically changes in synchronization with the vertical synchronization signal. Therefore, a sudden current does not flow through the light emitter, a current with respect to the light emitter is not suddenly interrupted, or a reverse current does not flow through the light emitter. By such a current behavior, it is possible to surely and reliably avoid a significant decrease in the durable life of the light emitter.
[0044]
In particular, when the rising and falling edges of the periodic waveform include a part of a sine wave, or the periodic waveform is almost a sine wave, the harmonic component can be reliably reduced or reduced. As a result, electromagnetic radiation that causes danger to the human body is greatly reduced, and the problem of electromagnetic interference can be overcome.
[0045]
Moreover, there is a period in which the light emission of the light emitter periodically decreases due to the drive signal applied to the light emitter. When a liquid crystal display device adopts such a light-emitting body driving method, only a moment with a high contrast ratio remains as an afterimage for a viewer, and it appears as a clear screen with a good contrast ratio. The quality can be made extremely good.
[0046]
The periodic waveform is not limited to a sine wave, but may be a triangular wave. Alternatively, the periodic waveform may be generally a repetition of a Gaussian distribution waveform. Alternatively, the periodic waveform may be generally a repetition of a Lorentz distribution waveform.
[0047]
In order to solve the above-described problems, the light emitting body of the present invention is characterized in that a drive signal having a dull rise and fall is input.
[0048]
According to the invention described above, the light emitted from the light emitter changes according to the drive signal. At this time, when the drive signal has a rectangular waveform, high-frequency electromagnetic radiation is observed, which adversely affects the human body. In addition, when a rectangular wave driving signal is applied to the light emitter, a sudden current flows through the light emitter when light emission rises, and when the light emission falls, the current to the light emitter is suddenly interrupted and a reverse current is applied to the light emitter. Such current behavior may significantly reduce the durable life of the light emitter.
[0049]
Therefore, according to the above-described invention, the drive signal whose rise and fall are blunted is input to the light emitter. As described above, when the driving signal of the light emitter is dulled in the vicinity of the rising edge, a sudden current does not flow to the light emitter. In addition, when the driving signal of the light emitter is dulled near the falling edge, similarly, the current to the light emitter is not cut off suddenly, and the reverse current can be prevented from flowing to the light emitter. Therefore, it is possible to reliably and surely prevent the durability life of the luminous body from being significantly reduced by such current behavior.
[0050]
Further, since the drive signal applied to the light emitter is controlled so that the light emission waveform of the light emitter is dull in the vicinity of the rise and fall, the harmonic component can be reliably reduced / reduced. As a result, electromagnetic radiation that causes danger to the human body is greatly reduced, and the problem of electromagnetic interference can be overcome.
[0051]
Moreover, the drive signal applied to the light emitter has a period in which the light emission of the light emitter is reduced. When such a light emitter is used in a liquid crystal display device, only a moment with a high contrast ratio remains as an afterimage for a viewer and a clear screen with a good contrast ratio is obtained. It can be good.
[0052]
A light emitter that receives a drive signal with a dull rise and fall of the envelope exhibits the same effect as described above. Or the light-emitting body which inputs the drive signal which has a periodic waveform synchronizing with the vertical synchronizing signal may be sufficient. Or the light-emitting body which inputs the drive signal which has a periodic waveform in which the envelope synchronized with the vertical synchronizing signal may be used.
[0053]
It is preferable that the rising and falling edges of the periodic waveform include a part of a sine wave. The periodic waveform may generally be a sine wave.
[0054]
In this case, a sudden current does not flow to the light emitter, and the light emission from the light emitter also includes a part of the sine wave, or the periodic waveform changes almost like a sine wave. Can be reliably reduced or reduced. As a result, electromagnetic radiation that causes danger to the human body is greatly reduced, and the problem of electromagnetic interference can be overcome.
[0055]
Moreover, there is a period in which the light emission of the light emitter periodically decreases due to the drive signal applied to the light emitter. When the liquid crystal display device adopts such a light emitting device driving method, only a moment with a high contrast ratio remains as an afterimage for the viewer, and it appears as a clear screen with a good contrast ratio. The quality can be made extremely good.
[0056]
The periodic waveform is not limited to a sine wave, and even if it is a triangular wave, the same effect as described above is achieved. Alternatively, the periodic waveform may be generally a repetition of a Gaussian distribution waveform. Or even if the said periodic waveform is a repetition of a Lorentz distribution waveform, there exists an effect | action similar to the above.
[0057]
DETAILED DESCRIPTION OF THE INVENTION
Of the present invention For reference The form will be described with reference to FIGS. 1 to 3 as follows.
[0058]
As shown in FIG. 1, the liquid crystal display device (active matrix type liquid crystal display device) according to this embodiment mainly includes an inverter control circuit 1, an inverter 2, a cold cathode tube 3 (light emitter), a liquid crystal panel control circuit 4, And the liquid crystal panel 5.
[0059]
The inverter control circuit 1 receives the vertical synchronization signal output from the liquid crystal panel control circuit 4 and outputs an inverter drive signal for driving the inverter 2 to the inverter 2. A high voltage whose frequency changes according to the inverter drive signal is applied from the inverter 2 to the cold cathode tube 3 (white cold cathode tube). When a high voltage is applied to the cold cathode tube 3, light is emitted from the cold cathode tube 3 and applied to the liquid crystal panel 5.
[0060]
When the video signal is input, the liquid crystal panel control circuit 4 separates the synchronization signal, and the vertical synchronization signal is sent to the inverter control circuit 1 as described above. Further, based on the video signal, a gate driver 5a and a source driver 5b for driving a scanning line and a signal line (both not shown) are driven to select a desired pixel (not shown), and the cold cathode tube 3 is selected. The light emitted from the light passes through the selected pixel and the video signal is displayed.
[0061]
Here, the case where the main part signals (vertical synchronization signal, inverter input signal (inverter drive signal), inverter output signal, light emission waveform) of the liquid crystal display device are as shown in FIG. 2 will be described.
[0062]
In this case, by providing a light extinction period for each frame, only the moment with a high contrast ratio remains as an afterimage for the viewer, so that it appears as a clear screen with a good contrast ratio, and particularly the display quality of high-speed moving images is improved. .
[0063]
However, when the inverter output signal has a rectangular waveform as shown in FIG. 2, high-frequency electromagnetic radiation is observed, and there is a concern about the influence on the human body. Moreover, when a high voltage of a rectangular wave is applied to the cold cathode tube 3, a rapid current flows to the cold cathode tube 3 at the rise of light emission (luminance), and the current to the cold cathode tube 3 abruptly at the fall of light emission. The reverse current may flow to the cold cathode tube 3, and the behavior of such current significantly reduces the durability life of the cold cathode tube 3.
[0064]
Therefore, according to this embodiment, as shown in FIG. 3, the inverter control circuit 1 blunts the rise and fall of the waveform of the inverter input signal (inverter drive signal). In response to this, the waveform of the inverter output signal applied from the inverter 2 to the cold cathode tube 3 also slows down.
[0065]
As described above, when a high voltage whose rise and fall is blunt is applied to the cold cathode tube 3, the rise and fall of the light emitted from the cold cathode tube 3 is similarly blunted. That is, when an inverter output signal as shown in FIG. 3 is applied to the cold cathode tube 3, the rise of light emission slows down, so that an abrupt current does not flow to the cold cathode tube 3, and at the fall of light emission, Since the fall is dull, the current to the cold cathode tube 3 is not suddenly interrupted, and it is possible to avoid the reverse current flowing to the cold cathode tube 3. Therefore, such a behavior of current prevents the endurance life of the cold-cathode tube 3 from significantly decreasing in advance.
[0066]
Further, since the rise and fall of the inverter output signal applied to the cold cathode tube 3 is dull, the harmonic components can be reduced / mitigated, thereby greatly reducing electromagnetic radiation that poses a danger to the human body, Can overcome the problem of electromagnetic interference.
[0067]
Moreover, by providing a fixed period in which the brightness of the cold cathode tube 3 is reduced for each frame, only a moment with a high contrast ratio remains as an afterimage for the viewer, so that it looks as a clear screen with a good contrast ratio, Thereby, in particular, the display quality of the high-speed moving image becomes extremely good.
[0068]
Here, other according to the present invention reference Will be described with reference to FIG. According to this embodiment, in the liquid crystal display device of FIG. 1, the inverter control circuit 1 is configured such that the rising edge and the falling edge of the waveform of the inverter input signal (inverter driving signal) are part of a sine wave, as shown in FIG. 4. Dulled to become. In response to this, the waveform of the inverter output signal applied from the inverter 2 to the cold cathode tube 3 is also blunted so that the rising and falling edges become a part of the sine wave.
[0069]
In this way, when a high voltage blunted so that the rise and fall become a part of a sine wave is applied to the cold cathode tube 3, the light emitted from the cold cathode tube 3 is also the same. The rise and fall are dulled to become part of the sine wave. That is, when an inverter output signal as shown in FIG. 4 is applied to the cold cathode tube 3, an abrupt current does not flow to the cold cathode tube 3, and the current to the cold cathode tube 3 is reduced when light emission falls. It is possible to prevent the reverse current from flowing through the cold cathode tube 3 without being suddenly interrupted. Therefore, such a behavior of current prevents the endurance life of the cold-cathode tube 3 from significantly decreasing in advance.
[0070]
In addition, the inverter output signal applied to the cold cathode tube 3 is dull so that the rise and fall become a part of a sine wave, so that harmonic components can be reduced / reduced, which is dangerous to the human body. Electromagnetic radiation that exerts a large decrease can overcome the problem of electromagnetic interference.
[0071]
Moreover, by providing a fixed period in which the brightness of the cold cathode tube 3 is reduced for each frame, only a moment with a high contrast ratio remains as an afterimage for the viewer, so that it looks as a clear screen with a good contrast ratio, Thereby, in particular, the display quality of the high-speed moving image becomes extremely good.
[0072]
Next, yet another aspect of the present invention reference Will be described with reference to FIGS. 5 and 6. FIG. According to this embodiment, in the liquid crystal display device of FIG. 1, the inverter 2 receives the drive waveform output from the inverter control circuit 1 and applies a predetermined high-frequency high-voltage waveform to the cold cathode tube 3.
[0073]
Here, the case where the main part signals (vertical synchronization signal, inverter input signal (inverter drive signal), inverter output signal, light emission waveform) of the liquid crystal display device are as shown in FIG. 5 will be described.
[0074]
Thus, by providing the extinguishing period for each frame, the display quality of high-speed moving images is particularly improved. However, at this time, electromagnetic wave radiation of harmonics of the inverter drive signal is observed, and there is a concern about the influence on the human body. In addition, the endurance life is significantly reduced compared to when the cold cathode tubes are continuously lit.
[0075]
Therefore, as shown in FIG. 6, the inverter control circuit 1 causes the rise and fall of the waveform of the inverter input signal (inverter drive signal) so that the rise and fall of the envelope of the waveform of the inverter output signal are dull. Dulled.
[0076]
In order to dull the waveform, the drive signal line of the inverter control circuit 1 is grounded via a capacitor (not shown). A capacitor having a capacitance of 1 μF was selected. As a result, a circuit time constant based on the inverter input resistance and the capacitance of the capacitor is formed, and the inverter input signal which is a rectangular wave can be dulled with a time constant of about 1 ms to 2 ms.
[0077]
The same result was obtained even when the capacitor was provided in the inverter 2. However, when the cold-cathode tube is driven by high-frequency alternating current as described later, it is better to insert the capacitor before the inverter 2 generates the high-frequency alternating current waveform.
[0078]
In this way, when a high frequency high voltage with a slow rise and fall of the envelope is applied to the cold cathode tube 3, the light emitted from the cold cathode tube 3 similarly rises and rises of the envelope. The fall is dull. That is, when an inverter output signal as shown in FIG. 6 is applied to the cold cathode tube 3, an abrupt current does not flow to the cold cathode tube 3, and the current to the cold cathode tube 3 falls when the emission waveform falls. Can be prevented from being cut off suddenly and the reverse current flowing into the cold cathode tube 3 can be avoided. Therefore, such a behavior of current prevents the endurance life of the cold-cathode tube 3 from significantly decreasing in advance.
[0079]
Further, since the rise and fall of the envelope of the inverter output signal applied to the cold-cathode tube 3 is dull, the harmonic components can be reduced / reduced, and as a result, the electromagnetic radiation that causes danger to the human body is greatly increased. It can be reduced and the problem of electromagnetic interference can be overcome.
[0080]
Moreover, by providing a fixed period in which the brightness of the cold cathode tube 3 is reduced for each frame, only a moment with a high contrast ratio remains as an afterimage for the viewer, so that it looks as a clear screen with a good contrast ratio, Thereby, in particular, the display quality of the high-speed moving image becomes extremely good.
[0081]
Here, an embodiment according to the present invention will be described with reference to FIG. According to this embodiment, in the liquid crystal display device of FIG. 1, the inverter 2 receives the drive waveform output from the inverter control circuit 1 and applies a predetermined high-frequency high-voltage waveform to the cold cathode tube 3. As shown in FIG. 7, the inverter control circuit 1 is configured such that the waveform of the inverter input signal (inverter drive signal) is a sine wave whose frequency matches the frame frequency. Accordingly, the rising and falling edges of the waveform of the inverter output signal applied from the inverter 2 to the cold cathode tube 3 are sine waves whose frequency matches the frame frequency. In the present embodiment, the inverter control circuit 1 includes a sine wave generation circuit to realize the sine wave. However, the present invention is not limited to this, and for example, the above-described sine wave is generated. A sine wave generating circuit may be provided in the inverter 2, and the same result was obtained in this case.
[0082]
Thus, the rise and fall of the envelope becomes a sine wave whose frequency matches the frame frequency, and when this high frequency high voltage is applied to the cold cathode tube 3, the light emitted from the cold cathode tube 3. Similarly, the envelope rises and falls into a sine wave whose frequency matches the frame frequency. That is, when an inverter output signal as shown in FIG. 7 is applied to the cold cathode tube 3, the rising edge of the envelope of the light emission waveform becomes a sine wave, so that a sudden current does not flow to the cold cathode tube 3. When the emission waveform falls, since the fall becomes a sine wave, the current to the cold cathode tube 3 is not suddenly interrupted, and it is possible to avoid the reverse current from flowing to the cold cathode tube 3. Therefore, such a behavior of current prevents the endurance life of the cold-cathode tube 3 from significantly decreasing in advance.
[0083]
Further, in the inverter output signal applied to the cold cathode tube 3, the rise and fall of the envelope is a sine wave whose frequency matches the frame frequency, so that the harmonic component can be reduced / relieved, As a result, electromagnetic radiation that causes danger to the human body is greatly reduced, and the problem of electromagnetic interference can be overcome.
[0084]
Moreover, by providing a fixed period in which the brightness of the cold cathode tube 3 is reduced for each frame, only a moment with a high contrast ratio remains as an afterimage for the viewer, so that it looks as a clear screen with a good contrast ratio, Thereby, in particular, the display quality of the high-speed moving image becomes extremely good.
[0085]
In the above embodiment, the case where the rise and fall of the envelope of the waveform of the inverter output signal is a sine wave whose frequency matches the frame frequency has been described, but the present invention is not limited to this. Alternatively, a configuration in which a sine wave having a frequency that matches the frame frequency itself may be applied to the cold cathode tube 3, and even in this configuration, it is needless to say that the same operations and effects as described above are achieved.
[0086]
In the above embodiment, the sine wave has been described. However, the present invention is not limited to this, and the same result can be obtained by using a waveform having a similar shape such as a triangular wave in addition to the sine wave. It was.
[0087]
The response time of light emission (rise) and quenching (fall) of the cold cathode tube in FIG. 2 was selected to be extremely fast (response time of 1 ms or less). Adjustment of the response time is achieved by selecting a phosphor to be enclosed in the cold cathode tube.
[0088]
Therefore, depending on the type of phosphor encapsulated in the cold cathode fluorescent lamp, there are cases where the response time is several ms to tens of ms. However, the response time of the light emission phenomenon is determined by the waveform of the inverter output signal regardless of the current phenomenon in the cold cathode tube. Therefore, even when a phosphor with a slow response time was enclosed, the effect of the present invention could be confirmed.
[0089]
Here, another embodiment according to the present invention will be described with reference to FIG. According to this embodiment, in the liquid crystal display device of FIG. 1, the inverter 2 receives the drive waveform output from the inverter control circuit 1 and applies a predetermined high-frequency high-voltage waveform to the cold cathode tube 3. As shown in FIG. 8, the inverter control circuit 1 is configured such that the waveform of the inverter input signal (inverter drive signal) has a Gaussian distribution waveform whose repetition cycle matches the reciprocal of the frame frequency. In response to this, the envelope of the waveform of the inverter output signal applied from the inverter 2 to the cold-cathode tube 3 also has a Gaussian distribution waveform whose repetition period matches the reciprocal of the frame frequency.
[0090]
Thus, when a high-frequency high voltage having a Gaussian distribution waveform in which the repetition period of the envelope coincides with the reciprocal of the frame frequency is applied to the cold-cathode tube 3, the light emitted from the cold-cathode tube 3 is similarly The repetition cycle of the envelope becomes a Gaussian distribution waveform with the reciprocal of the frame frequency. That is, when an inverter output signal as shown in FIG. 8 is applied to the cold cathode tube 3, the repetition cycle of the envelope of the light emission waveform has a Gaussian distribution waveform that matches the reciprocal of the frame frequency. The current does not flow to the cathode tube 3 and the current to the cold cathode tube 3 is not suddenly interrupted, so that it is possible to avoid the reverse current from flowing to the cold cathode tube 3. Therefore, such a behavior of current prevents the endurance life of the cold-cathode tube 3 from significantly decreasing in advance.
[0091]
Further, in the inverter output signal applied to the cold cathode tube 3, since the repetition period of the envelope is a Gaussian distribution waveform that matches the reciprocal of the frame frequency, the harmonic component can be reduced / reduced, thereby Electromagnetic radiation that poses a danger to the environment is greatly reduced and the problem of electromagnetic interference can be overcome.
[0092]
Moreover, by providing a fixed period in which the brightness of the cold cathode tube 3 is reduced for each frame, only a moment with a high contrast ratio remains as an afterimage for the viewer, so that it looks as a clear screen with a good contrast ratio, Thereby, in particular, the display quality of the high-speed moving image becomes extremely good.
[0093]
In the above embodiment, the case where the repetition cycle of the envelope of the inverter output signal has a Gaussian distribution waveform that matches the reciprocal of the frame frequency has been described, but the present invention is not limited to this, and the repetition cycle is A configuration in which a Gaussian distribution waveform itself that matches the reciprocal of the frame frequency may be applied to the cold-cathode tube 3. Even in this configuration, it is needless to say that the same operations and effects as described above are achieved.
[0094]
In the above embodiment, the Gaussian distribution waveform has been described. However, the present invention is not limited to this, and a similar result was obtained using a Lorentz distribution waveform in addition to the Gaussian distribution waveform. .
[0095]
In each of the above embodiments, a liquid crystal display device having a single light emitter has been described. However, the present invention is not limited to this, and has a plurality of light emitting regions in the scanning direction. The present invention can also be applied to the case where the light emitting area is synchronized with the vertical synchronizing signal of the liquid crystal display device, and the respective light emitters are sequentially scanned and lighted while applying the voltage waveform as in the above embodiment.
[0096]
In each of the above embodiments, the case where a cold cathode tube is used as a light emitter has been described. However, the present invention is not limited to this, and a light emitting diode, an electroluminescent element, a hot cathode tube, a mercury lamp. It can also be applied to the case of using a light emitter such as a halogen lamp or a laser.
[0097]
In the embodiment according to the present invention, description has been made on the premise of the video signal of the interlace drive system, but the present invention is not limited to this. For example, it can be realized even in the case of a video signal of a non-interlace drive system. In the case of the interlace driving method, one field corresponds to one vertical period, whereas in the non-interlace driving method, one frame corresponds to one vertical period.
[0098]
As described above, the first liquid crystal display device of the present invention includes the illumination device, and is characterized in that a certain period in which the luminance of the illumination device is reduced is provided for each frame.
[0099]
According to the second liquid crystal display device of the present invention, in the first liquid crystal display device, when the luminance of the lighting device is increased, the voltage applied to the light emitter of the lighting device is prevented so that the current flowing through the light emitter does not increase rapidly. It is characterized by adjusting the waveform.
[0100]
The third liquid crystal display device of the present invention is characterized in that, in the first liquid crystal display device, when the luminance of the lighting device is increased, the rising waveform of the voltage waveform applied to the light emitter of the lighting device is blunted. .
[0101]
According to the fourth liquid crystal display device of the present invention, in the first liquid crystal display device, when the luminance of the lighting device is increased, the rising waveform of the envelope of the voltage waveform applied to the light emitter of the lighting device is blunted. It is a feature.
[0102]
According to the fifth liquid crystal display device of the present invention, in the first liquid crystal display device, when the luminance of the lighting device is reduced, the current flowing through the light emitter does not rapidly decrease or a large reverse current does not flow through the light emitter. As described above, the voltage waveform applied to the light emitter of the lighting device is adjusted.
[0103]
The sixth liquid crystal display device of the present invention is characterized in that, in the first liquid crystal display device, the falling waveform of the voltage waveform applied to the light emitter of the lighting device is blunted when the luminance of the lighting device is reduced. Yes.
[0104]
In the seventh liquid crystal display device of the present invention, in the first liquid crystal display device, when the luminance of the lighting device is reduced, the falling waveform of the envelope of the voltage waveform applied to the light emitter of the lighting device is blunted. It is characterized by.
[0105]
In the eighth liquid crystal display device of the present invention, in the first liquid crystal display device, when the luminance of the lighting device is increased, the rising waveform of the voltage waveform applied to the light emitter of the lighting device is generally a part of the sine wave. It is characterized by that.
[0106]
According to the ninth liquid crystal display device of the present invention, in the first liquid crystal display device, when the luminance of the illumination device is increased, the rising waveform of the envelope of the voltage waveform applied to the light emitter of the illumination device is approximately one sine wave. It is characterized by being part.
[0107]
According to the tenth liquid crystal display device of the present invention, in the first liquid crystal display device, when the luminance of the lighting device is reduced, the falling waveform of the voltage waveform applied to the light emitter of the lighting device is approximately a part of the sine wave. It is characterized by that.
[0108]
In the eleventh liquid crystal display device of the present invention, in the first liquid crystal display device, when the luminance of the lighting device is reduced, the falling waveform of the envelope of the voltage waveform applied to the light emitter of the lighting device is generally a sine wave. It is characterized by being part.
[0109]
As described above, the twelfth liquid crystal display device of the present invention includes the illumination device, and the voltage waveform applied to the light emitter of the illumination device is a sine wave whose frequency is approximately equal to the inverse of the vertical period. Yes.
[0110]
As described above, the thirteenth liquid crystal display device of the present invention is characterized in that the envelope of the voltage waveform applied to the light emitter of the illuminating device is a sine wave whose frequency roughly matches the reciprocal of the vertical period.
[0111]
As described above, the fourteenth liquid crystal display device of the present invention is characterized in that the voltage waveform applied to the illuminator of the lighting device is such that a Gaussian distribution waveform whose repetition period substantially matches the reciprocal of the frame frequency is repeated. .
[0112]
As described above, the fifteenth liquid crystal display device of the present invention includes a lighting device, and has a Gaussian distribution waveform in which the repetition period of the envelope of the voltage waveform applied to the light emitter of the lighting device generally matches the reciprocal of the frame frequency. It is characterized by being repeated.
[0113]
As described above, the sixteenth liquid crystal display device of the present invention includes the illumination device, and the voltage waveform applied to the light emitter of the illumination device is such that the Lorentz distribution waveform in which the repetition period roughly matches the reciprocal of the frame frequency is repeated. It is characterized by that.
[0114]
As described above, the seventeenth liquid crystal display device of the present invention includes a lighting device, and has a Lorentz distribution waveform in which the repetition period of the envelope of the voltage waveform applied to the light emitter of the lighting device is approximately equal to the reciprocal of the frame frequency. It is characterized by being repeated.
[0115]
As described above, the eighteenth liquid crystal display device of the present invention includes the illumination device, and is characterized in that the voltage waveform applied to the light emitter of the illumination device is a triangular wave whose frequency substantially matches the reciprocal of the vertical period.
[0116]
As described above, the nineteenth liquid crystal display device of the present invention includes the illumination device, and the envelope of the voltage waveform applied to the light emitter of the illumination device is a triangular wave whose frequency roughly matches the reciprocal of the vertical period. It is said.
[0117]
According to a twentieth liquid crystal display device of the present invention, in the first, twelfth to nineteenth liquid crystal display devices, a cold cathode tube, a light emitting diode element, an electroluminescence element, a hot cathode tube, a mercury lamp, A halogen lamp or a laser is used.
[0118]
According to the first to twentieth liquid crystal display devices, there is provided a liquid crystal display device having good display quality in high-speed moving images while suppressing a decrease in the durability life of the light emitter of the illumination unit and reducing electromagnetic interference. it can.
[0119]
【The invention's effect】
As described above, the liquid crystal display device of the present invention is a liquid crystal display device including a light emitter that irradiates a pixel with light according to a drive signal. It is characterized by having a light emission control means for controlling the drive signal so as to make the falling edge dull.
[0120]
According to the above invention, the light emitted from the light emitter is changed according to the drive signal, and is emitted to the pixels to display desired information. At this time, the drive signal is controlled by the light emission control means so as to blunt the rise and fall of the light emission waveform of the light emitter every vertical period. In this way, since the drive signal is controlled so that the light emission waveform of the light emitter is dull near the rising edge, no sudden current flows through the light emitter, and similarly, the light emitting body is also near the falling edge of the light emitting waveform. Therefore, it is possible to prevent the reverse current from flowing through the light emitter. Therefore, it is possible to reliably and surely prevent the durability life of the luminous body from being significantly reduced by such current behavior.
[0121]
Further, since the drive signal applied to the light emitter is controlled so that the light emission waveform of the light emitter is dull in the vicinity of the rise and fall, the harmonic component can be reliably reduced / reduced. As a result, electromagnetic radiation that causes danger to the human body is greatly reduced, and the problem of electromagnetic interference can be overcome.
[0122]
Moreover, the drive signal applied to the light emitter has a period in which the light emission of the light emitter is reduced every vertical period, and for the viewer, only a moment with a high contrast ratio remains as an afterimage, and the contrast signal has a good contrast ratio. As a result, the high-speed moving image display quality can be particularly improved.
[0123]
In the liquid crystal display device, the light emission control means blunts the rise and fall of the waveform of the drive signal applied to the light emitter, and gradually increases the light emission of the light emitter near the rise, Moreover, it is preferable to reduce gradually near the fall.
[0124]
In this case, since the rise and fall of the waveform of the drive signal is dull, as described above, it is possible to lengthen the durable life of the light emitter, to reduce and mitigate electromagnetic interference that causes harmonic components to be dangerous to the human body, and The display quality of high-speed moving images can be made extremely good.
[0125]
The light emission control means blunts the rise and fall of the envelope of the waveform of the drive signal applied to the light emitter, and gradually increases the light emission of the light emitter near the rise and falls. It may be gradually reduced in the vicinity.
[0126]
The light emission control means may generally make the rise and fall of the waveform of the drive signal part of a sine wave.
[0127]
The light emission control means may generally make the rise and fall of the envelope of the waveform of the drive signal part of a sine wave.
[0128]
In another liquid crystal display device of the present invention, in the liquid crystal display device including a light emitter that irradiates the pixel with light according to the drive signal, the drive signal is set so that the frequency becomes a sine wave substantially matching the reciprocal of the vertical period. It is characterized by having a light emission control means for controlling the above.
[0129]
According to the above invention, the light emitted from the light emitter is changed according to the drive signal, and is emitted to the pixels to display desired information. At this time, the drive signal is controlled by the light emission control means so that the frequency becomes a sine wave whose frequency substantially coincides with the reciprocal of the vertical period. In this way, since the drive signal is controlled so that the frequency becomes a sine wave that substantially matches the reciprocal of the vertical period (since it is not a rectangular wave as in the past), no sudden current flows through the light emitter. Similarly, the light emission from the light emitter also changes so that the frequency becomes a sine wave that roughly matches the reciprocal of the vertical period. Therefore, a sudden current does not flow through the light emitter, a current with respect to the light emitter is not suddenly interrupted, or a reverse current does not flow through the light emitter. By such a current behavior, it is possible to surely and reliably avoid a significant decrease in the durable life of the light emitter.
[0130]
In addition, since the drive signal applied to the light emitter is controlled to be a sine wave whose frequency substantially matches the reciprocal of the vertical period, the harmonic component can be reliably reduced / reduced. As a result, electromagnetic radiation that causes danger to the human body is greatly reduced, and the problem of electromagnetic interference can be overcome.
[0131]
In addition, there is a period in which light emission of the light emitter is reduced every vertical period due to the drive signal applied to the light emitter, and for the viewer, only the moment with a high contrast ratio remains as an afterimage, and the contrast ratio is good. It appears as a clear screen, and this also brings about the effect that the display quality of high-speed moving images can be made extremely good.
[0132]
The drive signal may be controlled so that the frequency of the envelope is a sine wave that roughly matches the reciprocal of the vertical period.
[0133]
The drive signal may be controlled so as to have a Gaussian distribution waveform in which the repetition period substantially coincides with the vertical period.
[0134]
The drive signal may be controlled so as to have a Gaussian distribution waveform in which the repetition period of the envelope generally matches the vertical period.
[0135]
The drive signal may be controlled so as to have a Lorentz distribution waveform in which the repetition period substantially coincides with the vertical period.
[0136]
The drive signal may be controlled so as to have a Lorentz distribution waveform in which the repetition period of the envelope substantially matches the vertical period.
[0137]
The drive signal may be controlled such that the frequency is a triangular wave that substantially matches the reciprocal of the vertical period.
[0138]
The drive signal may be controlled so that the frequency of the envelope is a triangular wave that roughly matches the reciprocal of the vertical period.
[0139]
As the light emitter, it is preferable to use a cold cathode tube, a light emitting diode element, an electroluminescence element, a hot cathode tube, a mercury lamp, a halogen lamp, or a laser.
[0140]
In order to solve the above-described problem, the light emitter driving method of the present invention is characterized in that the rise and fall of the drive signal of the light emitter included in the liquid crystal display device are blunted.
[0141]
According to said invention, the light emitted from the light-emitting body with which a liquid crystal display device is provided changes according to a drive signal. At this time, the rise and fall of the drive signal are blunted. As described above, when the driving signal of the light emitter is dulled in the vicinity of the rising edge, a sudden current does not flow to the light emitter. In addition, when the driving signal of the light emitter is dulled near the falling edge, similarly, the current to the light emitter is not cut off suddenly, and the reverse current can be prevented from flowing to the light emitter. Therefore, it is possible to reliably and surely prevent the durability life of the luminous body from being significantly reduced by such current behavior.
[0142]
Further, since the light emission waveform of the light emitter is dull in the vicinity of the rise and fall of the drive signal applied to the light emitter, the harmonic components can be reliably reduced / reduced. As a result, electromagnetic radiation that causes danger to the human body is greatly reduced, and the problem of electromagnetic interference can be overcome.
[0143]
In addition, the drive signal applied to the light emitter has a period in which the light emission of the light emitter is reduced. Thereby, in particular, there is an effect that the display quality of the high-speed moving image can be made extremely good.
[0144]
The same effect can be obtained by dulling the rise and fall of the envelope of the drive signal instead of the drive signal.
[0145]
In order to blunt the waveform of the drive signal, the drive signal line related to the drive signal is preferably grounded via a capacitor. In this case, an integrating circuit is formed by the resistance of the drive signal line and the capacitor. This integration circuit also has an effect that the drive signal which is a rectangular wave can be blunted according to the time constant.
[0146]
The same effect can be obtained by using a periodic waveform obtained by synchronizing the drive signal of the light emitter included in the liquid crystal display device with the vertical synchronization signal instead of the drive signal.
[0147]
Alternatively, the same effect can be obtained even when the envelope of the drive signal of the light emitter provided in the liquid crystal display device is a periodic waveform synchronized with the vertical synchronization signal.
[0148]
The rising and falling edges of the periodic waveform preferably include a part of a sine wave. Alternatively, the periodic waveform may be approximately a sine wave.
[0149]
In this case, an abrupt current does not flow to the light emitter, and light emission from the light emitter also periodically changes in synchronization with the vertical synchronization signal. Therefore, a sudden current does not flow through the light emitter, a current with respect to the light emitter is not suddenly interrupted, or a reverse current does not flow through the light emitter. By such a current behavior, it is possible to surely and reliably avoid a significant decrease in the durable life of the light emitter.
[0150]
In particular, when the rising and falling edges of the periodic waveform include a part of a sine wave, or the periodic waveform is almost a sine wave, the harmonic component can be reliably reduced or reduced. As a result, electromagnetic radiation that causes danger to the human body is greatly reduced, and the problem of electromagnetic interference can be overcome.
[0151]
Moreover, there is a period in which the light emission of the light emitter periodically decreases due to the drive signal applied to the light emitter. When the liquid crystal display device adopts such a light emitting device driving method, only a moment with a high contrast ratio remains as an afterimage for the viewer, and it appears as a clear screen with a good contrast ratio. It also has the effect that the quality can be made extremely good.
[0152]
The periodic waveform is not limited to a sine wave, but may be a triangular wave. Alternatively, the periodic waveform may be generally a repetition of a Gaussian distribution waveform. Alternatively, the periodic waveform may be generally a repetition of a Lorentz distribution waveform.
[0153]
In order to solve the above-described problems, the light emitting body of the present invention is characterized in that a drive signal having a dull rise and fall is input.
[0154]
According to the invention described above, the light emitted from the light emitter changes according to the drive signal. At this time, a drive signal with a dull rise and fall is input to the light emitter. As described above, when the driving signal of the light emitter is dulled in the vicinity of the rising edge, a sudden current does not flow to the light emitter. In addition, when the driving signal of the light emitter is dulled near the falling edge, similarly, the current to the light emitter is not cut off suddenly, and the reverse current can be prevented from flowing to the light emitter. Therefore, it is possible to reliably and surely prevent the durability life of the luminous body from being significantly reduced by such current behavior.
[0155]
Further, since the light emission waveform of the light emitter is dull in the vicinity of the rise and fall of the drive signal applied to the light emitter, the harmonic components can be reliably reduced / reduced. As a result, electromagnetic radiation that causes danger to the human body is greatly reduced, and the problem of electromagnetic interference can be overcome.
[0156]
Moreover, the drive signal applied to the light emitter has a period in which the light emission of the light emitter is reduced. When such a light emitter is used in a liquid crystal display device, only a moment with a high contrast ratio remains as an afterimage for a viewer, and it appears as a clear screen with a good contrast ratio. The effect that it can be made favorable is also produced.
[0157]
It may be a light emitter that inputs a drive signal in which the rise and fall of the envelope are blunted. Or the light-emitting body which inputs the drive signal which has a periodic waveform synchronizing with the vertical synchronizing signal may be sufficient. Or the light-emitting body which inputs the drive signal which has a periodic waveform in which the envelope synchronized with the vertical synchronizing signal may be used.
[0158]
It is preferable that the rising and falling edges of the periodic waveform include a part of a sine wave. The periodic waveform may generally be a sine wave.
[0159]
In this case, a sudden current does not flow to the light emitter, and the light emission from the light emitter also includes a part of the sine wave, or the periodic waveform changes almost like a sine wave. Can be reliably reduced or reduced. As a result, electromagnetic radiation that causes danger to the human body is greatly reduced, and the problem of electromagnetic interference can be overcome.
[0160]
Moreover, there is a period in which the light emission of the light emitter periodically decreases due to the drive signal applied to the light emitter. When the liquid crystal display device adopts such a light emitting device driving method, only a moment with a high contrast ratio remains as an afterimage for the viewer, and it appears as a clear screen with a good contrast ratio. It also has the effect that the quality can be made extremely good.
[0161]
The periodic waveform is not limited to a sine wave, but may be a triangular wave. Alternatively, the periodic waveform may be generally a repetition of a Gaussian distribution waveform. Alternatively, the periodic waveform may be generally a repetition of a Lorentz distribution waveform.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing a configuration example of a liquid crystal display device of the present invention.
FIG. 2 is a waveform diagram showing an example of an applied signal waveform for explaining the operation of the liquid crystal display device.
FIG. 3 is a waveform diagram illustrating an example of an applied signal waveform for overcoming the problems caused by the signal waveform of FIG. 2;
4 is a waveform diagram showing another example of an applied signal waveform for overcoming the problems caused by the signal waveform of FIG. 2; FIG.
FIG. 5 is a waveform diagram showing another example of an applied signal waveform for explaining the operation of the liquid crystal display device.
6 is a waveform diagram showing an example of an applied signal waveform for overcoming the problems caused by the signal waveform of FIG.
7 is a waveform diagram showing another example of an applied signal waveform for overcoming the problems caused by the signal waveform of FIG.
FIG. 8 is a waveform diagram showing still another example of an applied signal waveform for overcoming the problems caused by the signal waveform of FIG. 5;
[Explanation of symbols]
1 Inverter control circuit (light emission control means)
2 Inverter
3 Cold cathode tube (light emitter)
4 LCD panel control circuit
5 LCD panel
5a Gate driver
5b Source driver

Claims (4)

In a liquid crystal display device including a light emitter that irradiates pixels with light corresponding to an inverter input signal , light emission for controlling the inverter input signal so that the frequency of the inverter input signal becomes a sine wave that matches the inverse of the vertical period A liquid crystal display device comprising control means. In the liquid crystal display device having a light emitter for emitting light in response to the inverter output signal to the pixel, the inverter output signal so that the sine wave frequency of the envelope of the inverter output signal matches the inverse of the vertical period A liquid crystal display device comprising light emission control means for controlling.   3. The liquid crystal display device according to claim 1, wherein the luminous body is a cold cathode tube, a light emitting diode element, an electroluminescence element, a hot cathode tube, a mercury lamp, a halogen lamp, or a laser.   4. The light emission control unit according to claim 1, wherein the light emission control unit controls the light emitter so that a certain period in which the luminance decreases for each frame is provided by the inverter input signal or the inverter output signal. The liquid crystal display device according to any one of the above.

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