JP2002014318A - Liquid crystal display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquid crystal display device with low power consumption and high reliability in which display irregularity is prevented. SOLUTION: In the liquid crystal display device, time-division driving is performed by switching as required between the whole display mode to display the whole display part of a liquid crystal display panel 20 and the partial screen display mode to display only a full-time display region 20a as a part of the display part. In the device, the driving conditions are controlled to satisfy at least one of the following conditions. (1) The set value of the asynchronous M signal in the partial screen display mode is smaller than the set value of the asynchronous M signal in the whole display mode. (2) The driving frequency in the partial screen display mode is set to be higher than the driving frequency in the whole display mode.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal which is incorporated in, for example, a cellular phone and performs time-division driving by switching between a full-screen display mode and a partial-screen display mode as required for low-voltage driving. The present invention relates to a display device.

[0002]

2. Description of the Related Art A liquid crystal display device is thin and light, and is therefore used for various uses including a display of a portable information terminal (such as a mobile phone). The liquid crystal is a light-receiving element that performs display by changing light transmission intensity without emitting light by itself, and can be driven with a low effective value voltage of about several volts. Therefore, in particular, when a reflection plate is provided below the liquid crystal and configured in the form of a reflection-type liquid crystal display device that performs display using reflected light of external light, a display device with extremely low power consumption is obtained.
Further, such a reflection type liquid crystal display device is driven in a time-division (multiplex) manner by STN (Super-Twisted Nemat).
ic) type liquid crystal display device not only simplifies the panel structure but also achieves low power consumption.
It is known that lower prices can be realized.

In other words, the liquid crystal display device which performs the above-described time-division driving has an active matrix type liquid crystal display device in which the effective value voltage during driving is high and the power consumption is large, and the number of electrodes and the number of drive circuit elements are large. Very low power consumption compared to a static drive type liquid crystal display device. Therefore, in particular, the use as a display device to be assembled in a portable device is attracting attention, lowering the effective value voltage at the time of driving,
Many attempts have been made to further reduce power consumption.

In order to reduce the power consumption of the liquid crystal display device, a method of lowering the driving voltage of the liquid crystal display panel (the peak value of the ON voltage applied to the liquid crystal) is generally performed. Attempts have been made to reduce power consumption not only on the liquid crystal display panel but also on the liquid crystal driver side. For example, in a STN-type liquid crystal display device to be assembled in a mobile phone or the like, a system (partial drive system) in which a driver application voltage is reduced during input standby by switching from a full screen display mode to a partial screen display mode in a standby state is adopted. (JP-A-6-149184, JP-A-1
0-207438).

For example, Japanese Patent Application Laid-Open No. 6-149184 discloses that a liquid crystal display device is miniaturized and reduced in cost by connecting to a high voltage power supply circuit in a full screen display mode and switching to a low voltage power supply circuit in a partial screen display mode. Is disclosed. On the other hand, JP-A-10-20743
No. 8 discloses driving conditions such as bias setting in partial driving. More specifically, the bias ratio is set so that the ratio between the effective value of the on-voltage and the effective value of the off-voltage is as large as possible within a range that the liquid crystal driver can withstand.

[0006]

In order to reduce the power consumption of the liquid crystal display device, a method of lowering the driving voltage of the liquid crystal display panel (liquid crystal panel) includes, for example, an attempt to increase the dielectric constant of the liquid crystal. Even being done day and night. However, as the dielectric constant of the liquid crystal increases, the amount of ionic impurities taken into the liquid crystal during the production process increases. Therefore, during continuous energization, display unevenness shown in FIG. Cause problems.

It is considered that the cause of the display unevenness is that ionic impurities contained in the liquid crystal are adsorbed on the alignment film and disturb the electric field in that region. Also, it is considered that the closer the applied voltage waveform to the liquid crystal is to the DC waveform, the more the electric field in the liquid crystal layer is applied in a certain direction, and the ionic impurities move in one direction and are more easily adsorbed on the alignment film.

For example, in a general partial drive type liquid crystal display device, in a partial screen display mode, a voltage is applied to only some of the driving electrodes, so that the duty number D, which is the reciprocal of the duty ratio, decreases. . At this time, if other driving conditions such as the driving frequency (ie, the frequency of the driving voltage applied to the liquid crystal) and the set value of the asynchronous M signal are set the same as in the full display mode, the application to the liquid crystal is performed. The minimum frequency of the voltage waveform is smaller than in the full display mode. As a result, the DC component in the applied voltage increases,
There is a problem that the reliability at the time of energization is deteriorated (for example, the display unevenness is generated).

[0009] In the above-mentioned JP-A-6-149184 and JP-A-10-207438, for example,
It does not describe details of driving conditions for eliminating deterioration in reliability at the time of energization, such as setting of a driving frequency and an asynchronous M signal in the full screen display mode and the partial screen display mode.

The present invention has been made in view of the above-mentioned conventional problems, and has as its object to provide a highly reliable liquid crystal display which has low power consumption and prevents display unevenness in a partial screen display mode. It is to provide a device.

[0011]

Means for Solving the Problems The present inventors have intensively studied the mechanism of display unevenness in a partial drive type liquid crystal display device, particularly in a partial screen display mode. As a result, in a general partial drive type liquid crystal display device, the duty ratio D, which is the reciprocal of the duty ratio, decreases in the partial screen display mode compared with the full screen display mode. If the applied drive voltage frequency f and the set value M ₁ of the asynchronous M signal are set to the same conditions as in the full-screen display mode, the applied voltage waveform (the voltage applied to the liquid crystal) in the partial screen display mode Frequency) (D × f / M ₁ ) greatly decreases from the minimum frequency of the applied voltage waveform in the full-screen display mode, the DC component in the applied voltage increases, and the reliability during energization is deteriorated. I found something to do. Then, in the entire screen display mode and a partial screen display mode, by at least one different value of the set value M ₁ of the driving frequency or asynchronous M signal, an increase in the DC component is suppressed, the reliability of energization It has been found that the deterioration of can be solved, and the present invention has been completed.

The above-mentioned asynchronous M signal is applied to the liquid crystal asynchronously with the scanning start signal for the purpose of increasing the ratio of the AC component in the voltage waveform applied to the liquid crystal and reducing display unevenness that occurs during energization. (Also referred to as an AC signal) (refer to correspondence education liquid crystal display system introductory course No. 3 driving a liquid crystal display (1) p. 73-(Nikkan Kogyo Shimbun)). In general, the inversion of the polarity of the applied voltage waveform is roughly classified into line inversion in which the inversion is performed for each line and frame inversion in which the inversion is performed for each frame.
₁ is a value that determines how many lines the polarity is inverted. For example, M ₁ = ₁ cp indicates line inversion, and M ₁ = D (duty number) c
p indicates frame inversion. The driving frequency, which is the frequency of the driving voltage of the liquid crystal, usually indicates フ レ ー ム of the frame frequency.

In order to solve the above-mentioned problems, a liquid crystal display device according to the present invention has a full-screen display mode for displaying the entire display unit of a liquid crystal display panel and a partial screen display mode for displaying only a part of the display unit. In the liquid crystal display device that performs time-division driving by switching between as necessary, the set value of the asynchronous M signal in the partial screen display mode is set to a value smaller than the set value of the asynchronous M signal in the full screen display mode. It is characterized by having.

According to the above configuration, the set value of the asynchronous M signal in the partial screen display mode is set to a value smaller than the set value of the asynchronous M signal in the full screen display mode. Therefore, like the conventional partial drive type liquid crystal display device,
As compared with the state where the drive frequency f and the set value M ₁ of the asynchronous M signal are set under the same conditions as in the full screen display mode, the minimum frequency of the applied voltage waveform in the partial screen display mode is increased, The DC component at is reduced. As a result, it is possible to provide a highly reliable liquid crystal display device that has low power consumption and prevents display unevenness in the partial screen display mode.

In order to solve the above-mentioned problems, the liquid crystal display device according to the present invention has a full screen display mode for displaying the entire display section of the liquid crystal display panel, and a partial screen display for displaying only a part of the display section. In a liquid crystal display device that performs time-division driving by switching between modes as needed, the drive frequency in the partial screen display mode is set to be higher than the drive frequency in the full-screen display mode.

According to the above configuration, the drive frequency in the partial screen display mode is set to a value larger than the drive frequency in the full screen display mode. Therefore, as in the conventional partial driving type liquid crystal display device, the set value M ₁ of the drive frequency f and the asynchronous signal M as compared to the state of being set to the same conditions as under entire screen display mode, partial screen display mode The minimum frequency of the lower applied voltage waveform increases, and the DC component in the applied voltage decreases. As a result, it is possible to provide a highly reliable liquid crystal display device that has low power consumption and prevents display unevenness in the partial screen display mode.

In order to solve the above-mentioned problems, the liquid crystal display device according to the present invention further comprises a full-screen mode for displaying the entire display section of the liquid crystal display panel and a partial screen display for displaying only a part of the display section. In the liquid crystal display device which performs the time-division driving by switching between the modes as needed, the set value of the asynchronous M signal in the partial screen display mode is
The drive frequency in the partial screen display mode is set to be higher than the drive frequency in the full screen display mode, while being set to a value smaller than the set value of the asynchronous M signal in the full screen display mode.

According to the above configuration, the set value of the asynchronous M signal in the partial screen display mode is set to a value smaller than that under the full screen display mode, and the drive frequency in the partial screen display mode is set to The value is set to a value larger than the drive frequency in the mode. Therefore, like the conventional partial drive type liquid crystal display device,
As compared with the state where the drive frequency f and the set value M ₁ of the asynchronous M signal are set under the same conditions as in the full screen display mode, the minimum frequency of the applied voltage waveform in the partial screen display mode is increased, The DC component at is reduced. As a result, it is possible to provide a highly reliable liquid crystal display device that has low power consumption and prevents display unevenness in the partial screen display mode.

The liquid crystal display device according to the present invention also may, subject to any of the configurations described above, the inverse of the duty ratio D, and the driving frequency f, and set values of the asynchronous M signal is taken as M _1, f ( min) = D × f / M ₁ ,
The minimum frequency f (min) of the voltage waveform applied to the liquid crystal may be set to a value substantially equal to or higher than the value in the full screen display mode in the partial screen display mode.

According to the above configuration, the frequency of the minimum frequency component in the AC applied voltage in the partial screen display mode is
It is almost equal to or higher than the frequency of the minimum frequency component in the AC applied voltage in the full screen display mode, and the ratio of the DC component in the applied voltage in the partial screen display mode is
Compared with the case of the full screen display mode, it is reduced to the same or less. As a result, it is possible to provide a highly reliable liquid crystal display device in which display unevenness in the partial screen display mode is almost completely prevented.

It is more preferable that the minimum frequency of the applied voltage waveform in the partial screen display mode and the minimum frequency of the applied voltage waveform in the full screen display mode are set substantially equal. This is because the power consumption of the liquid crystal display device increases as the minimum frequency of the applied voltage waveform increases.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [Embodiment 1] The following will describe one embodiment of a liquid crystal display device of the present invention with reference to FIGS.

As shown in FIG. 2, the liquid crystal display panel provided in the liquid crystal display device according to the present embodiment includes a polarizing plate 1 and a phase difference plate (upper phase difference plate) from the observer side (upper side of FIG. 2).
2, a phase difference plate (lower phase difference plate) 3, a substrate (first substrate) 4 made of a transparent material such as glass, a liquid crystal layer 5, a color filter 6, a reflection plate 7, and a transparent material such as glass. (Second substrate) 8 are arranged in this order. A signal electrode (matrix electrode) 9 made of a transparent conductive material such as ITO (indium tin oxide) and a scanning electrode (matrix electrode) 10 are arranged in a matrix so as to face each other with the liquid crystal layer 5 interposed therebetween. Have been.

As the polarizing plate 1, for example, a high transmission and high polarization degree polarizing plate manufactured by Nitto Denko Corporation is used. For example, a retardation film made of polycarbonate is used for the retardation plates 2 and 3, and the retardation of the retardation plate 2 is set to 665 nm for light having a wavelength of 550 nm. Was set to 170 nm for light having a wavelength of 550 nm.

The two alignment films (not shown) provided so as to sandwich the liquid crystal layer 5 are for aligning the liquid crystal layer 5, and their surfaces on the liquid crystal layer 5 side are oriented in a predetermined direction. The rubbing process is performed along. The liquid crystal layer 5 has, for example, a twist angle of 240 ° (that is, an angle formed by rubbing axes of two alignment films), a dielectric anisotropy of 14.2,
A high dielectric constant STN (super twisted nematic) liquid crystal having a refractive index anisotropy (Δn) of 0.132 with respect to light having a wavelength of 589 nm is used.

The absorption axis 1a of the polarizing plate 1 and the retardation plate 2
, The rubbing axis 6a of the alignment film (not shown) on the observer (upper) side, and the rubbing axis 8a of the lower alignment film (not shown), For example, it is configured so as to have a shaft arrangement shown in FIG. More specifically, the angle between the slow axis 3a and the absorption axis 1a is 65 °, the angle between the slow axis 3a and the slow axis 2a is 40 °, and the angle between the slow axis 3a and the rubbing axis 6a is 60 °. The angle between the slow axis 3a and the rubbing shaft 8a is 60 °, and the angle between the rubbing shafts 6a and 8a is 240 °.

Next, an overall configuration of the liquid crystal display device of the present embodiment including the liquid crystal display panel shown in FIG. 2 and peripheral circuits will be described with reference to FIG.

As shown in FIG. 1, the liquid crystal display panel 20 has a plurality of signal electrodes 9 and a plurality of scanning electrodes 10 arranged so as to intersect each other as matrix electrodes.
At the intersection of the signal electrode 9 and the scanning electrode 10.
3 are formed. In this liquid crystal display device, as a peripheral circuit, a signal side driving circuit (voltage applying means: liquid crystal driver) 14 for applying a signal voltage to the signal electrodes 9 and a scanning voltage for sequentially selecting the scanning electrodes 9. Scanning electrode 9
, And a control circuit (control means) 16 for controlling the signal-side drive circuit 14 and the scan-side drive circuit 15 in a time-division manner. Driving (time-division driving) is performed.

The time-division driving means that a selection waveform is applied to each scanning electrode 9 line-sequentially, and when the selection waveform (selection voltage) is applied to all the scanning electrodes 9, scanning is repeated again. It is a driving method. Then, as shown in FIG. 4, the time required to perform such scanning once is called a frame period (t _f ), and the frequency is called a frame frequency (1 / t _f ). In addition, the ratio between the selection time of each scan electrode (the time required to apply a selected waveform to the scan electrode) and the frame cycle is defined as a duty ratio (1 / N).
, And the reciprocal N of the duty ratio is generally called a duty number (D).

The liquid crystal display device that performs time-division driving is
There is a problem that a voltage is applied not only to the ON pixel but also to the OFF pixel.
In addition, in each of the off pixel groups, voltage averaging is performed so that the effective value voltage applied to the liquid crystal becomes substantially equal,
2) It can be solved by a general method such as using an STN liquid crystal exhibiting a steep electro-optical response characteristic as described above.

Signal side drive circuit 14 and scan side drive circuit 15
The control circuit 16 connected to the display unit switches between an entire display mode for displaying the entire display unit of the liquid crystal display panel 20 and a partial screen display mode for displaying only the constant display area 20a which is a partial area of the display unit. Mode control means. That is, the liquid crystal display device shown in FIG. 1 employs a partial drive system.

In the full display mode, for example, the duty number of the scanning voltage is set to a number corresponding to the total number of the scanning electrodes 10, and the selection voltage is sequentially applied to all the scanning electrodes 10. On the other hand, in the partial screen display mode, the duty number of the scanning voltage is set to a number corresponding to the number of scanning electrodes in the constant display area 20a (a number smaller than the duty number in the full display mode), and the selection voltage is set in the constant display area 20a. Are sequentially applied only to the scan electrodes 10. Thus, for example, if the mode is switched from the full-screen display mode to the partial-screen display mode when no operation is performed, it is not necessary to constantly apply a voltage to the scanning electrodes 10 in an area other than the display area 20a. It is possible to always display information (battery level, date, time, and the like) necessary when the operation is not performed in the display area 20a.

In such a partial drive type liquid crystal display device, display unevenness occurs particularly in a partial screen display mode (see FIG. 5). This is because the duty number D is set to be smaller in the partial screen display mode than in the full screen display mode for the purpose of reducing power consumption (lower voltage) as described above. Hereinafter, a more specific description will be given.

[0034] The drive frequency of the liquid crystal f, the set value of the asynchronous M signal is taken as M _1, the minimum frequency f of the voltage waveform applied to the liquid crystal (min) is the following formula (1) f (min) = D × f / M ₁ ... (1) The drive frequency (liquid crystal drive frequency) is, as usually used, one drive cycle shown in FIG. 4 (2t _f : a cycle in which a drive voltage (on-voltage) signal returns to an initial state due to twice inversion of polarity). , That is, 1/2 of the frame frequency 1 / t _f , and the minimum frequency f (min) of the voltage waveform V (t) applied to the liquid crystal is asynchronous which is the minimum AC component. This corresponds to the frequency of the M signal (that is, the reciprocal 1 / t ' _f of one cycle t' _f of the asynchronous M signal). In addition, the asynchronous M signal is an AC signal applied to the liquid crystal asynchronously with the scan start signal for the purpose of increasing the ratio of an AC component in the voltage waveform applied to the liquid crystal and reducing display unevenness that occurs during energization. Refers to a signal. Further, the set value M ₁ of the asynchronous M signal indicates a value which determines how many lines the polarity inversion of the voltage waveform applied to the liquid crystal is performed. In FIG. 4, the set value M _{1 is} 2 cp. Is set.

As is apparent from the above equation (1), the drive frequency f and the set value M ₁ of the asynchronous M signal are set to the same value in both the full screen display mode and the partial screen display mode. The minimum frequency f in the partial screen display mode in proportion to the decrease in the duty number D.
(Min) is the minimum frequency f (mi) in the full display mode.
n). As a result, in the partial screen display mode, the ratio of the DC component in the applied voltage increases, and the adsorption of the ionic impurities in the liquid crystal on the alignment film is promoted, which is caused by the disturbance of the electric field in the peripheral region. It is considered that display unevenness occurs.

More specifically, in the liquid crystal driving, the polarity inversion of the voltage waveform applied to the liquid crystal and the display unevenness have a fixed relationship. As the number of times of the polarity inversion increases, the display unevenness decreases, and the display unevenness decreases. (The DC component increases).
Although the reason for this is not necessarily clear, the ionic impurities in the liquid crystal layer 5 cannot follow and move when the number of times of the polarity reversal is large, but follow and move when the number of times of the polarity reversal is small. It is presumed that this is due to adsorption.

In order to eliminate the above-mentioned display unevenness, as is apparent from equation (1), the decrease in the duty number D in the partial screen display mode is complemented, and the minimum frequency f (min ),
At least one of the set value M ₁ of the driving frequency f or asynchronous M signal may be set to different values in the partial screen display mode and entire screen display mode. In other words, the number of times of inversion of the polarity of the voltage waveform applied to the liquid crystal can be suppressed from decreasing as the duty number D decreases (the ratio of the DC component in the voltage applied to the liquid crystal increasing) can be suppressed. ,
The driving conditions in the partial screen display mode may be set.

For example, in the liquid crystal display device according to the present invention, 1) Asynchronous M in the partial screen display mode
The set value of the signal is set to a value smaller than the set value of the asynchronous M signal in the full display mode, or
2) The drive frequency in the partial screen display mode is
The driving condition is set so as to satisfy at least one of the driving frequency and the driving frequency in the full-screen display mode. Also, more preferably,
The driving conditions are set so as to satisfy both of the above conditions 1) and 2).

When the driving conditions are set so as to satisfy the above conditions, the driving frequency f and the set value M _{1 of the} asynchronous M signal are set as in the conventional partial drive type liquid crystal display device.
As compared with a state in which the same condition is set in the full screen display mode, the minimum frequency of the applied voltage waveform in the partial screen display mode is increased, and the DC component in the applied voltage is reduced. As a result, it is possible to provide a highly reliable liquid crystal display device that has low power consumption and prevents display unevenness in the partial screen display mode.

Further, in the liquid crystal display device according to the present invention, on the assumption that the driving conditions are determined so as to satisfy at least one of the above conditions 1) and 2), furthermore, the minimum voltage waveform applied to the liquid crystal is minimized. Frequency f (min)
However, in the partial screen display mode, it is more preferable that the value is set to be substantially equal to or larger than the value in the full screen display mode. Here, the minimum frequency f (min) of the voltage waveform applied to the liquid crystal is defined as a value (referred to as f ₁ (min)) in the partial screen display mode and a value (referred to as f ₂ (min)) in the full screen display mode. Is set to be “substantially equivalent” by f ₂ (min) ± (f ₂ (mi)
n) × 0.1) f ₁ (mi
n) is set.

When the minimum frequency f (min) is set as described above, the frequency of the minimum frequency component in the AC applied voltage in the partial screen display mode becomes the frequency of the minimum frequency component in the AC applied voltage in the full screen display mode. , The ratio of the DC component in the applied voltage in the partial screen display mode is reduced to be equal to or less than that in the full screen display mode. As a result, it is possible to provide a highly reliable liquid crystal display device in which display unevenness in the partial screen display mode is almost completely prevented.

Further, the above f ₁ (min) and f ₂ (mi)
It is particularly preferred that n) be set substantially equal.
This is because, as the minimum frequency of the applied voltage waveform increases, the effect of preventing display unevenness increases, but the power consumption of the liquid crystal display device increases.

The change of the set value M ₁ of the asynchronous M signal,
The setting and changing of the driving conditions of the liquid crystal display device, such as the change of the driving frequency and the minimum frequency f (min) of the voltage waveform applied to the liquid crystal, are all performed by the signal side driving circuit 14 which is a liquid crystal driver and the scanning side. It can be easily realized by changing the setting on the drive circuit 15 side, and the description is omitted.
Further, a condition that the minimum frequency f ₁ (min) of the applied voltage in the partial screen display mode is substantially equal to or higher than the minimum frequency f ₂ (min) in the full screen display mode (that is, driving in the partial screen display mode) The combination of the frequency f and the set value M ₁ of the asynchronous M signal)
It can be easily obtained from the above equation (1), and the description is omitted.

[0044]

EXAMPLES The following comparative examples and examples were performed using a liquid crystal display device having the same configuration as that according to the first embodiment. The driving conditions of the liquid crystal display device are as follows: driving voltage at 70 ° C. = 9.4 (V), duty ratio (= 1 / D) = 1/66, bias ratio = 9, driving frequency f = 40 in the entire display mode. (Hz), set value M ₁ of asynchronous M signal =
7 cp, which was common to the embodiment and the corresponding comparative example. The minimum frequency f (min) of the voltage waveform applied to the liquid crystal under this condition is 66 × 40/7 = 377 (H
z).

On the other hand, in the partial screen display mode, the driving voltage at 70 ° C. = 6.5 (V) and the duty ratio = 1 /
26, the setting of bias ratio = 6 is common to the embodiment and the comparative example, but at least one of the set value M ₁ of the asynchronous M signal or the driving frequency f is used as a parameter, Frequency f of the applied voltage waveform at
(Min) was evaluated for the energization reliability.

The above-mentioned drive voltage indicates the peak value (V) of the ON voltage applied to the liquid crystal. Also,
In both full screen mode and partial screen display mode,
The bias ratio was set using the optimal bias method. That is, the bias ratio was set so as to satisfy the optimum condition for maximizing the ratio V _on / V _off between the ON voltage and the OFF voltage.

[Comparative Example 1] First, in order to confirm the display non-uniformity generation time during energization in the full-screen display mode, the minimum frequency f (min) was set to the above condition (377 Hz), and 70 ° C.
In the constant temperature bath, an acceleration current test (acceleration test) in which an excessive voltage 1.1 times the driving voltage 9.4 (V) at 70 ° C. was applied to the liquid crystal was performed. As a result, in the full display mode, display unevenness (see FIG. 5) occurred after 300 hours of continuous energization.

As in the case of the full screen display mode,
Set value M ₁ of asynchronous M signal in partial screen display mode
Is set to 7 cp, the driving frequency f is set to 40 (Hz), and the minimum frequency f (min) is set to 26 × 40/7 = 149 (H
z) <377 (Hz). Then, in a 70 ° C. constant temperature bath, an accelerated energization test was performed in which an excessive voltage 1.1 times the driving voltage 6.5 (V) at 70 ° C. was applied to the liquid crystal.
As a result, in the partial screen display mode, display unevenness (see FIG. 5) occurred after 100 hours of continuous energization.

[Embodiment 1] In the partial screen display mode, the set value M ₁ of the asynchronous M signal is set to 5 cp, the driving frequency f is set to 40 (Hz), and the minimum frequency f (min) is set to 26 × 40/5. = 208 (Hz) <377 (Hz). That is, in this embodiment, the set value M ₁ of the asynchronous M signal in the partial screen display mode is set smaller than the set value M ₁ = 7 cp in the full screen display mode. Then, in a constant temperature bath at 70 ° C., an accelerated energization test was performed in which an excessive voltage 1.1 times the driving voltage 6.5 (V) at 70 ° C. was applied to the liquid crystal. As a result, in the partial screen display mode, display unevenness (see FIG. 5) occurred after 200 hours of continuous power supply, but the time required for the display unevenness to be significantly longer than that of Comparative Example 1.

[Embodiment 2] In the partial screen display mode, the set value M ₁ of the asynchronous M signal is set to 7 cp, the driving frequency f is set to 80 (Hz), and the minimum frequency f (min) is set to 26 × 80/7. = 297 (Hz) <377 (Hz). That is, in this embodiment, the drive frequency f in the partial screen display mode is set to be higher than the drive frequency f = 40 (Hz) in the full screen display mode. 5. Drive voltage at 70 ° C. in a constant temperature bath at 70 ° C.
An accelerating current test in which an excessive voltage 1.1 times 5 (V) was applied to the liquid crystal was performed. As a result, in the partial screen display mode, display non-uniformity (see FIG. 5) occurred after 150 hours of continuous energization, but the time required for display non-uniformity was significantly extended compared to Comparative Example 1.

[Embodiment 3] In the partial screen display mode, the set value M ₁ of the asynchronous M signal is set to 3 cp, the driving frequency f is set to 40 (Hz), and the minimum frequency f (min) is set to 26 × 40/3. ≒ 350 (Hz). That is, in the present embodiment, the set value M ₁ of the asynchronous M signal in the partial screen display mode is the set value M ₁ =
By setting smaller than 7 cp, the minimum frequency in the full-screen display mode (f (min) = 377 (Hz))
And the minimum frequency in the partial screen display mode are substantially equal. Then, in a 70 ° C constant temperature bath, 70 ° C
, An accelerated energization test in which an excessive voltage 1.1 times the drive voltage 6.5 (V) was applied to the liquid crystal was performed. As a result, it was confirmed that in the partial screen display mode, display unevenness (see FIG. 5) did not occur even after 300 hours of continuous energization, and the energization reliability level was equal to or higher than that in the full screen display mode. .

[0052]

As described above, according to the liquid crystal display device of the present invention, the asynchronous M signal in the partial screen display mode is switched in the liquid crystal display device performing the time division drive by switching between the full screen display mode and the partial screen display mode. Is set to a value smaller than the set value in the full screen display mode.

As described above, in the liquid crystal display device according to the present invention, in the liquid crystal display device which performs the time division driving by switching between the full screen display mode and the partial screen display mode, the driving frequency in the partial screen display mode is In this configuration, the driving frequency is set to be higher than the driving frequency in the display mode.

As described above, in the liquid crystal display device according to the present invention, the setting of the asynchronous M signal in the partial screen display mode is performed in the liquid crystal display device performing time division driving by switching between the full screen display mode and the partial screen display mode. The value is set to a value smaller than the set value in the full screen display mode, and the driving frequency in the partial screen display mode is
In this configuration, the driving frequency is set to be higher than the driving frequency in the full screen display mode.

According to any one of the above configurations, compared to the state where the drive frequency and the set value of the asynchronous M signal are set to the same conditions as in the full screen display mode, the applied voltage waveform in the partial screen display mode is reduced. Increases, and the DC component in the applied voltage decreases. Therefore, there is an effect that it is possible to provide a highly reliable liquid crystal display device that has low power consumption and prevents display unevenness in the partial screen display mode.

[0056] The liquid crystal display device according to the present invention also may, subject to any of the configurations described above, the inverse of the duty ratio D, and the driving frequency f, and set values of the asynchronous M signal is taken as M _1, f ( min) = D × f / M ₁ ,
The minimum frequency f (min) of the voltage waveform applied to the liquid crystal may be set to a value substantially equal to or higher than the value in the full screen display mode in the partial screen display mode.

According to the above configuration, the ratio of the DC component in the applied voltage in the partial screen display mode is reduced to be equal to or less than that in the full screen display mode. Therefore, it is possible to provide a highly reliable liquid crystal display device in which the occurrence of display unevenness in the partial screen display mode is almost completely prevented.

[Brief description of the drawings]

FIG. 1 is a perspective view illustrating a configuration of a liquid crystal display device according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view illustrating a configuration of a liquid crystal display panel included in the liquid crystal display device illustrated in FIG.

FIG. 3 is an explanatory diagram illustrating an optical axis arrangement of the liquid crystal display device shown in FIG.

FIG. 4 is a waveform diagram showing a waveform of a voltage applied to a liquid crystal in the liquid crystal display device shown in FIG.

FIG. 5 is an explanatory diagram illustrating a state in which display unevenness occurs on a liquid crystal display panel provided in a conventional liquid crystal display device in a partial screen display mode.

[Explanation of symbols]

 20 liquid crystal display panel 20a constant display area (part of display section) V (t) applied voltage waveform

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G09G 3/20 680 G09G 3/20 680S 3/36 3/36 F-term (Reference) 2H093 NA07 NA31 NA46 NA24 NC24 ND39 NE06 NF13 NH02 NH03 NH04 NH16 NH18 5C006 AA22 AC02 AC26 AF31 AF69 BA19 BB12 BC03 BC13 EC13 FA25 FA38 FA46 FA47 GA02 5C080 AA10 BB05 CC03 DD05 DD26 DD30 EE28 EE32 FF09 JJ01 JJ04 JJ06 KK07

Claims (4)

[Claims] 1. A liquid crystal display which performs time division driving by switching as necessary between a full screen display mode for displaying the entire display section of a liquid crystal display panel and a partial screen display mode for displaying only a part of the display section. 2. The liquid crystal display device according to claim 1, wherein a set value of the asynchronous M signal in the partial screen display mode is set to a value smaller than a set value of the asynchronous M signal in the full screen display mode. 2. A liquid crystal display which performs time division driving by switching as necessary between a full screen display mode for displaying the entire display section of the liquid crystal display panel and a partial screen display mode for displaying only a part of the display section. A liquid crystal display device, wherein the drive frequency in the partial screen display mode is set higher than the drive frequency in the full screen display mode. 3. A liquid crystal display that performs time division driving by switching as necessary between a full screen display mode in which the entire display section of the liquid crystal display panel is displayed and a partial screen display mode in which only a part of the display section is displayed. In the apparatus, the set value of the asynchronous M signal in the partial screen display mode is set to a value smaller than the set value of the asynchronous M signal in the full screen display mode, and the driving frequency in the partial screen display mode is The liquid crystal display device is set to be higher than the driving frequency in the above. 4. The inverse of the duty ratio D, and the driving frequency f, and set values of the asynchronous M signal is taken as M _1, f (min) = it is defined as D × f / M _1, the liquid crystal Minimum frequency f of applied voltage waveform
4. The apparatus according to claim 1, wherein (min) is set to a value substantially equal to or greater than a value in the full screen display mode in the partial screen display mode.
The liquid crystal display device according to claim 1.