JPH05181432A - Active matrix liquid crystal display device - Google Patents

Abstract

PURPOSE:To provide an active matrix liquid crystal display device where the charge of a video signal to each picture element is completely executed in a short time and a high-definitive and bright picture is obtained. CONSTITUTION:A picture element electrode plate 1a where a scanning signal line 13 and a data signal line 14 are wired in a grid shape and a TFT is disposed in a matrix shape at a part surrounded by both signal lines 13 and 14 is stuck with a counter electrode plate 1b where a counter electrode 7 is formed, and liquid crystal is encapsuled between both electrode plates 1a and 1b. Each scanning signal line 13 is connected to a scanning driver 2 and each data signal line 14 is connected to a segment driver 3. The video signal is given to the segment driver 3 through a video signal inversion circuit 4 and a video signal control circuit 8, and initial voltage is given to the driver 3 from an initial voltage charge circuit 81 through the video signal control circuit 8. Then, counter voltage is impressed on the counter electrode 7 from a counter voltage impressing circuit 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an active matrix liquid crystal display device used for displaying television images and the like.

[0002]

2. Description of the Related Art FIG. 7 shows a conventional example of an active matrix liquid crystal display device. A liquid crystal panel 1 of this active matrix liquid crystal display device is formed by laminating an image electrode plate 1a and a counter electrode plate 1b, and a liquid crystal (liquid crystal layer) as a display medium is sealed between the both electrode plates 1a, 1b. ..

FIG. 8 shows the structure of the pixel electrode plate 1a. A large number of scanning signal lines 13, 13 ... Are arranged in the row direction on the substrate 11, and a large number of data signal lines 14, 14 ... Are arranged in the column direction orthogonal to the scanning signal lines 13, 13. In addition, a large number of pixel electrodes 12, 12 ... Which configure each pixel are arranged in a matrix in a region surrounded by the scanning signal lines 13 and the data signal lines 14. A TFT (thin film transistor) 15 as a switching element is connected to the scanning signal line 13, the data signal line 14, and the pixel electrode 12. On the other hand, the counter electrode plate 1b has the counter electrode 7 formed on one surface of the substrate.

As shown in FIG. 7, a scan driver 2 is connected to the pixel electrode plate 1a. Specifically, the scan signal line 13 of the pixel electrode plate 1a is connected to the scan driver 2 to electrically connect the two. The scan driver 2 is a circuit that sequentially outputs a scan signal to each scan signal line 13, 13 ... With a shift register.

A segment driver 3 is connected to the pixel electrode plate 1a. Specifically, the data signal line 14 of the pixel electrode plate 1a is connected to the segment driver 3 to electrically connect the two. Segment driver 3
Is configured to sample a video signal input through the video signal inverting circuit 4 connected to the segment driver 3 at a predetermined sampling pitch and output a video signal for one horizontal scanning line to each data signal line 14. Circuit. Then, the counter voltage serving as the reference of the video signal is constantly applied to the counter electrode 7 from the counter voltage circuit 6 connected to the counter electrode 7.

The operation timings of the scan driver 2, the segment driver 3 and the video signal inverting circuit 4 are controlled by the timing control circuit 5. More specifically, the timing control circuit 5 controls these operation timings based on the sync signal separated from the video signal.

FIG. 9 shows the operation timing of the active matrix liquid crystal display device having the above structure. FIG. 9 (a),
As shown in (b), the scan signals are input to each scan signal line 13 from the scan driver 2 sequentially from the first scan signal line by a horizontal scanning period TH. This scanning signal is repeatedly sent for each vertical scanning period TV.

Further, from the segment driver 3, a video signal for one horizontal scanning line is sampled for each horizontal scanning period TH and is output to each data signal line 14. It should be noted that FIG. 9C shows a video signal supplied from the video signal inverting circuit 4 to the segment driver 3.

When a scanning signal is input, the TFT 15 connected to the corresponding scanning signal line 13 is turned on (ON), whereby the video signal on the data signal line 14 (see FIG. 9E) is supplied to each pixel. The scanning signal line 1 is sent to the electrode 12.
A voltage corresponding to the difference from the counter voltage (see FIG. 9 (f)) is applied to the liquid crystal above 3.

Moreover, this applied voltage is applied to the horizontal scanning period T
Even after the TFT 15 is cut off (OFF) after passing H,
After the vertical scanning period TV, it is held by the capacitance of the liquid crystal layer or the like until the TFT 15 becomes conductive again. Therefore, the video signal is applied to each pixel of the liquid crystal not only in the horizontal scanning period TH in which the TFT 15 is conductive but also in the entire vertical scanning period TV thereafter.

Since the life of the liquid crystal is shortened if it is driven by direct current, the video signal input to the segment driver 3 is actually inverted by the video signal inversion circuit 4 shown in FIG. In order to make it difficult to see,
AC drive is performed as shown in (g).

[0012]

By the way, recently, there is a tendency that liquid crystal display devices are required to have high definition, and in order to realize this, the number of data signal lines 14 and scanning signal lines 13 is increased, Moreover, it is necessary to shorten the time for sampling the video signal of the segment driver 3. On the other hand, 1H inversion drive is performed to make flicker hard to see.

However, when the 1H inversion drive is performed under such a situation, the polarity of the voltage charged in the sampling capacitor of the segment driver 3 is changed every time the video signal is sampled, as shown in FIG. 9D. Therefore, especially when C _S - _on gate drive and source inversion drive are performed, a voltage having a polarity opposite to the voltage applied to the pixel electrode 12 from the data signal line 14 cannot be applied to the counter electrode 7. Therefore, it is necessary to charge the sampling capacitor with the voltage applied to the liquid crystal as it is.

As a result, the voltage charged in the sampling capacitor greatly changes each time the video signal is sampled, so that the time required for sampling becomes long, and eventually,
The sampling capacitor cannot be fully charged and a clear image cannot be obtained. Therefore, it is the current situation that the high definition of the active matrix liquid crystal display device cannot be achieved.

FIG. 10 shows an example of the circuit configuration of the segment driver 3 described above. The segment driver 3 sequentially turns on a large number of sampling switches 31 arranged in the middle of connection with each data signal line 14 to sequentially charge the sampling capacitor 32 with the video signal from the video signal inverting circuit 4. When the sampling of the video signal for one horizontal scanning line is completed, the discharge switch 36 is turned off.
N As a result, the previous video signal for one horizontal scanning line charged in the hold capacitor 34 and the video amplifier 35 is discharged. When the discharge is completed, the discharge switch 36 is turned off at that point. Then, the transfer switch 33 is turned on, and the video signal for one horizontal scanning line (currently) charged in the sampling capacitor 32 is transferred to the hold capacitor 34. The video signals transferred to the respective hold capacitors 34 are simultaneously output to the respective data signal lines 14.

FIG. 11 shows such a segment driver 3
The operation timing of the active matrix liquid crystal display device using is shown. The operation timing is substantially the same as that shown in FIG. However, TI indicates the discharge period of the hold capacitor 34 and the video amplifier 35 as shown in FIG.

By the way, in such a driving method,
If the scan signal is output to the scan signal line 13 during the period TI during which the hold capacitor 34 and the video amplifier 35 in the segment driver 3 are discharged, up to each pixel connected to the scan signal line 13 is output. It will be discharged. Therefore, no scanning signal is output to any scanning signal line 13 during this period.

In addition to this, as the definition of the active matrix display device becomes higher, the number of scanning signal lines 13 increases, and when the double speed line sequential driving method or the like is performed to improve the horizontal resolution, one scanning signal is obtained. The line selection time is shorter.

For the above reasons, according to the above driving method, the pixels are not sufficiently charged, and it is not possible to obtain a high-definition and clear image.

The present invention solves the above-mentioned drawbacks of the prior art, and an active matrix capable of sufficiently sampling a video signal in a short time and consequently obtaining a high-definition and clear image. An object is to provide a liquid crystal display device.

Another object of the present invention is to provide an active matrix liquid crystal display device capable of sufficiently charging a video signal to each pixel in a short time and consequently obtaining a high-definition and clear image. To do.

[0022]

In the active matrix liquid crystal display device of the present invention, a plurality of pixel electrodes are connected to respective data signal lines via a plurality of switching elements whose switching is controlled by a plurality of wired scanning signal lines. A liquid crystal panel is provided, in which the counter electrodes are connected to each other and sandwich the liquid crystal layer between the plurality of pixel electrodes, and a scanning signal is sequentially applied to the plurality of scanning signal lines in a state where a counter voltage is applied to the counter electrodes. In the active matrix liquid crystal display device which sequentially sends the video signals to the plurality of pixel electrodes through the respective data signal lines by making the segment drivers connected to the respective data signal lines 1 Before sampling the video signal of the horizontal scanning line segment, all sampling capacitors of the segment driver are previously It includes an initial voltage charging circuit for charging the constant voltage, the object can be achieved.

Further, in the active matrix liquid crystal display device of the present invention, the plurality of pixel electrodes are connected to the respective data signal lines through the plurality of switching elements whose switching is controlled by the plurality of wired scanning signal lines. A liquid crystal panel in which a counter electrode is arranged so as to face the plurality of pixel electrodes with a liquid crystal layer interposed therebetween, and in the state where a counter voltage is applied to the counter electrodes, a scanning signal is sequentially sent to the plurality of scanning signal lines, In an active-matrix liquid crystal display device in which a plurality of switching elements are made conductive and video signals are sequentially sent to the plurality of pixel electrodes via respective data signal lines, one horizontal scanning line after each switching element is made conductive. Minutes before applying the video signal to the pixels.
An initial voltage charging circuit for charging a pixel of a horizontal scanning line with a predetermined voltage is provided, thereby achieving the above object.

[0024]

As described above, before the segment driver starts sampling the video signal of one horizontal scanning line, if all the sampling capacitors of the segment driver are charged with a predetermined voltage by the initial voltage charging circuit, Then, when the video signal corresponding to each data signal line is sampled by the sampling capacitor, the voltage change can be small regardless of the display of the video signal to be sampled. Therefore, the sampling operation can be performed in a short time. In other words, the video signal can be sufficiently sampled even if the sampling time is shortened.

The initial voltage is charged to all the sampling capacitors from the end of transfer of the video signal from the sampling capacitors in the segment driver to the sampling of the first data signal line. Since the charging may be performed in the interval, the initial voltage can be sufficiently charged over time.

Further, as described above, after the switching element is turned on, before the video signal is applied to the pixel for one horizontal scanning line, each pixel is charged with a predetermined voltage in advance by the initial voltage charging circuit. After that, when the video signal corresponding to each data signal line is charged to each pixel, the voltage change can be small regardless of the display of the video signal to be charged similarly to the above. Therefore, each pixel can be sufficiently charged in a short time.

Since the initial voltage of the pixels for one horizontal scanning line may be charged within the discharging period of the hold capacitor and the video amplifier in the segment driver, the charging time of each pixel of the video signal is as described above. If the time is the same as in the conventional example, it is possible to sufficiently charge the battery over a period of time during this time.

[0028]

EXAMPLES Examples of the present invention will be described below.

FIG. 1 shows an embodiment of the active matrix liquid crystal display device of the present invention. A liquid crystal panel 1 of this active matrix liquid crystal display device is formed by adhering an image electrode plate 1a and a counter electrode plate 1b to each other.
A liquid crystal (liquid crystal layer) as a display medium is sealed between b.

The structure of the pixel electrode plate 1a is the same as that of the conventional example shown in FIG. 8, and will be described with reference to FIG.
A large number of scanning signal lines 13, 13 ... Are laid in the row direction, and a large number of data signal lines 14, 14 ... Are laid in the column direction orthogonal to the scanning signal lines 13, 13. in addition,
In a region surrounded by the scanning signal lines 13 and the data signal lines 14, a large number of pixel electrodes 12, 12 ... Which constitute each pixel are arranged in a matrix.

Further, the scanning signal line 13 and the data signal line 14
And the pixel electrode 12 has a TF as a switching element.
T15 is connected. Specifically, the TFT 15 is formed on the scanning branch line branched from the scanning signal line 13 and uses the scanning branch line as a gate terminal. The TFT 15 has a branch line from the data signal line 14 as a source terminal and a drain terminal connected to the pixel electrode 12.

With this wiring configuration, when a scanning signal is sent to the scanning signal line 13, the TFT 15 turns on and the video signal on the data signal line 14 is applied to the pixel electrode 12. Further, each pixel electrode 12 can hold the video signal thus applied by the capacitance of the liquid crystal layer even after the TFT 15 is cut off.

On the other hand, the counter electrode plate 1b of the liquid crystal panel 1 is
As shown in FIG. 1, the counter electrode 7 is formed on one surface of the substrate. The counter electrode 7 serves as a common electrode for each pixel electrode 12. A constant counter voltage is constantly applied to the counter electrode 7 from the counter voltage applying circuit 6.

As shown in FIG. 1, the scanning signal lines 13, 13, ... Of the pixel electrode plate 1a in the liquid crystal panel 1 are connected to the scan driver 2. The scan driver 2 shifts the scanning signal to each scanning signal line 13, 13 ...
It is a circuit that sequentially outputs to each of the vertical scanning periods and repeats this for each vertical scanning period. A sync signal separated from a video signal is input to the scan driver 2 via a timing control circuit 5 connected to the scan driver 2.

On the other hand, each data signal line 14, 14 ... Is connected to the segment driver 3. A video signal received by a tuner circuit (not shown) is input to the segment driver 3 via the video signal inverting circuit 4 and the video signal control circuit 8.
Further, a synchronization signal is input to the segment driver 3 via the timing control circuit 5, and an initial voltage is charged from the initial voltage charging circuit 81 via the video signal control circuit 8.

FIG. 2 shows a circuit configuration of the segment driver 3. The circuit configuration will be described below together with the operation. The segment driver 3 first turns on all the sampling switches 31, 31 ... And charges the initial voltage from the initial voltage charging circuit 81 to all the sampling capacitors 32, 32 ... Through the video signal control circuit 8. When the charging of the initial voltage is completed, next, the sampling switch 31,
31 are sequentially turned on to perform a sampling operation of charging the respective sampling capacitors 32, 32 ... With a video signal input via the video signal inverting circuit 4 and the video signal control circuit 8.

When the sampling of the video signal for one horizontal scanning line is completed, the sampling capacitor 32
Then, the transfer switch 33 for switching the connection state between the and hold capacitors 34 is turned on to connect the two. As a result, the video signals once charged (stored) in the sampling capacitors 32, 32 ...
4, 34 ... Each hold capacitor 3
The video signal of one horizontal scanning line charged to 4, 34, ...
After that, each data signal line 1 is passed through the video amplifier 35.
It is simultaneously output to 4, 14 ...

The structure of the initial voltage charging circuit 81 and the video signal control circuit 8 will now be described briefly. In the initial voltage charging circuit 81, the segment driver 3 performs the first sampling of the data signal line 14 as described above. This is a circuit for charging the initial voltage before, and the polarity of this initial voltage is set to be the same as the polarity of the video signal with reference to the counter voltage applied to the counter electrode 7 of the counter electrode plate 1b. That is, it is a circuit that inverts the polarity of the initial voltage corresponding to the polarity of the video signal.

The video signal control circuit 8 is a circuit for switching the signals supplied from the video signal inverting circuit 4 and the initial voltage charging circuit 81 and sending the signals to the segment driver 3.
Before the first sampling of No. 4 is performed, the initial voltage from the initial voltage charging circuit 81 is sent to the segment driver 3, and then the video signal from the video signal inverting circuit 4 is sent to the segment driver 3.

Therefore, in the liquid crystal panel 1 having the above structure, the scan driver 2 scans to sequentially scan the signal lines 13,
13 are selected, and all the TFTs 15, 15 ... Connected to the selected scanning signal line 13 are made conductive,
A video signal for one horizontal scanning line from the segment driver 3 is connected to the scanning signal lines 13, 13 ... Selected via the respective data signal lines 14, 14 ... Applied to. This operation is repeatedly performed for each horizontal scanning period, whereby a video signal for one screen is reproduced.

However, the video signals applied to the respective pixel electrodes 12, 12, ... Are sequentially applied with their polarities inverted by the video signal inversion circuit 4, and correspondingly, the initial voltage charging circuit 81 is applied as described above. Reverses the polarity of the initial voltage charged in the sampling capacitor 32. The polarity reversal of the video signal by the video signal reversing circuit 4 is also performed with the counter voltage applied to the counter electrode 7 as a reference, whereby the liquid crystal is AC driven.

The operation timings of the scan driver 2, the segment driver 3, the video signal inverting circuit 4, the video signal control circuit 8 and the initial voltage charging circuit 81 are as follows.
The timing control circuit 5 controls based on the synchronization signal.

FIG. 3 shows a specific operation timing of the liquid crystal display device having the above structure. The scanning driver 2 sequentially outputs scanning signals to the scanning signal lines 13, 13 ... At the timings shown in FIGS. That is, FIG.
As shown in (a), the first scanning signal line 13 is at the time t.
When the scanning signal is generated at 1, the signal rises to the H level (high level), and falls to the L level (low level) at time t2 after the elapse of the horizontal scanning period TH from the time t1. That is, the first scanning signal line 13 is at the H level during the period from t1 to t2. This H-L state is repeated for each vertical scanning period TV. Therefore, at time t4 after the elapse of the vertical scanning period TV from time t1, the scanning signal line 1
3 rises to H level again.

On the other hand, the second scanning signal line 13
Is the first scanning signal line 13 as shown in FIG.
The level rises to the H level at time t2 after the lapse of the horizontal scanning period TH and falls to the L level at time t3 after the lapse of the horizontal scanning period TH from the time t2. This HL
The state is similarly repeated for each vertical scanning period TV. Therefore, the second scanning signal line 13 rises to the H level again at time t5 after the elapse of the vertical scanning period TV from time t2.
As described above, the scanning signals sequentially output from the scan driver 2 to the respective scanning signal lines 13, 13 ... Are delayed by the horizontal scanning period TH, and the scanning signals are activated with the horizontal scanning period TH being delayed.

When each scanning signal line 13, 13 ... sequentially goes to H level at the above timing, all the TFTs 15 connected to the scanning signal line 13 are turned on, so that the pixel electrode 12 and each data signal are connected via the TFT 15. The line 14 is sequentially connected. At this time, the video signal control circuit 8 has an intermediate voltage between the voltage of the video signal for black display and the voltage of the video signal for white display with the same polarity as the video signal from the initial voltage charging circuit 81 as a reference. An initial voltage, which is a voltage with a value of, is given. Further, a video signal is sent from the video signal inverting circuit 4. The counter voltage is applied from the counter voltage applying circuit 6 as described above, and is always a constant value as shown in FIG.

The video signal control circuit 8 is shown in FIG.
As shown in (c), the segment driver 3 transfers from the sampling capacitor 32 to the hold capacitor 34 the previous video signal for one horizontal scanning line until the sampling of the first data signal line 14 is started. The initial voltage applied from the initial voltage charging circuit 81 is applied to the segment driver 3 only for the period TI. Then, the video signal control circuit 8 causes the remaining horizontal scanning period TH,
That is, the video signal from the video signal inversion circuit 4 is applied to the segment driver 3 during the (TH-TI) period (see FIG. 3C).

Then, the segment driver 3 turns on all the sampling switches 31, 31, ... Only during the period TI in which the initial voltage is applied. As a result, the sampling capacitor 32 is charged with the initial voltage. After that, the segment driver 3 sequentially turns on the sampling switch 31, samples the video signal given during the period shown in FIG. 3C, and charges the sampling capacitor 32 (see FIG. 3D). The polarity of the voltage charged in the sampling capacitor 32 corresponds to the polarity of the video signal applied to the segment driver 3.

Subsequently, the segment driver 3 turns on the transfer switch 33 to transfer the video signal once charged in the sampling capacitor 32 to the hold capacitor 34. Then, after the video signal for one horizontal scanning line is amplified to a predetermined level by the video amplifier 34, each data signal line 1
Output to 4, 14, ... Simultaneously. FIG. 3E shows a voltage waveform of the video signal output to the same data signal line 14. The video signal output to the data signal line 14 is transmitted through the TFT 15 selected by the scanning signal to the corresponding pixel electrode 12
Applied to.

Even after the TFT 15 is turned off, the image for the pixel electrode 12 which is connected to the other scanning signal line 13 via the TFT 15 is connected to the data signal line 14 until the next vertical scanning period TV. Signals are sequentially applied, but once the TFT 15 is turned off, the accumulated charge of the pixel electrode 12 does not change, so that the voltage applied to the liquid crystal does not change (see FIG. 3 (g)). ).

The segment driver 3 and the video signal control circuit 8 repeat the above operation for each horizontal scanning period TH, whereby the video signals for each horizontal scanning line are sequentially applied to all the pixel electrodes 12 on the liquid crystal panel 1. To be done.
However, the initial voltage sent to the segment driver 3 is inverted by the initial voltage charging circuit 81, and the video signal is inverted by the video signal inverting circuit 4 in the horizontal scanning period TH as described above with the counter voltage as a reference. Further, this polarity inversion is also inverted every vertical scanning period TV so that the voltage applied to the liquid crystal becomes an alternating current as shown in FIG.

While the video signal is sequentially applied to each pixel electrode 12 as described above, a constant counter voltage is constantly applied to the counter electrode 7 from the counter voltage applying circuit 6. As a result, in the sampling capacitor 32 in the segment driver 3, the voltage of the video signal when displaying black and the voltage of the video signal when displaying white with the same polarity as the video signal with reference to the counter voltage as an initial voltage are preset. Since the voltage having just the intermediate value is charged, when the video signal is sampled in the sampling capacitor 32 thereafter, a small voltage change is sufficient no matter what the video signal to be sampled is displayed. This means that the transmitted video signal can be sampled in a short time.

Therefore, according to this embodiment, it is possible to sufficiently sample the video signal even if the number of the data signal lines 14 is increased and the time for sampling the video signal of the segment driver 3 is shortened. Further, the period TI required to charge the initial voltage can be set longer than the sampling time per sampling capacitor 32 when the segment driver 3 sequentially samples the video signals sent from the video signal inverting circuit 4. For,
A sufficient initial voltage can be charged to the sampling capacitor 32. Therefore, according to the active matrix liquid crystal display device of this embodiment, a high-definition and clear image can be obtained.

4 to 6 show another embodiment of the active matrix liquid crystal display device of the present invention. In this embodiment, before applying the video signal to the pixels of one horizontal scanning line,
A predetermined voltage is applied to each pixel in advance, whereby the charging time of the video signal to each pixel is shortened, and an active matrix liquid crystal display device capable of obtaining a high-definition and clear image is realized. The configuration will be described in detail below, but since there are many parts in common with the active matrix liquid crystal display device of the above-described embodiment, common parts are designated by the same reference numerals to simplify the description, and different parts will be described in detail.

As shown in FIG. 4, the active matrix liquid crystal display device of the present embodiment is different from the active matrix liquid crystal display device of the above embodiment in the connection position of the segment driver 3 and the video signal control circuit 8 and the initial stage. The voltage charging circuit 81 charges each pixel electrode 12 with an initial voltage via the video signal control circuit 8,
This point is largely different from the configuration of the above embodiment. The configuration of each device will be described below along with the operation.

Similarly to the above-described embodiment, the scan driver 2 sequentially outputs the scanning signal to each scanning signal line 13, 13 ... While shifting the scanning signal by the shift register every horizontal scanning period, and repeats this operation every vertical scanning period. Circuit.
However, in the scan driver 2 of the present embodiment, the segment driver 3 described below has its hold capacitor 34.
Also, the period during which the video amplifier 35 is discharged is 1
The operation of selecting the scanning signal line 13 of each pixel electrode 12 for which the next video signal for the horizontal scanning line is being charged is performed.

FIG. 5 shows the circuit configuration of the segment driver 3 of this embodiment. The segment driver 3 sequentially turns on the respective sampling switches 31, 31, ..., Samples the video signal supplied from the video signal inverting circuit 4, and sequentially charges the respective sampling capacitors 32, 32. When charging of the video signal for one horizontal scanning line is completed,
Turn on each discharge switch 36, and hold capacitor 3
4 and the video signal of the previous one horizontal scanning line charged in the video amplifier 35 is discharged. When the discharge operation is completed, the discharge switches 36, 36 ...
Turn off. Then, the transfer switch 33 that switches the connection between the sampling capacitor 32 and the hold capacitor 34 is turned on, and the video signal once charged in the sampling capacitor 32 is transferred to the hold capacitor 34. The video signal for one horizontal scanning line transferred to the hold capacitor 34 is then transferred to each of the data signal lines 14 and 1.
It is output simultaneously to 4 ...

The initial voltage charging circuit 81 of this embodiment, which is connected to the video signal control circuit 8, has data for each period during which the segment driver 3 discharges the hold capacitor 34 and the video amplifier 35 as described above. This is a circuit for sending an initial voltage to the signal line 14. More specifically, the counter voltage applying circuit 6 to the counter electrode 7 will be described.
It is a circuit for sending out an initial voltage whose polarity is inverted so that the polarity is always the same as that of the video signal with reference to a constant constant counter voltage applied to.

Further, the video signal control circuit 8 of the present embodiment switches the video signal supplied from the video signal inverting circuit 4 and the initial voltage supplied from the initial voltage charging circuit 81 and supplies the data signal lines 14, 14 ... Circuit. Specifically, this switching is performed as follows.

That is, between the output terminal of the video amplifier 35 and the output terminal of the initial voltage charging circuit 81, the initial voltage charging switch 37 for switching the connection state between these and the respective data signal lines 14, 14 ... 37 are provided respectively, and the position of the initial voltage charging switch 37 is switched to the positions of a and b shown in the drawing to perform the switching operation.

Specifically, the initial voltage charging switch 37 is switched to the b position only while the segment driver 3 is discharging the hold capacitor 34 and the video amplifier 35, and is switched to the a position during the other periods. It is designed to be used. Each initial voltage charging switch 37, 3
7 is switched to the position of b, the initial voltage charging circuit 81 and the respective data signal lines 14, 14 ... Are connected, so during this period, the initial voltage charging circuit 81 moves to the respective data signal lines 14, 1.
The initial voltage is sent to 4 ... When the hold capacitor 34 and the video amplifier 35 are completely discharged, the initial voltage charging switch 37 is switched to the position a at that time, and the video signal from the segment driver 3 is sent to each of the data signal lines 14, 14. To be done.

It should be noted that even during the period when the segment driver 3 is discharging the hold capacitor 34 and the video amplifier 35, the scan driver 2 is going to charge the video signal for one horizontal scanning line for the next one horizontal scanning. All T's on the scanning signal line 13 connected to each pixel of the line segment
Since the FTs 15, 15, ... Are turned on, the initial voltage is charged to each pixel for one horizontal scanning line via each data signal line 14, 14 ... In the discharge period.

Therefore, in the liquid crystal panel 1 of the present embodiment, the scanning driver 2 scans to sequentially select the scanning signal lines 13 and all the TFTs 15 on the selected scanning signal lines 13 are turned on. Voltage charging circuit 8
The initial voltage from 1 is applied to the selected scanning signal line 13 by TF.
Are sequentially applied to the respective pixel electrodes 12, 12 ... Connected via T15, and then the video signal for one horizontal scanning line from the segment driver 3 is applied to the video signal control circuit 8
And are applied to the respective pixel electrodes 12, 12 ... Via the respective data signal lines 14, 14. This operation is repeated for each horizontal scanning period, whereby the video signal for one screen is reproduced.

Both the initial voltage and the video signal are applied with their polarities sequentially reversed. This polarity reversal is
Similar to the above embodiment, the counter voltage applied to the counter electrode 7 is used as a reference, and the liquid crystal is driven by an alternating current.

Scan driver 2, segment driver 3, video signal inverting circuit 4, video signal control circuit 8
The operation timing of the initial voltage charging circuit 81 is controlled by the timing control circuit 5 as in the above embodiment.

FIG. 6 shows the specific operation timing of the liquid crystal display device of this embodiment. As shown in FIGS. 6A and 6B, also in the present embodiment, similarly to the above embodiment, the scanning signal lines 13, 13 ... Are sequentially supplied with scanning signals delayed by the horizontal scanning period TH from the scan driver 2. It is issued and becomes an operating state (= H level) with a delay of each horizontal scanning period TH.

When each of the scanning signal lines 13, 13 ... sequentially goes to the H level at the above timing, all the TFTs 15 connected to the scanning signal line 13 are turned on. Therefore, the pixel electrode 12 and each data signal are connected via the TFT 15. The line 14 is sequentially connected.

As shown in FIG. 6E, the horizontal scanning period T
A period TI in H is a discharging period of the hold capacitor 34 and the video amplifier 35 in the segment driver 3, and only during this period TI, the video signal control circuit 8 switches the initial voltage charging switch 37 to the position b.
Therefore, during this period TI, the initial voltage charging circuit 81 has the same polarity as the video signal with reference to the counter voltage having a constant value shown in FIG. The initial voltage (see FIG. 6 (e ')), which is a voltage of an intermediate value of the voltage of the video signal at the time of, is applied to each data signal line 1
Are given to pixels of one horizontal scanning line via 4, 14, ...

In the conventional example shown in FIG. 11, this period T
I is a hold capacitor 34 and a video amplifier 35.
Since it was during the discharge period, the scanning signal line 13 was not selected so as not to discharge each pixel. On the other hand, in the present embodiment, the video signal control circuit 8 switches the initial voltage charging switch 37 to the position of b, disconnects the respective data signal lines 14, 14 ... From the segment driver 3, and the initial voltage charging circuit 81. Since the initial voltage is output from each of the data signal lines 14, 14 ...
Also in I, the scanning signal line 13 can be selected and the initial charging of each pixel can be performed.

In addition, the initial voltage is the initial voltage charging circuit 81.
Since the voltage is directly applied without passing through the segment driver 3, the output impedance can be reduced and sufficient charging can be performed even in a short period.

After the lapse of the period T1, the initial voltage charging switch 3
Since 7 is switched to the position a, the video signal from the segment driver 3 is applied to each pixel of one horizontal scanning line in the remaining period of the horizontal scanning period TH, that is, in the (TH-TI) period. .. At this time, since the above-mentioned initial voltage is charged in advance as an initial voltage in each pixel, the voltage change required for charging is small regardless of the display of the video signal to be charged. This means that the transmitted video signal can be charged in a short time. Therefore, according to the present embodiment, it is possible to sufficiently charge each pixel of one horizontal scanning line with the video signal sent via each data signal line 14, 14 ... During the horizontal scanning period TH. ..

Further, the segment driver 3 sequentially turns on the sampling switches 31, 31, ..., And causes the sampling capacitor 32 to sequentially sample the video signal having the waveform shown in FIG. 6C supplied from the video signal inverting circuit 4 (FIG. 6). (See (d)). Subsequently, as shown in FIG. 6E, the hold capacitor 34 and the video amplifier 35 are discharged during the period TI. After that, transfer switch 3
3 is turned on, the video signal once charged in the sampling capacitor 32 is transferred to the hold capacitor 34, and
The video signal of the horizontal scanning line is supplied to each of the data signal lines 14, 14 ...
Output to. This video signal is applied to each pixel electrode 12, 12 ... Through the TFT 15 selected by the scanning signal.

As in the above embodiment, the initial voltage sent to the segment driver 3 is supplied by the initial voltage charging circuit 81, and the video signal is supplied by the video signal inverting circuit 4 in polarity with respect to the counter voltage every horizontal scanning period TH. Flipped.
Further, the polarity is also inverted every vertical scanning period TV so that the current applied to each pixel electrode 12, 12 ... Is AC (see FIG. 6G).

Also in the present embodiment, when the video signal is charged to each pixel as in the above-mentioned embodiment, the voltage change required for charging is small regardless of the display of the video signal to be charged. The signal can be charged to each pixel in a short time. Therefore, according to this embodiment, in order to obtain a high-definition and clear image, the number of scanning signal lines is increased, or the double-speed line sequential driving method is performed to improve the horizontal resolution.
Even if the time for charging the video signal to each pixel is shortened due to this, the video signal can be sufficiently charged. Therefore, according to this embodiment, it is possible to realize an active matrix liquid crystal display device capable of obtaining a high-definition and clear image.

In each of the above-described embodiments, the initial voltage is the same polarity as that of the video signal and has a value just in between the voltage of the video signal during black display and the voltage of the video signal during white display. However, the value of the initial voltage is not limited to such an intermediate value, and any value having the same polarity as the video signal with reference to the counter voltage may be used.

In each of the above embodiments, the video signal control circuit 8 and the initial voltage charging circuit 81 are provided separately from the segment driver 3, but they may be provided within the segment driver 3.

[0076]

According to the active matrix liquid crystal display device of the first aspect, since the sampling of the video signal can be sufficiently performed in a short time, the data signal line or the scanning signal line can be obtained in order to obtain a high-definition and clear image. It is possible to realize an active matrix liquid crystal display device in which a high-definition and clear image can be obtained by coping with the recent technological trend in which the sampling time of the video signal of the segment driver tends to be shortened inevitably due to the large number of pixels.

According to the active matrix liquid crystal display device of the second aspect, since the video signal can be sufficiently charged to the pixels in a short time, the number of scanning signal lines is increased in order to obtain a high-definition and clear image. However, in order to improve the horizontal resolution, the double-speed line sequential drive method is used, which inevitably
The active matrix liquid crystal display device capable of coping with the recent technical trend in which the time for selecting the scanning signal line of the book tends to be short and obtaining a high-definition and clear image can be realized.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of an active matrix liquid crystal display device of the present invention.

FIG. 2 is a circuit diagram showing a segment driver of the active matrix liquid crystal display device of FIG.

FIG. 3 is a timing chart showing an operation of the active matrix liquid crystal display device of FIG.

FIG. 4 is a block diagram showing another embodiment of the active matrix liquid crystal display device of the present invention.

5 is a circuit diagram showing a segment driver of the active matrix liquid crystal display device shown in FIG. 4 together with an initial voltage charging circuit.

6 is a timing chart showing the operation of the active matrix liquid crystal display device shown in FIG.

FIG. 7 is a block diagram showing a conventional example of an active matrix liquid crystal display device.

8 is a circuit diagram showing a liquid crystal panel of the active matrix liquid crystal display device shown in FIG.

9 is a timing chart showing an operation of the active matrix liquid crystal display device shown in FIG.

FIG. 10 is a circuit diagram showing a conventional example of a segment driver.

11 is a timing chart showing an operation of the active matrix liquid crystal display device including the segment driver shown in FIG.

[Explanation of symbols]

 1 liquid crystal panel 1a pixel electrode plate 1b counter electrode plate 2 scan driver 3 segment driver 4 video signal inversion circuit 5 timing control circuit 6 counter voltage applying circuit 7 counter electrode 8 video signal control circuit 11 substrate 12 pixel electrode 13 scan signal line 14 data Signal line 15 TFT 31 Sampling switch 32 Sampling capacitor 33 Transfer switch 34 Hold capacitor 35 Video amplifier 81 Initial voltage charging circuit

Claims (2)

[Claims] 1. A plurality of pixel electrodes are connected to respective data signal lines through a plurality of switching elements whose switching is controlled by a plurality of wired scanning signal lines, and a liquid crystal layer is provided on the plurality of pixel electrodes. A liquid crystal panel is provided in which counter electrodes are arranged to face each other with a counter electrode interposed therebetween, and in the state where a counter voltage is applied to the counter electrodes, scanning signals are sequentially sent to the plurality of scanning signal lines to make the plurality of switching elements conductive, respectively. In an active matrix liquid crystal display device that sequentially sends video signals to the plurality of pixel electrodes via data signal lines, before the segment driver connected to each data signal line starts sampling video signals for one horizontal scanning line, An active matrix having an initial voltage charging circuit for pre-charging a predetermined voltage to all sampling capacitors of the segment driver Liquid crystal display device. 2. A plurality of pixel electrodes are connected to respective data signal lines through a plurality of switching elements whose switching is controlled by a plurality of wired scanning signal lines, and a liquid crystal layer is provided on the plurality of pixel electrodes. A liquid crystal panel is provided in which counter electrodes are arranged to face each other with a counter electrode interposed therebetween, and in the state where a counter voltage is applied to the counter electrodes, scanning signals are sequentially sent to the plurality of scanning signal lines to make the plurality of switching elements conductive, respectively. In an active matrix liquid crystal display device that sequentially sends video signals to the plurality of pixel electrodes via data signal lines, the video signals are applied to pixels of one horizontal scanning line after each switching element is turned on. An active matrix liquid crystal display device, which is provided with an initial voltage charging circuit for charging pixels of one horizontal scanning line with a predetermined voltage in advance.