JP2001282205A - Active matrix type liquid crystal display device and method for driving the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a drive circuit built-in type liquid crystal display device to allow a capacity coupled dot inversion drive system as well as capacity coupled column inversion drive system which are heretofore impossible with the conventional drive systems and a method for driving the same. SOLUTION: The device has a first drive circuit 20 for compensation voltage impression and a second drive circuit 21 for compensation voltage impression. At pixel electrodes 9 connected to the same scanning signal wiring 3, the first and second drive circuits 20 and 21 for compensation voltage impression are alternately connected to the pixel electrodes 9 across storage capacitors 8 by each of the adjacent display signal wiring 4. At the pixel electrodes 9 connected to the same display signal wiring 4, the first and second drive circuits 20 and 21 for compensation voltage impression are alternately connected to the pixel electrodes 9 across storage capacitors 8 by each of the adjacent display signal wiring 4.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an active matrix type liquid crystal display device using thin film transistors and a method for driving the same, and more particularly, to an active matrix type liquid crystal display device using a polycrystalline silicon thin film transistor as a driving circuit and a driving method therefor. Things.

[0002]

2. Description of the Related Art In recent years, thin liquid crystal display devices having characteristics of low power consumption have been widely used in movies, car navigation systems, notebook computers, and the like, and are being actively developed and commercialized. . In particular, an active matrix type liquid crystal display device using an amorphous silicon thin film transistor (a-SiTFT) as a switching element has a high contrast and is widely and generally used.

FIG. 7 shows a general configuration of an active matrix type liquid crystal display device using an a-Si TFT. In FIG. 9, reference numeral 1 denotes a scanning side driving circuit, 2 denotes a display side driving circuit, 3 denotes a scanning signal line (gate line), 4 denotes a display signal line (source line), 5 denotes an image signal line, and 6 denotes switching for a display signal line. An element, 7 is a liquid crystal element, 8 is a storage capacitor, 9 is a pixel electrode, 10 is a pixel electrode switching element (pixel transistor), and 11 is a counter electrode. In addition,
The counter electrode potential is indicated by Vcom. FIG. 10 shows an electrical equivalent circuit of a display element in order to briefly describe a general driving method of an active matrix type liquid crystal display device using the a-Si TFT. Each display element has an a-Si TFT as a switching element at the intersection of the scanning signal wiring Vg and the display signal wiring Vs. The storage capacitor Cst and a liquid crystal layer having a capacitance value of Clc are connected to the drain side of the a-Si TFT, and they are connected to the counter electrode Vcom. The a-Si TFT has a gate-drain capacitance Cgd as a parasitic capacitance. This a-Si
FIG. 11 shows a driving waveform diagram when the active matrix liquid crystal display device using TFTs is driven by the one-frame inversion driving method. In FIG. 11, Vg is a scanning signal transmitted from the scanning driver circuit to the scanning signal line, Vs is an image signal transmitted from the display driver circuit to the display signal wiring, Vd is a pixel electrode potential, and Vsc is an image signal. Shows the central value of. The image signal Vs is written to the pixel electrode when the a-Si TFT is ON, but the a-Si TFT is OFF.
, A penetration voltage ΔVp is generated by the parasitic capacitance Cgd existing between the gate and the drain of the a-Si TFT, and a DC voltage component is applied between the pixel electrode and the counter electrode. The penetration voltage ΔVp is given by the following equation.

ΔVp = (Vgh + Vgl) · Cgd / Ctot where Ctot = Cgd + Cst + Clc, where Vgh is the high signal potential of the scanning signal Vg, and Vgl is the low signal potential of the scanning signal Vg.

If the counter electrode potential Vcom is set to the center value Vsc of the image signal ignoring this penetration voltage, the voltage applied to the liquid crystal that is driven by the alternating current causes a potential difference between the high potential side and the low potential side. And flickering is observed. Generally, the penetration voltage ΔVp
By setting the common electrode potential Vcom to the center value-penetration voltage (Vsc-ΔVp) of the image signal to prevent the DC voltage component from being applied to the liquid crystal layer. However, the penetration voltage ΔVp cannot be compensated uniformly in the entire range from white to black due to the dielectric anisotropy of the liquid crystal.

As a driving method for effectively compensating a punch-through voltage due to a parasitic capacitance existing between the gate and the drain of such an a-Si TFT, a capacitive coupling driving method disclosed in Japanese Patent Application Laid-Open No. 2-157815 (constant counter electrode 1) is disclosed. Field inversion) has been proposed and implemented. FIG. 12 shows a configuration diagram of an active matrix liquid crystal display device using a capacitive coupling drive system. As shown in FIG. 12, the capacitive coupling drive system has a configuration in which the storage capacitor is not connected to the counter electrode as in the related art, but is connected to the preceding scanning signal wiring. Therefore, in this driving method, a voltage pulse for compensating the penetration voltage is superimposed on the preceding scanning signal wiring.
FIG. 13 shows a driving waveform in the capacitive coupling driving method. FIG.
In the equation, Vgh and -Vgl are the ON potential and the OFF potential of the switching element, respectively.
Vel is two bias potentials for compensating for the potential drop due to the parasitic capacitance and the threshold voltage of the liquid crystal. Reference values for each potential level are shown below.

Vgh: 13.5 (V) Vgl: −7.0 (V) Veh: 3.5 (V) Vel: −16.5 (V) In the above capacitive coupling drive method, the potential drop due to the parasitic capacitance Can be eliminated, and the image signal voltage written to the pixel electrode can be shifted up and down by the compensation voltage as shown in FIG. 14. Therefore, even if the potential of the counter electrode is constant, the image signal having a low amplitude can be obtained. There is an advantage that the liquid crystal can be AC driven. On the other hand, it has the following disadvantages. That is, as shown in FIG. 13, the potential (Veh, -Vel) for compensating for the potential drop due to the parasitic capacitance and shifting the image signal potential written in the pixel electrode up and down is superimposed on the scanning signal wiring. Therefore, the maximum amplitude of the scanning signal Vg becomes very large. In the above example, the maximum amplitude is Vgh-V
el = 30V. As a result, it is necessary to increase the breakdown voltage of the switching element, which leads to an increase in chip size, cost, or power consumption.

In order to solve this disadvantage, Japanese Patent Laid-Open No.
Japanese Patent No. 39277 discloses a liquid crystal display device with a built-in driving circuit using a polycrystalline silicon thin film transistor, in addition to a scanning driving circuit for switching a switching element, and a scanning driving circuit for applying a compensation voltage. It has been proposed to provide a scanning signal for applying a compensation voltage to the pixel electrode.

FIG. 15 shows a configuration diagram. According to the present invention, the scanning signal in the conventional capacitive coupling driving method using the scanning signal wiring of the preceding stage is converted into an original scanning signal (Vgh and -Vgl) for on / off control of the switching element,
The potential drop due to the parasitic capacitance is compensated, and the image signal potential written to the pixel electrode is separated into compensation signals (Veh and -Vel) for shifting up and down, and applied through separate drive circuits and wirings. I do. Therefore, the maximum amplitude of the scanning signal is Vgh-Vgl, which is much smaller than that of the conventional Vgh-Vel, and a driver with a high withstand voltage is not required. Further, since the driving circuit is built in by the polycrystalline silicon thin film transistor, a new external driver is not required even if the driving circuit is separated into the scanning side driving circuit and the compensation voltage applying driving circuit. As described above, in the capacitive coupling drive system with a built-in drive circuit using a polycrystalline silicon thin film transistor, the withstand voltage of the switching element can be reduced without impairing the advantages of the capacitive coupling drive method, and the chip size and cost can be reduced. Becomes

[0010]

However, in this capacitive coupling drive, since the compensation voltage cannot be changed during one horizontal period of the scanning signal, it can be applied to the frame inversion drive system and the line inversion drive system. There is a drawback that it cannot be applied to the dot inversion driving method or the column inversion driving method. Considering the driving method applied to the current liquid crystal panel, the line inversion driving method is often used for small AV panels and OA panels, but for large-screen panels such as monitors, such as crosstalk, etc. In order to avoid image quality deterioration, a dot inversion driving method is often used. Further, the column inversion driving method may be adopted to realize a low power panel.

The present invention has been made in view of the above points, and enables a capacitively coupled dot inversion driving method and a capacitively coupled column inversion driving method which cannot be performed by a conventional driving method, thereby achieving high image quality and low power consumption. It is another object of the present invention to provide an active matrix type liquid crystal display device having high reliability and a driving method thereof.

[0012]

In order to achieve the above object, a liquid crystal display device according to the present invention comprises an active matrix type liquid crystal display device having a compensating voltage application drive circuit separated into two systems. It is characterized by the following.

Thus, the compensation voltage can be changed even during one horizontal period of the scanning signal, so that the capacitively-coupled dot inversion drive system and the capacitively-coupled column inversion drive system can be performed, and image quality deterioration such as crosstalk can be solved. Characteristics such as low power consumption, high image quality, and high reliability can be realized.

The specific structure is as follows.

According to the first aspect of the present invention, a switching element and a pixel electrode are formed corresponding to each intersection of a plurality of display signal wirings and a plurality of scanning signal wirings arranged in a matrix on an insulating substrate. An active matrix type liquid crystal display comprising a compensation voltage application drive circuit for applying a compensation voltage signal of a high potential compensation voltage and a low potential compensation voltage to a compensation voltage application signal line connected to the pixel electrode via a storage capacitor. In the apparatus, the driving circuit for applying the compensation voltage includes:
The first and second compensation voltage applying drive circuits are composed of a first compensation voltage applying drive circuit and a second compensation voltage applying drive circuit section, and the pixel electrodes connected to the same scanning signal line. Are alternately connected to the pixel electrode via the storage capacitor for each adjacent display signal line, and the pixel electrode connected to the same display signal line has the first and second compensation voltage application drive The circuit is characterized in that the circuit is alternately connected to the pixel electrode via the storage capacitor for each adjacent scanning signal wiring.

According to this structure, in the pixel electrode connected to the same scanning signal line, the compensation voltage can be changed alternately for each adjacent display signal line, and the pixel electrode connected to the same display signal line can be changed. In the electrode, the compensation voltage can be changed alternately for each adjacent scanning signal wiring.

According to a second aspect of the present invention, a switching element and a pixel electrode are formed corresponding to each intersection of a plurality of display signal wirings and a plurality of scanning signal wirings arranged in a matrix on an insulating substrate. An active matrix type liquid crystal display comprising a compensation voltage application drive circuit for applying a compensation voltage signal of a high potential compensation voltage and a low potential compensation voltage to a compensation voltage application signal line connected to the pixel electrode via a storage capacitor. In the device, the compensation voltage application drive circuit includes a first compensation voltage application drive circuit and a second compensation voltage application drive circuit unit, and in the pixel electrode connected to the same scan signal line, First and second compensation voltage application drive circuits are alternately connected to the pixel electrodes via the storage capacitors for adjacent display signal lines, and are connected to the same display signal line. In connection pixel electrodes, the same compensation voltage application drive circuit, is characterized in that through the storage capacitor is connected to structure the pixel electrode.

According to this configuration, in the pixel electrode connected to the same scanning signal line, the compensation voltage can be changed alternately for each adjacent display signal line, and the pixel electrode connected to the same display signal line can be changed. The same compensation voltage can be applied to the electrodes.

The third aspect of the present invention provides the first aspect.
3. The active matrix type liquid crystal display device according to claim 2, wherein a scanning side drive circuit for applying a scan signal to the scan signal line, a display side drive circuit for applying an image signal to the display signal line, and the first and second compensation voltages The driving circuit for application is formed by a process of forming the switching element.
The switching element is a built-in circuit formed on the same substrate.

According to this configuration, not only the scan-side drive circuit section and the display-side drive circuit section, but also the compensation voltage application drive circuits 1 and 2 are formed on the same substrate as the switching element by a process including a process of forming the switching element. Since it is formed and built in, an external driver is not required, and the cost can be reduced.

The invention according to claim 4 of the present invention is the invention according to claim 3.
In the active matrix type liquid crystal display device described in the above,
The method is characterized in that a polycrystalline silicon thin film transistor forming process is applied as the process.

The fifth aspect of the present invention is the first aspect of the present invention.
A method for driving an active matrix type liquid crystal display device according to the above, wherein the potential of an image signal applied to the display signal wiring is inverted for each adjacent display signal wiring and each scanning signal wiring. A pixel electrode is written, a positive image signal voltage is written to the pixel electrode connected to the first compensation voltage application drive circuit, and the pixel electrode is connected to the second compensation voltage application drive circuit. In the frame in which the negative image signal voltage is written to the pixel, the potential of the pixel electrode connected to the first compensation voltage applying drive circuit is shifted to the high potential side after the completion of the writing by the first compensation voltage applying drive circuit. Then, the potential of the pixel electrode connected to the second compensation voltage applying drive circuit is shifted to a lower potential side after the writing is completed by the second compensation voltage applying drive circuit, A negative image signal voltage is written to the pixel electrode connected to the compensation voltage application drive circuit, and a positive image signal voltage is written to the pixel electrode connected to the second compensation voltage application drive circuit. In the frame, the first compensation voltage applying drive circuit
The potential of the pixel electrode connected to the compensating voltage applying drive circuit is shifted to a lower potential after the writing is completed, and the pixel connected to the second compensating voltage applying drive circuit by the second compensating voltage applying drive circuit. It is characterized in that the potential of the electrode is shifted to the high potential side after the writing is completed, and the electrode is driven by the capacitive coupling dot inversion driving method.

According to this method, in the configuration according to the first aspect, after the level of the pixel signal is inverted and written into the pixel electrode for each of the adjacent display signal wirings and for each of the scanning signal wirings, the first and second pixel signals are written. The potential of the pixel electrode is shifted to the opposite level by the compensation voltage application drive circuit 2. As a result, the potential of the pixel electrode connected to the same scanning signal line is alternately shifted to the opposite level for each adjacent display signal line, and the potential of the pixel electrode connected to the same display signal line. Is alternately shifted to the opposite level for each adjacent scanning signal wiring, so that the capacitive coupling dot inversion driving can be realized.

According to the sixth aspect of the present invention, the second aspect is provided.
A method for driving an active matrix type liquid crystal display device according to claim 1, wherein the potential of the image signal applied to the display signal wiring is inverted for each adjacent display signal wiring, and the potential of the adjacent scanning signal wiring is changed. For each signal wiring, the level is written to the pixel electrode without inverting, and a positive image signal voltage is written to the pixel electrode connected to the first compensation voltage applying drive circuit, and the second In a frame in which a negative image signal voltage is written to the pixel electrode connected to the compensation voltage applying drive circuit, the first
The potential of the pixel electrode connected to the first compensation voltage applying drive circuit is shifted to a high potential side after the writing is completed by the compensation voltage application driving circuit, and the second compensation is performed by the second compensation voltage application drive circuit. The potential of the pixel electrode connected to the voltage application drive circuit is shifted to a lower potential after the completion of writing, and a negative image signal voltage is written to the pixel electrode connected to the first compensation voltage application drive circuit. And the second
In a frame in which a positive image signal voltage is written to the pixel electrode connected to the compensation voltage applying drive circuit,
The potential of the pixel electrode connected to the first compensation voltage applying drive circuit is shifted to a lower potential side after writing is completed by the first compensation voltage applying drive circuit, and the second compensation voltage is applied to the second potential by the second compensation voltage applying drive circuit. The potential of the pixel electrode connected to the compensation voltage application drive circuit is shifted to a high potential side after writing is completed, and the pixel electrode is driven by the capacitive coupling column inversion driving method.

According to this method, in the structure according to the second aspect, the level of the image signal is inverted and written into the pixel electrode for each adjacent display signal line, and the image signal is inverted for each adjacent scan signal line. After writing without inverting the level, the potentials of the pixel electrodes are shifted to opposite levels by the first and second driving circuits for applying a compensation voltage. As a result, the potential of the pixel electrode connected to the same scanning signal line is alternately shifted to the opposite level for each adjacent display signal line, and the potential of the pixel electrode connected to the same display signal line is , Regardless of the scanning signal wiring, it is possible to realize the capacitive coupling column inversion driving.

The invention according to claim 7 of the present invention is directed to claim 5
7. The method of driving an active matrix liquid crystal display device according to 6, wherein the means for shifting the image signal potential of the pixel electrode to a higher potential side by the first and second compensation voltage applying drive circuits includes a switching element. In the ON period, the pixel signal is written to the pixel electrode while the electrode potential of the storage capacitor connected to the compensation voltage applying drive circuit is set to a low potential compensation voltage. As means for applying a high-potential compensation voltage by inverting the electrode potential of the storage capacitor to a high-potential compensation voltage and shifting the image signal potential of the pixel electrode to the low-potential side, in the ON period of the switching element, With the electrode potential of the storage capacitor connected to the compensation voltage application drive circuit set to the high potential compensation voltage, the pixel signal Writing to the electrode, the OFF period of the switching element, is characterized by applying a compensation voltage of a low potential by reversing the electrode potential of the storage capacitor to the low potential compensation voltage.

As described above, the image signal potential of the pixel electrode can be easily shifted by changing the compensation voltage at the time of writing the image signal and after the end of the writing.

[0028]

Embodiments of the present invention will be described below.

(Embodiment 1) Embodiment 1 of the present invention will be described. FIG. 1 is a circuit diagram of an active matrix type liquid crystal display device which enables the capacitive coupling dot inversion driving method of the present invention. The same reference numerals are given to portions corresponding to the conventional example, and detailed description is omitted. The first embodiment is characterized in that a compensation voltage application drive circuit separated into two systems is provided. The configuration will be described with reference to FIG. Reference numeral 20 denotes a first compensation voltage application drive circuit, 21 denotes a second compensation voltage application drive circuit, and 22 denotes the first compensation voltage application drive circuit 2.
Reference numeral 23 denotes a compensation voltage application signal wiring for the second compensation voltage application drive circuit 21. These first and second compensation voltage applying drive circuits 20 and 21 are alternately connected to the pixel electrodes 9 through the storage capacitors 8 for each of the display signal wirings 4 and the scanning signal wirings 3. The specific connection state between each pixel electrode 9 and the first and second compensation voltage applying drive circuits 20 and 21 is as follows. That is, in the pixel electrode 9 connected to the same scanning signal line 3, the first and second compensation voltage applying drive circuits 20 and 21 are alternately provided via the storage capacitor 8 for each adjacent display signal line 4. Are connected to the pixel electrode 9 and connected to the same display signal line 4,
First and second compensation voltage application drive circuits 20, 21
Are alternately connected to the pixel electrode 9 via the storage capacitor 8 for each adjacent scanning signal wiring 3. Therefore, if a certain pixel electrode is connected to the first compensation voltage application drive circuit 20, the upper, lower, left and right pixel electrodes are connected to the second compensation voltage application drive circuit 21, and a certain pixel electrode is connected. Are connected to the second compensation voltage applying drive circuit 21, the upper, lower, left and right pixel electrodes are connected to the first compensation voltage applying drive circuit 20. Depending on the connection state between the respective pixel electrodes and the first and second compensation voltage applying drive circuits 20 and 21,
As will be described later, the capacitive coupling dot inversion driving can be performed.

FIG. 2 is a driving waveform diagram in the method of driving the liquid crystal display device. Taking three scanning signal wirings of n rows, n + 1 rows, and n + 2 rows as an example, the pixel electrodes to which the driving waveform of the first compensation voltage applying drive circuit 20 is applied are the scanning signal wirings of the nth row. For (n, 1),
(N, 3), (n, 5),..., And (n + 1, 2), (n + 1,
4), (n + 1, 6),..., And (n + 2, 1), (n + 2, 3),
(N + 2, 5),... Here, (n, 1) is n
It means a pixel electrode (or pixel) in the row and in the first column. The same expression format is used for (n, 3), (n, 5), etc.

The second compensation voltage applying drive circuit 21
Pixel electrodes to which the drive waveform is applied are (n, 2), (n, 4), (n,
6),..., And (n + 1, 1), (n + 1, 3), (n + 1,
5),..., And (n + 2, 2), (n + 2, 4), (n + 2,
6), ...

The first and second compensation voltage applying drive circuits 20, 21 operate opposite to each other as shown in FIG. For example, the first compensation voltage applying drive circuit 20
Changes from −Vel → 0 in an odd frame and Veh → 0 in an even frame, the driving waveform of the second compensation voltage applying drive circuit 21 changes from Veh → in an odd frame.
0, -Vel → 0 in even frames.

FIG. 3 shows a change in the voltage written to the pixel electrode when the compensation voltage of the compensation voltage application drive circuit changes. FIG. 3 shows the case of the first compensation voltage applying drive circuit 20. In odd frames, the compensation voltage is Ve
At 1 the scanning signal voltage goes high (Vgh) and the image signal voltage Vsh is written to the pixel electrode. When the scanning signal voltage becomes low level (−Vgh), the voltage of the pixel electrode decreases by the penetration voltage ΔVp. afterwards,
When the compensation voltage increases from −Vel → 0, the voltage of the pixel electrode increases through the storage capacitor, and finally, VH = (Vsh−ΔVp) + (Vel × Cst / Cto)
t) Here, Ctot = Cgd + Cst + Clc. Where Cgd is the gate-drain capacitance,
Cst is a storage capacity, and Clc is a liquid crystal capacity.

In an even-numbered frame, when the compensation voltage is Veh, the scanning signal voltage goes high (Vgh), and the signal voltage Vsl is written to the pixel electrode. When the scanning signal voltage becomes low level (−Vgl), the penetration voltage ΔVp
Only, the voltage of the pixel electrode decreases. Thereafter, when the compensation voltage drops from Veh to 0, the voltage of the pixel electrode decreases through the storage capacitor, and finally, VL = (Vsl−ΔVp) − (Veh × Cst / Cto)
t) Here, Ctot = Cgd + Cst + Clc.

As described above, in the capacitive coupling method, the voltage written to the pixel electrode can be freely shifted up and down through the storage capacitor by changing the compensation voltage. Therefore, as shown in FIG.
When m is set to Vcom = (Vsh + Vsl) / 2, to make the voltage applied to the liquid crystal equal between the odd frame and the even frame, VH−Vcom = Vcom−VL∴Vel−Veh = 2ΔVp × Ctot / Cst (= 2
Veh and Vel may be set so as to satisfy (Vgh + Vgl) × Cgd / Cst.

When the above condition is satisfied, FIG.
As shown in the figure, in the odd-numbered frames, the black level is set to the maximum value V
sh, the white level is set to the minimum value Vsl, and the compensation voltage Ve is set.
Is raised from −Vel to 0, the image signal written to the pixel electrode is shifted to the plus side, and in the even-numbered frame, the black level is reduced to the minimum value Vs as shown in FIG.
1, the white level is set to the maximum value Vsh, the compensation signal Ve is reduced from Veh to 0, and the image signal written to the pixel electrode is shifted to the negative side, so that the voltage of the counter electrode is constant and low amplitude. Signal voltage (Vsh-V
The liquid crystal can be AC driven in sl).

In the first embodiment of the present invention, the first and second driving circuits 20 and 21 for applying the compensation voltage are alternately connected to the respective storage capacitors. As described above, when the drive circuits 20 and 21 operate in opposition to each other, if a certain pixel electrode potential shifts positively, the upper, lower, left and right pixel electrode potentials shift negatively, as shown in FIG. In addition, dot inversion driving by the capacitive coupling method can be performed.

(Embodiment 2) Embodiment 2 of the present invention will be described. FIG. 6 is a circuit diagram of an active matrix type liquid crystal display device which enables the capacitive coupling column inversion driving method of the present invention. In the second embodiment, parts corresponding to the first embodiment are denoted by the same reference numerals.
In the second embodiment, in the pixel electrodes 9 connected to the same scanning signal line 3, the first and second compensation voltage applying drive circuits 20 and 21 are alternately stored for each adjacent display signal line 4. In the pixel electrode 9 connected to the pixel electrode 9 via the capacitor 8 and connected to the same display signal line 4,
The same compensation voltage application drive circuit is connected to the pixel electrode 9 via the storage capacitor 8. Therefore, if the pixel electrode connected to the display signal wiring 4 in a certain column is connected to the first compensation voltage applying drive circuit 20, the pixel electrode connected to the display signal wiring 4 in the front row / back row is 2 if the pixel electrode connected to the display signal wiring 4 in a certain column is connected to the second compensation voltage applying drive circuit 21, the front row and the rear row The pixel electrode connected to the display signal wiring 4 is connected to the first compensation voltage applying drive circuit 20. Each such pixel electrode and the first
The connection state of the second compensation voltage applying drive circuits 20 and 21 enables the capacitive coupling column inversion drive as described later.

FIG. 7 shows a driving waveform in the driving method of the liquid crystal display device. Taking as an example three scanning signal wirings of n rows, n + 1 rows, and n + 2 rows, the pixel electrodes to which the drive waveform of the first compensation voltage application drive circuit 20 is applied are:
Regarding the scanning signal wiring of the n-th row, (n, 1), (n,
3), (n, 5),..., And (n + 1, 1), (n + 1, 3), (n
+1, 5),..., And (n + 2, 1), (n + 2, 3), (n + 2,
5), ...

Further, the second compensation voltage applying drive circuit 21
Pixel electrodes to which the drive waveform is applied are (n, 2), (n, 4), (n,
6),..., And (n + 1, 2), (n + 1, 4), (n + 1,
6),..., And the (n + 2, 2), (n + 2, 4), (n + 2,
6), ...

The first and second compensation voltage applying drive circuits 20 and 21 operate in opposition to each other, as in the first embodiment. As described in the first embodiment, when the compensation voltage rises from -Vel to 0, the image signal written to the pixel electrode shifts to the plus side, and when the compensation voltage falls from Veh to 0, the image signal is written to the pixel electrode. Since the image signal shifts to the negative side, the liquid crystal can be AC-driven with a low-amplitude signal voltage even when the voltage of the counter electrode is constant.

In the second embodiment of the present invention, the first and second compensation voltage application driving circuits 20 and 21 are alternately connected to the respective storage capacitors 8 for each display signal wiring 4, so that the first
As described above, when the driving circuits 20 and 21 for applying the second compensation voltage oppose each other, when a certain pixel electrode potential shifts to plus, the left and right pixel electrode potentials shift to minus. , The potential of the upper and lower pixel electrodes shifts to a positive value because it does not depend on the scanning signal wiring 3. Therefore, as shown in FIG. 8, column inversion driving by the capacitive coupling method can be performed.

(Other Matters) (1) The first and second compensation voltage applying drive circuits 20 and 21 described in the first and second embodiments.
Is preferably formed on the same substrate by a process including a process for forming the switching element 10 and incorporated therein. More preferably, a polycrystalline silicon thin film transistor forming process is applied. As a result, a new external driver is not required for applying the compensation voltage, so that the capacitive coupling dot inversion driving and the capacitance coupling column inversion driving can be realized at low cost.

(2) In the first and second embodiments, in order to shift the image signal potential of the pixel electrode to the high potential side (or the low potential side), the level of the low potential compensation voltage is changed from the low potential compensation voltage to zero level after the completion of writing. Although the voltage is changed (or from the high-potential compensation voltage to the 0 level), a high-potential (low-potential) compensation voltage may be applied by inverting the high-potential compensation voltage (or the low-potential compensation voltage).

[0045]

As described above, according to the active matrix liquid crystal display device with a built-in drive circuit of the present invention, the merit of the capacitive coupling driving that the potential amplitude of the display signal wiring can be reduced and the potential amplitude of the scanning signal wiring can be reduced. Capacitively-coupled dot inversion driving method and capacitively-coupled column inversion driving method become possible while inheriting the advantage of the drive circuit built-in method that can be made smaller, eliminating image degradation such as crosstalk and flicker, reducing power consumption, high image quality, Characteristics such as high reliability can be realized, and the practical effect is great.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing an electrical configuration of a capacitively coupled dot inversion driving type active matrix liquid crystal display device according to a first embodiment of the present invention.

FIG. 2 is a driving waveform diagram of an active matrix liquid crystal display device of a capacitively coupled dot inversion driving method according to the first embodiment of the present invention.

FIG. 3 is a voltage waveform diagram of each part of the capacitively-coupled dot inversion driving type active matrix liquid crystal display device according to the first embodiment of the present invention.

FIG. 4 is a diagram illustrating a shift state of a pixel electrode potential level due to capacitive coupling.

FIG. 5 is a diagram illustrating polarities of pixels in odd-numbered frames and even-numbered frames in the case of capacitive coupling dot inversion driving.

FIG. 6 is a circuit diagram showing an electrical configuration of a capacitively coupled column inversion driving type active matrix liquid crystal display device according to a second embodiment of the present invention.

FIG. 7 is a drive waveform diagram of a capacitively coupled column inversion drive type active matrix liquid crystal display device according to Embodiment 2 of the present invention.

FIG. 8 is a diagram illustrating polarities of pixels of odd frames and even frames in the case of capacitive coupling column inversion driving.

FIG. 9 is a general configuration diagram of an active matrix type liquid crystal display device.

FIG. 10 is an electrical equivalent circuit diagram of a display element.

FIG. 11 is a driving waveform diagram in the one-frame inversion driving method.

FIG. 12 is a configuration diagram of an active matrix liquid crystal display device based on a capacitive coupling drive system disclosed in Japanese Patent Application Laid-Open No. 2-157815.

FIG. 13 is a driving waveform diagram of Japanese Patent Application Laid-Open No. 2-157815.

FIG. 14 is a diagram showing a shift state of a pixel electrode potential level by a capacitive coupling driving method disclosed in Japanese Patent Application Laid-Open No. 2-157815.

FIG. 15 is a configuration diagram of an active matrix type liquid crystal display device according to a capacitive coupling drive method using a polycrystalline silicon thin film transistor disclosed in Japanese Patent Application Laid-Open No. 10-39277.

[Explanation of symbols]

1: scanning-side drive circuit 2: display-side drive circuit 3: scanning signal wiring (gate line) 4: display signal wiring (source line) 5: image signal wiring 6: switching element for display signal wiring 7: liquid crystal element 8: storage Capacitance 9: Pixel electrode 10: Pixel electrode switching element (pixel transistor) 11: Counter electrode 20: First compensation voltage application drive circuit 21: Second compensation voltage application drive circuit 22: First compensation voltage application Voltage Wiring for Compensation Voltage Application for Compensation Drive Circuit 23: Signal Wiring for Compensation Voltage Application for Second Compensation Voltage Application Drive Circuit

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G09G 3/20 624 G02F 1/136 500 (72) Inventor Makoto Yamakura 1006 Odakadoma, Kadoma City, Osaka Prefecture Matsushita Electric Within Sangyo Co., Ltd. (72) Inventor Masahito Matsunami 1006 Kadoma, Kazuma, Osaka Prefecture Matsushita Electric Industrial Co., Ltd. (72) Inventor Takashi Okada 1006, Oaza Kadoma, Kadoma, Osaka Prefecture Matsushita Electric Industrial Co., Ltd. Reference) 2H092 GA59 JA24 JB63 JB69 KA04 KA07 NA25 PA06 2H093 NA16 NC16 NC18 NC34 NC67 ND09 ND35 ND54 NF04 NF28 5C006 AC25 AC26 AF46 BB16 BC20 FA25 FA37 FA47 FA52 5C080 AA10 BB05 DD01 FF11 JJ02A09 A04 A09 A04 A09 AA EA04 EA04 HA05 HA08

Claims (7)

[Claims] A switching element and a pixel electrode are formed corresponding to respective intersections of a plurality of display signal lines and a plurality of scanning signal lines arranged in a matrix on an insulating substrate, and a switching element and a pixel electrode are formed on the pixel electrode via a storage capacitor. An active matrix type liquid crystal display device comprising a compensation voltage application drive circuit for applying a compensation voltage signal of a high potential compensation voltage and a low potential compensation voltage to a compensation voltage application signal wire connected in a connected manner. The circuit includes a first compensation voltage application drive circuit and a second compensation voltage application drive circuit. In the pixel electrodes connected to the same scanning signal line,
The first and second compensation voltage applying drive circuits are alternately connected to the pixel electrodes via the storage capacitors for adjacent display signal lines, and in the pixel electrodes connected to the same display signal line, ,
An active matrix liquid crystal display, wherein the first and second compensation voltage application drive circuits are alternately connected to the pixel electrodes via the storage capacitors for adjacent scanning signal lines. apparatus. 2. A switching element and a pixel electrode are formed corresponding to respective intersections of a plurality of display signal lines and a plurality of scanning signal lines arranged in a matrix on an insulating substrate. An active matrix type liquid crystal display device comprising a compensation voltage application drive circuit for applying a compensation voltage signal of a high potential compensation voltage and a low potential compensation voltage to a compensation voltage application signal wire connected in a connected manner. The circuit includes a first compensation voltage application drive circuit and a second compensation voltage application drive circuit. In the pixel electrodes connected to the same scanning signal line,
The first and second compensation voltage applying drive circuits are alternately connected to the pixel electrodes via the storage capacitors for adjacent display signal lines, and in the pixel electrodes connected to the same display signal line, ,
An active matrix liquid crystal display device, wherein the same compensation voltage application drive circuit is connected to the pixel electrode via the storage capacitor. 3. A scanning drive circuit for applying a scan signal to the scan signal wiring, a display drive circuit for applying an image signal to the display signal wiring, and the first and second compensation voltage applying drive circuits, 3. The active matrix type liquid crystal display device according to claim 1, wherein a built-in circuit formed on the same substrate as the switching element by a process including a process of forming the switching element. 4. The active matrix type liquid crystal display device according to claim 3, wherein a polycrystalline silicon thin film transistor forming process is applied as said process. 5. The method for driving an active matrix type liquid crystal display device according to claim 1, wherein a potential of an image signal applied to the display signal wiring is set for each of adjacent display signal wirings and each scanning signal wiring. Then, the level is inverted and written to the pixel electrode. A positive image signal voltage is written to the pixel electrode connected to the first compensation voltage applying drive circuit, and the second compensation voltage is applied to the pixel electrode. In the frame in which the negative image signal voltage is written to the pixel electrode connected to the drive circuit, the potential of the pixel electrode connected to the first compensation voltage application drive circuit is changed by the first compensation voltage application drive circuit. After the writing is completed, the potential of the pixel electrode connected to the second compensation voltage applying drive circuit is shifted to the high potential side by the second compensation voltage applying drive circuit. To the pixel electrode connected to the first compensation voltage application drive circuit, a negative image signal voltage is written to the pixel electrode connected to the first compensation voltage application drive circuit, and the pixel electrode connected to the second compensation voltage application drive circuit In the frame in which the image signal voltage of the positive polarity is written, the potential of the pixel electrode connected to the first driving circuit for applying the compensation voltage by the first driving circuit for applying the compensation voltage is shifted to the low potential side after the writing is completed. After the writing is completed, the potential of the pixel electrode connected to the second compensation voltage applying drive circuit is shifted to the high potential side by the second compensation voltage applying drive circuit, and the pixel electrode is driven by the capacitive coupling dot inversion driving method. A method for driving an active matrix type liquid crystal display device, comprising: 6. A method for driving an active matrix type liquid crystal display device according to claim 2, wherein a potential of an image signal applied to said display signal line is set to a level for each adjacent display signal line. Is written to the pixel electrode without inverting the level of each adjacent scanning signal wiring, and a positive image signal voltage is applied to the pixel electrode connected to the first compensation voltage applying drive circuit. In the frame in which the negative image signal voltage is written to the pixel electrode connected to the second compensation voltage applying drive circuit, the first compensation voltage is applied by the first compensation voltage applying drive circuit. The potential of the pixel electrode connected to the application driving circuit is shifted to a higher potential after the writing is completed, and the potential of the pixel electrode is connected to the second compensation voltage applying driving circuit by the second compensation voltage applying drive circuit. The written potential of the pixel electrode is shifted to a lower potential side after the writing is completed, a negative image signal voltage is written to the pixel electrode connected to the first compensation voltage applying drive circuit, and the second In the frame in which the positive image signal voltage is written to the pixel electrode connected to the compensation voltage applying drive circuit, the first compensation voltage applying drive circuit is connected to the first compensation voltage applying drive circuit. The potential of the pixel electrode is shifted to the low potential side after the writing is completed, and the potential of the pixel electrode connected to the second compensation voltage applying drive circuit is changed to the high potential after the writing is completed by the second compensation voltage applying drive circuit. A driving method for an active matrix type liquid crystal display device, wherein the driving method is shifted to the side and driven by a capacitive coupling column inversion driving method. 7. The means for shifting the image signal potential of the pixel electrode to a higher potential side by the first and second compensation voltage application drive circuits includes the compensation voltage application drive during the ON period of the switching element. The pixel signal is written to the pixel electrode with the electrode potential of the storage capacitor connected to a circuit set to a low potential compensation voltage, and during the OFF period of the switching element, the electrode potential of the storage capacitor is changed to a high potential compensation voltage. As a means for applying a high-potential compensation voltage by inverting the pixel signal and shifting the image signal potential of the pixel electrode to a lower potential side, the switching element is connected to the compensation voltage applying drive circuit during the ON period. The pixel signal is written to the pixel electrode while the electrode potential of the storage capacitor is set to a high potential compensation voltage, and the switching element is turned off.
7. The driving method of an active matrix type liquid crystal display device according to claim 5, wherein a low potential compensation voltage is applied by inverting an electrode potential of the storage capacitor to a low potential compensation voltage during the period.