JPH0922023A - Active matrix liquid crystal display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To cause no cross talk and to obtain an excellent display even when a V line is inversion-driven by nearly equalizing coupling capacities causing between both side sides of a pixel electrode and signal lines adjacent to the both side sides. SOLUTION: An interval d1L between the left-side side of the pixel electrode 28 and the signal line 22 adjacent to the left-side side is set in larger than the interval d1R between the right-side side of the pixel electrode 28 and the signal line 22 adjacent to the right-side side (diL>d1R) so that the coupling capacities C1 L, C1 R causing between the pixel electrode 28 and the signal lines 22, 22 become equal in the left/right of the pixel electrode 28 (C1 L=C1 R). Thus, even when the V line is inversion-driven, the potential change of the signal lines 22, 22 are canceled excellently in the both sides of the pixel electrode 28 holding an electric charge, and the potential fluctuation of the pixel electrode 28 according to the potential change is suppressed. Thus, the excellent display, that is, the image without cross talk and burning is obtained.

Description

Detailed Description of the Invention

[0001]

The present invention relates to an active matrix type liquid crystal display device.

[0002]

2. Description of the Related Art An active matrix type liquid crystal display device is generally constructed by holding liquid crystal between an array substrate and a counter substrate via an alignment film, and a plurality of pixel electrodes are switched on the array substrate. It is arranged so as to be electrically connected to the element.

For example, in a conventional active matrix type liquid crystal display device, an array substrate 100 has a plurality of signal lines 101 and a plurality of scanning lines 102 arranged in a matrix on a glass substrate as shown in FIG. The ITO is provided via thin film transistors (hereinafter referred to as TFTs) 103 arranged as switching elements near the intersections where the signal lines 101 and the scanning lines 102 intersect.
A pixel electrode 104 made of (Indium Tin Oxide) is arranged. An auxiliary capacitance line 105 is arranged below the pixel electrode 104 via an insulating film substantially in parallel with the scanning line 102, and an auxiliary capacitance is formed between the auxiliary capacitance line 105 and the pixel electrode 104. .

In this array substrate 100, each pixel electrode 1
In 04, the signal line 10 adjacent to the pixel electrode 104
The distances d0 and d0 between the pixel electrodes 104 and 101 and the pixel electrode 104
However, the pixel electrode 104 and the signal line 101 are arranged at equal intervals on both sides of the pixel electrode 104. This is because the distance d0 between the pixel electrode 104 and the signal line 101 is reduced to the limit of the array design in order to maximize the aperture ratio, that is, conventionally, the signal line 101 on both sides of the pixel electrode 104, The aperture ratio is earned by setting the distances d0 and d0 with respect to 101 both as design limit values (for example, 5 μm).

[0005]

By the way, the pixel electrode 1
Coupling capacitance C0 is generated between 04 and the signal line 101 adjacent thereto. This coupling capacity C0
Occurs in the adjacent portion where the side of the pixel electrode 104 and the signal line 101 are adjacent to each other, and the size varies depending on the length of the adjacent portion.

Here, in the conventional liquid crystal display device,
As shown in FIG. 5, on the left side of the pixel electrode 104, the drain electrode 106 is led out from the signal line 101. Like the signal line 101, the extracted drain electrode 106 generates a coupling capacitance with the adjacent pixel electrode 104. Therefore, on the left side of the pixel electrode 104,
The length of the adjacent portion where the coupling capacitance C0 is generated becomes longer than the right side by the length of the drain electrode 106. As a result, the coupling capacitance C0 generated on the left side of the pixel electrode 104 is larger than the coupling capacitance C0 generated on the right side.

As described above, when the coupling capacitances C0 and C0 are different on both sides of the pixel electrode 104, especially in the case of so-called V line inversion driving in which the display signal applied to the liquid crystal is inverted for every adjacent signal line. It's a problem. that is,
In the case of V line inversion driving, the positive and negative voltages of the signal lines 101, 101 adjacent to the pixel electrode 104 on both sides are different, so that the potential change of the signal lines 101, 101 on both sides of the pixel electrode 104 during the holding operation is suppressed. This is because it cannot be canceled well and the potential fluctuation of the pixel electrode 104 becomes large. As a result, there is a problem that crosstalk occurs and a good display cannot be obtained.

Therefore, in view of the above problems, it is an object of the present invention to provide an active matrix type liquid crystal display device in which crosstalk does not occur even when V line inversion driving is performed and good display can be obtained. .

[0009]

According to another aspect of the present invention, there is provided an active matrix type liquid crystal display device comprising a plurality of scanning lines and signal lines arranged on an insulating substrate so as to intersect with each other, and the scanning lines and the signal lines. An array substrate having switching elements arranged at each intersection and pixel electrodes connected to the switching elements; a counter substrate having counter electrodes arranged to face the array substrate; and the array substrate. In an active matrix type liquid crystal display device including a liquid crystal held between the counter substrate and a counter substrate, a coupling capacitance generated between both side edges of the pixel electrode and the signal lines respectively adjacent to the both side edges. Are almost equal.

According to a second aspect of the present invention, in the active-matrix liquid crystal display device according to the first aspect, the distance between the first side of the pixel electrode and the signal line adjacent to the first side and the first side of the pixel electrode. The distance between the second side and the other signal line adjacent to the second side is different, and the coupling capacitances are set to be substantially equal.

An active matrix liquid crystal display device according to a third aspect is the liquid crystal display device according to the first aspect, wherein a switching element is formed from the signal line located on the first side of the pixel electrode toward the pixel electrode. Of the coupling capacitance generated between the pixel electrode and the switching element, and the coupling capacitance generated between the first side of the pixel electrode and the signal line adjacent to the first side. The first coupling capacitance, which is the sum, is substantially equal to the second coupling capacitance generated between the second side of the pixel electrode and the other signal line adjacent to the second side. As described above, the distance between the first side of the pixel electrode and the signal line adjacent to the first side, and the other signal line adjacent to the second side and the second side of the pixel electrode. With a different distance from That.

According to a fourth aspect of the present invention, in the active matrix type liquid crystal display device according to the first aspect, a shield member that forms an auxiliary capacitance between the pixel electrode and the pixel electrode is provided so as to extend along both sides of the pixel electrode. The length of the shield member on the first side of the pixel electrode is made different from the length of the shield member on the second side of the pixel electrode, and the coupling capacitances are set to be substantially equal.

An active matrix liquid crystal display device according to a fifth aspect is the liquid crystal display device according to the first aspect, wherein a switching element is formed from the signal line located on the first side of the pixel electrode toward the pixel electrode. A shield member that forms an auxiliary capacitance between the pixel electrode and the pixel electrode is provided so as to extend along both sides of the pixel electrode, and the coupling capacitance generated between the pixel electrode and the switching element and the pixel A first coupling capacitance, which is the sum of the coupling capacitance generated between the first side of the electrode and the signal line adjacent to the first side, the second side of the pixel electrode, and the second side of the pixel electrode. The length of the shield member on the first side of the pixel electrode and the pixel electric potential are substantially equal to the second coupling capacitance generated between the other signal line adjacent to the second side. It is obtained by difference and the length of the shield member of the second side edge of the.

[0014]

In the active matrix type liquid crystal display device according to the first aspect, the coupling capacitances generated on both sides of the pixel electrode and the signal lines adjacent to the both sides are substantially equal to each other. Therefore, even when the polarities of the voltages applied to the two signal lines adjacent to both sides of one pixel electrode are different from the reference voltage as in the V line inversion drive, the signal line during the holding operation of the pixel electrode is performed. It is possible to satisfactorily cancel the potential change on both sides of the pixel electrode, and suppress the pixel potential fluctuation associated with the potential change.

According to another aspect of the active matrix type liquid crystal display device of the present invention, for example, a space between a left side of the pixel electrode and a signal line adjacent to the left side, a right side of the pixel electrode and a signal line adjacent to the right side of the pixel electrode. The distances between and are different from each other, and the left and right coupling capacities are set to be substantially equal.
If the distances between the pixel electrodes and the signal lines on both sides are equal, the left and right coupling capacitances are not equal due to the influence of switching elements and the like. Therefore, one of the left and right sides is separated from the signal line by a larger distance than the other side, so that the coupling capacitance of the one side is reduced by the above influence to reduce the coupling capacitance of the left and right sides. They are almost equal.

According to another aspect of the active matrix type liquid crystal display device, for example, a switching element is formed by the signal line located on the left side of the pixel electrode, and the coupling generated between the switching element and the pixel electrode. In consideration of the capacitance, the intervals between the left and right side signal lines of the pixel electrode are made different so that the left and right coupling capacitances are substantially equal. Alternatively, for example, a switching element is formed from a signal line located on the right side of the pixel electrode, and the left and right coupling capacitances are substantially equal in consideration of the coupling capacitance generated between the switching element and the pixel electrode. The distances from the signal lines on the left and right sides of the pixel electrodes are made different so as to be equal.

In the active matrix type liquid crystal display device according to a fourth aspect of the present invention, the shield member provided so as to extend along both sides of the pixel electrode forms an auxiliary capacitance between the shield member and the pixel electrode. In the portion where the member is arranged, there is no potential variation of the pixel electrode due to the potential variation of the signal line, and therefore the coupling capacitance with the signal line can be ignored. That is, since the size of the coupling capacitance generated between the signal line and the signal line can be adjusted by the length of the shield member, for example, the length of the shield member is made different between the left and right side edges of the pixel electrode, The left and right coupling capacities are set to be substantially equal. If the lengths of the shield members are equal on both sides of the pixel electrode, the left and right coupling capacitances will not be equal due to the influence of switching elements and the like. Therefore, the length of the shield member on one side of the left and right sides is made longer than the length of the other side, and the coupling capacity of the one side is reduced by the above influence to reduce the coupling capacity of the left and right sides. They are almost equal.

In the active matrix type liquid crystal display device according to a fifth aspect, for example, a switching element is formed from a signal line located on the left side of the pixel electrode, and the coupling generated between the switching element and the pixel electrode. In consideration of the capacitance, the lengths of the shield members on the left and right sides of the pixel electrode are made different so that the left and right coupling capacitances are substantially equal. Alternatively, for example, a switching element is formed from a signal line located on the right side of the pixel electrode, and the left and right coupling capacitances are substantially equal in consideration of the coupling capacitance generated between the switching element and the pixel electrode. The lengths of the shield members on the left and right sides of the pixel electrodes are made different so as to be equal.

[0019]

DETAILED DESCRIPTION OF THE INVENTION An active matrix type liquid crystal display device 10 according to an embodiment of the present invention will be described below with reference to FIGS.

The active matrix type liquid crystal display device 10 is a normally white mode light transmission type liquid crystal display device, and is twisted between the array substrate 12 and the counter substrate 14 via alignment films 13 and 15. A liquid crystal panel 18 holding a nematic liquid crystal 16 is used.

The array substrate 12 is formed on the glass substrate 20.
The 640 × 3 signal lines 22 and the 480 scanning lines 24 are arranged so as to be substantially orthogonal to each other. The scanning lines 24 are arranged directly on the glass substrate 20, while the signal lines 22 are arranged on the insulating film 30 formed on the glass substrate 20 and made of a multilayer film of silicon oxide and silicon nitride. Pixel electrodes 28 are arranged in the vicinity of the intersections where the signal lines 22 and the scanning lines 24 intersect with each other through the TFTs 26 at the respective intersections.

In the TFT 26, the scanning line 24 itself is used as a gate electrode, and an insulating film 30 is disposed on the gate electrode.
An a-Si: H film is provided on the semiconductor film 32, and a channel protection film 34 made of silicon nitride is provided on the semiconductor film 32. Then, the semiconductor film 32
Is a low resistance semiconductor film 36 made of an n ⁺ type a-Si: H film.
The pixel electrode 28 disposed on the insulating film 30 is electrically connected to the pixel electrode 28 via the source electrode 38. The semiconductor film 32 is electrically connected to the signal line 22 via the low resistance semiconductor film 36 and the drain electrode 40 extending from the signal line 22.

Now, the structure of the pixel electrode 28 will be described with reference to FIG. The pixel electrode 28 has a substantially rectangular shape.
Adjacent to the signal lines 22 and 22 on the long side arranged on the left and right,
These two signal lines 22 and 22 and the two scanning lines 2 are adjacent to the scanning lines 24 and 24 on the short side arranged vertically.
It is surrounded on all sides by 4 and 24. The upper side is connected to the left signal line 22 through the TFT 26, and the lower side is connected to the pixel electrode 2 of the next stage.
A notch 42 for extending the TFT 26 of No. 8 as the drain electrode 40 is formed.

The distance d1L between the left side of the pixel electrode 28 and the signal line 22 adjacent to the left side is the coupling capacitance C1L generated between the pixel electrode 28 and the signal lines 22, 22.
C1R should be equal on the left and right of the pixel electrode 28 (C1L =
C1R) is set to be larger than the distance d1R between the right side of the pixel electrode 28 and the signal line 22 adjacent to the right side (d1R).
1L> d1R). This is because, on the left side of the pixel electrode 28, the length of the portion that generates the coupling capacitance is longer than that on the right side due to the influence of the drain electrode 40 of the next stage. Therefore, when d1L = d1R, the coupling is generated on the left side. This is because the capacity becomes large. In this way, the pixel electrode 2
Distances d1L and d1R from the signal line 22 on both left and right sides of 8
Is set so that C1L = C1R, so that the coupling capacitance between one signal line 22 and the two pixel electrodes 28 adjacent to the left and right sides thereof is also equal.

Below the pixel electrode 28, the scanning line 24
An auxiliary capacitance line 44 is arranged substantially in parallel with and passing through substantially the center of the pixel electrode 28. This auxiliary capacitance line 4
4 is directly formed on the glass substrate 20. And
An insulating film 30 is interposed between the auxiliary capacitance line 44 and the pixel electrode 28 to form an auxiliary capacitance Cs. In order to avoid a short circuit with the signal line 22 while securing the auxiliary capacitance Cs, the auxiliary capacitance line 44, as shown in FIG.
8 is thick in a region overlapping with 8 and thin in a region intersecting with the signal line 22.

On the other hand, the counter substrate 14 is such that the TFT 26 and the pixel electrode 28 of the array substrate 12 are provided on the transparent glass substrate 48.
A light-shielding film 50 made of a chromium oxide film for light-shielding a gap between the light-shielding films, and red (R), green (G), and blue (B) for realizing a color display disposed between the light-shielding films 50. And a color section 52 composed of three primary colors. Then, a counter electrode 56 made of ITO is arranged thereon as a smoothing layer via an organic protective film 54.

Polarizing plates 58 and 60 are provided on the outer surfaces of the glass substrates 20 and 48 on the front and back surfaces of the liquid crystal panel 18 constructed as described above, respectively. Further, the signal line 22 and the scanning line 24 are drawn out to one side of the wiring, respectively, and are provided on a drive circuit board (not shown) for driving the liquid crystal panel 18.
It is connected via B (not shown), and a drive voltage is supplied.

In the liquid crystal display device 10 described above, the coupling capacitances C1L, C1 between the pixel electrode 28 and the signal line 22 are provided.
Since 1R is equal on both the left and right sides of the pixel electrode 28, the potential changes of the signal lines 22 and 22 are well canceled on both sides of the pixel electrode 28 where the electric charge is retained even when the V line inversion drive is performed. It is possible to suppress the potential fluctuation of the pixel electrode 28 due to this potential change. Therefore, it is possible to obtain a good display, that is, an image without crosstalk or burn-in.

Further, since the coupling capacitances C1L and C1R are equal on both sides of the pixel electrode 28, there is no application of an undesired DC component to the liquid crystal 16, and therefore the durability is improved and even for long-term use. Image deterioration is unlikely to occur. This is not limited to the case of the V line inversion drive described above, but for example, so-called H line inversion drive in which the display signal applied to the liquid crystal 16 for every adjacent scanning line or every several scanning lines is inverted between positive and negative with respect to the reference potential. In addition, this is an effect that can be obtained even in HV inversion driving in which V line inversion driving and H line inversion driving are combined.

Next, an active matrix type liquid crystal display device 70 according to another embodiment of the present invention will be described with reference to FIGS.
This will be described with reference to FIG.

The liquid crystal display device 70 is different from the above-described liquid crystal display device 10 in the arrangement of the pixel electrode 28 with respect to the signal line 22 and the shape of the auxiliary capacitance line 44. Hereinafter, only this difference will be described.

In the array substrate 12 of this device 70, in each pixel electrode 28, the left and right sides 28 of the pixel electrode 28 are formed.
a, 28b and the distances d2L, d2R between the signal lines 22, 22 respectively adjacent to the both sides 28a, 28b are equal on both sides of the pixel electrode 28 (d2L = d2R), that is, the pixel electrode 28 and The signal lines 22 are arranged at equal intervals.

The auxiliary capacitance line 44 is composed of two adjacent scanning lines 2.
4 and 24 are arranged at substantially equal intervals and in parallel with each other, and elongated strip-shaped wiring portions 72 are extended from both upper and lower sides of the wiring portions 72 so as to be orthogonal to the wiring portions 72. An auxiliary capacitance Cs is formed between the extension portion 74 and the pixel electrode 28. This extension 74
Are formed along the left and right side edges 28a and 28b of the pixel electrode 28, and shield the edge area of the pixel electrode 28 inside the side edges 28a and 28b, and the side edge 2
It has an appropriate width so as to partially shield the region between the signal line 22 and the pixel electrode 28 outside the portions 8a and 28b. The extended portion 74 is formed on the left side 2 of the pixel electrode 28.
The extension portion 74a of 8a is set to be longer than the extension portion 74b of the right side 28b by k on both upper and lower sides of the wiring portion 72. This difference 2 k in length is caused by the pixel electrode 28.
Are set so that the coupling capacitances C2L and C2R of the pixel electrode 28 and the signal line 22 are equal on the left and right sides (C2L = C2R).

In the case of this liquid crystal display device 70, the signal line 2
Since the extended portion 74 of the constant potential auxiliary capacitance line 44 extends along both sides 28a and 28b of the pixel electrode 28 adjacent to 2, the potential change of the signal line 22 in this extended portion. It is possible to eliminate the potential fluctuation of the pixel electrode 28 due to the above, and thus the coupling capacitance with the signal line 22 can be ignored. Therefore, the size of the coupling capacitance generated between the extension portion 74 and the signal line 22 can be adjusted by the length of the extension portion 74. In the present device 70, the increase in the coupling capacitance on the left side of the pixel electrode 28 due to the influence of the drain electrode 40 in the next stage is taken as the extension 74a on the left side.
Is made longer than the extension portion 74b on the right side by 2k, thereby maintaining the relationship of C2L = C2R.

Further, in the present device 70, as described above, since the extension portion 74 of the auxiliary capacitance line 44 shields the influence of the potential change of the signal line 22, the extension portion 74 shields the pixel electrode. The absolute values of the coupling capacitances C2L and C2R on both sides of 28 can be reduced.

As described above, according to the present device 70, the effect of suppressing the potential variation of the pixel electrode 28 when the V line inversion drive is performed is excellent, and thus a good display without crosstalk or burn-in can be obtained. . Further, in various driving methods such as H line inversion driving, the durability of the liquid crystal is improved, and it is possible to prevent image deterioration due to long-term use.

Furthermore, since the extended portion 74 of the auxiliary capacitance line 44 has the relationship of C2L = C2R, the distances d2L and d2R between the pixel electrode 28 and the signal line 22 can be reduced to the design limit. Further, since the region where the extended portion 74 is arranged is a region which is shielded by the light shielding film 50 of the counter substrate 14, it is possible to reduce the reduction in the aperture ratio due to the auxiliary capacitance line 44. Therefore, the device 70 has a high aperture ratio.

In the present embodiment, the auxiliary capacitance line 44
It is preferable to extend the length of the extended portion 74 as long as possible because the absolute values of the coupling capacitances C2L and C2R can be further reduced, but if it is made too long, it is easy to short-circuit with the scanning line 24. Since the yield deteriorates, it is necessary to set the length in consideration of this point.

Further, in this embodiment, the auxiliary capacitance line 44 independent of the scanning line 24 forms a shield member for shielding both side portions of the pixel electrode 28. However, such a shield member is It can also be formed by extending from the scanning line 24.

In this embodiment, the pixel electrode 2
Although the distances d2L and d2R between the signal line 8 and the signal line 22 are set to be equal, the distances on both sides of the pixel electrode 28 may be different as in the previous embodiment. However, even in that case, it is necessary to set the left and right coupling capacitances C2L and C2R of the pixel electrode 28 to be substantially equal. Further, when changing the distance between both sides of the pixel electrode 28, the left and right extension portions 7
It is also possible to arrange the auxiliary capacitance line 44 in which the lengths of 4a and 74b are equal. In this case, the coupling capacitances on both sides of the pixel electrode 28 may be set to be equal depending on the arrangement configuration of the pixel electrodes 28. In this case, the absolute value of the coupling capacitance is reduced by the extension portion 74. effective.

In each of the above-mentioned embodiments, the pixel electrode 2 is used.
8 and the signal line 22 are arranged with a positive interval, this is a negative interval, in other words, the pixel electrode 28 and the signal line 22 are in a positional relationship such that they partially overlap. It doesn't matter.

[0042]

According to the active matrix type liquid crystal display device of the present invention, since the coupling capacitances generated between the pixel electrode and each of the adjacent signal lines are substantially equal to each other, even when the V line inversion drive is performed, for example. It is possible to suppress the fluctuation of the pixel potential due to the change of the potential of the signal line during the holding operation of the pixel electrode, and thus it is possible to obtain a good display without crosstalk or burn-in.

[Brief description of drawings]

FIG. 1 is a partial schematic plan view of an array substrate 12 of an active matrix type liquid crystal display device 10 according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view of the active matrix liquid crystal display device 10 taken along the line AA of FIG.

FIG. 3 is a partial schematic plan view of an array substrate 12 of an active matrix type liquid crystal display device 70 according to another embodiment of the present invention.

4 is a cross-sectional view of an essential part of an active matrix liquid crystal display device 70 taken along the line BB in FIG.

FIG. 5 is a partial schematic plan view of an array substrate 100 of a conventional active matrix type liquid crystal display device.

[Explanation of symbols]

10, 70 ... liquid crystal display device 12 ... array substrate 14 ... counter substrate 22 ... signal line 24 ... scanning line 26 ... TFT 28 ... pixel electrode 28a, 28b ... pixel electrode adjacent to the signal line 22 28
Side 44 of the auxiliary capacitance line 74 ... extended portion of the auxiliary capacitance line 44 d1L, R, d2L, R ... Distance between the pixel electrode 28 and the signal line C1L, R, C2L, R ... pixel electrode Coupling capacitance between 28 and signal line 22

Claims (5)

[Claims] 1. A plurality of scanning lines and signal lines arranged so as to intersect on an insulating substrate, a switching element arranged at each intersection of these scanning lines and signal lines, and a pixel electrode connected to the switching element. An active matrix type liquid crystal comprising: an array substrate having an array substrate; a counter substrate having a counter electrode arranged to face the array substrate; and a liquid crystal held between the array substrate and the counter substrate. In the display device, an active matrix type liquid crystal display device, wherein coupling capacities generated between both sides of the pixel electrode and the signal lines adjacent to the both sides are substantially equal to each other. 2. The distance between the first side of the pixel electrode and the signal line adjacent to the first side, and the second side of the pixel electrode.
2. The active matrix according to claim 1, wherein the coupling capacitances are set to be substantially equal to each other by setting a distance between a side edge and another signal line adjacent to the second side edge to be different. Type liquid crystal display device. 3. A liquid crystal display device in which a switching element is formed from the signal line located on the first side of the pixel electrode toward the pixel electrode, and occurs between the pixel electrode and the switching element. The coupling capacitance, the first side of the pixel electrode, and the first side
The first coupling capacitance, which is the sum of the coupling capacitance generated between the signal line adjacent to the side edge, and the second coupling edge adjacent to the second side edge and the second side edge of the pixel electrode. The distance between the first side of the pixel electrode and the signal line adjacent to the first side and the pixel electrode so that the second coupling capacitance generated between the pixel electrode and the signal line is substantially equal. 2. The active matrix type liquid crystal display device according to claim 1, wherein the second side and the other signal line adjacent to the second side have different intervals. 4. A shield member for forming an auxiliary capacitance between the pixel electrode and the pixel electrode is provided so as to extend along both sides of the pixel electrode, and a length of the shield member on a first side of the pixel electrode and 2. The active matrix type liquid crystal display device according to claim 1, wherein the length of the shield member on the second side of the pixel electrode is made different so that the coupling capacitances are set to be substantially equal. 5. A liquid crystal display device in which a switching element is formed from the signal line located on the first side of the pixel electrode toward the pixel electrode, the shield forming an auxiliary capacitance with the pixel electrode. A member is provided so as to extend along both sides of the pixel electrode, the coupling capacitance generated between the pixel electrode and the switching element, the first side of the pixel electrode, and the first side of the pixel electrode.
The first coupling capacitance, which is the sum of the coupling capacitance generated between the signal line adjacent to the side edge, and the second coupling edge adjacent to the second side edge and the second side edge of the pixel electrode. The length of the shield member on the first side of the pixel electrode and the shield member on the second side of the pixel electrode are set so that the second coupling capacitance generated between the signal line and the second line becomes substantially equal. The active matrix type liquid crystal display device according to claim 1, wherein the length is different.