TWI281065B - Multi-domain vertically alignment (MVA) LCD and Method for compensating color shifting - Google Patents

Abstract

A method for compensating a color shifting is adapted for a pixel cell with MVA structure. The pixel cell has least two display domain, and each display domain has a TFT. Wherein, a first source/drain electrode of each TFT receives a data voltage, and a second source/drain electrode of each TFT is coupled to a common voltage via parallel a storage capacitance and a liquid crystal capacitance. The present invention makes each display domain to have different parasitical capacitance, storage capacitance, or liquid crystal capacitance for having different feed-through voltage. Which can efficiently compensate the color shift of MVA panel caused by different viewing angle, and more uniform of display quality of MVA panel.

Description

I2810^7tw, doc/O〇6 IX. Description of the Invention: [Technical Field] The present invention relates to a method for compensating for color shift, and in particular to a multi-domain vertical alignment type (Multi- Domain

Vertically Alignment (MVA) panel compensation method for color shift. [Prior Art]

For a conventional multi-domain vertical alignment type liquid crystal display, liquid crystal molecules can be arranged in multiple directions due to alignment protrusions or slits disposed on a color filter substrate or a thin film transistor array substrate. 'Get a number of different alignment areas (Domain), so multi-domain vertical alignment liquid crystal display can achieve a wide viewing angle. Even so, the transmittance-level curve of the multi-domain vertical alignment liquid crystal display has different curvatures depending on the viewing angle. In other words, when the viewing angle changes, multi-domain vertical alignment liquid crystal display

The brightness displayed by the indicator changes, which leads to insufficient color shift and color saturation. Fig. 1A is a graph showing the characteristic of the package-to-penetration of a conventional multi-domain vertical alignment type liquid crystal display panel. Referring to FIG. 1A, the curve Η represents the frontal gaze of the rural area to the disciplinary panel. However, when the multi-domain vertical = time is viewed at an oblique angle, the penetration of the pupil surface at the same operating voltage, the α攸 curve 11 drifts to the curve 13. Figure 1 Β can not view the improved multi-domain vertical tilt angle. 1281065 16747twf.doc/006 Alignment liquid crystal display panel voltage versus penetration characteristics. Referring to FIG. 1B, curve 13 represents a change in the transmittance of a display region of the improved multi-domain vertical alignment type liquid crystal display panel at an oblique angle, the threshold voltage of which is lower than the threshold voltage when viewed from the front. Curve 15 represents the characteristic of the transmittance versus voltage of the other display region, and the threshold voltage is higher than the threshold voltage when viewed from the front. When curve 13 and curve 15 are optimized, the characteristic curve of curve 17 is obtained. The change in the curve will be similar to the change in penetration when looking straight ahead. Therefore, with the improved technique of Fig. 1B, when the modified multi-domain vertical alignment type liquid crystal display panel is viewed at an oblique angle, the change in transmittance is similar to the change in the transmittance in front view.

Fig. 2 is a schematic view showing a multi-domain vertical alignment type of a halogen region. In the pixel 200, it can be divided into display areas eight and six. Wherein, the threshold voltage of the display area A is greater than the display area B. Therefore, when the angle of the display area A is changed by a tilt angle, the change in the transmittance of the display area A is as shown by the curve 15 of FIG. 1B, and the voltage versus the transmittance of the display area b. The change will be as shown by curve 13 of green in Figure 1B. Therefore, the change in the electrical penetration of the main element 200 as a curve & the reason, the technology of the 1B to watch the 昼 肖 ,, whether it is direct or squint, its penetration The amount of change will be very similar. In order to realize the above technology, Fujitsu has developed a multi-domain vertical alignment type halogen structure, as shown in Fig. 3A. Please refer to the electric=substrate, covered with a nitrogen-cut protective layer 3〇3. However, the transparent electrodes 3〇5 and 3〇7 are arranged to ensure that the entire 1281065 16747twf.doc/006 pixel area is divided into the immersion 30Q non-region and B. Among them, the electrode 3〇7 is electrically connected to the 'and the electrode 305 is floated to the electrode 3〇9. Further, between the panel 301 and the opposite substrate 311, a liquid crystal layer 313 is filled. As can be seen from FIG. 3A, in the display region A, since the electrode 3〇7 and the source terminal 309 are equipotential, and the common electrode 315 on the opposite substrate is connected to a common voltage, liquid crystal is formed in the liquid crystal layer 313. Electricity &

In the display region b, the protective layer capacitance is formed between the electrode layer 309 and the electrode 3'5. The electrode 305 and the mound and the electrode 315 are the same as the display region a, and a liquid crystal cell CLC is also formed. & Figure 3B shows an equivalent circuit diagram of the germanium structure of g 3A. Please, according to Fig. 3A and Fig. 3B, the 汲 extreme electrical connection of the thin film transistor 321 & 资 line 31' is electrically connected to the scanning line %. In addition, the film is two inches

The first terminal is electrically connected to the storage capacitor Cst' and is connected to display S, the liquid crystal cell G, and the protective layer capacitor sm and the liquid crystal capacitor CLC in the connection display region B. The wiper, the liquid crystal capacitor in the display area A, and the protective layer capacitance CsiN and ^曰^ Q ' in the display area B are respectively stored to store the voltages V2 and v3, respectively, the threshold voltage is greater than the display: Effect. ^ |包土叫 Although the structure in Figure 3A, its structure is complex, so in the cloth μ / ' = problem ° & and by the crying & „ π $ 仕师线 (Lay〇ut), will be sacrificed Liquid crystal display [Summary of the invention] From the beginning of the day, the penetration of the surface is reduced. 6747twf.doc/006 Therefore, the object of the present invention is to provide a compensation method for color shift, which can effectively compensate for viewing at different angles. A color shift phenomenon generated when a multi-domain vertical alignment type liquid crystal display panel is provided. A further object of the present invention is to provide a multi-domain vertical alignment type liquid crystal display panel which can solve different angles of view without sacrificing opening degree. The color shift phenomenon. The multi-domain vertical alignment (MVA) structure of the present invention provides a halogen (hereinafter referred to as MVA halogen), which has at least two display regions, and each display region is configured with a thin film transistor. Wherein, each of the thin film electro-crystal systems is electrically connected to the halogen electrode and the storage capacitor, and each of the thin film transistors has a parasitic capacitance between the gate terminal and the second source/drain terminal, and the parasitic capacitance values are mutually phase Therefore, each display area has a different feed-through voltage. In addition, the multi-domain vertical alignment type (MVA) liquid crystal display π panel φ board provided by the present invention includes a substrate and a majority Among them, 'all the elements are placed on the substrate. * Each - the halogen is divided into a plurality of display areas, and the capacitance values of the storage capacitors in each display area are different from each other' so that each display The area will have a non-feedthrough voltage. In addition, a plurality of data lines, a plurality of lines, and a plurality of storage capacitor lines are disposed on the substrate. The towel, the (four) line and the scan line are substantially perpendicular to each other, and the storage capacitor line is divided into Each side of each of the scan lines is disposed at the intersection of each of the lean line and the scan line, and is provided with a halogen. In the preferred embodiment, each element has a first one. The non-region and the second display region, um are on both sides of the corresponding scan line, and respectively correspond to the electric 12810 to 47twf.doc/006 12810 to 47twf.doc/006 to connect the above storage capacitor line. f In the present invention Every 昼素 has - two and - A halogen electrode, wherein the first transistor crystal field, and: the second display region and the second display region line, and the gate terminal, the electrical connection ίΓ: two or two electricity: connected to the same - pheromone electrode system! Sexually connected to the first transistor, and the second book: the first picture corresponds to the position of the first display area, and the electrical connection: the first = the corresponding storage capacitance line. The second element electrode 4;:: : a two-region transistor, and the position of the second halogen electrode is ^2 to 22, and on the substrate, there are a plurality of data lines and sweeps and the culverts (4) are arranged parallel to each other along a predetermined direction, and The selection lines are also arranged parallel to each other. In addition, the line: this mutual f: 'There are a number of storage capacitor lines, which are also arranged parallel to the scanning skin. In addition to this, there are also a number of elements that are arranged on the top three and each of the elements corresponds to the -f feed line and the scan line. Each of the eight elements is divided into a plurality of display areas, each of which is arranged in the pair of scales. Further, the present invention further provides a multi-domain vertical alignment type liquid crystal display surface f having a substrate. On the substrate, there are a plurality of data lines and a sweeping line, wherein the data lines are arranged parallel to each other along a predetermined direction and perpendicular to the scanning lines, and the scanning lines are also arranged parallel to each other. In addition,

1281065 16747twf.doc/006 There are also a number of active switching elements on the substrate, which are electrically connected to each other, and each active-with-’, – source and – drain. Its: ": Second, the source of the component is at the same time with the electric circuit switch board of the data line, f2 right this month provides a multi-domain vertical alignment type liquid crystal display surface t and on the substrate has a lot of data edges There are two scanning lines and a plurality of storage capacitor lines, wherein the data lines are arranged parallel to each other along the -preset = and perpendicular to the scanning lines, and each of the scanning lines and the storage capacitors are arranged parallel to each other. In the area surrounded by the storage capacitor line of each data line f, there is a - element. Among them, each of the halogen elements corresponds to a plurality of active switching elements, and these wire type switching elements have different parasitic capacitances. - In the present invention, different display regions have different feed-through voltages by fabricating a ratio of parasitic valleys and storage valleys between different display regions. Thereby, it is possible to compensate for the color shift phenomenon of the MVA panel at different viewing angles. The above and other objects, features, and advantages of the present invention will be apparent from the description of the appended claims. [Embodiment] FIG. 4 is a schematic diagram of an MVA panel in accordance with a preferred embodiment of the present invention. Referring to FIG. 4, on the substrate of the mva panel, a plurality of data lines DL1 to DLm and a plurality of scanning lines SLi to SLn are disposed. Where the 'data lines DL^DLn^ are arranged in parallel with each other, and the scanning line SL^SLn

1281065 16747twf.doc/006 , arranged parallel to each other and interlaced with the data line team ~ DLm. Generally, the direction of the line line SLrSLn will be substantially perpendicular to the data and lines DLi~DLj_. In each intersection of the data line and the scan line, there is a - element. For example, 'the pixel 411 is placed at the parent meeting where the data line is called the scan line %. In addition, on the MVA panel, a plurality of storage capacitor lines 1 to fLn+1j are arranged in parallel with the scanning lines SL! to SLn, and are respectively arranged on both sides of each scanning line. For example, on both sides of the scanning line sL1, storage capacitance lines CLi and CL2 are disposed, and on both sides of the scanning line SL2, storage capacitance lines CL2* cl3 are disposed. In terms of the structure of the MVA, each of the alizarins can be displayed in a plurality of times. Taking the pixel 411 as an example, it can be divided into display areas A and B. In particular, in the present invention, the position of each display area is respectively disposed on both sides of the corresponding scan line, and is electrically connected to one of the storage capacitor lines. FIG. 5 is an enlarged view of one of the elements of the MVA panel of FIG. 4. Referring to Fig. 5, in order to clarify the following description, the person skilled in the art can clearly understand the main spirit of the present invention. Therefore, the following description will be made only with the structure of the prime. Those skilled in the art should be able to infer the structure of the remaining elements by means of pixels. In the halogen 5, thin film dielectrics 501 and 503 are included. Wherein, the source terminals 5〇la and 503a of the thin film transistors 501 and 5〇3 are electrically connected to the data line 01^, and the gate terminal and the 5〇 complement are electrically connected to the scan line SLj, and the terminal is not extremely 501c and 503c are electrically connected to the halogen electrodes 505 and 507, respectively. 128 l〇65twfM〇6 Eight, the position of the halogen electrode 5〇5 and 5〇7, .... In other words, = 507 曰 / knife is located on both sides of the scan line. , special _ is 'on the date of this, by making each - capacitance value different from each other, so that each - display shell teeth will be repeated. That is to say, the storage capacitors and the ‘capacitance values are different from each other, so that the 昼素口口 〇:ΐ has different feedthrough voltages. Since the driving electric drive per per-display area is the lean voltage, the feedthrough is subtracted. Moreover, since each display area has a voltage that does not pass through, the voltage of each turn of the area and the voltage applied to the pixel electrode in each display area are different. That is to say, the voltage difference between the liquid crystal layers in each display area is different, so that the liquid crystal molecules in the liquid crystal layer in each display area are deflected to different degrees, and the transmittance of the mother-side region is changed. There will be differences, which compensates for the color shift caused by the viewing angle of the MVA panel. Gantu 6 shows the equivalent circuit of the pixel structure of Fig. 5. Referring to FIG. 6, in the display area 50A, the source terminal 5〇1 of the thin film transistor 5〇1 is electrically connected to the data line DLj to receive a data voltage, and the gate terminal 5〇1b is electrically connected to the scan line SLj. To receive a scan signal, the 汲 extreme 5 〇 lc is electrically connected to the storage capacitor Cstl and the liquid crystal capacitor CLC1. In addition, in the display area 5〇〇b, the source terminal 12 1281065 of the thin film transistor 503 is electrically connected to the data line DLi to receive — two electrical connections to the scan line SLj to receive one. Scan === transistor ~^ reduce memory Cst:2 and liquid crystal capacitor Clc2 〇When scanning signal is input from scan line SLj to thin film transistor, h 501b ' material voltage is transmitted through thin film transistor 5G1 At the gate of the thin film transistor 5〇1, in the preparation of the oceanic hopper, 4 thousand to J (7) bits are finer than the 汲 extreme 501c. Similarly, parasitic capacitance is also generated between the gates of the thin film transistor 503. In general, the correction will be broken, but the charge will still be combined with the (four) age capacitor, so that the sputum secret will continue to maintain the pressure of the package. However, the voltage value maintained by the elemental electrode is There is a gap in the voltage value of the halogen electrode when the thin film is turned on. This kind of image is the Feed-Through Effect. And this is called the feed-through voltage (Feed-Through V〇ltage) " From the above, it can be known that the display area 5, such as at least two private valleys within 5〇%, is the parasitic capacitance cgsl and cgs2, storage Capacitors Csti and two and liquid crystal electricity *CLC1 and CLC2. Therefore, the present invention can make the display region (10)^ and the chirp ratio S different feedthrough voltages by the two=capacitance capacitors Cgs1 and Cgs2, the storage capacitors Cstl and Cst2, and the liquid crystal package and the 电容(2) capacitance value 彡. Among them, (10) voltage can be obtained by learning:

ΔV (VgsH _VgsL) Cg Clc +CSt +c. (1) where Δν is the feedthrough voltage and (VgsH_VgsL) is the scan signal

13 12810 Start 7twf.doc/006 The potential difference between the enabled and disabled states. According to the present invention, the lock-through voltage of the display region 5. can be determined by changing the capacitance values of the parasitic capacitance & storage capacitor and capacitor CLC1. In the present invention, the present invention can also store the voltage of the parasitic capacitance cgs2^. The capacitance values of the electric valley Cst2 and the liquid crystal capacitor CLC2 determine the feedthrough voltage of the display region 5〇〇. Figure 7 is a table showing the relationship between voltages in a pixel in accordance with a preferred embodiment of the present invention. Referring to Fig. 6 and Fig. 7 in combination, in order to clarify the simplifications, only the case of the grayscale value 丨28 will be described below, and those skilled in the art can self-deduct other situations. In this embodiment, the common voltage Vcom is 5.5 volts. Since the present invention can also be applied to MVA panels of various polarity inversion operations, such as dot reversal, line inversion, column inversion, etc., the polarity of the data voltage is positive and negative. ^ 'In the case of a grayscale value of 128, the positive data voltage value is 8.4, inch' and the negative data voltage value is 3.3 volts. φ ^ additionally 'the feedthrough voltage of the display region 500a is 06 volts according to the above formula (1), and the feedthrough voltage of the display region 500b is designed to be ο·1 ml η this day can be 'in the case of positive polarity driving Next, the dynamic voltage of the positive two-year zone of the display area 5〇〇a is the positive data voltage minus the feed of the display area 500a, and the 3 temples are at 7·8 volts, and the positive polarity driving electric two-pole data voltage of the display area 500b is displayed. The feed-through voltage of the display area 500b is subtracted and the machine k is in the range of 'negative drive'. The negative polarity drive φ2 of the display area 5〇〇a, w, 'is the negative data voltage minus the display area 500b. The feeding pressure is _V* ^ is found at 2.7 volts, and the negative driving power of the display area 5 〇〇b is 14 I281 〇 65t „, which is the negative data voltage minus the feedthrough voltage of the display area 500b and equal to 3.2 volts. In Fig. 7, the 'voltage value of the liquid crystal voltage' is the voltage difference across the liquid crystal capacitor. Therefore, in the case of positive polarity driving, the positive liquid crystal voltage value of the page selection non-region 500a is Positive polarity driving voltage of region 500a Subtracting the common voltage to be equal to 2.3 volts, and the positive polarity liquid crystal voltage value of the display region 500b is the positive polarity driving voltage value of the display region 500b minus the common voltage and equal to 2.8 volts; in the case of the negative polarity driving, the display region 500a The negative liquid crystal voltage value is the negative driving voltage value of the display region 500a minus the common voltage and equal to -2.8 volts, and the negative liquid crystal voltage value of the display region 500b is the negative driving voltage value of the display region 500b minus the common value. The voltage is equal to -2.3 volts. As can be seen from the above, in the case of positive polarity driving, the absolute value of the liquid crystal electric bar of the display region 500a is smaller than the absolute value of the liquid crystal voltage of the display region 500b. Conversely, the negative polarity is driven. In this case, the absolute value of the liquid crystal voltage of the display region 500a is larger than the absolute value of the liquid crystal voltage of the display region 500b. Thus, in the case of positive polarity driving, the threshold voltage of the display region 500a is larger than the threshold voltage of the display region 500b. , in the case of negative polarity driving, the threshold voltage of the display area 500a will be closer to the display area 500b The voltage is small. Therefore, the brightness of the display areas 500a and 500b is different, and the brightness relationship between the display areas 500a and 500b is also changed with the difference of the positive polarity driving or the negative polarity driving. Therefore, it is possible to compensate for the color 15 I28·-difference caused by the difference in viewing angle of the MVA panel, and also does not cause a problem of a decrease in the aperture ratio. Fig. 8 illustrates a gamma (Gama) using the MVA panel of the present invention. The characteristic curve is shown in Fig. 8. The curve 81 represents the gamma characteristic curve of the front view MVA panel and the curve 83 is the gamma characteristic curve of the M VA panel which is not utilized by the present invention. It can be clearly seen here that the difference between curve 81 and curve 83 is very large. However, if the compensation method provided by the present invention is utilized, curve 83 is corrected to curve 85. and

Clearly, the variation characteristics of curve 85 and curve 81 are very similar. From this, it can be seen that the present invention effectively reduces the chromatic aberration caused by the difference in viewing angle of the MVA panel. Figure 9A is an enlarged view of the dotted line region 91 of Figure 9A in accordance with the present invention. In order to achieve the above-described effect 'in Fig. 9A, the difference in the area of the gate and the drain is the same as the area of the gate", the display regions have different parasitic capacitances (and the C〆 can be clearly seen from the diagram, Since the area between the interlayer and the drain is different, the parasitic capacitance Cgsi*. The capacitance value will also be the same, so the resulting feed-through voltage will be different. Figure 10 illustrates a composition in accordance with another embodiment of the present invention. Referring to FIG. 1(), the present invention can also be changed by

Therefore, each of the display regions has a different liquid crystal capacitance and the electric power of C. Each of the -_ regions has the same information. It is shown that the image is constructed in accordance with the present invention. Referring to FIG. 11, the overlapping area of the memory line of the present invention is further reduced, so that the county==capacitor electrode and the storage area are different. 16 1281065 16747twf.doc/006 Capacitor cstl And Cst2, and each of the first _ no regions have different feedthrough voltages. In summary, the present invention has at least the following features: * 1. Since the present invention can include multiple feeds within the same The display area of the tooth voltage can therefore be called the chromatic aberration caused by the different viewing angles of the ground MVA panel. . 2. Since the present invention provides different feedthrough voltages in different display areas, it does not make the brightness of a particular display area always brighter, but selectively makes the brightness of a part of the display area as the polarity is switched. Brighter, and the rest of the display series is darker. #This, the enamel of the MVA panel can be more uniform. 3. In the present invention, since the structure is simple and does not have complicated layout, the liquid crystal can be added. The opening ratio of the display. Although the present invention has been disclosed in the above preferred embodiments, it is not intended to limit the invention, and those skilled in the art can make some changes without departing from the spirit of the invention. The scope of the present invention is defined by the scope of the appended claims. [FIG. 1A] FIG. 1A illustrates the voltage versus transmittance of a conventional multi-domain vertical alignment liquid crystal display. FIG. 1B is a graph showing the voltage versus transmittance of the improved multi-domain vertical alignment liquid crystal display panel. FIG. 2 illustrates a multi-domain vertical alignment pixel region. Fig. 3A shows a cross-sectional view of a conventional multi-domain vertical alignment pixel structure. Fig. 3B shows the equivalent circuit of the pixel structure of Fig. 3A. A schematic diagram of a multi-domain vertical alignment type liquid crystal display panel according to a preferred embodiment of the present invention is shown in Fig. 5. Fig. 5 is a structural diagram of a halogen element according to a preferred embodiment of the present invention.

FIG. 6 is an equivalent circuit diagram of the pixel structure of FIG. 5. Figure 7 is a table showing the relationship between voltages in a halogen in accordance with a preferred embodiment of the present invention. —” Figure 8 shows a graph using the characteristics of the present invention.

FIG. 9A illustrates an element of a pixel in accordance with another embodiment of the present invention. FIG. 9B illustrates an enlarged view of a broken line area 91 of FIG. 9A. FIG. 10 illustrates a view of another embodiment of the present invention. FIG. 11 is a diagram showing a knot of a scorpion in accordance with another embodiment of the present invention. [Main component symbol description] 31: Data line 33: Scanning line 200, 500: Alizarin 301: Thin film transistor Substrate 18 128 1 O^^7twfdoc/006 303: protective layer 305, 307: transparent electrode 309: electrode 311: opposite substrate 313: liquid crystal layer 315: common electrode 321, 501, 503: thin film transistor 401: halogen space 505, 507: halogen electrodes A, B, 500a, 500b: display area DL wide DLm: lean line SLfSLn: scan line CL wide CLn+1: storage capacitor line CLla* CLlb: metal layer

Cgs: parasitic capacitance

Csti, Cst2: storage capacitor

Clci, Clc2: Liquid crystal capacitor 19

Claims (1)

1281065 16747twf.doc/006 X. Patent Application Range: L A multi-domain vertical alignment type (MVA) liquid crystal display panel comprising: a substrate; and a plurality of halogen elements disposed on the substrate, each of which is The prime is divided into a plurality of display areas, and each of the display areas has a different feedthrough voltage. 2. The multi-domain vertical alignment type liquid crystal display panel according to claim 1, wherein each of the display regions has a thin film transistor. 3. The multi-domain vertical alignment type liquid crystal display panel as described in claim 2, wherein the thin film transistors corresponding to each of the display regions have different parasitic capacitances. 4. The multi-domain vertical alignment type liquid crystal head panel as described in claim 1 wherein each of the display regions has a different area. 5. The multi-domain vertical alignment type liquid crystal display panel as described in claim 1, wherein each of the display regions has a different storage capacitance value. a multi-domain vertical alignment type liquid crystal display panel having: a substrate; a plurality of data lines 'disposed on the substrate' are arranged in parallel with each other along a predetermined direction; a plurality of scanning lines are disposed on the substrate, The data lines are perpendicular to each other and arranged in parallel with each other; a plurality of storage capacitor lines are arranged parallel to each other with respect to the scan lines; and a plurality of pixels are disposed on the substrate, wherein each of the elements is also 20 12810 twf.doc/006 respectively corresponds to a data line and a scan line, wherein each of the pixels is divided into a plurality of display areas, and each of the t display areas is respectively disposed on two sides of the corresponding scan line. H-7. The multi-domain vertical alignment type liquid crystal display panel as described in claim 6 is surrounded by the data lines and the storage capacitor lines. ...8. The multi-domain vertical alignment type liquid crystal according to item 6 of the patent application scope is not equal to the area of the display area.卜9·If you please turn over the multi-domain vertical alignment type liquid crystal mentioned in item -6, and the panel is not the panel's towel--the surface display system-line switching element. 10·-Multi-domain vertical alignment The liquid crystal display panel has a substrate; a plurality of data lines are disposed on the substrate and arranged in parallel with each other along a predetermined direction; and the plurality of scanning lines are perpendicular to the data lines and arranged parallel to each other; And a plurality of active switching elements are electrically connected to the scan lines. Each of the active switching elements has a gate, a source and a drain; wherein at least two of the The source of the active switching element is electrically connected to one of the data lines at the same time. u. The multi-domain vertical alignment type liquid described in the application _ 1G item, the at least two active forms in the panel 2 The source of the switching element can receive the data signal transmitted by the same lean line. 21 twf.d〇c/〇〇6 1281065 Γ67?7 曰Η 1ΖMulti-domain vertical alignment type as described in claim 10 Liquid = no panel, of which at least two The wire-type element is difficult to be electrically connected to a different halogen electrode. 曰β 13. The multi-domain vertical alignment type liquid according to claim 10 of the patent application is a non-panel, wherein the at least two active switching elements The recording system is electrically connected to different capacitor electrodes. 14. A multi-domain vertical alignment type liquid crystal display panel, comprising: a substrate; a plurality of weft lines arranged on the substrate, parallel to each other along a predetermined direction Arranging a plurality of scan lines, which are perpendicular to the data lines and arranged in parallel with each other, a plurality of storage capacitor lines, which are arranged with the sweep lines and arranged with each other; and j is disposed on the _ lines and the The storage capacitor line and the halogen system correspond to a plurality of active switching elements, and the active switching elements have different parasitic capacitances. 曰曰B 15. For example, the multi-domain vertical alignment type liquid described in the 14th item of the brothers _ The =im active correlation component is a _transistor. The multi-domain vertical alignment type liquid described in 4m 4 is a panel, a middle mother-the scan line spans a plurality of the halogens.