CN109949760B - Pixel matrix driving method and display device - Google Patents

Pixel matrix driving method and display device Download PDF

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CN109949760B
CN109949760B CN201711392030.1A CN201711392030A CN109949760B CN 109949760 B CN109949760 B CN 109949760B CN 201711392030 A CN201711392030 A CN 201711392030A CN 109949760 B CN109949760 B CN 109949760B
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pixel
data
driving voltage
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pixels
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CN109949760A (en
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吴永良
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Xianyang Caihong Optoelectronics Technology Co Ltd
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Xianyang Caihong Optoelectronics Technology Co Ltd
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Abstract

The invention discloses a pixel matrix driving method, wherein a pixel matrix comprises a plurality of sub-pixels which are arranged in a matrix, the polarities of the sub-pixels controlled by adjacent data lines are opposite, and the voltage input of two single-side sub-pixels is controlled by any one column of data lines, wherein the method comprises the following steps: receiving image data, and acquiring original pixel data according to the image data; obtaining first gray scale data and second gray scale data according to the original pixel data; generating a first driving voltage corresponding to the first gray scale data and a second driving voltage corresponding to the second gray scale data according to the first gray scale data and the second gray scale data; and in one frame, loading the first driving voltage or the second driving voltage to the pixel matrix along the direction of a data line. The invention avoids crosstalk bright and dark lines and improves the display effect.

Description

Pixel matrix driving method and display device
Technical Field
The invention belongs to the field of pixel matrix display, and particularly relates to a pixel matrix driving method and a display device.
Background
VA type liquid crystal panels are widely used in current display products, and at present, VA type panels are mainly classified into two types, one is MVA (Multi-domain Vertical Alignment) type, and the other is PVA (Patterned Vertical Alignment) type. The MVA technique is based on the addition of protrusions to form multiple viewing zones. The liquid crystal molecules are not completely vertically aligned in a static state, and are horizontally aligned after a voltage is applied, so that light can pass through the layers. PVA is a vertical image adjustment technology, which directly changes the structure of the liquid crystal cell, greatly improves the display performance, and can obtain a luminance output and contrast ratio superior to MVA.
However, in the conventional 4-domain VA technology, the VA-mode lcd panel is configured to easily generate color shift (color washout) at a large viewing angle as the viewing angle is adjusted, so that the displayed image is easily distorted, and particularly, the appearance of the skin color of a person tends to be bluish or bright white, and referring to fig. 1, the color shift is more serious as the viewing angle is increased (0 °, 45 °, and 60 °), and the arrangement of the 4-domain is affected by the polarity of the sub-pixels, thereby causing the problems of crosstalk and bright and dark lines, and the display effect is poor.
Disclosure of Invention
In order to solve the above problems in the prior art, the present invention provides a pixel matrix driving method and a display device for solving the color shift phenomenon and improving the display effect.
An embodiment of the present invention provides a pixel matrix driving method, where the pixel matrix includes a plurality of sub-pixels arranged in a matrix, the polarities of the sub-pixels controlled by adjacent data lines are opposite, and any one column of data lines controls the voltage inputs of two sub-pixels on a single side, where the method includes:
receiving image data, and acquiring original pixel data according to the image data;
obtaining first gray scale data and second gray scale data according to the original pixel data;
generating a first driving voltage corresponding to the first gray scale data and a second driving voltage corresponding to the second gray scale data according to the first gray scale data and the second gray scale data;
and in one frame, loading the first driving voltage or the second driving voltage to the pixel matrix along the direction of a data line.
In one embodiment, the applying the first driving voltage or the second driving voltage to the pixel matrix along a data line direction includes:
alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along the direction of a data line;
and alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along the direction of a scanning line.
In one embodiment, the applying the first driving voltage or the second driving voltage to the pixel matrix along a data line direction includes:
alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along the direction of a data line;
and alternately loading the first driving voltage and the second driving voltage to every two adjacent sub-pixels along the direction of a scanning line.
In one embodiment, obtaining the first gray scale data and the second gray scale data according to the original pixel data comprises:
and obtaining an original pixel value of each pixel position according to the original pixel data, and converting the original pixel value of each pixel position into the first gray scale data or the second gray scale data according to a preset conversion mode.
The invention also provides a display device, which comprises a time schedule controller, a data driving unit, a scanning driving unit and a pixel matrix, wherein in the pixel matrix, the polarities of the sub-pixels controlled by adjacent data lines are opposite, and any one column of data lines controls the voltage input of two sub-pixels on one side; the time sequence controller is respectively connected with the data driving unit and the scanning driving unit, and the data driving unit and the scanning driving unit are both connected with the pixel matrix;
the time sequence controller is used for forming first gray scale data and second gray scale data according to the original pixel data and outputting the first gray scale data and the second gray scale data to the data driving unit;
the data driving unit is used for generating a first driving voltage according to the first gray scale data and generating a second driving voltage according to the second gray scale data; and loading the first driving voltage or the second driving voltage to the pixel matrix along a data line direction within a frame.
In one embodiment, the timing controller is specifically configured to: and obtaining an original pixel value of each pixel position according to the original pixel data, and converting the original pixel value of each pixel position into first gray scale data or second gray scale data according to a preset conversion mode.
In one embodiment, the data driving unit is further configured to alternately apply the first driving voltage and the second driving voltage to adjacent sub-pixels along a data line direction; and alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along the direction of a scanning line.
In one embodiment, the data driving unit is further configured to alternately apply the first driving voltage and the second driving voltage to adjacent sub-pixels along a data line direction; and alternately loading the first driving voltage and the second driving voltage to every two adjacent sub-pixels along the direction of a scanning line.
The invention also provides a pixel matrix driving method, wherein the pixel matrix comprises a plurality of sub-pixels arranged in a matrix, and the pixel matrix is characterized in that the polarity of the voltage applied to the sub-pixels is reversed once every two sub-pixels along the direction of a data line, and the polarity of the voltage applied to the sub-pixels is reversed once every two sub-pixels along the direction of a scanning line; wherein the method comprises the following steps:
receiving image data, and acquiring original pixel data according to the image data;
obtaining an original data driving signal of each pixel position according to the original pixel data;
obtaining a first driving voltage and a second driving voltage according to the original data driving signal;
and in one frame, loading the first driving voltage or the second driving voltage to the pixel matrix along the direction of a data line.
In one embodiment, obtaining the first driving voltage and the second driving voltage according to the original data driving signal includes:
obtaining an original gray-scale value of a corresponding pixel position according to the original data driving signal;
and converting the original gray-scale value of the corresponding pixel position into a first driving voltage or a second driving voltage according to a preset conversion rule.
In one embodiment, the applying the first driving voltage or the second driving voltage to the pixel matrix along a data line direction includes:
alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along the direction of a data line;
and alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along the direction of a scanning line.
In one embodiment, the applying the first driving voltage or the second driving voltage to the pixel matrix along a data line direction includes:
alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along the direction of a data line;
and alternately loading the first driving voltage and the second driving voltage to every two adjacent sub-pixels along the direction of a scanning line.
The invention also provides another display device which comprises a time schedule controller, a data driving unit, a scanning driving unit and a pixel matrix, wherein the polarities of the sub-pixels controlled by the adjacent data lines in the pixel matrix are opposite, and the voltage input of two single-side sub-pixels is controlled by any one column of data lines; the time sequence controller is connected with the data driving unit and the scanning driving unit, and the data driving unit and the scanning driving unit are both connected with the pixel matrix;
the time sequence controller is used for obtaining an original data driving signal according to the original pixel data;
the data driving unit is used for generating a first driving voltage and a second driving voltage according to the original data driving signal; and in one frame, the data driving unit is further configured to load the first driving voltage or the second driving voltage to the pixel matrix along a data line direction.
In a specific embodiment, the data driving unit is further configured to obtain an original gray-scale value of the corresponding pixel position according to the original data driving signal; and converting the original gray-scale value of the corresponding pixel position into a first driving voltage or a second driving voltage according to a preset conversion rule.
In one embodiment, the data driving unit is further configured to alternately apply the first driving voltage and the second driving voltage to adjacent sub-pixels along a data line direction; and alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along the direction of a scanning line.
In one embodiment, the data driving unit is further configured to alternately apply the first driving voltage and the second driving voltage to adjacent sub-pixels along a data line direction; and alternately loading the first driving voltage and the second driving voltage to every two adjacent sub-pixels along the direction of a scanning line.
Compared with the prior art, the invention has the beneficial effects that:
the pixel matrix driving method provided by the invention has the advantages that the pixels in the pixel matrix are not influenced by polarity by matching the high gray scale voltage and the low gray scale voltage reasonably, the problems of crosstalk, bright and dark lines and the like are avoided, and the display effect is improved.
Drawings
FIG. 1 is a schematic diagram illustrating the variation of viewing angle with gray scale in the prior art;
fig. 2 is a flowchart of a pixel matrix driving method according to an embodiment of the invention;
FIG. 3 is a schematic view of polarity loading of a pixel matrix according to an embodiment of the present invention;
FIG. 4 is a schematic view of gray scale loading of a pixel matrix according to an embodiment of the present invention;
FIG. 5 is a schematic view of gray scale loading of another pixel matrix according to an embodiment of the present invention;
FIG. 6 is a schematic view of gray scale loading of another pixel matrix according to an embodiment of the present invention;
FIG. 7 is a flowchart of another pixel matrix driving method according to an embodiment of the invention;
FIG. 8 is a schematic diagram of a sub-pixel region according to an embodiment of the present invention;
FIG. 9 is a schematic diagram of another sub-pixel region according to an embodiment of the present invention;
FIG. 10 is a schematic diagram of another sub-pixel region according to an embodiment of the present invention;
FIG. 11 is a schematic diagram illustrating a driving method of a pixel matrix according to an embodiment of the invention;
FIG. 12 is a schematic view of one embodiment of the drive of FIG. 11;
FIG. 13 is a schematic view of another embodiment of the drive of FIG. 11;
FIG. 14 is a schematic view of another embodiment of the driving scheme of FIG. 11;
fig. 15 is a schematic view of a display device according to an embodiment of the invention.
Detailed Description
The present invention will be described in further detail with reference to specific examples, but the embodiments of the present invention are not limited thereto.
Example one
Referring to fig. 2, fig. 2 is a flowchart of a pixel matrix driving method according to an embodiment of the invention. The pixel matrix driving method is suitable for displays currently having pixel arrays, such as LCD displays, LED displays, OLED displays, and the like.
Further, the pixel matrix comprises a plurality of sub-pixels arranged in a matrix, the polarities of the adjacent data lines are opposite, that is, the polarities of the data lines are column inversion, in one row, any one column of data lines controls the voltage input of two sub-pixels on one side, the voltage applied to the sub-pixels along the direction of the data lines is changed for one polarity for each sub-pixel, and the voltage applied to the sub-pixels along the direction of the scanning lines is changed for one polarity for every two sub-pixels. Specifically, for the sub-pixel polarity, the inversion system is 2N inversion in the scanning line direction, and the inversion system is 1+2N inversion in the data line direction.
Specifically, the method may comprise the steps of:
step 1, receiving image data, and acquiring original pixel data according to the image data;
step 2, obtaining first gray scale data and second gray scale data according to the original pixel data;
step 3, generating a first driving voltage corresponding to the first gray scale data and a second driving voltage corresponding to the second gray scale data according to the first gray scale data and the second gray scale data;
and 4, loading the first driving voltage or the second driving voltage to the pixel matrix along the direction of a data line in one frame.
In the prior art, the original pixel data, that is, a specific pixel value displayed by each sub-pixel in a pixel matrix in each frame correspondingly, is directly determined by the image data input into the TCON without processing the original pixel data, which is affected by the polarity of the sub-pixels, so that the polarity of the sub-pixels is easily subjected to negative effects such as crosstalk, bright and dark lines, and the like.
In this embodiment, the original pixel data is processed to obtain further first gray scale data and second gray scale data, and the pixel gray scales of the first gray scale data and the second gray scale data are different, and then the first gray scale data and the second gray scale data are loaded onto the corresponding sub-pixels at certain arrangement intervals between different pixels or different frames.
In a specific example, the first gray scale data is regarded as high gray scale data, the second gray scale data is regarded as low gray scale data, and correspondingly, the voltage magnitude input to the sub-pixel is determined by the gray scale, and a high gray scale voltage corresponding to the high gray scale data, namely, a first driving voltage is generated; it should be noted that the low gray scale voltage corresponding to the low gray scale data, i.e. the second driving voltage, represents the relative values of the two gray scales, and the values are not limited separately.
Referring to fig. 3, fig. 3 is a schematic view illustrating polarity loading of a pixel matrix according to an embodiment of the invention. Two consecutive sub-pixels have the same polarity when viewed from a row, the polarity of the next two consecutive sub-pixels is opposite to that of the previous two sub-pixels, the polarities of the sub-pixels are alternately inverted when viewed from a column, and so on, and the voltages applied to the sub-pixels are inverted every two sub-pixels along the data line direction, the voltages applied to the sub-pixels are inverted every sub-pixel polarity along the scan line direction, P in fig. 3 represents a positive voltage, N represents a negative voltage, when viewed from a column, the polarity inversion can be represented as NNPP … NNPP or PPNN … PPNN, and when viewed from a row, the polarity inversion can be represented as NNPP … NNPP or PPNN … PPNN.
In one embodiment, obtaining the first gray scale data and the second gray scale data according to the original pixel data comprises: and obtaining an original pixel value of each pixel position according to the original pixel data, and converting the original pixel value of each pixel position into first gray scale data or second gray scale data according to a preset conversion mode.
After the gray scale to be displayed at each pixel position is correspondingly determined according to the rule of the invention, the time schedule controller correspondingly adjusts the original gray scale of the pixel position into a high gray scale or a low gray scale and sends the adjusted gray scale value to the data driving unit, and the data driving unit outputs corresponding voltage according to the gray scale value.
For example, if the original pixel value at the a position is 128 gray, and the a position should output a high gray, i.e. H, according to the above rule of the present invention, after calculation, in this example, H of 128 is 138 gray, 138 gray is output to the a position, the data driving unit receives 138 gray, and according to the predetermined conversion rule, the voltage corresponding to 138 gray is 10V, and finally the voltage signal of 10V is output to the a position. Generally, the high-low gray scale adjustment range is determined according to the material of the liquid crystal or the like.
For example, if the original pixel value at the B position is 128 gray, and the B position should output a low gray, i.e., L, according to the above rule of the present invention, the calculation is performed, in this example, if L of 128 is 118 gray, 118 gray is output to the B position, the data driving unit receives 118 gray, and according to the predetermined conversion rule, the voltage corresponding to 118 gray is 8V, and finally the voltage signal of 8V is output to the B position.
In a specific embodiment, the applying the first driving voltage or the second driving voltage to the pixel matrix along the data line direction includes:
alternately loading the first driving voltage or the second driving voltage to adjacent sub-pixels along a data line direction to the pixel matrix;
and alternately loading the first driving voltage or the second driving voltage to the adjacent sub-pixels along the scanning line direction to the pixel matrix.
The pixel matrix is physically divided into a plurality of small blocks arranged in a matrix by a plurality of data lines and scanning lines which are communicated in a staggered way, each small block is a sub-pixel, and every two adjacent sub-pixels are divided by a corresponding data line or scanning line. Alternately loading the first driving voltage or the second driving voltage to the pixel matrix representation along the data line direction every other scanning line, and loading different driving voltages between adjacent sub-pixels when viewed from a certain column; or, regarding a certain row, different driving voltages are loaded between every two adjacent sub-pixels; are alternately applied to the sub-pixels according to the above-mentioned relationship.
Referring to the following example, please refer to fig. 4, wherein fig. 4 is a schematic view illustrating gray scale loading of a pixel matrix according to an embodiment of the present invention. From a certain row, the gray scale voltages of two sub-pixels loaded continuously are the same, the gray scale voltages of two sub-pixels loaded continuously are different from the gray scale voltages of the two sub-pixels loaded continuously, from a certain column, the gray scale voltages loaded to the sub-pixels are alternately changed, and the like, in fig. 4, H represents a high gray scale voltage, L represents a low gray scale voltage, from a certain column, the gray scale voltage change can be represented as HLHL … HLHL or LHLH … LHLH, and from a certain row, the gray scale voltage change can be represented as HLHL … HLHL or LHLH … LHLH.
According to the driving method of the pixel matrix, the pixels in the pixel matrix are not influenced by polarity by matching the high gray scale voltage and the low gray scale voltage reasonably, the problems of crosstalk, bright and dark lines and the like are avoided, and the display effect is improved.
Example two
Referring to the following example, please refer to fig. 5, wherein fig. 5 is a schematic view illustrating gray scale loading of another pixel matrix according to an embodiment of the invention. The loading the first driving voltage or the second driving voltage to the pixel matrix along a data line direction includes:
loading the first driving voltage and the second driving voltage to adjacent sub-pixels alternately along the direction of a data line, wherein the gray levels of the adjacent sub-pixels on two sides of the data line are different;
and alternately loading the first driving voltage and the second driving voltage to every two adjacent sub-pixels along the direction of a scanning line.
The gray levels of the adjacent sub-pixels on the two sides of the data line are different, namely when the adjacent sub-pixel on the left side of the data line is H, the adjacent sub-pixel on the right side of the data line is L, and vice versa.
The gray scale voltages loaded to two consecutive sub-pixels are the same from a certain row, the gray scale voltages loaded to the sub-pixels are alternately changed from the previous two, and so on, the gray scale voltages loaded to the sub-pixels are represented by H and the low gray scale voltages in fig. 4, the gray scale voltage changes can be represented by HLHL … HLHL or LHLH … LHLH from a certain row, and the gray scale voltage changes can be represented by HHLL … HHLL or LLHH … LLHH from a certain row.
According to the driving method of the pixel matrix, the pixels in the pixel matrix are not influenced by polarity by matching the high gray scale voltage and the low gray scale voltage reasonably, the problems of crosstalk, bright and dark lines and the like are avoided, and the display effect is improved.
EXAMPLE III
Referring to fig. 6, fig. 6 is a schematic view illustrating gray scale loading of a pixel matrix according to another embodiment of the present invention. Loading the first drive voltage or the second drive voltage to the matrix of pixels along a data line direction comprises:
loading the first driving voltage or the second driving voltage to adjacent sub-pixels alternately along the direction of a data line, wherein the gray scales on the adjacent sub-pixels on the two sides of the data line are the same;
and alternately loading the first driving voltage or the second driving voltage to every two adjacent sub-pixels along the scanning line direction.
The gray scales of the adjacent sub-pixels on the two sides of the data line are the same, namely when the adjacent sub-pixel on the left side of the data line is H, the adjacent sub-pixel on the right side of the data line is H, and when the adjacent sub-pixel on the left side of the data line is L, the adjacent sub-pixel on the right side of the data line is L.
From a certain row, the gray scale voltages loaded to two continuous sub-pixels are different, the gray scale voltages loaded to the two continuous sub-pixels are different from the two gray scale voltages loaded to the two continuous sub-pixels, from a certain column, the gray scale voltages loaded to the sub-pixels are alternately changed, and the like, in fig. 4, H represents a high gray scale voltage, L represents a low gray scale voltage, from a certain column, the gray scale voltage change can be represented as HLHL … HLHL or LHLH … LHLH, and from a certain row, the gray scale voltage change can be represented as HLLH … HLLH or LHHL … LHHL.
According to the driving method of the pixel matrix, the pixels in the pixel matrix are not influenced by polarity by matching the high gray scale voltage and the low gray scale voltage reasonably, the problems of crosstalk, bright and dark lines and the like are avoided, and the display effect is improved.
Example four
Referring to fig. 7, fig. 7 is a flowchart of another pixel matrix driving method according to an embodiment of the invention. The pixel matrix comprises a plurality of sub-pixels which are arranged in a matrix, the polarity of the voltage applied to the sub-pixels is reversed once every two sub-pixels along the direction of a data line, and the polarity of the voltage applied to the sub-pixels is reversed once every sub-pixel along the direction of a scanning line;
specifically, the method comprises the following steps:
step 1, receiving image data, and acquiring original pixel data according to the image data;
step 2, obtaining an original data driving signal of each pixel position according to the original pixel data;
step 3, obtaining a first driving voltage and a second driving voltage according to the original data driving signal;
and 4, loading the first driving voltage or the second driving voltage to the pixel matrix along the direction of a data line in one frame.
Alternately loading the first driving voltage or the second driving voltage to adjacent sub-pixels along a data line direction to the pixel matrix;
and alternately loading the first driving voltage or the second driving voltage to the adjacent sub-pixels along the scanning line direction to the pixel matrix.
Or in one frame, the first driving voltage and the second driving voltage are alternately loaded to adjacent sub-pixels along the direction of a data line, and the gray levels on the adjacent sub-pixels on the two sides of the data line are different;
and alternately loading the first driving voltage and the second driving voltage to every two adjacent sub-pixels along the direction of a scanning line.
Or in one frame, the first driving voltage and the second driving voltage are alternately loaded to adjacent sub-pixels along the direction of a data line, and the gray scales on the adjacent sub-pixels on the two sides of the data line are the same;
and alternately loading the first driving voltage and the second driving voltage to every two adjacent sub-pixels along the direction of a scanning line.
In one implementation, the present embodiment generates the driving signals for driving the sub-pixels by using two different sets of gammas (gammas) to generate the driving signals for driving the sub-pixels, so that the set of original data driving signals generate two sets of driving voltages under the action of different gammas, thereby implementing the driving control of the present invention. In a specific implementation of the embodiment, the Tcon outputs a set of gray scales, and the data driving circuit generates two sets of gammas, each set of gammas respectively driving different sub-pixels, thereby achieving the same technical effect as the embodiment.
In one embodiment, obtaining the first driving voltage and the second driving voltage according to the original data driving signal includes: the method comprises the steps of obtaining an original gray-scale value and a conversion rule of a corresponding pixel position according to an original data driving signal, and converting the original gray-scale value of the corresponding pixel position into a first driving voltage or a second driving voltage according to the conversion rule.
The method of the invention does not directly carry out gray scale conversion in the time sequence controller, and sends the original gray scale value and the conversion rule of the corresponding H or L to the data driving unit, and the data driving unit directly outputs the corresponding driving voltage according to the original gray scale value and the corresponding H or L according to the rule.
For example, in one embodiment, if the original pixel value at the a position is 128 gray levels, the a position is output 128 gray levels, and the a position is H according to the conversion rule, after the driving circuit receives the 128 gray levels, the corresponding voltage 10V is found in the voltage conversion table corresponding to the gray level of H, and finally the driving voltage signal of 10V is output to the a position.
For example, if the original pixel value at the B position is 128 gray levels, the B position is output 128 gray levels, and after the L driving circuit receives the 128 gray levels according to the conversion rule, the corresponding voltage 8V is found in the corresponding voltage conversion table corresponding to the gray levels of L, and finally, the data signal of 8V is output to the a position.
In the embodiment, the high gray scale voltage and the low gray scale voltage are reasonably matched, so that the pixels in the pixel matrix are not influenced by polarity, the problems of crosstalk, bright and dark lines and the like are avoided, and the display effect is improved.
EXAMPLE five
In a specific embodiment, corresponding to one of the above solutions, in order to show the solution of the present invention more clearly, the pixel matrix includes a plurality of sub-pixel regions, each of the sub-pixel regions includes:
a first sub-pixel;
a second sub-pixel adjacent to the first sub-pixel along a scan line direction;
a third sub-pixel adjacent to the second sub-pixel along a scan line direction;
a fourth sub-pixel adjacent to the third sub-pixel along a scan line direction;
a fifth sub-pixel adjacent to the first sub-pixel in a data line direction;
a sixth subpixel adjacent to the second subpixel in a data line direction;
a seventh sub-pixel adjacent to the third sub-pixel in a data line direction;
an eighth subpixel adjacent to the fourth subpixel in a data line direction;
a first data line electrically connected to the first sub-pixel, the second sub-pixel, the fifth sub-pixel, and the sixth sub-pixel;
a second data line electrically connected to the third, fourth, seventh, and eighth sub-pixels;
the first scanning line is electrically connected with the first sub-pixel and the third sub-pixel;
the second scanning line is electrically connected with the second sub-pixel and the fourth sub-pixel;
a third scanning line electrically connected to the fifth sub-pixel and the seventh sub-pixel;
and the fourth scanning line is electrically connected with the sixth sub-pixel and the eighth sub-pixel.
Referring to fig. 8, fig. 8 is a schematic view of a sub-pixel region according to an embodiment of the present invention. The region denoted by the symbol a is denoted as a sub-pixel region, each sub-pixel region includes eight sub-pixels, which are divided into two upper and lower rows of four sub-pixels, wherein the first pixel a1, the second pixel a2, the third pixel A3, and the fourth pixel a4 are in one row, and the fifth pixel a5, the sixth pixel a6, the seventh pixel a7, and the eighth pixel A8 are in the next row opposite to the upper row. The pixel matrix is sequentially filled with a number of sub-pixel regions. A first data line D1 electrically connected to the first sub-pixel a1, the second sub-pixel a2, the fifth sub-pixel a5, and the sixth sub-pixel a 6; a second data line D2 electrically connected to the third sub-pixel A3, the fourth sub-pixel a4, the seventh sub-pixel a7, and the eighth sub-pixel a 8; a first scan line G1 electrically connected to the first sub-pixel a1 and the third sub-pixel A3; a second scan line G2 electrically connected to the second sub-pixel a2 and the fourth sub-pixel a 4; a third scanning line G3 electrically connected to the fifth sub-pixel a5 and the seventh sub-pixel a 7; and a fourth scan line G4 electrically connected to the sixth sub-pixel a6 and the eighth sub-pixel a 8.
In one embodiment, the polarity of the voltages applied to the first pixel a1, the second pixel a2, the fifth pixel a5 and the sixth pixel a6 is the same, and is opposite to the polarity of the voltages applied to the third pixel A3, the fourth pixel a4, the seventh pixel a7 and the eighth pixel A8.
The gray levels of voltages applied to the first pixel a1, the third pixel A3, the sixth pixel a6 and the eighth pixel A8 are different from the gray levels of voltages applied to the second pixel a2, the fourth pixel a4, the fifth pixel a5 and the seventh pixel a 7.
According to the above matching relationship between the voltage polarity and the voltage gray scale loaded on the sub-pixel, a specific embodiment is shown, in one frame, a negative polarity low gray scale voltage, which can be represented as LN, is loaded on the first pixel a 1; loading a negative polarity high grayscale voltage, denoted as HN, to the second pixel a 2; loading the third pixel a3 with a positive polarity low gray scale voltage, which may be denoted as LP; applying a positive polarity high grayscale voltage, which may be denoted as HP, to the fourth pixel A4; loading a negative polarity high grayscale voltage, denoted as HN, to the fifth pixel a 5; -applying a negative polarity low gray scale voltage, which may be denoted LN, to said sixth pixel a 6; loading a positive polarity high grayscale voltage, which may be denoted as HP, to the seventh pixel a 7; the eighth pixel A8 is loaded with a positive polarity low gray scale voltage, which may be denoted as LP.
For more clear description of the voltage loading relationship, the voltage loading relationship for each sub-pixel in any column is sequentially expressed as follows: LN, HN, LP, HP, LN, HN, LP, HP … cycle in turn; from a certain row, the voltage relationship loaded for each sub-pixel in any row is sequentially expressed as: LN, HN, LP, HP, LN, HN, LP, HP … circulate in sequence.
Alternatively, a positive polarity low gray scale voltage, which may be denoted as LP, is applied to the first pixel a 1; loading a positive polarity high grayscale voltage, which may be denoted as HP, to the second pixel a 2; -loading said third pixel a3 with a negative polarity low gray scale voltage, which may be denoted LN; loading a negative polarity high grayscale voltage, denoted as HN, to the fourth pixel a 4; loading a positive polarity high grayscale voltage, which may be denoted as HP, to the fifth pixel a 5; loading the sixth pixel a6 with a positive polarity low gray scale voltage, which may be denoted as LP; loading a negative polarity high grayscale voltage, which may be denoted as HN, to the seventh pixel a 7; the eighth pixel A8 is loaded with a negative polarity low gray scale voltage, which may be denoted as LN.
For more clear description of the voltage loading relationship, the voltage loading relationship for each sub-pixel in any column is sequentially expressed as follows: LP, HP, LN, HN, LP, HP, LN and HN … are circulated in sequence; from a certain row, the voltage relationship loaded for each sub-pixel in any row is sequentially expressed as: LP, HP, LN, HN, LP, HP, LN, HN … circulate sequentially.
In another embodiment, the polarity of the voltages applied to the first pixel a1, the second pixel a2, the seventh pixel a7 and the eighth pixel A8 is the same, and is opposite to the polarity of the voltages applied to the third pixel A3, the fourth pixel a4, the fifth pixel a5 and the sixth pixel a 6. The gray levels of voltages applied to the first pixel a1, the third pixel A3, the sixth pixel a6 and the eighth pixel A8 are different from the gray levels of voltages applied to the second pixel a2, the fourth pixel a4, the fifth pixel a5 and the seventh pixel a 7. In this driving method, the other pixels are correspondingly arranged in the above-described manner. And the relationship of the gray scale voltage loaded on the pixel is obtained again according to the above example, and the description is omitted again.
EXAMPLE six
In a specific embodiment, corresponding to one of the above solutions, in order to show the solution of the present invention more clearly, the pixel matrix includes a plurality of sub-pixel regions, each of the sub-pixel regions includes:
a first sub-pixel;
a second sub-pixel adjacent to the first sub-pixel along a scan line direction;
a third sub-pixel adjacent to the second sub-pixel along a scan line direction;
a fourth sub-pixel adjacent to the third sub-pixel along a scan line direction;
a fifth sub-pixel adjacent to the first sub-pixel in a data line direction;
a sixth subpixel adjacent to the second subpixel in a data line direction;
a seventh sub-pixel adjacent to the third sub-pixel in a data line direction;
an eighth subpixel adjacent to the fourth subpixel in a data line direction;
a first data line electrically connected to the first sub-pixel, the second sub-pixel, the fifth sub-pixel, and the sixth sub-pixel;
a second data line electrically connected to the third, fourth, seventh, and eighth sub-pixels;
the first scanning line is electrically connected with the first sub-pixel and the third sub-pixel;
the second scanning line is electrically connected with the second sub-pixel and the fourth sub-pixel;
a third scanning line electrically connected to the fifth sub-pixel and the seventh sub-pixel;
and the fourth scanning line is electrically connected with the sixth sub-pixel and the eighth sub-pixel.
Referring to fig. 9, fig. 9 is a schematic view of another sub-pixel region provided by the embodiment of the invention, in which the region denoted by the symbol a is denoted as a sub-pixel region, each sub-pixel region includes eight sub-pixels, which are divided into an upper row and a lower row, and each row includes four sub-pixels, wherein the first pixel a1, the second pixel a2, the third pixel A3, and the fourth pixel a4 are in a row, and the fifth pixel a5, the sixth pixel a6, the seventh pixel a7, and the eighth pixel A8 are in a row opposite to the upper row and the lower row. The pixel matrix is sequentially filled with a number of sub-pixel regions. A first data line D1 electrically connected to the first sub-pixel a1, the second sub-pixel a2, the fifth sub-pixel a5, and the sixth sub-pixel a 6; a second data line D2 electrically connected to the third sub-pixel A3, the fourth sub-pixel a4, the seventh sub-pixel a7, and the eighth sub-pixel a 8; a first scan line G1 electrically connected to the first sub-pixel a1 and the third sub-pixel A3; a second scan line G2 electrically connected to the second sub-pixel a2 and the fourth sub-pixel a 4; a third scanning line G3 electrically connected to the fifth sub-pixel a5 and the seventh sub-pixel a 7; and a fourth scan line G4 electrically connected to the sixth sub-pixel a6 and the eighth sub-pixel a 8.
In one embodiment, the polarity of the voltages applied to the first pixel a1, the second pixel a2, the fifth pixel a5 and the sixth pixel a6 is the same, and is opposite to the polarity of the voltages applied to the third pixel A3, the fourth pixel a4, the seventh pixel a7 and the eighth pixel A8.
The gray scales of the voltages loaded to the first pixel a1, the second pixel a2, the seventh pixel a7 and the eighth pixel A8 are the same, i.e., both H and both L, and are opposite to the gray scales of the voltages loaded to the third pixel A3, the fourth pixel a4, the fifth pixel a5 and the sixth pixel a 6.
According to the above matching relationship between the voltage polarity and the voltage gray scale loaded on the sub-pixel, a specific embodiment is shown, in one frame, a negative polarity low gray scale voltage, which can be represented as LN, is loaded on the first pixel a 1; loading the second pixel a2 with a negative polarity low gray scale voltage, which may be denoted as LN; loading a positive polarity high grayscale voltage, which may be denoted as HP, to the third pixel a 3; applying a positive polarity high grayscale voltage, which may be denoted as HP, to the fourth pixel A4; loading a negative polarity high grayscale voltage, denoted as HN, to the fifth pixel a 5; loading a negative polarity high grayscale voltage, which may be denoted as HN, to the sixth pixel a 6; loading the seventh pixel a7 with a positive polarity low gray scale voltage, which may be denoted as LP; the eighth pixel A8 is loaded with a positive polarity low gray scale voltage, which may be denoted as LP.
For more clear description of the voltage loading relationship, the voltage loading relationship for each sub-pixel in any column is sequentially expressed as follows: LN, HN, LP, HP, LN, HN, LP, HP … cycle in turn; from a certain row, the voltage relationship loaded for each sub-pixel in any row is sequentially expressed as: LN, HP, LN, HP … cycle in sequence.
Alternatively, within one frame, a positive polarity low gray scale voltage, which may be denoted as LP, is applied to the first pixel a 1; loading the second pixel a2 with a positive polarity low gray scale voltage, which may be denoted as LP; loading a negative polarity high grayscale voltage, denoted as HN, to the third pixel a 3; loading a negative polarity high grayscale voltage, denoted as HN, to the fourth pixel a 4; loading a positive polarity high grayscale voltage, which may be denoted as HP, to the fifth pixel a 5; applying a positive polarity high grayscale voltage, which may be denoted as HP, to the sixth pixel a 6; -loading said seventh pixel a7 with a negative polarity low gray scale voltage, which may be denoted LN; the eighth pixel A8 is loaded with a negative polarity low gray scale voltage, which may be denoted as LN.
For more clear description of the voltage loading relationship, the voltage loading relationship for each sub-pixel in any column is sequentially expressed as follows: LP, HP, LN, HN, LP, HP, LN and HN … are circulated in sequence; from a certain row, the voltage relationship loaded for each sub-pixel in any row is sequentially expressed as: LP, HN, LP, HN … cycle sequentially.
In another embodiment, the polarity of the voltages applied to the first pixel a1, the second pixel a2, the seventh pixel a7 and the eighth pixel A8 is the same, and is opposite to the polarity of the voltages applied to the third pixel A3, the fourth pixel a4, the fifth pixel a5 and the sixth pixel a 6. The gray scales of the voltages loaded to the first pixel a1, the second pixel a2, the seventh pixel a7 and the eighth pixel A8 are the same, i.e., both H and both L, and are opposite to the gray scales of the voltages loaded to the third pixel A3, the fourth pixel a4, the fifth pixel a5 and the sixth pixel a 6. In this driving mode, the other pixels are correspondingly arranged in the above-described manner. And the relationship of gray scale voltage loaded to the pixel is obtained again according to the above example, which is not described herein again.
EXAMPLE seven
In a specific embodiment, corresponding to one of the above solutions, in order to show the solution of the present invention more clearly, the pixel matrix includes a plurality of sub-pixel regions, each of the sub-pixel regions includes:
a first sub-pixel;
a second sub-pixel adjacent to the first sub-pixel along a scan line direction;
a third sub-pixel adjacent to the second sub-pixel along a scan line direction;
a fourth sub-pixel adjacent to the third sub-pixel along a scan line direction;
a fifth sub-pixel adjacent to the first sub-pixel in a data line direction;
a sixth subpixel adjacent to the second subpixel in a data line direction;
a seventh sub-pixel adjacent to the third sub-pixel in a data line direction;
an eighth subpixel adjacent to the fourth subpixel in a data line direction;
a first data line electrically connected to the first sub-pixel, the second sub-pixel, the fifth sub-pixel, and the sixth sub-pixel;
a second data line electrically connected to the third, fourth, seventh, and eighth sub-pixels;
the first scanning line is electrically connected with the first sub-pixel and the third sub-pixel;
the second scanning line is electrically connected with the second sub-pixel and the fourth sub-pixel;
a third scanning line electrically connected to the fifth sub-pixel and the seventh sub-pixel;
and the fourth scanning line is electrically connected with the sixth sub-pixel and the eighth sub-pixel.
Referring to fig. 10, fig. 10 is a schematic diagram of another sub-pixel region provided by an embodiment of the present invention, where the region denoted by a reference character a is denoted as a sub-pixel region, each sub-pixel region includes eight sub-pixels, which are divided into two upper and lower rows, and four sub-pixels are provided in each row, where the first pixel a1, the second pixel a2, the third pixel A3, and the fourth pixel a4 are in one row, and the fifth pixel a5, the sixth pixel a6, the seventh pixel a7, and the eighth pixel A8 are in a row right opposite to the upper row and the lower row. The pixel matrix is sequentially filled with a number of sub-pixel regions. A first data line D1 electrically connected to the first sub-pixel a1, the second sub-pixel a2, the fifth sub-pixel a5, and the sixth sub-pixel a 6; a second data line D2 electrically connected to the third sub-pixel A3, the fourth sub-pixel a4, the seventh sub-pixel a7, and the eighth sub-pixel a 8; a first scan line G1 electrically connected to the first sub-pixel a1 and the third sub-pixel A3; a second scan line G2 electrically connected to the second sub-pixel a2 and the fourth sub-pixel a 4; a third scanning line G3 electrically connected to the fifth sub-pixel a5 and the seventh sub-pixel a 7; and a fourth scan line G4 electrically connected to the sixth sub-pixel a6 and the eighth sub-pixel a 8.
In one embodiment, the polarity of the voltages applied to the first pixel a1, the second pixel a2, the fifth pixel a5 and the sixth pixel a6 is the same, and is opposite to the polarity of the voltages applied to the third pixel A3, the fourth pixel a4, the seventh pixel a7 and the eighth pixel A8.
The gray levels of voltages applied to the first pixel a1, the fourth pixel a4, the sixth pixel a6 and the seventh pixel a7 are the same, i.e., both H and both L, and are opposite to the gray levels of voltages applied to the second pixel a2, the third pixel A3, the fifth pixel a5 and the eighth pixel A8.
According to the above matching relationship between the voltage polarity and the voltage gray scale loaded on the sub-pixel, a specific embodiment is shown, in one frame, a negative polarity low gray scale voltage, which can be represented as LN, is loaded on the first pixel a 1; loading a negative polarity high grayscale voltage, denoted as HN, to the second pixel a 2; loading a positive polarity high grayscale voltage, which may be denoted as HP, to the third pixel a 3; loading the fourth pixel a4 with a positive polarity low gray scale voltage, which may be denoted as LP; loading a negative polarity high grayscale voltage, denoted as HN, to the fifth pixel a 5; -applying a negative polarity low gray scale voltage, which may be denoted LN, to said sixth pixel a 6; loading the seventh pixel a7 with a positive polarity low gray scale voltage, which may be denoted as LP; the eighth pixel A8 is loaded with a positive polarity high grayscale voltage, which may be denoted as HP.
For more clear description of the voltage loading relationship, the voltage loading relationship for each sub-pixel in any column is sequentially expressed as follows: LN, HN, LP, HP, LN, HN, LP, HP … cycle in turn; from a certain row, the voltage relationship loaded for each sub-pixel in any row is sequentially expressed as: LN, HN, HP, LP, LN, HN, HP, LP … circulate sequentially.
Alternatively, within one frame, a positive polarity low gray scale voltage, which may be denoted as LP, is applied to the first pixel a 1; loading a positive polarity high grayscale voltage, which may be denoted as HP, to the second pixel a 2; loading a negative polarity high grayscale voltage, denoted as HN, to the third pixel a 3; -applying a negative polarity low gray scale voltage, which may be denoted LN, to said fourth pixel a 4; loading a positive polarity high grayscale voltage, which may be denoted as HP, to the fifth pixel a 5; loading the sixth pixel a6 with a positive polarity low gray scale voltage, which may be denoted as LP; -loading said seventh pixel a7 with a negative polarity low gray scale voltage, which may be denoted LN; the eighth pixel A8 is loaded with a negative polarity high grayscale voltage, which may be denoted as HN.
For more clear description of the voltage loading relationship, the voltage loading relationship for each sub-pixel in any column is sequentially expressed as follows: LP, HP, LN, HN, LP, HP, LN and HN … are circulated in sequence; from a certain row, the voltage relationship loaded for each sub-pixel in any row is sequentially expressed as: LP, HP, HN, LN, LP, HP, HN, LN … circulate in sequence.
In another embodiment, the polarity of the voltages applied to the first pixel a1, the second pixel a2, the seventh pixel a7 and the eighth pixel A8 is the same, and is opposite to the polarity of the voltages applied to the third pixel A3, the fourth pixel a4, the fifth pixel a5 and the sixth pixel a 6. The gray levels of voltages applied to the first pixel a1, the fourth pixel a4, the sixth pixel a6 and the seventh pixel a7 are the same, i.e., both H and both L, and are opposite to the gray levels of voltages applied to the second pixel a2, the third pixel A3, the fifth pixel a5 and the eighth pixel A8. In this driving mode, the other pixels are correspondingly arranged in the above-described manner. And the relationship of gray scale voltage loaded to the pixel is obtained again according to the above example, which is not described herein again.
Example eight
Referring to fig. 11 and 12 together, fig. 11 is a schematic diagram illustrating a pixel matrix driving method according to an embodiment of the invention; FIG. 12 is a schematic view of one embodiment of the drive of FIG. 11; in an optional 4 × 4 region, in this embodiment, the first pixel a1, the second pixel a2, the fifth pixel a5, and the sixth pixel A6 are connected to a first data line D1, the third pixel A3, the fourth pixel a4, the seventh pixel a7, the eighth pixel A8, the ninth pixel a9, the tenth pixel a10, the thirteenth pixel a13, the fourteenth pixel a14 are connected to a second data line D2, the eleventh pixel a11, the twelfth pixel a12, the fifteenth pixel a15, and the sixteenth pixel a16 are connected to a third data line D3;
at a first time in a frame, a scan signal is loaded on the scan line G1 in the first row, and a voltage corresponding to LN is loaded on the first data line D1 to the first pixel a1, a voltage corresponding to LP is loaded on the second data line D2 to the third pixel A3, and so on;
at the next time (i.e., the second time), the scan signal is loaded on the scan line G2 of the second row, and the voltage corresponding to HN is loaded on the first data line D1 to the second pixel a2, the voltage corresponding to HP is loaded on the second data line D2 to the fourth pixel a4, and so on;
at the next time (i.e., the third time), the scan signal is loaded on the scan line G3 of the third row, and the voltage corresponding to HN is loaded on the first data line D1 to the fifth pixel a5, the voltage corresponding to HP is loaded on the second data line D2 to the seventh pixel a7, and so on;
at the next time (i.e., the fourth time), the scan signal is loaded on the scan line G4 of the fourth row, and the voltage corresponding to LN is loaded on the first data line D1 to the sixth pixel a6, the voltage corresponding to LP is loaded on the second data line D2 to the eighth pixel a8, and so on;
at the next time (i.e., the fifth time), the scan signal is loaded on the scan line G5 of the fifth row, and the voltage corresponding to HP is loaded on the second data line D2 to the tenth pixel a10, the voltage corresponding to HN is loaded on the third data line D3 to the twelfth pixel a12, and so on;
at the next time (i.e., the sixth time), the scan signal is applied to the scan line G6 of the sixth row, and the voltage corresponding to LP is applied to the ninth pixel a9 on the second data line D2, the voltage corresponding to LN is applied to the eleventh pixel a11 on the third data line D3, and so on;
at the next time (i.e., the seventh time), the scan signal is loaded on the scan line G7 of the seventh row, and the voltage corresponding to LP is loaded on the second data line D2 to the fourteenth pixel a14, the voltage corresponding to LN is loaded on the third data line D3 to the sixteenth pixel a16, and so on;
at the next time (i.e., the eighth time), the scan signal is loaded on the scan line G8 of the eighth row, and the voltage corresponding to HP is loaded on the second data line D2 to the thirteenth pixel a13, the voltage corresponding to HN is loaded on the third data line D3 to the fifteenth pixel a15, and so on.
In this embodiment, the voltage loading case of 4 × 4 is exemplified, and the voltages are sequentially loaded to other sub-pixels and other time points according to the above rule.
By adopting the embodiment of the invention, the positive and negative polarity voltages and the high and low gray scale voltages are loaded to the pixel matrix alternately, so that the side visibility can be improved, the pixels in the pixel matrix are not influenced by the polarity, the problems of crosstalk, bright and dark lines and the like are solved, and the display effect is improved.
Example nine
Referring to fig. 11 and fig. 13 together, fig. 11 is a schematic diagram illustrating a pixel matrix driving method according to an embodiment of the invention; FIG. 13 is a schematic view of another embodiment of the drive of FIG. 11; in an optional 4 × 4 region, in this embodiment, the first pixel a1, the second pixel a2, the fifth pixel a5, and the sixth pixel A6 are connected to a first data line D1, the third pixel A3, the fourth pixel a4, the seventh pixel a7, the eighth pixel A8, the ninth pixel a9, the tenth pixel a10, the thirteenth pixel a13, the fourteenth pixel a14 are connected to a second data line D2, the eleventh pixel a11, the twelfth pixel a12, the fifteenth pixel a15, and the sixteenth pixel a16 are connected to a third data line D3;
at a first time in a frame, a scan signal is loaded on the scan line G1 in the first row, and a voltage corresponding to LN is loaded on the first data line D1 to the first pixel a1, a voltage corresponding to HP is loaded on the second data line D2 to the third pixel A3, and so on;
at the next time (i.e. the second time), the scan signal is loaded on the scan line G2 of the second row, and the voltage corresponding to LN is loaded on the first data line D1 to the second pixel a2, the voltage corresponding to HP is loaded on the second data line D2 to the fourth pixel a4, and so on;
at the next time (i.e., the third time), the scan signal is loaded on the scan line G3 of the third row, and the voltage corresponding to HN is loaded on the first data line D1 to the fifth pixel a5, the voltage corresponding to LP is loaded on the second data line D2 to the seventh pixel a7, and so on;
at the next time (i.e., the fourth time), the scan signal is loaded on the scan line G4 of the fourth row, and the voltage corresponding to HN is loaded on the first data line D1 to the sixth pixel a6, the voltage corresponding to LP is loaded on the second data line D2 to the eighth pixel a8, and so on;
at the next time (i.e., the fifth time), the scan signal is loaded on the scan line G5 of the fifth row, and the voltage corresponding to LP is loaded on the second data line D2 to the tenth pixel a10, the voltage corresponding to HN is loaded on the third data line D3 to the twelfth pixel a12, and so on;
at the next time (i.e., the sixth time), the scan signal is applied to the scan line G6 of the sixth row, and the voltage corresponding to LP is applied to the ninth pixel a9 on the second data line D2, the voltage corresponding to HN is applied to the eleventh pixel a11 on the third data line D3, and so on;
at the next time (i.e., the seventh time), the scan signal is loaded on the scan line G7 of the seventh row, and the voltage corresponding to the HP is loaded on the second data line D2 to the fourteenth pixel a14, the voltage corresponding to the LN is loaded on the third data line D3 to the sixteenth pixel a16, and so on;
at the next time (i.e., the eighth time), the scan signal is loaded on the scan line G8 of the eighth row, and the voltage corresponding to the HP is loaded on the second data line D2 to the thirteenth pixel a13, the voltage corresponding to the LN is loaded on the third data line D3 to the fifteenth pixel a15, and so on.
In this embodiment, the voltage loading case of 4 × 4 is exemplified, and the voltages are sequentially loaded to other sub-pixels and other time points according to the above rule.
According to the embodiment of the invention, the positive and negative polarity voltages and the high and low gray scale voltages are loaded to the pixel matrix alternately, so that the side visibility can be improved, the pixels in the pixel matrix are not influenced by the polarity, the problems of crosstalk, bright and dark lines and the like are solved, and the display effect is improved.
Example ten
Referring to fig. 11 and 14 together, fig. 11 is a schematic diagram illustrating a pixel matrix driving method according to an embodiment of the invention; FIG. 14 is a schematic view of another embodiment of the drive of FIG. 11;
in an optional 4 × 4 region, in this embodiment, the first pixel a1, the second pixel a2, the fifth pixel a5, and the sixth pixel A6 are connected to a first data line D1, the third pixel A3, the fourth pixel a4, the seventh pixel a7, the eighth pixel A8, the ninth pixel a9, the tenth pixel a10, the thirteenth pixel a13, the fourteenth pixel a14 are connected to a second data line D2, the eleventh pixel a11, the twelfth pixel a12, the fifteenth pixel a15, and the sixteenth pixel a16 are connected to a third data line D3;
at a first time in a frame, a scan signal is loaded on the scan line G1 in the first row, and a voltage corresponding to LN is loaded on the first data line D1 to the first pixel a1, a voltage corresponding to HP is loaded on the second data line D2 to the third pixel A3, and so on;
at the next time (i.e., the second time), the scan signal is loaded on the scan line G2 of the second row, and the voltage corresponding to HN is loaded on the first data line D1 to the second pixel a2, the voltage corresponding to HL is loaded on the second data line D2 to the fourth pixel a4, and so on;
at the next time (i.e., the third time), the scan signal is loaded on the scan line G3 of the third row, and the voltage corresponding to HN is loaded on the first data line D1 to the fifth pixel a5, the voltage corresponding to LP is loaded on the second data line D2 to the seventh pixel a7, and so on;
at the next time (i.e., the fourth time), the scan signal is loaded on the scan line G4 of the fourth row, and the voltage corresponding to LN is loaded on the first data line D1 to the sixth pixel a6, the voltage corresponding to HP is loaded on the second data line D2 to the eighth pixel a8, and so on;
at the next time (i.e., the fifth time), the scan signal is loaded on the scan line G5 of the fifth row, and the voltage corresponding to LP is loaded on the second data line D2 to the tenth pixel a10, the voltage corresponding to HN is loaded on the third data line D3 to the twelfth pixel a12, and so on;
at the next time (i.e., the sixth time), the scan signal is loaded on the scan line G6 of the sixth row, and the voltage corresponding to the HP is loaded on the second data line D2 to the ninth pixel a9, the voltage corresponding to the LN is loaded on the third data line D3 to the eleventh pixel a11, and so on;
at the next time (i.e., the seventh time), the scan signal is loaded on the scan line G7 of the seventh row, and the voltage corresponding to the HP is loaded on the second data line D2 to the fourteenth pixel a14, the voltage corresponding to the LN is loaded on the third data line D3 to the sixteenth pixel a16, and so on;
at the next time (i.e., the eighth time), the scan signal is applied to the scan line G8 of the eighth row, the voltage corresponding to LP is applied to the thirteenth pixel a13 on the second data line D2, the voltage corresponding to HN is applied to the fifteenth pixel a15 on the third data line D3, and so on.
In this embodiment, the voltage loading case of 4 × 4 is exemplified, and the voltages are sequentially loaded to other sub-pixels and other time points according to the above rule.
By adopting the embodiment of the invention, the positive and negative polarity voltages and the high and low gray scale voltages are loaded to the pixel matrix alternately, so that the side visibility can be improved, the pixels in the pixel matrix are not influenced by the polarity, the problems of crosstalk, bright and dark lines and the like are solved, and the display effect is improved.
EXAMPLE eleven
Referring to fig. 15, fig. 15 is a schematic view of a display device according to an embodiment of the present invention. The invention also provides a display device for implementing the method, which comprises a timing controller 81, a data driving unit 82, a scanning driving unit 83 and a display panel 84, wherein the display panel 84 is provided with a pixel matrix 85; the timing controller 81 is connected to the data driving unit 82 and the scan driving unit 83, and both the data driving unit 82 and the scan driving unit 83 are connected to the pixel matrix 85;
the timing controller 81 is configured to output first gray scale data and second gray scale data to the data driving unit 82;
the data driving unit 82 is configured to generate a first driving voltage according to the first gray scale data, and generate a second driving voltage according to the second gray scale data;
the scan driving unit 83 is used for loading scan signals to the pixel matrix 85;
and the data driving unit 82 is further configured to apply a first driving voltage corresponding to the first gray-scale data or a second driving voltage corresponding to the second gray-scale data to the pixel matrix 85 along the data line direction within one frame.
In a specific embodiment, the data driving unit 82 is further configured to alternately apply the first driving voltage and the second driving voltage to adjacent sub-pixels along a data line direction;
and alternately loading the first driving voltage and the second driving voltage to every two adjacent sub-pixels along the direction of a scanning line.
In one embodiment, the timing controller 81 is specifically configured to obtain an original pixel value of each pixel position according to the original pixel data, and convert the original pixel value of each pixel position into the first gray scale data or the second gray scale data according to a predetermined conversion manner.
In one embodiment, the data driving unit 82 is further configured to alternately apply the first driving voltage and the second driving voltage to adjacent sub-pixels along a data line direction; and alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along the direction of a scanning line.
In one embodiment, the data driving unit 82 is further configured to alternately apply the first driving voltage and the second driving voltage to adjacent sub-pixels along a data line direction; and alternately loading the first driving voltage and the second driving voltage to every two adjacent sub-pixels along the direction of a scanning line.
The display panel 84 includes a plurality of data lines, a plurality of scan lines, and a plurality of sub-pixels connected to the data lines and the scan lines, the sub-pixels being arranged in a data line direction and in a scan line direction on the display panel to constitute a pixel matrix 85, and the timing controller 81 inputs RGB data signals of an image from the outside.
The timing controller 81 can input red image data R, green image data G, blue image data B, or image data of other colors from the outside, and generate corresponding original pixel data according to the image data, and make the original pixel data correspond to two sets of gray scales, high gray scale data, and low gray scale data according to the above-described rule of the present invention. The data driving circuit converts the high gray scale data and the low gray scale data respectively by using a fixed gamma and outputs corresponding high gray scale voltage and low gray scale voltage. The data driving unit 82 controls the specific output operation according to the above method of the present invention, and outputs of high gray scale, low gray scale, positive voltage, and negative voltage are selected according to the timing.
In another implementation, the display device includes a timing controller 81, a data driving unit 82, a scan driving unit 83, and a display panel 84, where a pixel matrix 85 is disposed on the display panel 84; the timing controller 81 is connected to the data driving unit 82 and the scan driving unit 83, and both the data driving unit 82 and the scan driving unit 83 are connected to the pixel matrix 85;
the timing controller 81 is configured to obtain an original data driving signal according to the original pixel data;
the data driving unit 82 is configured to obtain a first driving voltage and a second driving voltage according to the original data driving signal;
the scan driving unit 83 is used for loading scan signals to the pixel matrix 85;
and within a frame, the data driving unit 82 is further configured to apply the first driving voltage or the second driving voltage to the pixel matrix 85 along a data line direction.
The data driving unit 82 is further configured to obtain an original gray-scale value and a conversion rule of a corresponding pixel position according to the original data driving signal, and convert the original gray-scale value of the corresponding pixel position into a first driving voltage or a second driving voltage according to the conversion rule.
In one embodiment, the data driving unit 82 is further configured to alternately apply the first driving voltage and the second driving voltage to adjacent sub-pixels along a data line direction; and alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along the direction of a scanning line.
In one embodiment, the data driving unit 82 is further configured to alternately apply the first driving voltage and the second driving voltage to adjacent sub-pixels along a data line direction; and alternately loading the first driving voltage and the second driving voltage to every two adjacent sub-pixels along the direction of a scanning line.
The timing controller 81 inputs image data from the outside, generates corresponding original pixel data according to the image data, and outputs an original data driving signal to the data driving circuit, and the data driving circuit correspondingly generates a high gray scale voltage of high gamma and a low gray scale voltage of low gamma through two different sets of gamma because the data driving circuit only receives the original gray scale value and a corresponding H or L conversion rule. The data driving unit 82 controls the specific output operation according to the above method of the present invention, and outputs of high gray scale, low gray scale, positive voltage, and negative voltage are selected according to the timing.
The foregoing is a more detailed description of the invention in connection with specific preferred embodiments and it is not intended that the invention be limited to these specific details. For those skilled in the art to which the invention pertains, several simple deductions or substitutions can be made without departing from the spirit of the invention, and all shall be considered as belonging to the protection scope of the invention.

Claims (8)

1. A method for driving a pixel matrix, the pixel matrix including a plurality of sub-pixels arranged in a matrix, wherein polarities of sub-pixels controlled by adjacent data lines are opposite, and a data line in any one column controls voltage inputs of two sub-pixels on a single side, wherein the method comprises:
receiving image data, and acquiring original pixel data according to the image data;
obtaining first gray scale data and second gray scale data according to the original pixel data;
generating a first driving voltage corresponding to the first gray scale data and a second driving voltage corresponding to the second gray scale data according to the first gray scale data and the second gray scale data;
loading the first driving voltage or the second driving voltage to the pixel matrix along a data line direction within a frame;
the loading the first driving voltage or the second driving voltage to the pixel matrix along a data line direction includes:
alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along the direction of a data line; alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along a scanning line direction;
or, along the direction of the data line, alternately loading the first driving voltage and the second driving voltage to the adjacent sub-pixels;
and in the direction of a scanning line, one group of adjacent sub-pixels is loaded with the first driving voltage and the second driving voltage alternately between the two adjacent groups.
2. The pixel matrix driving method according to claim 1, wherein obtaining first gray scale data and second gray scale data from the original pixel data comprises:
and obtaining an original pixel value of each pixel position according to the original pixel data, and converting the original pixel value of each pixel position into the first gray scale data or the second gray scale data according to a preset conversion mode.
3. A display device comprises a time schedule controller, a data driving unit, a scanning driving unit and a pixel matrix, and is characterized in that in the pixel matrix, the polarities of sub-pixels controlled by adjacent data lines are opposite, and any one column of data lines controls the voltage input of two sub-pixels on one side; the time sequence controller is respectively connected with the data driving unit and the scanning driving unit, and the data driving unit and the scanning driving unit are both connected with the pixel matrix;
the time sequence controller is used for forming first gray scale data and second gray scale data according to original pixel data and outputting the first gray scale data and the second gray scale data to the data driving unit;
the data driving unit is used for generating a first driving voltage according to the first gray scale data and generating a second driving voltage according to the second gray scale data; and loading the first driving voltage or the second driving voltage to the pixel matrix along a data line direction within a frame;
the data driving unit is configured to further function to,
alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along the direction of a data line; alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along a scanning line direction;
or, along the direction of the data line, alternately loading the first driving voltage and the second driving voltage to the adjacent sub-pixels;
and in the direction of a scanning line, one group of adjacent sub-pixels is loaded with the first driving voltage and the second driving voltage alternately between the two adjacent groups.
4. The display device according to claim 3, wherein the timing controller is specifically configured to: and obtaining an original pixel value of each pixel position according to the original pixel data, and converting the original pixel value of each pixel position into first gray scale data or second gray scale data according to a preset conversion mode.
5. A pixel matrix driving method, the pixel matrix comprises a plurality of sub-pixels arranged in a matrix, and is characterized in that the polarity of the voltage applied to the sub-pixels is reversed once every two sub-pixels along the direction of a data line, and the polarity of the voltage applied to the sub-pixels is reversed once every two sub-pixels along the direction of a scanning line; wherein the method comprises the following steps:
receiving image data, and acquiring original pixel data according to the image data;
obtaining an original data driving signal of each pixel position according to the original pixel data;
obtaining a first driving voltage and a second driving voltage according to the original data driving signal;
loading the first driving voltage or the second driving voltage to the pixel matrix along a data line direction within a frame;
the loading the first driving voltage or the second driving voltage to the pixel matrix along a data line direction includes:
alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along the direction of a data line; alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along a scanning line direction;
or, along the direction of the data line, alternately loading the first driving voltage and the second driving voltage to the adjacent sub-pixels;
and in the direction of a scanning line, one group of adjacent sub-pixels is loaded with the first driving voltage and the second driving voltage alternately between the two adjacent groups.
6. The pixel matrix driving method according to claim 5, wherein deriving the first driving voltage and the second driving voltage according to the original data driving signal comprises:
obtaining an original gray-scale value of a corresponding pixel position according to the original data driving signal;
and converting the original gray-scale value of the corresponding pixel position into a first driving voltage or a second driving voltage according to a preset conversion rule.
7. A display device comprises a time schedule controller, a data driving unit, a scanning driving unit and a pixel matrix, and is characterized in that the pixel matrix comprises a plurality of sub-pixels which are arranged in a matrix, the polarity of the voltage applied to the sub-pixels is reversed once every two sub-pixels along the direction of a data line, and the polarity of the voltage applied to the sub-pixels is reversed once every two sub-pixels along the direction of a scanning line; the time sequence controller is connected with the data driving unit and the scanning driving unit, and the data driving unit and the scanning driving unit are both connected with the pixel matrix;
the time sequence controller is used for obtaining an original data driving signal according to original pixel data;
the data driving unit is used for generating a first driving voltage and a second driving voltage according to the original data driving signal; and in one frame, the data driving unit is further configured to load the first driving voltage or the second driving voltage to the pixel matrix along a data line direction;
the data driving unit is configured to further function to,
alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along the direction of a data line; alternately loading the first driving voltage and the second driving voltage to adjacent sub-pixels along a scanning line direction;
or, along the direction of the data line, alternately loading the first driving voltage and the second driving voltage to the adjacent sub-pixels;
and in the direction of a scanning line, one group of adjacent sub-pixels is loaded with the first driving voltage and the second driving voltage alternately between the two adjacent groups.
8. The display device according to claim 7, wherein the data driving unit is further configured to obtain an original gray-scale value corresponding to the pixel position according to an original data driving signal; and converting the original gray-scale value of the corresponding pixel position into a first driving voltage or a second driving voltage according to a preset conversion rule.
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