JP2004287251A - Image display apparatus, image processing apparatus, control program for image display apparatus and control program for image processing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image display apparatus, an image processing apparatus, a control program for an image display apparatus, and a control program for an image processing apparatus which are capable of accurate non-sequential scanning by converting the size of an image to be displayed into a size which can be accurately divided according to the number of scanning lines in the objective display region comprising scanning lines in such a number that the sum of the number of the scanning lines plus one can be accurately divided into a group of numbers according to the proportions of 2<SP>n</SP>. <P>SOLUTION: The image display apparatus 10 comprises a panel 10a, controlling section 10b, driving section 10c, frame memory 10d, image analyzing section 10e and image converting section 10f. The apparatus functions in such a manner that: an input image from an external device is analyzed by the image analyzing section 10e; an appropriate size converting method is selected by the image converting section 10f based on the result of the analysis; the size of the input image is converted according to the number of the scanning lines in the display region on the panel 10a; and accurate non-sequential scanning processing is performed. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an electro-optical device including pixels including light-emitting elements, and more particularly, to an image display device suitable for suppressing display unevenness of an image by gradation display and an image size to be input to the electro-optical device. The present invention relates to an image processing device suitable for converting the image into a number corresponding to the number of scanning lines.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, an electro-optical device, for example, a liquid crystal display device using liquid crystal as an electro-optical material has been widely used as a display device in place of a cathode ray tube (CRT) in a display unit of various information processing equipment and a liquid crystal television. Here, in the conventional electro-optical device, for example, an element substrate provided with pixel electrodes arranged in a matrix, switching elements connected to the pixel electrodes, and a counter electrode facing the pixel electrodes are formed. It is composed of an opposing substrate and a liquid crystal as an electro-optical material filled between the two substrates. Then, in such a configuration, when one certain scanning line is selected, the switching element becomes conductive. In this conduction state, when an image signal of a voltage corresponding to the gradation is applied to the pixel electrode via the data line, a charge corresponding to the voltage of the image signal is applied to the liquid crystal layer between the pixel electrode and the counter electrode. Is accumulated. After the charge storage, even if the switching element is turned off, the charge storage in the liquid crystal layer is maintained by the capacitance of the liquid crystal layer itself, the storage capacitance, and the like. As described above, when each switching element is driven and the amount of charge to be stored is controlled according to the gradation, the alignment state of the liquid crystal changes for each pixel. For this reason, since the density changes for each pixel, it is possible to perform gradation display.
[0003]
At this time, since it is sufficient to accumulate charges in the liquid crystal layer of each pixel during a part of the period, first, each scanning line is sequentially selected, and second, the pixels intersecting with the selected scanning line are selected. By applying an image signal having a voltage corresponding to the gradation of the pixel to the corresponding data line, time-division multiplex driving in which the scanning line and the data line are shared by a plurality of pixels can be performed.
[0004]
However, the image signal applied to the data line is a voltage corresponding to the gradation of the pixel, that is, an analog signal. For this reason, a peripheral circuit of the electro-optical device requires a D / A conversion circuit, an operational amplifier, and the like, thereby increasing the cost of the entire device. Further, display unevenness occurs due to the characteristics of the D / A conversion circuit and the operational amplifier and the non-uniformity of various wiring resistances, so that it is extremely difficult to perform high-quality display. There is a problem that it becomes remarkable when displaying. There is also a problem such as an increase in power consumption due to the D / A conversion circuit and the operational amplifier.
[0005]
Therefore, a method of controlling the light emission time of the electro-optical element to obtain a gradation has been developed. In this method, a binary signal (digital signal) indicating whether or not the electro-optical element emits light may be supplied to the data line, and there is an advantage that the above-described analog circuit which adversely affects image quality is not required. However, there is a problem that the time for selecting a scanning line is too long in performing this control.
[0006]
Therefore, a non-sequential scanning method has been developed as a driving method of a liquid crystal display using a digital signal to solve the above problem. This is equivalent to the number of bits of a bit string constituting grayscale data having a bit length N indicating the light emission grayscale of the optical element. ⁿ Based on the numerical value group corresponding to the ratio of the values (n = 0, 1, 2,..., (N−1)), the scanning lines are arranged in a specific order (the order in which the scanning lines are not arranged but not arranged in order). ), The gradation is obtained by controlling the light emission time of the optical element (for example, see Patent Document 1).
[0007]
[Patent Document 1]
JP-A-2001-166730.
[0008]
[Problems to be solved by the invention]
However, in the above-described electro-optical device that performs the non-sequential scanning, the image data side is not created in accordance with the non-sequential scanning, and therefore, an addition number obtained by adding 1 to the number of scanning lines determined by the image data. Is the number of bits 2 in the bit string constituting the above-described gradation data. ⁿ In some cases, it is impossible to accurately divide into numerical value groups according to the ratio of the values (n = 0, 1, 2,..., (N−1)). Therefore, especially when displaying an image whose display content changes rapidly, such as a moving image, the image quality may be significantly deteriorated due to the inability to accurately divide the image.
[0009]
Therefore, the present invention has been made by focusing on such unresolved problems of the conventional technology, and the number of additions obtained by adding 1 to the number of scanning lines is 2 ⁿ By converting the size of the image displayed on the display area consisting of the number of scanning lines that can be accurately divided into a numerical group corresponding to the value ratio into a size that can be accurately divided according to the number of scanning lines, It is an object of the present invention to provide an image display device, an image processing device, an image display device control program, and an image processing device control program capable of performing accurate non-sequential scanning.
[0010]
[Means for Solving the Problems]
In order to achieve the above object, an image display device according to the present invention includes a pixel matrix in which pixels including optical elements are arranged in a matrix,
A plurality of scanning lines respectively connected to a pixel group arranged along one of a row direction and a column direction of the pixel matrix;
A plurality of data lines respectively connected to a pixel group arranged along the other of the row direction and the column direction of the pixel matrix,
A scanning line driving circuit for sequentially selecting the plurality of scanning lines one by one;
A data line drive circuit that outputs a control signal related to light emission of the optical element to at least one data line of the plurality of data lines;
A control unit that controls the operation of the scanning line driving circuit and the data line driving circuit,
It is generated based on the number of scanning lines in a display area including a predetermined number of the scanning lines and the data lines, and grayscale data having a bit length N corresponding to the number of light emission gradations indicating the light emission gradation of the optical element. The added number obtained by adding 1 to the total number of the scanning lines in the display area is represented by the number of bits 2 ⁿ Each optical element corresponding to each scanning line in the display area selected by the scanning line driving circuit, based on the numerical value group divided into numerical values according to the ratio consisting of the values, every time the scanning line is selected, A selection order of the scanning lines is determined so that light emission can be performed for a time corresponding to one numerical value selected in a predetermined order from a numerical value group, and a predetermined image is displayed in the display area by non-sequential scanning in the selection order. An image display device capable of gradation display
When a predetermined image is displayed in gradation in the display area, the size of the predetermined image before the non-sequential scanning is determined based on the number of scanning lines in the display area by one of a plurality of types of size changing methods. Size changing means that can be enlarged or reduced to a size corresponding to the number of scanning lines using
When the size of the predetermined image is increased or reduced by the size changing unit, a size change method that selects a size change method suitable for expansion or reduction among the plurality of types of size change methods based on the size of the predetermined image. And a method selecting means.
[0011]
With such a configuration, the first invention is characterized in that, when an image is displayed in a display area including a predetermined number of scanning lines and data lines by a non-sequential scanning method, scanning of the display area is performed by size changing means. Based on the number of lines, enlarging or reducing the size of the predetermined image before performing the non-sequential scanning to a size corresponding to the number of scanning lines by using any one of a plurality of types of size changing methods. When the size of the predetermined image is enlarged or reduced by the size changing unit by the size changing method selecting unit, the size of the plurality of types of size changing methods is enlarged or reduced based on the size of the predetermined image. It is possible to select a resizing method suitable for the above.
[0012]
Therefore, a suitable size changing method is selected from a plurality of types of size changing methods based on the size of the predetermined image, and the size of the predetermined image can be converted to an appropriate size according to the number of scanning lines in the display area by the size changing method. Therefore, in image display processing by non-sequential scanning, image display processing of an appropriate size such that the number of scanning lines matches the number of pixels in the vertical direction of the image becomes possible, and image quality deterioration such as display unevenness during image display is possible. Can be suppressed.
[0013]
Here, the above-mentioned optical element is, for example, a liquid crystal, an electroluminescent element, a plasma display, a light emitting diode, or the like.
In image enlargement processing or image reduction processing (these two processings are collectively referred to as resampling), a post-filter after coordinate transformation in the enlargement / reduction processing known as a resizing method is actually used. The nearest neighbor method, the bilinear method, the bicubic method, and the like are used. The image quality after processing is improved in the order of the nearest neighbor method, the bilinear method, and the bicubic method. Hereinafter, the three size changing methods will be briefly described.
[0014]
(1) Nearest neighbor method
Generally, the coordinates of the pixels of the image before enlargement or reduction corresponding to a certain pixel of the image after enlargement or reduction take real values instead of integer values. Therefore, a method of selecting the nearest pixel and drawing this density value on the corresponding pixel of the enlarged or reduced image is the nearest neighbor method. This method is very suitable for computers and can be processed at high speed, and is used when any resampling is acceptable. However, in the reduction processing, aliasing frequently occurs, and the image quality deteriorates. On the other hand, the output image has relatively high contrast, and depending on the type of the input image, there is a case where the enlargement process can be performed very straightforwardly.
[0015]
(2) Bi-linear method (bi-linear interpolation)
In the nearest neighbor method, the nearest pixel is selected. In the bilinear method, linear density interpolation is performed from the density values of four surrounding pixels according to the coordinates (real values). This method does not cause aliasing unlike the nearest neighbor method, but has the disadvantage that the luminance change becomes too linear and the image is blurred.
[0016]
(3) Bi-cubic method
In order to perform interpolation with higher precision than the bilinear method, interpolation is performed using the cubic function from the density values of the surrounding 16 pixels. The equation used for interpolation is sin (πx) / πx, which is known to be the most perfect density interpolation equation in theory. The features of this method are that aliasing does not occur unlike the bilinear method, and that the image is not as blurry as the bilinear method. However, it has disadvantages such as a large amount of calculation, a low processing speed, and slight fluctuations in the image.
[0017]
In a second aspect based on the first aspect, the size changing method selecting means selects the size changing method based on the size of the predetermined image in addition to the size of the predetermined image. It is characterized by.
That is, the size change method selection means can select the size change method based on the size change of the predetermined image in addition to the size of the predetermined image.
[0018]
For example, when there is a bilinear method as a size changing method, in this method, if the size of a predetermined image is reduced to half or less, a phenomenon called line dropout occurs and the image quality is reduced at a stretch. Here, by selecting the size changing method based on the contents of the change in the image size, it is possible to select another method without selecting the bilinear method at the time of such a size change.
[0019]
In a third aspect based on the first or second aspect, a serial number is associated with each of the scanning lines in the order in which the scanning lines are arranged.
A predetermined number among the serial numbers associated with the scanning lines is an initial value corresponding to the least significant bit (0th digit) of the bit string constituting the gradation data;
A value obtained by adding the largest numerical value among the numerical values included in the numerical value group to the initial value corresponding to the least significant bit is the most significant bit ((N-1) th digit) of the bit string constituting the gradation data. And the initial value of the scanning line corresponding to
Other bits between the most significant bit and the least significant bit correspond to bits one digit above the number of bits of the other bit in order from the larger number of bits of the other bit. A value obtained by adding the initial value and the numerical value obtained by adding 1 to the bit number of the other bit from the smaller one of the numerical values included in the numerical value group corresponds to the initial value of the other bit. Attached
First, a scanning line having a serial number indicated by the initial value corresponding to the least significant bit is selected, and then the most significant bit and the bit from this bit to the bit immediately before the least significant bit one by one in order. A first process of sequentially selecting scan lines of serial numbers indicated by the initial values corresponding to the shifted bits, respectively;
1 is added to the value associated with each bit of the gradation data, and the value corresponding to each bit of the gradation data after the addition exceeds a value obtained by subtracting 1 from the total number of the scanning lines. A second process of updating the value to the minimum value of the serial number when
And a third unit for selecting a scanning line corresponding to a value associated with each bit of the gradation data after the second process in the same order as the first process. ,
By repeating the second processing and the third processing until all the scanning lines in the display area are selected for each bit of the bit string constituting the gradation data, the scanning lines in the non-sequential scanning are repeated. It is characterized in that the selection order is determined.
[0020]
That is, according to the above-described procedure, each optical element corresponding to each scanning line in the display area of the image selected by the scanning line driving circuit is set to 2 every time the scanning line is selected. ⁿ Light emission is enabled for a time corresponding to one numerical value selected in a predetermined order from a numerical value group corresponding to a ratio of values.
According to a fourth aspect of the present invention, in any one of the first to third aspects, a scanning line number detecting unit for detecting the number of scanning lines in the display area is provided.
[0021]
That is, the number of scanning lines in the display area can be detected by the number of scanning lines detecting unit. Therefore, for example, when the display area is a variable window, the number of scanning lines can be detected according to the change.
According to a fifth aspect of the present invention, there is provided a pixel matrix in which pixels including optical elements are arranged in a matrix,
A plurality of scanning lines respectively connected to a pixel group arranged along one of a row direction and a column direction of the pixel matrix;
A plurality of data lines respectively connected to a pixel group arranged along the other of the row direction and the column direction of the pixel matrix,
A scanning line driving circuit for sequentially selecting the plurality of scanning lines one by one;
A data line drive circuit that outputs a control signal related to light emission of the optical element to at least one data line of the plurality of data lines;
A control unit that controls the operation of the scanning line driving circuit and the data line driving circuit,
It is generated based on the number of scanning lines in a display area including a predetermined number of the scanning lines and the data lines, and grayscale data having a bit length N corresponding to the number of light emission gradations indicating the light emission gradation of the optical element. The added number obtained by adding 1 to the total number of the scanning lines in the display area is represented by the number of bits 2 ⁿ Each optical element corresponding to each scanning line in the display area selected by the scanning line driving circuit, based on a numerical value group divided into numerical values according to the ratio consisting of the values, every time the scanning line is selected, A selection order of the scanning lines is determined so that light emission can be performed for a time corresponding to one numerical value selected in a predetermined order from a numerical value group, and a predetermined image is displayed in the display area by non-sequential scanning in the selection order. An image processing apparatus that converts the predetermined image into an image of an appropriate size, which is input to an image display device capable of displaying gradation,
Scanning line number detecting means for detecting the number of scanning lines in the display area,
Based on the number of scanning lines of the display area detected by the scanning line number detecting means, the size of the predetermined image before the non-sequential scanning, using any one of a plurality of types of size changing method Size changing means that can be enlarged or reduced to a size corresponding to the number of scanning lines;
When the size of the predetermined image is increased or reduced by the size changing unit, a size change method that selects a size change method suitable for expansion or reduction among the plurality of types of size change methods based on the size of the predetermined image. And a method selecting means.
[0022]
With such a configuration, when an image is displayed in a display area composed of a predetermined number of scanning lines and data lines by a non-sequential scanning method, the number of scanning lines in the display area is detected by the scanning line number detecting means. The size of the predetermined image before the non-sequential scanning is performed by the size changing unit using one of a plurality of types of size changing methods based on the acquired number of scanning lines. It is possible to enlarge or reduce the size of the predetermined image according to the number of scanning lines, and when enlarging or reducing the size of the predetermined image by the size changing means by the size changing method selecting means, It is possible to select a size change method suitable for enlargement or reduction from the plurality of types of size change methods based on the size.
[0023]
Therefore, a suitable size changing method is selected from a plurality of types of size changing methods based on the size of the predetermined image, and the size of the predetermined image can be converted to an appropriate size according to the number of scanning lines in the display area by the size changing method. Therefore, in image display processing by non-sequential scanning, image display processing of an appropriate size such that the number of scanning lines matches the number of pixels in the vertical direction of the image becomes possible, and image quality deterioration such as display unevenness during image display is possible. Can be suppressed.
[0024]
In a sixth aspect based on the fifth aspect, the size changing method selecting means selects the size changing method based on the size of the predetermined image in addition to the size of the predetermined image. It is characterized by.
That is, the size change method selection means can select the size change method based on the size change of the predetermined image in addition to the size of the predetermined image.
[0025]
For example, when there is a bilinear method as a size changing method, in this method, if the size of a predetermined image is reduced to half or less, a phenomenon called line dropout occurs and the image quality is reduced at a stretch. Here, by selecting the size changing method based on the content of the change in the image size, it is possible to select another method without selecting the bilinear method at the time of such a size change.
[0026]
In a seventh aspect based on the fifth or sixth aspect, the image display device comprises:
A serial number is associated with each of the scanning lines according to the arrangement order thereof,
A predetermined number among the serial numbers associated with the scanning lines is an initial value corresponding to the least significant bit (0th digit) of the bit string constituting the gradation data;
A value obtained by adding the largest numerical value among the numerical values included in the numerical value group to the initial value corresponding to the least significant bit is the most significant bit ((N-1) th digit) of the bit string constituting the gradation data. And the initial value of the scanning line corresponding to
Other bits between the most significant bit and the least significant bit correspond to bits one digit above the number of bits of the other bit in order from the larger number of bits of the other bit. A value obtained by adding the initial value and the numerical value obtained by adding 1 to the bit number of the other bit from the smaller one of the numerical values included in the numerical value group corresponds to the initial value of the other bit. Attached
First, a scanning line having a serial number indicated by the initial value corresponding to the least significant bit is selected, and then the most significant bit and the bit from this bit to the bit immediately before the least significant bit one by one in order. A first process of sequentially selecting scan lines of serial numbers indicated by the initial values corresponding to the shifted bits, respectively;
1 is added to the value associated with each bit of the gradation data, and the value corresponding to each bit of the gradation data after the addition exceeds a value obtained by subtracting 1 from the total number of the scanning lines. A second process of updating the value to the minimum value of the serial number when
And a third unit for selecting a scanning line corresponding to a value associated with each bit of the gradation data after the second process in the same order as the first process. ,
By repeating the second processing and the third processing until all the scanning lines in the display area are selected for each bit of the bit string constituting the gradation data, the scanning lines in the non-sequential scanning are repeated. It is characterized in that the selection order is determined.
[0027]
That is, according to the above-described procedure, each optical element corresponding to each scanning line in the display area of the image selected by the scanning line driving circuit is set to 2 every time the scanning line is selected. ⁿ Light emission is enabled for a time corresponding to one numerical value selected in a predetermined order from a numerical value group corresponding to a ratio of values.
Further, an eighth invention is a program for controlling the first invention,
Based on the number of scanning lines in the display area, the size of the predetermined image before the non-sequential scanning is enlarged to a size corresponding to the number of scanning lines by using any one of a plurality of types of size changing methods. Or a resizable resizing step,
Resizing the size of the predetermined image in the resizing step, selecting a suitable resizing method among the plurality of types of resizing methods based on the size of the predetermined image. And a method selecting step.
[0028]
Here, the present invention is a program for controlling the first invention, and the description thereof will be omitted because the effects are duplicated.
In a ninth aspect based on the eighth aspect, in the size changing method selecting step, the size changing method is selected based on the size of the predetermined image in addition to the size of the predetermined image. It is characterized by:
[0029]
Here, the present invention is a program for controlling the second invention, and the description thereof will be omitted because the effects are duplicated.
In a tenth aspect based on the eighth or ninth aspect, the method further comprises the step of detecting the number of scanning lines in the display area.
Here, the present invention is a program for controlling the fourth invention, and the description thereof will be omitted because the effects are duplicated.
[0030]
An eleventh invention is a program for controlling the fifth invention,
A scanning line number detecting step of detecting the number of scanning lines in the display area;
Based on the number of scanning lines of the display area detected in the scanning line number detecting step, the size of the predetermined image before the non-sequential scanning, using any one of a plurality of types of size change method A size changing step that can be enlarged or reduced to a size corresponding to the number of scanning lines;
Resizing the size of the predetermined image in the resizing step, selecting a suitable resizing method among the plurality of types of resizing methods based on the size of the predetermined image. And a method selecting step.
[0031]
Here, the present invention is a program for controlling the fifth invention, and the description thereof will be omitted because the effects are duplicated.
In a twelfth aspect based on the eleventh aspect, in the size change method selecting step, the size change method is selected based on the size of the predetermined image in addition to the size of the predetermined image. It is characterized by:
[0032]
Here, the present invention is a program for controlling the sixth invention, and the description thereof will be omitted because the effects are duplicated.
[0033]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. 1 to 7 are views showing an embodiment of an image display device and an image processing device according to the present invention.
First, the configuration of the image display device according to the present invention will be described with reference to FIG. FIG. 1 is a block diagram showing the configuration of the image display device according to the present invention.
[0034]
The image display device 10 includes a panel 10a, a control unit 10b, a drive unit 10c, a frame memory 10d, an image analysis unit 10e, and an image conversion unit 10f.
The panel 10a is configured by arranging pixel circuits including the light emitting elements shown in FIG. 3 in a matrix, and causes the selected light emitting element to emit light for a predetermined time by voltage supply (or current supply) from the driving unit 10c. . As shown in FIG. 3, the pixel circuit 3 includes a scanning line 30, a data line 31, a current supply line 32, a switching transistor 33, a driving transistor 34, an optical element 35, and a storage capacitor 36. It has a configuration that includes it. Here, the operation of the pixel circuit 3 in the present embodiment is controlled in response to the writing of the bright signal supplied from the control unit 10b via the driving unit 10c to high or low, and the scanning line 30 Irrespective of whether or not is driven, the optical element 35 emits light when the bright signal is written as high via the data line 31 and does not emit light when it is written as low. In the present embodiment, the optical element 35 is an electroluminescence element. That is, the image display device 10 according to the present embodiment converts the signal (bright signal) applied to the data line 31 into binary bit data, and uses the bit data to generate the optical element during one frame period. The light emission time is controlled for 35. Thus, gradation display is performed by controlling the light emission time of the optical element 35 in accordance with the time corresponding to each bit of the bit string forming the gradation data.
[0035]
The control unit 10b controls the driving unit 10c according to the basic vertical scanning signal, horizontal scanning signal, dot clock signal, and gradation data. That is, the driving unit 10c causes the scanning line of the image display area on the panel 10a to be selected in a specific order by non-sequential scanning, and applies a voltage (or applies a current to the pixel of the selected scanning line based on the display image data). Supply).
[0036]
The driving unit 10c is controlled by the control unit 10b, selects scanning lines in the image display area on the panel 10a in a specific order by non-sequential scanning, and outputs the scanning lines selected based on the image data to be displayed. A voltage is applied (or a current is supplied) to the pixel.
The frame memory 10d is a memory for handling an image to be displayed in the image display area. The frame memory 10d extracts image data corresponding to non-sequential scanning on the memory, and drives pixels of a corresponding scanning line of the panel 10a.
[0037]
The image analysis unit 10e analyzes the image data acquired from the external device, and transmits the analysis result to the image conversion unit 10f. The analysis contents here include the number of colors and the size of the image data, and the required number of scanning lines and the like of the image data can be determined.
The image conversion unit 10f selects an appropriate size conversion method for converting the size of the acquired image based on the analysis result from the image analysis unit 10e and the number of scanning lines on the display panel, and scans the size of the image. This is converted into an appropriate one according to the number of lines. The converted image data is stored in the frame memory 10d. Here, in the present embodiment, two methods, a bilinear method and a bicubic method, can be selected for the image enlargement processing or image reduction processing. In the change method selection process, the bilinear method is selected when the image size is equal to or larger than the predetermined size, and the bicubic method is selected when the image size is smaller than the predetermined size. In the present embodiment, it is assumed that an image of a predetermined size has 360 pixels in the vertical direction (actually, the number of pixels corresponding to the scanning line direction) of the image. However, when reducing the size of the input image to 1/2 or less, the bicubic method is selected regardless of the size of the image.
[0038]
Further, a more specific operation of the image display device 10 will be described with reference to FIGS. Here, FIG. 4 is a diagram showing an example of a display area on panel 10a.
First, image data such as a moving image is transmitted from an external device such as a PC (Personal Computer) to the image analysis unit 10e. Thus, the image analysis unit 10e performs the analysis processing of the image data. The analysis processing checks the number of colors and the size of the input image as described above. Thus, when the size of the image (for example, 640 (the number of horizontal pixels) × 480 (the number of vertical pixels)) is known, the image conversion unit 10f determines the arrangement direction of the scanning lines arranged in the pixel matrix of the panel 10a. The size of the input image in the same direction is compared with the number of scanning lines in the display area of the panel 10a (for example, 381 (number of signal lines) × 254 (number of scanning lines)). Here, in the present embodiment, the scanning lines are arranged in the row direction. Therefore, the vertical size (480 pixels) of the input image is compared with the number of scanning lines (254) of the panel 10a. The number of bits of the grayscale data of the input image is 8 bits.
[0039]
When the above comparison is performed, “480> 254” is obtained, and the number of vertical pixels of the input image is larger than the number of scanning lines in the display area. Therefore, the aforementioned bilinear method or bicubic method is selected to reduce the input image. Processing will be performed. In this case, since the size of the image has 480 vertical pixels, "480>360" is satisfied, and the bilinear method is selected as described above.
[0040]
Here, in the present embodiment, the horizontal size of the input image is determined according to the aspect ratio of the original image after the vertical size in the reduction processing is determined. That is, “vertical: horizontal = 480: 640 = 3: 4” from the size of the input image. Accordingly, since the vertical size is reduced from 480 pixels to 254 pixels, the horizontal size of the input image is reduced from 640 pixels to 339 pixels. Finally, the size of the input image after the reduction processing is “339 (number of horizontal pixels) × 254 (number of vertical pixels)”.
[0041]
On the other hand, contrary to the above case, when the size of the input image is 200 (the number of horizontal pixels) × 150 (the number of vertical pixels), which is smaller than the size of the display area, the image conversion unit 10f outputs the image of the display area. The bilinear method or the bicubic method is selected according to the size, and the input image is enlarged. In this case, since the number of vertical pixels in the image is 150, “150 <360” is satisfied, and the bicubic method is selected as described above.
[0042]
That is, using the bicubic method, the vertical size of the input image, 120 pixels, is expanded to 254 pixels in accordance with the number of scanning lines 254 (lines) in the display area. On the other hand, based on the aspect ratio of the original image “vertical: horizontal = 150: 200 = 3: 4”, the horizontal size of 200 pixels of the input image is enlarged to 339 pixels. That is, the size of the input image is increased from “200 (number of horizontal pixels) × 150 (number of vertical pixels)” to “339 (number of horizontal pixels) × 254 (number of vertical pixels)” by the enlargement processing. Will be converted.
[0043]
The converted image is stored in the frame memory 10d, and is displayed by the control unit 10b and the driving unit 10c on the display area of the panel 10a by non-sequential scanning.
Here, when the vertical size of the input image is larger than 720 (for example, 960 (pixel)), “(960/2)> 360” is satisfied, and the image size must be reduced to １ ／ or less. . In such a case, the bicubic method is selected as described above, and the image is reduced by this method.
[0044]
Further, in the present embodiment, the display area of the image display device 10 is such that only the entire panel 10a is the display area as in the display area 100a shown in FIG. This is because, in the configuration of FIG. 1, the image analysis unit 10e or the image conversion unit 10f is not configured to detect the number of scanning lines in the display area. Therefore, in the present embodiment, it is assumed that the image conversion unit 10f knows the number of scanning lines in the display area 100a in advance. The image display device 10 in FIG. 1 may be configured to detect the number of scanning lines in a display area by providing a functional unit similar to a scanning line detecting unit 21b described later. With this configuration, the display area on the panel 10a can be changed to an arbitrary size suitable for non-sequential scanning.
[0045]
Further, the principle of image display by the non-sequential scanning method will be described.
Here, for convenience of explanation, a case where the total number of scanning lines is 14 and the bit length of the gradation data is 4 bits will be described as an example.
First, 15 obtained by adding 1 to the total number 14 of the scanning lines is calculated as 2 which is the number of bits of the bit string constituting the grayscale data having the bit length N. ⁿ A numerical group divided according to a ratio consisting of values (n = 0, 1, 2,..., (N−1)) is generated. That is, since the bit length N of the gradation data is 4 bits, ⁰ : 2 ¹ : 2 ² : 2 ³ The value 15 obtained by adding 1 to the total number of scanning lines at a ratio of = 1: 2: 4: 8 is divided. In this case, it can be divided exactly into 1: 2: 4: 8. Therefore, it is divided into four numerical values of 1, 2, 4, and 8 according to the respective ratios.
[0046]
Next, serial numbers from 0 to 13 are associated with each of the 14 scanning lines in total. Then, the serial number 0 of the first selected scanning line (hereinafter referred to as an initial scanning line) is set as an initial value in the LSB (0th bit) of the grayscale data. Next, for the third bit (MSB) of the gradation data, the largest number 8 among the divided numerical values is added to the serial number 0 of the scanning line selected immediately before, and this serial number 8 is assigned to the initial scanning line. Set as a serial number. Further, for the second bit of the gradation data, the second largest 4 of the divided numerical values is added to the serial number 8 of the scanning line selected immediately before, and this 12 is used as the serial number of the initial scanning line. Set. Furthermore, the third largest 2 of the divided numerical values is added to the serial number 12 selected immediately before to the first bit of the gradation data. In this case, the numerical value after the addition is the serial number. Since it exceeds 13, the remainder (0) obtained by dividing 14 of the addition result by the total number of scanning lines 14 is set as the serial number of the initial scanning line. In the case of 15, which is obtained by adding 3 to 12, 15/14 = 1 (the remainder is 1), so that the serial number of the initial scanning line in this case is 1.
[0047]
Therefore, the serial number 0 is set as the initial value for the LSB, the serial number 8 is set as the initial value for the MSB, and the serial number 12 is set for the second bit in the bit length 4 bits of the gradation data. An initial value is set, and a serial number 0 is set as an initial value for the first bit.
As described above, according to the bit length of the gradation data, as described above, the numerical value obtained by sequentially adding the divided numerical values to the serial numbers of the scanning line selected immediately before from the larger one to the smaller one, The serial number of the initial scanning line corresponding to each bit of the gradation data is determined.
[0048]
Further, the determined initial scanning line is used as the initial scanning line corresponding to the LSB (0th bit), the initial scanning line corresponding to the MSB (3rd bit), and the initial scanning corresponding to the second bit of the gradation data. The scanning lines with serial numbers corresponding to the respective lines are sequentially selected in the order of the initial scanning line corresponding to the first bit, and each pixel of the selected scanning line is driven. After selecting each scanning line, 1 is added to the serial number of the initial scanning line corresponding to each bit. At this time, when the result of adding 1 to the initial value corresponding to each bit exceeds the value obtained by subtracting 1 from the total number of scanning lines (here, 13), the addition result is set to 0. That is, when the thirteenth scanning line is selected and 1 is added to the serial number 13, the addition result is not set to a numerical value (14) exceeding the serial number 13 of the scanning line, but 0, which is the minimum value of the serial number of the scanning line. And Therefore, in the next process, the 0th scanning line is selected. The order of selection of each bit of the gradation data is performed in the order of LSB → MSB → “upper bit between LSB and MSB → lower bit” → LSB → MSB →. That is, the repetition of the 0th bit → the 3rd bit → the 2nd bit → the 1st bit → the 0th bit → the 3rd bit → the 2nd bit →... That is, when the 0th scan line, the 8th scan line, the 12th scan line, and the 0th scan line are selected in correspondence with each bit of the gradation data, the 1st scan line, 9th scan line, In order to select the thirteenth scanning line, the thirteenth scanning line, and the first scanning line, sequentially select the scanning lines of serial numbers obtained by adding 1 to the serial numbers of the previously selected scanning lines corresponding to each bit. Then, each pixel is driven.
[0049]
In the image display device 10, the number of scanning lines in the display area is 254. Therefore, 255 obtained by adding 1 to this number is used as 2 bits of the number of bits of the bit string constituting the 8-bit gradation data. ⁿ The division is performed according to the ratio of the values (n = 0, 1, 2,... (8-1)). That is, 255 is divided into numerical groups according to the ratio of 1: 2: 4: 8: 16: 32: 64: 128, and the numerical value corresponding to each bit is 1, 2, 4, 8,. There are eight of 16, 32, 64 and 128.
[0050]
In addition, depending on the number of scanning lines in the display area, the number of additions obtained by adding 1 to the number of scanning lines is equal to the number of bits in the bit string constituting the N-bit gradation data, ie, 2 bits. ⁿ In some cases, it is not possible to accurately divide the image according to the ratio of the values (n = 0, 1, 2,..., (N-1)). For example, consider the case where the number of scanning lines in the display area is 240 and the bit length of the gradation data is 6 bits. In this case, the added number 241 obtained by adding 1 to the number of scanning lines is divided at a ratio of 1: 2: 4: 8: 16: 32, but the 241 cannot be accurately divided at this ratio. Therefore, when it is not possible to divide the value into a numerical value with an accurate ratio, such as 4, 7, 15, 30, 62, 123, a numerical value group is generated by setting a value near the value.
[0051]
Further, the flow of the operation processing of the image display device 10 will be described with reference to FIG. FIG. 5 is a flowchart illustrating an operation process of the image display device 10.
As shown in FIG. 5, the process first proceeds to step S500, and the image analysis unit 10e determines whether or not image data has been acquired. If it is determined that the image data has been acquired (Yes), the process proceeds to step S502, and so on. Otherwise (No), it waits until it is acquired.
[0052]
When the process proceeds to step S502, the image analysis unit 10e performs an analysis process on the acquired image data, and proceeds to step S504. Here, as described above, the number of colors and the image size of the image are analyzed and checked.
In step S504, the image analysis unit 10e transmits the analysis result to the image conversion unit 10f, and proceeds to step S506.
[0053]
In step S506, the image conversion unit 10f determines whether or not the input image needs to be enlarged based on the analysis result. If it is determined that the input image needs to be enlarged (Yes), the process proceeds to step S508, and so on. If not (No), the process moves to step S522.
When the process proceeds to step S508, the image conversion unit 10f determines whether or not the size of the input image is equal to or larger than the predetermined image size. Otherwise (No), the process moves to step S518.
[0054]
When the process proceeds to step S510, the image conversion unit 10f selects the bilinear method as the image size changing method, and proceeds to step S512.
In step S512, the image conversion unit 10f performs an input image enlargement process using the bilinear method, and proceeds to step S514.
In step S514, the image conversion unit 10f stores the converted image data in the frame memory 10d, and proceeds to step S516.
[0055]
In step S516, the control unit 10b and the driving unit 10c perform a process of displaying the image data stored in the frame memory 10d by non-sequential scanning, and then proceed to step S500. Here, the frame memory is provided with two areas of a predetermined capacity, and the two areas are switched to display an image. That is, while the converted image is stored in one area, the image stored in the other area is displayed.
[0056]
If the input image is smaller than the predetermined size in step S508 and the process proceeds to step S518, the image conversion unit 10f selects the bicubic method as a method of changing the image size, and proceeds to step S520.
In step S520, the image conversion unit 10f enlarges the input image using the bicubic method, and then proceeds to step S514.
[0057]
In step S506, if the input image needs to be reduced and the process proceeds to step S522, the image conversion unit 10f determines whether the size of the input image is equal to or larger than the predetermined image size. If determined (Yes), the process proceeds to step S524; otherwise (No), the process proceeds to step S534.
[0058]
When the process proceeds to step S524, the image conversion unit 10f determines whether or not the input image needs to be reduced to 以下 or less. If it is determined that the input image needs to be reduced (Yes), the process proceeds to step S526. Otherwise (No), the process proceeds to step S530.
When the process proceeds to step S526, the image conversion unit 10f selects the bicubic method as the image size changing method, and proceeds to step S528.
[0059]
In step S528, the image conversion unit 10f performs a reduction process on the input image using the bicubic method, and proceeds to step S514.
If it is determined in step S524 that the input image does not need to be reduced to 以下 or less and the process proceeds to step S530, the image conversion unit 10f selects the bilinear method as the image size changing method, and proceeds to step S532. .
[0060]
In step S532, the image conversion unit 10f performs a reduction process on the input image using the bilinear method, and proceeds to step S514.
If the image size is smaller than the predetermined size in step S522 and the process proceeds to step S534, the image conversion unit 10f selects the bicubic method as a method of changing the image size, and proceeds to step S536.
[0061]
In step S536, the image conversion unit 10f performs a process of reducing the input image using the bicubic method, and proceeds to step S514.
Further, a flow of processing for displaying the image data stored in the frame memory 10d by the non-sequential scanning in the image display device 10 will be described with reference to FIG. FIG. 6 is a flowchart showing processing for displaying image data by non-sequential scanning.
[0062]
As shown in FIG. 6, the process first proceeds to step S600, where the number of scanning lines in the display area and the number of light emission gradations of the display image are set, and the process proceeds to step S602.
In step S602, gradation data having a bit length N according to the set number of gradations is generated, and the flow advances to step S604. Here, when the number of gradations is determined from the beginning, there is no need to perform this processing if the gradation data is generated in advance. The gradation data is a variable having a bit length corresponding to the number of inputted gradations, for example, a variable having a bit length of 4 bits for 16 gradations, and a variable of 6 bits for 64 gradations. It becomes a variable having a length. In the present embodiment, there are 256 gradations of 8 bits.
[0063]
In step S604, the number of additions obtained by adding 1 to the total number of scanning lines is calculated by dividing the number of bits of the grayscale data having the bit length N by two. ⁿ A value group divided into numerical values corresponding to each ratio of the ratio group consisting of values (n = 0, 1, 2,..., (N−1)) is generated, and the process proceeds to step S606.
In step S606, the number of the initial scanning line corresponding to each bit of the gradation data is calculated and set based on the generated numerical value group, and the process proceeds to step S608.
[0064]
In step S608, the control circuit 10b instructs the drive circuit 10c to set the initial scanning line corresponding to each bit of the grayscale data in the order of LSB → MSB → “upper bit to lower bit between LSB and MSB”. It drives and moves to step S610.
In step S610, the control circuit 10b adds 1 to each of the numbers of the initial scanning lines driven by the drive circuit 10c, and proceeds to step S612.
[0065]
In step S612, it is determined whether or not the addition result of the number corresponding to each bit exceeds the total number of scanning lines. If it is determined that the number exceeds the number (Yes), the process proceeds to step S614. If not (No), the process proceeds to step S220.
When the process proceeds to step S614, the number of the addition result is updated to “0” and the process proceeds to step S616. That is, the serial number is updated to the minimum value (“0” in the present embodiment) of the serial number associated with the scanning line.
[0066]
In step S616, the selection of the scanning line of the number of the addition result corresponding to each bit is performed in the above-described order, and the process proceeds to step S618.
In step S618, 1 is added to the number of the scanning line selected immediately before (the number selected in step S616), and the flow advances to step S612.
On the other hand, when there is no addition result exceeding the total number of scanning lines and the process proceeds to step S620, the addition result is set as it is and the process proceeds to step S616.
[0067]
Here, in the flowchart of FIG. 6 described above, the selection order of the scanning lines and the like are performed by calculation. However, the present invention is not limited to this. In the image display device 10, the number of scanning lines in the display area is known in advance. Alternatively, the selection order of the scanning lines may be calculated in advance and prepared in a memory or the like.
As described above, in the image conversion unit 10f, as described above, an appropriate size change method is selected based on the size change of the input image, such as enlargement or reduction, and the panel 10a is selected by the selected size change method. The size of the input image is converted so that the number of pixels in the vertical direction on the input image side is the same in accordance with the number of scanning lines in the display area in. One line (horizontal row of pixels) is associated one-to-one, and non-sequential scanning can be performed accurately.
[0068]
Further, the configuration of the image display system according to the present invention will be described with reference to FIG. FIG. 2 is a block diagram showing the configuration of the image display system according to the present invention.
As shown in FIG. 2, the image display system 2 has a configuration including an electro-optical device 20 and an image processing device 21.
The electro-optical device 20 has a configuration including a panel 10a, a control unit 10b, a driving unit 10c, and a frame memory 10d.
[0069]
Since the panels 10a to 10d are the same as those shown in FIG. 1, the description is omitted.
The image processing device 21 includes an image analysis unit 21a, a scanning line detection unit 21b, and an image conversion unit 21c.
The image analysis unit 21a analyzes the image data obtained from the external device, and transmits the analysis result to the image conversion unit 21c. The analysis contents here include the number of colors and the size of the image data, and the required number of scanning lines and the like of the image data can be determined.
[0070]
The scanning line number detection unit 21b detects the number of scanning lines and the number of data lines in the display area of the panel 10a, and the detected number of scanning lines and the number of data lines are transmitted to the image conversion unit 21c.
The image conversion unit 21c selects an appropriate image resizing method based on the analysis result from the image analysis unit 21a and the detection result of the scanning line number detection unit 21b, and uses the selected method to input an image. Has a function of converting the size of the image into an appropriate one according to the number of detected scanning lines. The converted image data is stored in the frame memory 10d. Here, in the present embodiment, two methods, a bilinear method and a bicubic method, can be selected for the image enlargement processing or image reduction processing. In the change method selection process, the bilinear method is selected when the image size is equal to or larger than the predetermined size, and the bicubic method is selected when the image size is smaller than the predetermined size. In the present embodiment, it is assumed that an image of a predetermined size has 360 pixels in the vertical direction (actually, the number of pixels corresponding to the scanning line direction) of the image. However, when reducing the size of the input image to 1/2 or less, the bicubic method is selected regardless of the size of the image.
[0071]
Further, a more specific operation of the image display system 2 will be described with reference to FIGS.
First, image data is transmitted from an external device such as a PC to the image analysis unit 21a of the image processing device 21. Thus, the image analysis unit 21a performs an analysis process on the image data. The analysis processing checks the number of colors and the size of the input image as described above. Thereby, the size of the image (for example, 640 (the number of horizontal pixels) × 480 (the number of vertical pixels)) is known. Here, in the present embodiment, the number of bits of the gradation data of the input image is 7 bits.
[0072]
On the other hand, the scanning line number detection unit 21b detects the number of scanning lines and the number of data lines in the display area of the panel 10a via the control unit 10b of the electro-optical device 20, and transmits the detection result to the image conversion unit 21c. Here, the display area on the panel 10a is 100b shown in FIG. 4B, and here, it is assumed that 127 (the number of scanning lines) × 169 (the number of signal lines).
[0073]
Upon obtaining the analysis result of the image analysis unit 21a and the detection result of the scanning line number detection unit 21b, the image conversion unit 21c determines the vertical size (480 pixels) of the input image and the number of scanning lines (127 lines) in the display area of the panel 10a. ) And compare. Here, since “480> 127”, and the number of vertical pixels of the input image is larger than the number of scanning lines in the display area, the above-described bilinear method or bicubic method is selected to perform the reduction processing of the input image. become. In this case, since the size of the input image has 480 vertical pixels, “480> 360” is satisfied, and the bilinear method is selected as described above.
[0074]
Here, in the present embodiment, with regard to the horizontal size of the input image, after the vertical size is determined by the reduction processing, the size is determined according to the aspect ratio of the original image. That is, “vertical: horizontal = 480: 640 = 3: 4” from the size of the input image. Accordingly, since the vertical size is reduced from 480 pixels to 127 pixels, the horizontal size of the input image is reduced from 640 pixels to 169 pixels. Finally, the size of the input image after the reduction processing is “169 (the number of horizontal pixels) × 127 (the number of vertical pixels)”.
[0075]
On the other hand, contrary to the above case, if the size of the input image is 120 (the number of horizontal pixels) × 90 (the number of vertical pixels) and smaller than the size of the display area (90> 127), the image conversion unit 21c In the above, the input image is enlarged according to the size of the display area by selecting the bilinear method or the bicubic method. In this case, the size of the input image is 120 in the number of vertical pixels, so that "120 <360", and the bicubic method is selected as described above.
[0076]
That is, by using the bicubic method, the vertical size of the input image of 90 pixels is enlarged to 127 pixels according to the number of scanning lines 127 (lines) in the display area. On the other hand, based on the aspect ratio “vertical: horizontal = 90: 120 = 3: 4” of the original image, the horizontal size of the input image is enlarged to 120 pixels to 169 pixels. That is, the size of the input image is increased from “120 (number of horizontal pixels) × 90 (number of vertical pixels)” to “169 (number of horizontal pixels) × 127 (number of vertical pixels)” by the enlargement processing. Is converted to
[0077]
The converted image is stored in the frame memory 10d, and is displayed by the control unit 10b and the driving unit 10c on the display area of the panel 10a by non-sequential scanning. Here, the non-sequential scanning is the same as the processing in the image display device 10 described above, and the description thereof is omitted.
In the image display system 2, since the number of scanning lines in the display area is 127, 128, which is obtained by adding 1 to this number, is calculated as 2 which is the number of bits of the bit string constituting the 7-bit gradation data. ⁿ The division is performed according to the ratio of the values (n = 0, 1, 2,... (7-1)). That is, 128 is divided into numerical groups according to the ratio of 1: 2: 4: 8: 16: 32: 64, and numerical values corresponding to each bit are 1, 2, 4, 8, 16,. 32 and 64.
[0078]
When the vertical size of the input image is larger than 720 (for example, 960 (pixel)), “(960/2)> 360” is satisfied, and the image size must be reduced to 以下 or less. In such a case, the bicubic method is selected as described above, and the image is reduced by this method.
Further, the flow of the operation processing of the image processing apparatus 21 will be described with reference to FIG. FIG. 7 is a flowchart showing the operation processing of the image processing apparatus 21.
[0079]
As shown in FIG. 7, the process first proceeds to step S700, and the image analysis unit 21a determines whether or not image data has been acquired. If it is determined that the image data has been acquired (Yes), the process proceeds to step S702, and the process proceeds to step S702. If not (No), it waits until it is acquired.
When the process proceeds to step S702, the image analysis unit 21a performs an analysis process on the acquired image data, and proceeds to step S704. Here, as described above, the number of colors and the image size of the image are analyzed and checked.
[0080]
In step S704, the image analysis unit 21a transmits the analysis result to the image conversion unit 21c, and proceeds to step S706.
In step S706, the scanning line number detection unit 21b detects the number of scanning lines (here, also the number of data lines) in the display area of the panel 10a, and proceeds to step S708.
[0081]
In step S708, the scanning line number detection unit 21b transmits the detection result to the image conversion unit 21c, and proceeds to step S710.
In step S710, the image conversion unit 21c determines whether or not the input image needs to be enlarged based on the analysis result. If it is determined that the input image needs to be enlarged (Yes), the process proceeds to step S712. If not (No), the process moves to step S724.
[0082]
When the process proceeds to step S712, the image conversion unit 21c determines whether or not the size of the input image is equal to or larger than the predetermined image size. When it is determined that the size of the input image is equal to or larger than the predetermined size (Yes), the process proceeds to step S714. Otherwise (No), the process moves to step S720.
When the process proceeds to step S714, the image conversion unit 21c selects the bilinear method as the image size changing method, and proceeds to step S716.
[0083]
In step S716, the image conversion unit 21c performs an input image enlargement process using the bilinear method, and proceeds to step S718.
In step S718, the image conversion unit 21c transmits the converted image data to the frame memory 10d, and proceeds to step S700.
If the input image is smaller than the predetermined size in step S712 and the process proceeds to step S720, the image conversion unit 21c selects the bicubic method as a method of changing the image size, and proceeds to step S722.
[0084]
In step S722, the image conversion unit 21c performs enlargement processing of the input image using the bicubic method, and proceeds to step S718.
In step S710, if the input image needs to be reduced and the process proceeds to step S724, the image conversion unit 21c determines whether the size of the input image is equal to or larger than a predetermined image size, and determines that the size is larger than the predetermined size. If it is determined (Yes), the process proceeds to step S726; otherwise (No), the process proceeds to step S736.
[0085]
If the process proceeds to step S726, the image conversion unit 21c determines whether or not the input image needs to be reduced to 以下 or less, and if it is determined that the input image needs to be reduced (Yes), the process proceeds to step S728. Otherwise, (No), the process proceeds to step S732.
When the process proceeds to step S728, the image conversion unit 21c selects the bicubic method as the image size changing method, and proceeds to step S730.
[0086]
In step S730, the image conversion unit 21c performs a reduction process on the input image using the bicubic method, and proceeds to step S718.
If it is determined in step S726 that the input image does not need to be reduced to 以下 or less and the process proceeds to step S732, the image conversion unit 21c selects the bilinear method as the image size changing method, and proceeds to step S734. .
[0087]
In step S734, the image conversion unit 21c performs a reduction process on the input image using the bilinear method, and proceeds to step S718.
If the image size is smaller than the predetermined size in step S724 and the process proceeds to step S736, the image conversion unit 21c selects the bicubic method as a method for changing the image size, and proceeds to step S738.
[0088]
In step S738, the image conversion unit 21c performs a reduction process on the input image using the bicubic method, and proceeds to step S718.
As described above, in the image conversion unit 21c, as described above, an appropriate size changing method is selected based on the size of the input image and the size change such as enlargement or reduction, and the panel 10a is selected by the selected size changing method. The number of pixels in the vertical direction on the input image side is converted into the same number in accordance with the number of scanning lines in the display area in (1), so that the scanning lines in the display area and one line of pixels constituting the input image ( (Horizontal rows of pixels) are associated with each other on a one-to-one basis, and non-sequential scanning can be accurately performed.
[0089]
Here, the control unit 10b shown in FIGS. 1 and 2 corresponds to the control unit according to the first and fourth inventions, and the drive unit 10c corresponds to the scanning line drive described in the first and fourth inventions. The image size conversion processing by the image analysis unit 10e and the image conversion unit 10f shown in FIG. 1 corresponding to the circuit and the data line driving circuit corresponds to the size changing means described in the first invention, and is shown in FIG. The image size conversion processing by the image analysis unit 21a and the image conversion unit 21c corresponds to the size changing unit described in the fourth invention, and the scanning line number detection unit 21b performs the processing described in the third and fourth inventions. It corresponds to a scanning line number detecting means.
[0090]
In the above embodiment, any one of the nearest neighbor method, the bilinear method, and the bicubic method is used for the enlargement / reduction processing. However, the present invention is not limited to this, and another method may be used. .
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an image display device according to the present invention.
FIG. 2 is a block diagram showing a configuration of an image display system according to the present invention.
FIG. 3 is a diagram illustrating a configuration of a pixel circuit including a light emitting element.
FIG. 4 is a diagram showing an example of a display area on panel 10a.
FIG. 5 is a flowchart showing an operation process of the image display device 10;
FIG. 6 is a flowchart illustrating a process of displaying image data by non-sequential scanning.
FIG. 7 is a flowchart showing an operation process of the image processing apparatus 21.
[Explanation of symbols]
2 ... Image display system, 3 ... Pixel circuit, 10 ... Image display device, 10a ... Panel, 10b ... Control unit, 10c ... Drive unit, 10d ... Frame memory, 10e ... Image analysis unit, 10f ... Image conversion unit, 20 ... Electro-optical device, 21: Image processing device, 21a: Image analysis unit, 21b: Scan line number detection unit, 21c: Image conversion unit, 30: Scan line, 31: Data line, 32: Current supply line, 33: Switching transistor , 34: driving transistor, 35: optical element, 36: storage capacitor, 100a, 100b: display area

Claims (12)

A pixel matrix in which pixels including optical elements are arranged in a matrix,
A plurality of scanning lines respectively connected to a pixel group arranged along one of a row direction and a column direction of the pixel matrix;
A plurality of data lines respectively connected to a pixel group arranged along the other of the row direction and the column direction of the pixel matrix,
A scanning line driving circuit for sequentially selecting the plurality of scanning lines one by one;
A data line drive circuit that outputs a control signal related to light emission of the optical element to at least one data line of the plurality of data lines;
A control unit that controls the operation of the scanning line driving circuit and the data line driving circuit,
It is generated based on the number of scanning lines in a display area including a predetermined number of the scanning lines and the data lines, and grayscale data having a bit length N corresponding to the number of light emission gradations indicating the light emission gradation of the optical element. The scan line is formed based on a numerical value group obtained by dividing an addition number obtained by adding 1 to the total number of scan lines in the display area into a numerical value corresponding to a ratio of 2 ⁿ values of several bits of a bit string constituting the gradation data. Each optical element corresponding to each scanning line in the display area selected by the drive circuit is set to a time corresponding to one numerical value selected in a predetermined order from the numerical value group each time the scanning line is selected. An image display device capable of determining a selection order of the scanning lines and non-sequential scanning according to the selection order so that a predetermined image can be displayed in gradation in the display area, so that only the light can be emitted,
When a predetermined image is displayed in gradation in the display area, the size of the predetermined image before the non-sequential scanning is determined based on the number of scanning lines in the display area by one of a plurality of types of size changing methods. Size changing means that can be enlarged or reduced to a size corresponding to the number of scanning lines using
When the size of the predetermined image is increased or reduced by the size changing unit, a size change method that selects a size change method suitable for expansion or reduction among the plurality of types of size change methods based on the size of the predetermined image. An image display device comprising: a method selection unit. 2. The image display device according to claim 1, wherein the size changing method selecting unit selects the size changing method based on the size of the predetermined image in addition to the size of the predetermined image. A serial number is associated with each of the scanning lines according to the arrangement order thereof,
A predetermined number among the serial numbers associated with the scanning lines is an initial value corresponding to the least significant bit (0th digit) of the bit string constituting the gradation data;
A value obtained by adding the largest numerical value among the numerical values included in the numerical value group to the initial value corresponding to the least significant bit is the most significant bit ((N-1) th digit) of the bit string constituting the gradation data. And the initial value of the scanning line corresponding to
Other bits between the most significant bit and the least significant bit correspond to bits one digit above the number of bits of the other bit in order from the larger number of bits of the other bit. A value obtained by adding the initial value and the numerical value obtained by adding 1 to the bit number of the other bit from the smaller one of the numerical values included in the numerical value group corresponds to the initial value of the other bit. Attached
First, a scanning line having a serial number indicated by the initial value corresponding to the least significant bit is selected, and then the most significant bit and the bit from this bit to the bit immediately before the least significant bit one by one in order. A first process of sequentially selecting scan lines of serial numbers indicated by the initial values corresponding to the shifted bits, respectively;
1 is added to the value associated with each bit of the gradation data, and the value corresponding to each bit of the gradation data after the addition exceeds a value obtained by subtracting 1 from the total number of the scanning lines. A second process of updating the value to the minimum value of the serial number when
And a third unit for selecting a scanning line corresponding to a value associated with each bit of the gradation data after the second process in the same order as the first process. ,
By repeating the second processing and the third processing until all the scanning lines in the display area are selected for each bit of the bit string constituting the gradation data, the scanning lines in the non-sequential scanning are repeated. 3. The image display device according to claim 1, wherein the selection order is determined. 4. The image display device according to claim 1, further comprising a scanning line number detecting unit that detects the number of scanning lines in the display area. 5. A pixel matrix in which pixels including optical elements are arranged in a matrix,
A plurality of scanning lines respectively connected to a pixel group arranged along one of a row direction and a column direction of the pixel matrix;
A plurality of data lines respectively connected to a pixel group arranged along the other of the row direction and the column direction of the pixel matrix,
A scanning line driving circuit for sequentially selecting the plurality of scanning lines one by one;
A data line drive circuit that outputs a control signal related to light emission of the optical element to at least one data line of the plurality of data lines;
A control unit that controls the operation of the scanning line driving circuit and the data line driving circuit,
It is generated based on the number of scanning lines in a display area including a predetermined number of the scanning lines and the data lines, and grayscale data having a bit length N corresponding to the number of light emission gradations indicating the light emission gradation of the optical element. The scan line is formed based on a numerical value group obtained by dividing an addition number obtained by adding 1 to the total number of scan lines in the display area into a numerical value corresponding to a ratio of 2 ⁿ values of several bits of a bit string constituting the gradation data. Each optical element corresponding to each scanning line in the display area selected by the drive circuit is set to a time corresponding to one numerical value selected in a predetermined order from the numerical value group each time the scanning line is selected. The order in which the scanning lines are selected is determined so that only the light can be emitted, and the predetermined image is input to an image display device capable of displaying a predetermined image in gradation in the display area by non-sequential scanning according to the selection order. Change to an image An image processing apparatus for replacing
Scanning line number detecting means for detecting the number of scanning lines in the display area,
Based on the number of scanning lines of the display area detected by the scanning line number detecting means, the size of the predetermined image before the non-sequential scanning, using any one of a plurality of types of size changing method Size changing means that can be enlarged or reduced to a size corresponding to the number of scanning lines;
When the size of the predetermined image is increased or reduced by the size changing unit, a size change method that selects a size change method suitable for expansion or reduction among the plurality of types of size change methods based on the size of the predetermined image. An image processing apparatus comprising: a method selecting unit. The image processing apparatus according to claim 5, wherein the size change method selection unit selects the size change method based on a change in the size of the predetermined image in addition to the size of the predetermined image. A serial number is associated with each of the scanning lines according to the arrangement order thereof,
A predetermined number among the serial numbers associated with the scanning lines is an initial value corresponding to the least significant bit (0th digit) of the bit string constituting the gradation data;
A value obtained by adding the largest numerical value among the numerical values included in the numerical value group to the initial value corresponding to the least significant bit is the most significant bit ((N-1) th digit) of the bit string constituting the gradation data. And the initial value of the scanning line corresponding to
Other bits between the most significant bit and the least significant bit correspond to bits one digit above the number of bits of the other bit in order from the larger number of bits of the other bit. A value obtained by adding the initial value and the numerical value obtained by adding 1 to the bit number of the other bit from the smaller one of the numerical values included in the numerical value group corresponds to the initial value of the other bit. Attached
First, a scanning line having a serial number indicated by the initial value corresponding to the least significant bit is selected, and then the most significant bit and the bit from this bit to the bit immediately before the least significant bit one by one in order. A first process of sequentially selecting scan lines of serial numbers indicated by the initial values corresponding to the shifted bits, respectively;
1 is added to the value associated with each bit of the gradation data, and the value corresponding to each bit of the gradation data after the addition exceeds a value obtained by subtracting 1 from the total number of the scanning lines. A second process of updating the value to the minimum value of the serial number when
And a third unit for selecting a scanning line corresponding to a value associated with each bit of the gradation data after the second process in the same order as the first process. ,
By repeating the second processing and the third processing until all the scanning lines in the display area are selected for each bit of the bit string constituting the gradation data, the scanning lines in the non-sequential scanning are repeated. 7. The image processing apparatus according to claim 5, wherein the selection order is determined. A program for controlling the image display device according to claim 1,
Based on the number of scanning lines in the display area, the size of the predetermined image before the non-sequential scanning is enlarged to a size corresponding to the number of scanning lines by using any one of a plurality of types of size changing methods. Or a resizable resizing step,
Resizing the size of the predetermined image in the resizing step, selecting a suitable resizing method among the plurality of types of resizing methods based on the size of the predetermined image. An image display device control program, comprising: a method selecting step. 9. The image display apparatus control according to claim 8, wherein, in the size changing method selecting step, the size changing method is selected based on the size change of the predetermined image in addition to the size of the predetermined image. program. 10. The computer-readable storage medium according to claim 8, further comprising a scanning line number detecting step of detecting the number of scanning lines in the display area. A program for controlling the image processing apparatus according to claim 5,
A scanning line number detecting step of detecting the number of scanning lines in the display area;
Based on the number of scanning lines of the display area detected in the scanning line number detecting step, the size of the predetermined image before the non-sequential scanning, using any one of a plurality of types of size change method A size changing step that can be enlarged or reduced to a size corresponding to the number of scanning lines;
Resizing the size of the predetermined image in the resizing step, selecting a suitable resizing method among the plurality of types of resizing methods based on the size of the predetermined image. An image processing apparatus control program, comprising: a method selecting step. 12. The image processing apparatus control according to claim 11, wherein in the size changing method selecting step, the size changing method is selected based on the size of the predetermined image in addition to the size of the predetermined image. program.

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