JP2004279595A - Image display system, electro-optical device, image processor, and image processor control program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image display system suitable to reduce cost in an electro-optical device, and also to provide an electro-optical device, an image processor and an image processor control program in this system. <P>SOLUTION: The image processor 10 is composed of an input image data forming part 10a, an input image data dividing part 10b, a frame memory 10c, and an input image data transmitting part 10d. The electro-optical device 11 is composed of a panel 11a, a scanning line driving part 11b, a data line driving part 11c, a controller 11d, an input image data acquiring part 11e, and a line memory 11f. In the image processor 10, pixel data are preliminarily rearranged to form input image data in accordance with the selecting order of scanning lines in nonsequential scanning, the input image data for each scanning line are divided for each data line driving circuit, and further, after sequentially rearranged to the order suitable for serial transmission, the input image data is transmitted to the electro-optical device 11. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an electro-optical device, and more particularly, to a system for displaying an image on the electro-optical device by a non-sequential scanning process suitable for suppressing display unevenness of an image by gradation display.
[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. In this method, the light emission gradation of the optical element is indicated by gradation data of bit length N. Then, the number 2 of bits of the bit string constituting the gradation data is calculated. ⁿ A group of numerical values corresponding to the ratio of the values (n = 0, 1, 2,... (N-1)) is generated, and the scanning lines are non-sequentially selected using the group of numerical values. By thus selecting the scanning lines non-sequentially, the light emission time of the optical element is controlled. That is, gradation display is performed by controlling the issuance time in accordance with the issuance gradation (for example, see Patent Document 1).
[0007]
In addition, as the size of the display increases, the number of data line driving circuits in the electro-optical device increases. The electro-optical device transmits image data to be displayed to the plurality of data line driving circuits by parallel transmission using a bus.
[0008]
[Patent Document 1]
JP-A-2001-166730.
[0009]
[Problems to be solved by the invention]
However, the non-sequential scanning method requires a more complicated process (rearrangement of pixel data and the like) than the normal sequential scanning method. This requires a simple frame memory, a high-speed processor, and dedicated hardware, which causes a problem of increasing the cost of the electro-optical device.
[0010]
Further, as described above, when data is transmitted by a bus to a large number of data line driving circuits, the wiring of the substrate becomes complicated, and the necessity of three-dimensional wiring by a multi-layer substrate arises, thereby increasing the cost.
Therefore, the present invention has been made by focusing on the unresolved problems of the conventional technology, and is an image display system suitable for reducing the cost of the electro-optical device side. An object of the present invention is to provide an electro-optical device, an image processing device, and an image processing device control program.
[0011]
[Means for Solving the Problems]
In order to achieve the above object, an image display system according to the present invention includes an image processing device and an electro-optical device, and is an image display system that displays an input image from the image processing device on the electro-optical device. ,
The electro-optical device,
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 operations of the scanning line driving circuit and the data line driving circuit;
Input image data acquiring means for acquiring input image data transmitted from the image processing apparatus, wherein the plurality of data lines are divided into groups of a predetermined number, and the data line driving circuit comprises: It is provided for each,
A non-sequential scanning that scans in a non-continuous order with respect to the arrangement order of the scanning lines based on the input image data and gradation data having a predetermined bit length corresponding to the number of light emission gradations of the optical element; By controlling the effective time of the optical element, the input image is displayed in a gray scale in a display area including a predetermined number of the scanning lines and the data lines,
The image processing device,
Input image data for generating the input image data by rearranging pixel data constituting image data to be input to the electro-optical device in accordance with a selection order of scanning lines corresponding to the non-sequential scanning in the electro-optical device; Generating means;
Input image data dividing means for dividing the input image data generated by the input image data generating means for each pixel data handled by each of the plurality of data line driving circuits;
Input image data transmitting means for transmitting the input image data divided by the input image data dividing means to the electro-optical device for each of the divided data.
[0012]
With such a configuration, in the electro-optical device in the image display system according to the first aspect, the scanning line driving circuit can sequentially select a plurality of scanning lines one by one. The drive circuit can output a control signal related to light emission of the optical element to at least one of the plurality of data lines, and the control unit can control the scan line drive circuit and the data line drive circuit. The operation can be controlled, and the input image data transmitted from the image processing apparatus can be obtained by the input image data obtaining means. Pixel data constituting image data to be input to the device are arranged in accordance with the selection order of the scanning lines corresponding to the non-sequential scanning in the electro-optical device. The input image data can be generated by obtaining the input image data, and the input image data generated by the input image data generating unit is input to a pixel handled by each of the plurality of data line driving circuits. The input image data divided by the input image data dividing unit can be transmitted to the electro-optical device by the input image data transmitting unit for each of the divided data. It is.
[0013]
Therefore, the image processing apparatus rearranges the pixel data of the image data in the order corresponding to the non-sequential scanning, and rearranges the data in the order of data handled by each data line driving circuit on the electro-optical device side before transmitting the data to the electro-optical device. Therefore, it is not necessary to perform a process of rearranging pixel data on the electro-optical device side, and the hardware configuration on the electro-optical device side such as a reduction in the capacity of the frame memory, a simplification of the control unit, and a simplification of the substrate wiring is eliminated. This can be simplified. Therefore, cost can be reduced.
[0014]
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 a second aspect based on the first aspect, the input image data dividing means divides the input image data for every one scan line, for every data of the number of pixels of the one scan line, Also, by rearranging the pixel data constituting the divided input image data for each scanning line in a predetermined order for each group, one pixel corresponding to each of the plurality of data line driving circuits is rearranged. Is characterized in that a data block composed of pixel data is generated.
[0015]
That is, the input image data dividing means divides the input image data for each scan line, for each data of the number of pixels of the one scan line, and inputs the divided input image data for each scan line. Is arranged in a predetermined order for each group, it is possible to generate a data block composed of pixel data for one scanning line corresponding to each of the plurality of data line driving circuits. is there.
[0016]
Therefore, a data block in which data corresponding to the number of pixels of one scanning line grouped according to the number of data line drive circuits can be rearranged can be generated for each group. Input image data can be transmitted in a line. Further, the input image data dividing means divides the input image data for each data of the number of pixels for each scanning line and transmits the divided image data for each of the divided input image data. Can be reduced, and the cost of the electro-optical device can be reduced.
[0017]
In a third aspect based on the first or second aspect, the input image data transmitting means transmits the input image data divided for each of the plurality of data line driving circuits to the electro-optical device. , And the parallel transmission is performed based on the arrangement order of the pixel data in each data block.
That is, the input image data transmitting unit transmits the input image data divided for each of the plurality of data line driving circuits to the electro-optical device in parallel based on the arrangement order of the pixel data in each of the data blocks. Is possible.
[0018]
Therefore, the pixel data can be transmitted in parallel to the electro-optical device according to the arrangement order of the pixel data for each group, and the electro-optical device can transmit data that is easy to handle.
In a fourth aspect based on any one of the first to third aspects, the control unit stores the input image data acquired by the input image data acquisition means in the data block for each of the data blocks. The serial transmission is performed to each of the plurality of data line driving circuits based on the order.
[0019]
That is, the control unit can perform serial transmission of the input image data acquired by the input image data acquiring unit to the plurality of data line driving circuits. Therefore, it is possible to simplify the board wiring as compared with a case where parallel wiring is performed for each of the bus wiring and the data line driving circuit, and it is not necessary to use a multilayer board, so that the cost for the board and wiring can be reduced. It becomes.
[0020]
In the case of the present invention, for example, a memory for storing input image data and a memory controller are integrated in the control unit, and the gradation display processing of an image by non-sequential scanning is also performed under the control of the control unit. .
In a fifth aspect based on any one of the first to third aspects, the input image data acquiring means converts the acquired input image data for each of the data blocks based on the predetermined order. It is characterized in that serial transmission is performed to each of a plurality of data line driving circuits.
[0021]
That is, the input image data acquisition unit can perform serial transmission of the input image data acquired by the input image data acquisition unit to the plurality of data line driving circuits. Therefore, it is possible to simplify the board wiring as compared with a case where parallel wiring is performed for each of the bus wiring and the data line driving circuit, and it is not necessary to use a multilayer board, so that the cost for the board and wiring can be reduced. It becomes.
[0022]
In the case of the present invention, for example, a memory and a memory controller for storing input image data are included in the data line driving circuit, and the gradation display processing of an image by non-sequential scanning is also performed by each data line driving circuit. Will be
In a sixth aspect based on any one of the first to fifth aspects, the plurality of scanning lines are associated with serial numbers in the order in which the scanning lines are arranged.
The input image data transmitting means, when transmitting the divided input image data to the electro-optical device, transmits serial number data indicating the scanning line corresponding to each of the divided input image data. It is characterized by having.
[0023]
That is, when transmitting the divided input image data to the electro-optical device, the input image data transmitting unit can transmit the number data indicating the scanning line corresponding to each of the divided input image data. It is. Therefore, it is not necessary to perform the process of preparing the scanning line number on the electro-optical device side, and the process can be reduced, the configuration of the control unit can be simplified, and the cost of the electro-optical device can be reduced. .
[0024]
According to a seventh aspect of the present invention, in any one of the first to sixth aspects, an addition number, which is generated based on the grayscale data having a bit length N and is obtained by adding 1 to the number of scanning lines of the display area, The number 2 of bits of the bit string constituting the gradation data ⁿ Each scan in the display area selected by the scan line driving circuit is based on a numerical group divided into numerical values according to the ratio consisting of values (n = 0, 1, 2,..., (N-1)). Each optical element corresponding to a line, the scanning line determined to emit light only for 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 non-sequential scanning is performed according to the selection order.
[0025]
That is, the addition number obtained by adding 1 to the number of scanning lines in the display area is equal to the number of bits 2 ⁿ The light-emitting time of the light-emitting element is controlled based on a numerical group divided into numerical values corresponding to the ratios of the values (n = 0, 1, 2,... (N-1)). It is possible to display an image with less display unevenness on a large display area.
[0026]
In an eighth aspect based on any one of the first to seventh aspects, the input image data generating means comprises:
A bit length N of gradation data indicating a light emission gradation of the optical element;
The number obtained by adding 1 to the total number of the scanning lines is represented by 2 of the number of bits of the bit string constituting the gradation data. ⁿ While obtaining a numerical group divided into numerical values according to the ratio consisting of values (n = 0, 1, 2,..., (N−1)),
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;
A second process for driving the scanning line driving circuit to drive the scanning line of the selected number each time the scanning line is selected;
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 third process of updating the value to the minimum value of the serial number when
And a fourth unit for selecting a scan line corresponding to a value associated with each bit of the gradation data after the third process in the same order as the first process. ,
The second to fourth processes are repeated until all the scanning lines in the display area are selected for each bit of the bit string constituting the gradation data, thereby determining the selection order of the scanning lines. The input image data is generated based on the determined selection order.
[0027]
That is, by determining the order of selecting the scanning lines by the above procedure, it is possible to easily determine the order of selecting the scanning lines in the electro-optical device having an arbitrary number of scanning lines.
An electro-optical device according to a ninth aspect is the electro-optical device according to the first aspect,
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 operations of the scanning line driving circuit and the data line driving circuit;
Input image data acquiring means for acquiring input image data transmitted from the image processing apparatus, wherein the plurality of data lines are divided into groups of a predetermined number, and the data line driving circuit comprises: It is provided for each,
A non-sequential scanning that scans in a non-continuous order with respect to the arrangement order of the scanning lines based on the input image data and gradation data having a predetermined bit length corresponding to the number of light emission gradations of the optical element; By controlling the effective time of the optical element, the input image is displayed in a gray scale in a display area including a predetermined number of the scanning lines and the data lines.
[0028]
Here, the present invention is the electro-optical device according to the first invention, and the operation and effect thereof are duplicated, so that the description is omitted.
In a tenth aspect based on the ninth aspect, the control unit is configured to, based on the predetermined order, the input image data acquired by the input image data acquisition unit for each of the data blocks. It is characterized in that serial transmission is performed to each of the data line driving circuits.
[0029]
Here, the present invention is the electro-optical device according to the fourth invention, and the operation and effect thereof are duplicated, so that the description is omitted.
In an eleventh aspect based on the ninth aspect, the input image data acquiring means converts the acquired input image data into the plurality of data line drive circuits based on the predetermined order for each data block. It is characterized by serial transmission for each.
[0030]
Here, the present invention is the electro-optical device according to the fifth invention, and the operation and effect thereof are duplicated, so that the description is omitted.
According to a twelfth aspect, in any one of the ninth to eleventh aspects, an addition number, which is generated based on the grayscale data having a bit length N and is obtained by adding 1 to the number of scanning lines of the display area, is obtained. The number 2 of bits of the bit string constituting the gradation data ⁿ Each scan in the display area selected by the scan line drive circuit based on a numerical group divided into numerical values according to a ratio consisting of values (n = 0, 1, 2,..., (N-1)) Each optical element corresponding to a line, the scanning line determined to be able to emit light for 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 non-sequential scanning is performed according to the selection order.
[0031]
Here, the present invention is the electro-optical device according to the seventh invention, and the operation and effect thereof are duplicated, so that the description is omitted.
A thirteenth invention is the image processing device according to the first invention,
Input image data for generating the input image data by rearranging pixel data constituting image data to be input to the electro-optical device in accordance with a selection order of scanning lines corresponding to the non-sequential scanning in the electro-optical device; Generating means;
Input image data dividing means for dividing the input image data generated by the input image data generating means for each pixel data handled by each of the plurality of data line driving circuits;
Input image data transmitting means for transmitting the input image data divided by the input image data dividing means to the electro-optical device for each of the divided data.
[0032]
Here, the present invention is the image processing apparatus according to the first invention, and its operation and effect are duplicated, and therefore description thereof is omitted.
In a fourteenth aspect based on the thirteenth aspect, the input image data dividing means divides the input image data for every one scan line, for every data of the number of pixels of the one scan line, In addition, by rearranging the pixel data constituting the divided input image data for each scanning line in a predetermined order for each group, one pixel corresponding to each of the plurality of data line driving circuits is arranged. Is characterized in that a data block composed of pixel data is generated.
[0033]
Here, the present invention is the image processing apparatus according to the second invention, and the operation and effect thereof are duplicated, so that the description is omitted.
In a fifteenth aspect based on the fourteenth aspect, the input image data transmitting means transmits the input image data divided for each of the plurality of data line driving circuits to the electro-optical device. It is characterized in that parallel transmission is performed based on the arrangement order of the pixel data in the data block.
[0034]
Here, the present invention is the image processing apparatus according to the third invention, and its operation and effect are duplicated, so that the description is omitted.
In a sixteenth aspect based on any one of the thirteenth to fifteenth aspects, the plurality of scanning lines are associated with serial numbers in the order in which the scanning lines are arranged.
The input image data transmitting means, when transmitting the divided input image data to the electro-optical device, transmits serial number data indicating the scanning line corresponding to each of the divided input image data. It is characterized by having.
[0035]
Here, the present invention is the image processing apparatus according to the sixth invention, and its operation and effect are duplicated, so that the description is omitted.
In a seventeenth aspect based on any one of the thirteenth to sixteenth aspects, the input image data generating means includes:
A bit length N of gradation data indicating a light emission gradation of the optical element;
The number obtained by adding 1 to the total number of the scanning lines is represented by 2 of the number of bits of the bit string constituting the gradation data. ⁿ While obtaining a numerical group divided into numerical values according to the ratio consisting of the values (n = 0, 1, 2,... (N−1)),
A serial number is associated with each of the scanning lines according to the arrangement order thereof,
A predetermined number among the serial numbers of the scanning line is an initial value of the serial number of the scanning line 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;
A second process for driving the scanning line driving circuit to drive the scanning line of the selected number each time the scanning line is selected;
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 third process of updating the value to the minimum value of the serial number when
And a fourth unit for selecting a scan line corresponding to a value associated with each bit of the gradation data after the third process in the same order as the first process. ,
The second to fourth processes are repeated until all the scanning lines in the display area are selected for each bit of the bit string constituting the gradation data, thereby determining the selection order of the scanning lines. The input image data is generated based on the determined selection order.
[0036]
Here, the present invention is the image processing apparatus according to the eighth invention, and the operation and effect thereof are duplicated, so that the description is omitted.
Further, an electro-optical device control program according to an eighteenth aspect is a computer-executable program for controlling the ninth aspect,
Based on the input image data and gradation data of a predetermined bit length corresponding to the number of light emission gradations of the optical element, non-sequential scanning in which the scanning lines are arranged in a non-continuous order with respect to the arrangement order of the scanning lines. By controlling the effective time, the input image is displayed in a gray scale in a display area including a predetermined number of the scanning lines and the data lines.
[0037]
Here, the present invention is a program for controlling the ninth invention, and the description thereof is omitted because the effects are duplicated.
An image processing apparatus control program according to a nineteenth aspect is a program for controlling the thirteenth aspect,
Input image data for generating the input image data by rearranging pixel data constituting image data to be input to the electro-optical device in accordance with a selection order of scanning lines corresponding to the non-sequential scanning in the electro-optical device; Generating step;
A data dividing step of dividing the input image data generated in the input image data generating step into pixel data handled by each of the plurality of data line driving circuits;
Transmitting the input image data divided in the data dividing step to the electro-optical device for each of the divided data.
[0038]
Here, the present invention is a program for controlling the thirteenth invention, and the description thereof is omitted because the effects are duplicated.
(1) A computer-executable program for controlling a tenth invention,
The input image data obtained by the input image data obtaining means is serially transmitted to each of the plurality of data line driving circuits based on the predetermined order via the control unit for each data block. Electro-optical device control program.
[0039]
(2) A computer-executable program for controlling an eleventh invention,
The input image data obtained by the input image data obtaining means is serially transmitted to each of the plurality of data line driving circuits based on the predetermined order for each of the data blocks. Electro-optical device control program.
[0040]
(3) The number obtained by adding 1 to the number of scanning lines in the display area generated based on the grayscale data having a bit length N is calculated by adding 2 to the number of bits in the bit string constituting the grayscale data. ⁿ Each scanning line in the display area selected by the scanning line driving circuit based on a numerical group divided into numerical values corresponding to a ratio consisting of values (n = 0, 1, 2,... (N-1)) Each of the optical elements corresponding to the scanning line is determined so as to be able to emit light for 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 electro-optical device control program according to any one of the eighteenth aspects of the invention, wherein the non-sequential scanning is performed according to a selection order.
[0041]
(4) In the input image data dividing step, the input image data is divided for each one scan line for each data of the number of pixels of the one scan line, and for each of the divided one scan line. By rearranging the pixel data constituting the input image data in a predetermined order for each group, a data block composed of pixel data for one scanning line corresponding to each of the plurality of data line driving circuits is generated. An image processing apparatus control program according to the nineteenth aspect, characterized in that:
[0042]
(5) In the input image data transmitting step, the input image data divided for each of the plurality of data line driving circuits is transmitted to the electro-optical device based on the arrangement order of the pixel data in each of the data blocks. The image processing apparatus control program according to (4), wherein the image processing apparatus control program is configured to perform parallel transmission.
(6) The plurality of scanning lines are associated with serial numbers according to the arrangement order of the scanning lines,
In the input image data transmitting step, when transmitting the divided input image data to the electro-optical device, transmitting the number data indicating the scanning line corresponding to each of the divided input image data. The image processing apparatus control program according to any one of the nineteenth inventions (4) and (5), wherein
[0043]
(7) The input image data generating step includes:
A bit length N of gradation data indicating a light emission gradation of the optical element;
The number obtained by adding 1 to the total number of the scanning lines is represented by 2 of the number of bits of the bit string constituting the gradation data. ⁿ While obtaining a numerical group divided into numerical values according to the ratio consisting of values (n = 0, 1, 2,..., (N−1)),
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;
A second process for driving the scanning line driving circuit to drive the scanning line of the selected number each time the scanning line is selected;
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 third process of updating the value to the minimum value of the serial number when
A fourth process of selecting a scan line corresponding to a value associated with each bit of the gradation data after the third process in the same order as the first process,
The second to fourth processes are repeated until all the scanning lines in the display area are selected for each bit of the bit string constituting the gradation data, thereby determining the selection order of the scanning lines. The image processing apparatus control program according to any one of the nineteenth inventions (4) to (6), wherein the input image data is generated based on the determined selection order.
[0044]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. 1 to 13 are diagrams showing an embodiment of an image display system according to the present invention.
First, the configuration of the image display system according to the present invention will be described with reference to FIG. FIG. 1 is a block diagram showing the configuration of the first embodiment of the image display system according to the present invention.
[0045]
The image display system 1 according to the first embodiment has a configuration including an image processing device 10 and an electro-optical device 11.
The image processing apparatus 10 includes an input image data generation unit 10a, an input image data division unit 10b, a frame memory 10c, and an input image data transmission unit 10d.
[0046]
The input image data generation unit 10a rearranges pixel data in image data acquired from a device such as a PC (Personal Computer) in accordance with the selection order of scanning lines in image display by non-sequential scanning of the electro-optical device 11. This is a process for generating image data.
The input image data dividing unit 10b converts the input image data generated by the input image data generating unit 10a into first to fourth data line driving circuits 111a to 111c which constitute a data line driving unit 11c to be described later of the electro-optical device 11. The processing for dividing each data handled by each of the 111d is performed.
[0047]
The frame memory 10c is a memory for storing image data for performing processing in each unit. This memory has two storage areas, each of which has a capacity to store one image data.
The input image data transmission unit 10d transmits the divided input image data to the electro-optical device 11 via a 4-bit data bus with a scanning line number corresponding to the data.
[0048]
Here, although not illustrated, the image processing apparatus 10 includes a processor such as a CPU (Central Processing Unit) for executing a control program for controlling the above-described units, and a ROM (Read Only Memory) storing the program. The above-mentioned various processes are performed by reading out and executing the control program from the ROM. The present invention is not limited to this configuration, and may be realized as dedicated hardware.
[0049]
The electro-optical device 11 has a configuration including a panel 11a, a scanning line driving unit 11b, a data line driving unit 11c, a control unit 11d, an input image data obtaining unit 11e, and a line memory 11f. .
The panel 11a is configured such that a pixel circuit including a switching transistor, a driving transistor, an optical element, and a storage capacitor is provided in a matrix at intersections of a plurality of scanning lines and a plurality of data lines. Then, by controlling the light emission time of the optical element according to the bit length of the gradation data described later, the image is displayed in gradation on the panel.
[0050]
The scanning line driving unit 11b drives the scanning lines based on the selection order of the scanning lines in the non-sequential scanning included in the input image data acquired from the image processing apparatus 10 under the control of the control unit 11d described later.
The data line driving unit 11c includes first to fourth data line driving circuits 111a to 111d, and drives data lines under the control of a control unit 11d described later.
[0051]
The control unit 11d causes the scanning line driving unit 11b to select the scanning lines of the image display area on the panel 11a in a specific order by non-sequential scanning according to various control signals, and reads input image data from the line memory 11f, The data is serially transmitted to a plurality of data line driving units 11c to drive a pixel circuit corresponding to the selected scanning line.
[0052]
The input image data acquisition unit 11e acquires an input image data block composed of the divided input image data from the image processing device 10 at a predetermined timing.
Here, the pixel circuit configuring the panel 11a in the present embodiment is supplied from the control unit 11d via the data line in addition to the driving of the scanning line and the data line by the scanning line driving unit 11b and the data line driving unit 11c. The operation is controlled in response to the high signal being written as high or low, and the optical element emits light when the high signal is written as high, regardless of whether the scanning line is driven, When "low" is written, the optical element does not emit light. Also, in the present embodiment, the optical element is an electroluminescent element.
[0053]
The line memory 11f is a memory for storing input image data from the image processing apparatus 10, and has two storage areas for writing data and reading data in parallel.
Further, a mechanism of data transmission from the control unit 11d to the data line driving unit 11c of the image display system 1 according to the first embodiment will be described with reference to FIG. FIG. 2 is a block diagram illustrating a detailed configuration of the data line driving unit 11c, the control unit 11d, and the line memory 11f.
[0054]
As shown in FIG. 2, the data line driving section 11c has a configuration including first to fourth data line driving circuits 111a to 111d. Here, when the data lines on the panel 11a are represented by data lines 0 to 15, the first data line drive circuit 111a drives the data lines 0 to 3, and the second data line drive circuit 111b drives the data lines 4 to 3. 7, the third data line driving circuit 111c drives the data lines 8 to 11, and the fourth data line driving circuit 111d drives the data lines 12 to 15.
[0055]
The control unit 11d has a configuration including a memory control unit 110 that controls the line memory 11f.
Further, the line memory 11f has a configuration including two storage areas of a line memory A 112a and a line memory B 112b.
Then, the control unit 11d reads the input image data block stored in one of the storage areas of the line memory A 112a and the line memory B 112b of the line memory 11f, and reads the read image data block from the first to fourth data line driving circuits. Serial transmission is performed to each of 111a to 111d. Here, in the electro-optical device 11 according to the present embodiment, writing and reading processing of the input image data block are performed in parallel with respect to the two storage areas of the line memory 11f. For example, it is assumed that input image data blocks rearranged according to the non-sequential scanning are written in the line memory A 112a. In the present embodiment, while this data block is being written, the input image data blocks already written in the line memory B 112b are sequentially read out and the first to fourth data line driving circuits 111a for the data are read out. To 111d. Next, a new input image data block is written to the line memory B 112b from which the input image data has been read. Serial transmission to the fourth data line driving circuits 111a to 111d is performed. In this manner, by alternately writing and sequentially reading the input image data block from the line memory A 112a and the line memory B 112b, these processes are performed in parallel, and the gradation display of the image by non-sequential scanning is performed. Do.
[0056]
In addition, the electro-optical device 11 according to the present embodiment converts the signal (bright signal) applied to the data line into binary bit data, and uses the bit data to generate an optical element during one frame period. The light emission time is controlled. That is, the gradation display of the image is performed by controlling the light emission time of the optical element according to the time corresponding to each bit of the bit string constituting the gradation data.
[0057]
Further, a more specific operation of the image display system will be described with reference to FIGS. FIG. 3A is a diagram showing a state where a scanning line is selected when the number of scanning lines in the display area is 14 and gradation data is 4 bits, and FIG. 3B shows each scanning line. FIG. 4 is a diagram showing how the display data is counted in FIG. 4, FIG. 4 is a diagram showing the relationship between the selection order of scanning lines in non-sequential scanning and pixel data, and FIG. FIG. 3 is a diagram showing input image data blocks rearranged in an order suitable for serial transmission according to the number of data line driving circuits of the electro-optical device 11.
[0058]
First, image data such as a moving image is input to the image processing apparatus 10 from a device such as a PC. Then, this image data is stored in the frame memory 10c. Here, the frame memory 10c has two storage areas. Therefore, while image data write processing is being performed on one of the storage areas, image data read processing is performed from the other storage area, so that image data write processing and read processing are performed in parallel. It is possible. When the image data is stored in the frame memory 10c, the image processing apparatus 10 reads out the image data by the input image data generation unit 10a and analyzes the image data. When the size and the number of colors of the image data are found by this analysis, the pixels in the image data are then adjusted according to the number of scanning lines in the display area acquired from the electro-optical device 11 in the order of non-sequential scanning. Input image data is generated by rearranging the data. Here, the relationship between the scanning line numbers and the pixel data in the generated input image data is as shown in FIG.
[0059]
Further, the generated input image data is transmitted to the input image data dividing unit 10b, where the number of data line driving circuits (here, four) obtained from the electro-optical device 11 and the data handled by the data line driving circuit (Here, the four data lines described above), the data for the number of data lines handled by each data line drive circuit in each scanning line is divided into four groups as one group. Further, in order to transmit the pixel data of each group through a 4-bit data bus corresponding to the number of data line driving circuits, the pixel data of each group is rearranged. Further, the rearranged pixel data of each group is divided into data blocks of one scanning line, and a number indicating a scanning line corresponding to each data block is associated. That is, the input image data D0 to D15 (16 bits) corresponding to each scanning line number are divided into one block (4 bits) of D0 to D3 corresponding to the group of data lines 0 to 3 and the group of data lines 4 to 7. One block of D4 to D7 (4 bits), one block of D8 to D11 corresponding to the group of data lines 8 to 11 (4 bits), and one block of D12 to D15 corresponding to the group of data lines 12 to 15 (4 bits) are divided into four blocks. Then, as shown in FIG. 5, the pixel data of each block is rearranged in the order of D0 to D3, D4 to D7, D8 to D11 and D12 to D15, respectively, and the scanning line numbers corresponding to these blocks are arranged. Is associated.
[0060]
Further, when the division processing of the input image data for one image is completed, a processing of transmitting the input image data to the electro-optical device 11 is performed by the input image data transmission unit 10d. Here, in the present embodiment, a 4-bit data bus is used, and first, 4-bit scanning line number data is transmitted in parallel. Next, the data group (4 bits) for each data line drive circuit is transmitted four times, one bit at a time. That is, as shown in FIG. 5, after transmitting the scanning line number, the 4-bit input image data block of (D0, D4, D8, D12) is transmitted in parallel, and thereafter, (D1, D5, D9, D13) , Four bits (D2, D6, D10, D14) and four bits (D3, D7, D11, D15) in this order, the input image data for each scanning line is transmitted in parallel. Here, in the present embodiment, these 4-bit data are referred to as transmission data.
[0061]
On the other hand, in the electro-optical device 11, when the input image data acquisition unit 11e acquires transmission data transmitted in parallel from the image processing device 10 in 4-bit units, the data is transferred to the line memory 11f via the control unit 11d. Is stored in one of the two storage areas (the line memory A 112a and the line memory B 112b). The data of the scanning line numbers associated with these input image data blocks is transmitted from the control unit 11d to the scanning line driving unit 11b. When the input image data for one scanning line (for four blocks) is stored in one of the two storage areas of the line memory, the control unit 11d, the scanning line driving unit 11b, and the data line driving unit 11c cause the non- The process of displaying the image of the input image data on the panel 11a by gradation is started by the sequential scanning.
[0062]
The control unit 11d reads input image data for one scanning line from the line memory 11f, and serially transmits the read image data to each of the data line driving circuits 111a to 111d of the data line driving circuit 11c. Here, as described above, while one of the two storage areas (the line memory A 112a and the line memory B 112b) of the line memory 11f is being read and the display processing is being performed, the other is newly stored. Data is written. Accordingly, when the input image data for one scanning line corresponding to the selected scanning line number is read out and serially transmitted to each of the data line driving circuits 111a to 111d of the data line driving unit 11c in the order shown in FIG. Then, the input image data newly corresponding to the scanning line number 8 is written into the other storage area of the line memory 11f by the control unit 11d. At such a timing, data is written and read in and out of the two storage areas of the line memory 11f in parallel, and the target pixel is adjusted according to the timing of selecting a scanning line by the timing controller of the scanning line driving unit 11b. By driving the circuit, gradation display of an image on the panel 11a by non-sequential scanning is performed. That is, since the input image data is rearranged in the order of the non-sequential scanning and in the order suitable for the serial transmission, the control unit 11d does not need to perform processing such as data rearrangement.
[0063]
Further, the gradation display processing of an image by non-sequential scanning in the electro-optical device 11 will be described in more detail. Here, a case where the number of scanning lines in the display area of the panel 11a is 14, the bit length of gradation data is 4 bits, and the number of pixels in the display area is 224 (14 × 16) will be described as an example. However, in the present embodiment, color data (RGB) is not considered.
[0064]
First, a method of determining the selection order of the scanning lines when the total number of the scanning lines is 14 and the bit length of the gradation data is 4 bits will be specifically described. In the present embodiment, the determination of the selection order of the scanning lines is executed as a program on the image processing apparatus 10 side, and the image processing apparatus 10 sends the total number of the scanning lines and the gradation data from the electro-optical device 11. (Display capability data).
[0065]
When the program obtains the total number of scanning lines and the gradation data (display capability data), first, 15 obtained by adding 1 to the total number of scanning lines 14 is set to the number of bits of the bit string constituting the gradation data of bit length N. 2 ⁿ A numerical group divided according to the ratio of the 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 can be divided into four numerical values of 1, 2, 4, and 8 according to the respective ratios.
[0066]
Next, serial numbers 0 to 13 are associated with each of the total of 14 scanning lines. 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.
[0067]
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.
[0068]
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.
[0069]
That is, as shown in FIG. 3A, in the non-sequential scanning, the scanning line is the 0th scanning line → the 8th scanning line → the 12th scanning line → the 0th scanning line according to each bit of the gradation data. Are selected in this order.
Further, similarly to the serial numbers, if the numbers indicating the scanning lines are S0 to S13, and the pixels (input image data) for each scanning line are D0 to D15 to represent the display area, as shown in FIG. In addition, the number of pixels per scanning line is 16.
[0070]
Therefore, in order to perform the above-described non-sequential scanning, the input image data is rearranged in the image processing apparatus 10 in the order shown in FIG. 5, and is transmitted to the electro-optical device 11 after the division processing. . Here, the pixels D0 to D15 on the n-th (n = 0, 1, 2,..., 13) scanning line Sn are represented as (Sn, D0) to (Sn, D15). Further, since each scanning line is selected for each bit of the gradation data, it is selected four times while one image is displayed in gradation. Here, focusing on the scanning line S0, the scanning line S0 is selected such that the first time is selected at T0, the second time at T3, the third time at T10, and the fourth time at T25. Examining the time interval, it is 3 from T0 to T2, 7 from T3 to T9, 15 from T10 to T24, and 31 from T25 to T55. That is, the light emitting element emits light at a ratio of 3: 7: 15: 31, such that the interval from the first light emission to the second light emission is 3, the third light is 7, the fourth light is 15, the fifth light is 31, and so on. You can see that is being done.
Further, the flow of the image data acquisition processing in the image processing apparatus 10 will be described with reference to FIG. FIG. 6 is a flowchart illustrating an image data acquisition process in the image processing apparatus 10. Here, the two storage areas of the frame memory 10c are referred to as a storage area 1 and a storage area 2, respectively.
[0071]
As shown in FIG. 6, first, the process proceeds to step S600, and it is determined whether or not the image data has been acquired. If it is determined that the image data has been acquired (Yes), the process proceeds to step S602; otherwise (No), Wait until you get it.
When the process proceeds to step S602, it is determined whether or not the flag F1 corresponding to the storage area 1 of the frame memory 10c is in a set state (a state in which 1 is set in a dedicated register), and is determined to be in a set state. If yes (Yes), the process moves to step S604; otherwise (No), the process moves to step S612.
[0072]
Here, in the present embodiment, when F1 is in the set state, the unprocessed image data is stored in the storage area 1 of the frame memory 10c, and F1 is in the clear state (0 is set in the dedicated register). (Set state), the processed image data is stored in the storage area 1 of the frame memory 10c, nothing is stored, or the image data is being written.
[0073]
When the process proceeds to step S604, it is determined whether or not the flag F2 corresponding to the storage area 2 of the frame memory 10c is in a set state (a state in which 1 is set in a dedicated register), and is determined to be in a set state. If so (Yes), the process moves to step S606; otherwise (No), the process moves to step S608.
Here, in the present embodiment, similarly to F1, when F2 is in the set state, unprocessed image data is stored in the storage area 2 of the frame memory 10c, and F2 is in the clear state (dedicated Is set to 0), the processed image data is stored in the storage area 2 of the frame memory 10c, nothing is stored, or image data is being written. It becomes.
[0074]
When the process proceeds to step S606, the writing of data to the frame memory 10c is prohibited, and the process proceeds to step S602.
That is, unprocessed image data is stored in both the storage area 1 and the storage area 2 of the frame memory 10c. In this case, the processing of steps S602 to S606 is repeated until one of them is processed. Will do.
[0075]
On the other hand, when the process proceeds to step S608, the input image data is stored in the storage area 2 corresponding to F2, and the process proceeds to step S610.
In step S610, the flag F2 corresponding to the storage area 2 of the frame memory 10c is set, and the flow shifts to step S600.
In step S602, when F1 is in the clear state and the process proceeds to step S612, the input image data is stored in the storage area 1 corresponding to F1, and the process proceeds to step S614.
[0076]
In step S614, the flag F1 corresponding to the storage area 1 of the frame memory 10c is set, and the flow shifts to step S600.
That is, when image data is input, it is determined whether or not a flag is set in the storage area of the frame memory 10c, and the image data is stored in the storage area where the flag is not set. Thus, even if the flag of one storage area is set by the processing of generating input image data or the like, the image data can be stored unless the flag of the other storage area is set.
[0077]
Further, a flow of a process of generating transmission data and a process of transmitting transmission data in the image processing apparatus 10 will be described with reference to FIG. FIG. 7 is a flowchart illustrating a process of generating transmission data and a process of transmitting transmission data in the image processing apparatus 10.
As shown in FIG. 7, first, the process proceeds to step S700, where the number of scanning lines and gradation information of the display area is acquired from the electro-optical device 11 via the input image data transmission unit 10d, and the process proceeds to step S702. Here, the number of scanning lines and the gradation information are acquired on the assumption that the electro-optical device 11 changes the display area and the number of gradations. Only the information may be obtained, or the information may be input in advance.
[0078]
In step S702, the input image data generation unit 10a analyzes the acquired image data, and proceeds to step S704. Here, in the analysis of the image, the size (the number of pixels) and the number of colors of the image are analyzed.
In step S704, the input image data generation unit 10a determines whether or not the flag F1 corresponding to the storage area 1 of the frame memory 10c is set, and if it is determined that the flag F1 is set ( (Yes) moves on to step S706, otherwise (No) moves on to step S720.
[0079]
If the process proceeds to step S706, the image data block is read from the storage area of the frame memory 10c corresponding to the set flag in accordance with the non-sequential scanning image data selection rule and the order, and the process proceeds to step S708.
In step S708, the input image data generating unit 10a rearranges the pixel data in the image data based on the number of scanning lines and gradation information of the electro-optical device 11, generates input image data, and generates the generated input image data. Is transmitted to the input image data dividing unit 10b, and the flow shifts to step S710.
[0080]
In step S710, the information of the data line driving unit 11c is acquired from the electro-optical device 11, and based on the information of the data line driving unit 11c, as described above, the input image data is reduced by 1 according to the number of data line driving circuits. Data for transmission is generated by dividing the data into data blocks for each scanning line and rearranging the pixel data of each data block corresponding to each data line drive circuit in accordance with parallel transmission by a 4-bit data bus. Then, control is passed to step S712.
[0081]
In step S712, the input image data transmission unit 10c adds a scanning line number to the generated transmission data, and proceeds to step S714.
In step S714, the transmission data to which the scanning line number is added is transmitted to the electro-optical device 11 in the order rearranged in step S710, and the process proceeds to step S716.
[0082]
In step S716, it is determined whether the transmission of the image data for one image has been completed. If it is determined that the transmission has been completed (Yes), the process proceeds to step S718; otherwise (No), the process proceeds to step S706. I do.
When the process proceeds to step S718, the flag of the storage area corresponding to the image data subjected to the transmission processing is cleared, and the process proceeds to step S700.
[0083]
In step S704, when the flag F1 is not set and the process proceeds to step S720, the input image data generation unit 10a determines whether the flag F2 is set, and determines whether the flag F2 is set. Is determined (Yes), the process proceeds to step S706; otherwise (No), the process proceeds to step S704.
[0084]
That is, by performing the processing of steps S700 to S720, the image data selection rule and the scanning line selection order in the non-sequential scanning from the storage area in which the flag corresponding to the storage area of the frame memory 10c is set are set. The image data block is read, and the read image data block is further processed based on the information of the data line driving unit 11c to generate transmission data, and a scanning line number corresponding to the transmission data is added thereto. The input image data can be transmitted to the image display device 11 for each data to which the scanning line number is added.
[0085]
Then, when the transmission processing of the input image data corresponding to the selected storage area is completed, the flag of this storage area is reset. Therefore, in the processing of steps S600 to S614, the image data is written to this storage area. Becomes possible.
That is, since the flag is set during the generation or transmission of the transmission data, the image data cannot be written to the storage area in the above-described processing of steps S600 to S614. However, while generation or transmission of transmission data is being performed in one storage area, image data writing processing can be performed on the other storage area whose flag is reset. .
[0086]
Therefore, the image data writing process and the image data reading process (transmission process) for the storage area 1 and the storage area 2 of the frame memory 10c are performed for each area when image data is continuously transmitted. , Alternately and in parallel.
Further, a flow of a process of writing input image data to the line memory 11f in the electro-optical device 11 will be described with reference to FIG. FIG. 8 is a flowchart illustrating a process of writing input image data to the line memory 11f in the electro-optical device 11.
[0087]
As shown in FIG. 8, first, the process proceeds to step S800, in which the control unit 11d determines whether or not the above-described transmission data for every 4 bits has been input from the image processing apparatus 10, and when it is determined that the data has been input. (Yes) moves on to step S802, otherwise (No) stands by until input.
When the process proceeds to step S802, the control unit 11d determines whether or not the flag FA corresponding to the line memory A 112a is set (a state in which the dedicated register is set to 1). If it is determined that the state is the state (Yes), the process proceeds to step S804; otherwise (No), the process proceeds to step S814.
[0088]
Here, in the present embodiment, when the FA is in the set state, the unprocessed image data is stored in the line memory A 112a of the line memory 11f, and the FA is in the clear state (0 is set in the dedicated register). In the state (set state), the line memory A112a of the line memory 11f is in a state where processed image data is stored, in a state where nothing is stored, or in a state where image data is being written.
[0089]
When the process proceeds to step S804, the control unit 11d determines whether or not the flag FB corresponding to the line memory B 112b is set (a state in which the dedicated register is set to 1). If it is determined that it is in the state (Yes), the process proceeds to step S806; otherwise (No), the process proceeds to step S808.
[0090]
Here, in the present embodiment, similarly to the FA, when the FB is in the set state, the unprocessed input image data block is stored in the line memory B 112b of the line memory 11f, and the FB is in the clear state. In the state (a state where 0 is set in the dedicated register), the line memory B 112b of the line memory 11f is in a state in which processed image data is stored, in a state where nothing is stored, or Data is being written.
[0091]
If the process proceeds to step S806, the control unit 11d prohibits the writing of data to the line memory 11f, and proceeds to step S802.
On the other hand, when the process proceeds to step S808, the control unit 11d writes the acquired transmission data in units of 4 bits into the line memory B 112b corresponding to the flag FB, and proceeds to step S810.
[0092]
In step S810, the control unit 11d determines whether or not transmission data for one scanning line has been written. If it is determined that the data has been written (Yes), the process proceeds to step 812; otherwise (No). Shifts to step S808.
If the process has proceeded to step S812, the flag FB is set and the process proceeds to step S800.
[0093]
When the flag FA is not in the set state in step S802 but shifts to step S814, the control unit 11d writes the acquired transmission data for each 4 bits into the line memory A 112a corresponding to the flag FA and shifts to step S816. .
In step S816, the control unit 11d determines whether transmission data for one scanning line has been written. If it is determined that the data has been written (Yes), the process proceeds to step S818; otherwise (No). Shifts to step S814.
[0094]
When the process proceeds to step S818, the flag FA is set, and the process proceeds to step S800.
That is, by the processing of the above steps S800 to S818, it is determined whether or not the flag FA or the flag FB is set, and data is not written into the line memory where the flag is set, and Write to memory.
[0095]
Further, a flow of an image display process by non-sequential scanning in the electro-optical device 11 will be described with reference to FIG. FIG. 9 is a flowchart illustrating a process of displaying an image by non-sequential scanning in the electro-optical device 11.
As shown in FIG. 9, first, the process proceeds to step S900, where the control unit 11d determines whether or not the flag FA corresponding to the line memory A112a is set, and determines that the flag FA is set. If yes (Yes), the process moves to step S902; otherwise (No), the process moves to step S910.
[0096]
When the process proceeds to step S902, the control unit 11d reads the input image data for one scanning line written in the line memory A112a in the line memory 11f, and proceeds to step S904.
In step S904, the data read in step S902 is serially transmitted to each of the data line driving circuits 111a to 111d of the data line driving unit 11c, and the process proceeds to step S906.
[0097]
In step S906, the control unit 11d confirms that the transmission of the input image data has been completed, clears the flag FA corresponding to the line memory A112a, and proceeds to step S908.
In step S908, the control unit 11d controls the scanning line driving unit 11b and the data line driving unit 11c based on the read input image data for one scanning line, and performs the gradation display processing of the image by the non-sequential scanning. Move to step S900.
[0098]
On the other hand, when the process proceeds to step S910, it is determined whether or not the flag FB corresponding to the line memory B 112b is set. When it is determined that the flag FB is set (Yes), the process proceeds to step S912; In the case (No), the process moves to step S900.
When the process proceeds to step S912, the control unit 11d reads the input image data for one scanning line written in the line memory B 112b in the line memory 11f, and proceeds to step S914.
[0099]
In step S914, the data read in step S912 is serially transmitted to each of the data line driving circuits 111a to 111d of the data line driving unit 11c, and the flow shifts to step S916.
In step S916, the control unit 11d confirms that the transmission of the input image data has been completed, clears the flag FB corresponding to the line memory B 112b, and proceeds to step S908.
[0100]
In other words, by repeating the processing of steps S900 to S916, one scan is performed from the storage area in which either the flag FA or FB corresponding to the line memory A 112a or the line memory B 112b, which is the storage area of the line memory 11f, is in the set state. Reads the input image data of the line segment, drives the scanning line driving unit 11b based on the scanning line number included in the read input image data, and further drives the data line driving unit 11c to correspond to the selected scanning line. Driving the pixel circuit to perform the gradation display of the image.
[0101]
Then, when the processing of reading the input image data for one scanning line from the selected storage area is completed, the flag of this storage area is reset, so that in the above-described processing of steps S800 to S818, It becomes possible to write input image data transmitted as transmission data for every 4 bits.
In other words, while data is being read from the line memory, the flag is in the set state. In the above-described processing of steps S800 to S818, the writing processing of the input image data block is performed on the storage area. I can't. However, while data read processing is being performed on one storage area, data write processing can be performed on the other storage area where the read processing has been completed and the flag has been reset. It is.
[0102]
Accordingly, the input image data writing process and the input image data reading process for the line memory A 112a and the line memory B 112b of the line memory 11f are performed alternately for each area with respect to the continuously transmitted input image data. It will be done in parallel.
Further, a second embodiment according to the present invention will be described with reference to FIGS. FIG. 10 is a block diagram illustrating a configuration of the image display system 2 according to the second embodiment, and FIG. 11 is a block diagram illustrating a detailed configuration of the data line driving unit 11c ′.
[0103]
The image display system 2 according to the second embodiment has a configuration including an image processing device 10 and an electro-optical device 11.
The image processing apparatus 10 includes an input image data generation unit 10a, an input image data division unit 10b, a frame memory 10c, and an input image data transmission unit 10d.
[0104]
The input image data generation unit 10a rearranges pixel data in image data acquired from a device such as a PC (Personal Computer) in accordance with the selection order of scanning lines in image display by non-sequential scanning of the electro-optical device 11. This is a process for generating image data.
The input image data dividing unit 10b converts the input image data generated by the input image data generating unit 10a into first to fourth data line driving circuits 111a to 111c which constitute a data line driving unit 11c to be described later of the electro-optical device 11. The processing for dividing each data handled by each of the 111d is performed.
[0105]
The frame memory 10c is a memory for storing image data for performing processing in each unit. This memory has two storage areas, each of which has a capacity to store one image data.
The input image data transmission unit 10d assigns a scanning line number corresponding to the divided input image data to the divided input image data and transmits the input image data to the electro-optical device 11 via a 4-bit bus.
[0106]
Here, although not illustrated, the image processing apparatus 10 includes a processor such as a CPU (Central Processing Unit) for executing a control program for controlling the above-described units, and a ROM (Read Only Memory) storing the program. The above-mentioned various processes are performed by reading out and executing the control program from the ROM. The present invention is not limited to this configuration, and may be realized as dedicated hardware.
[0107]
The electro-optical device 11 includes a panel 11a, a scanning line driving unit 11b ', a data line driving unit 11c', and an input image data obtaining unit 11e.
The panel 11a is configured such that a pixel circuit including a switching transistor, a driving transistor, an optical element, and a storage capacitor is provided in a matrix at intersections of a plurality of scanning lines and a plurality of data lines. Then, by controlling the light emission time of the optical element according to the bit length of the gradation data described later, the image is displayed in gradation on the panel.
[0108]
The scanning line driving section 11b 'drives the scanning lines based on the selection order of the scanning lines in the non-sequential scanning included in the input image data acquired from the image processing apparatus 10. Here, in the present embodiment, the scanning line driving unit 11b includes a timing controller that controls the timing of selecting a scanning line based on the scanning line number data included in the divided input image data.
[0109]
The data line driving unit 11c 'includes first to fourth data line driving circuits 111a' to 111d '. Each of the data line driving circuits 111a' to 111d 'includes a driver for driving a data line. , A line memory for storing input image data, and a memory controller for controlling the line memory.
The input image data obtaining unit 11e obtains input image data including the divided input image data from the image processing apparatus 10 at predetermined timings, and sends this data to each of the data line driving circuits 111a 'to 111d'. It is for serial transmission.
[0110]
Further, a detailed configuration of the data line driving unit 11c 'will be described with reference to FIG.
The data line driving unit 11c 'includes a first control unit 110a to a fourth control unit 110d including a line memory and a memory control unit, and a first data line driving circuit 111a' to a fourth data line driving circuit 111d '. And is included. Here, the line memory includes two storage areas A and B each having a capacity capable of storing 4-bit data. When data lines on the panel 11a are represented by data lines 0 to 15, the first data line driving circuit 111a 'drives the data lines 0 to 3, and the second data line driving circuit 111b' 4 to 7, the third data line driving circuit 111 c ′ drives the data lines 8 to 11, and the fourth data line driving circuit 111 d ′ drives the data lines 12 to 15. I have.
[0111]
Also, as shown in FIG. 11, the first to fourth control units 110a to 110d and the first to fourth data line driving circuits 111a 'to 111d' correspond one-to-one.
Accordingly, the first to fourth control units 110a to 110d receive the input data divided for the first to fourth data line driving circuits 111a 'to 111d' serially transmitted from the input image data obtaining unit 11e. The image data is transmitted to the corresponding data line driver.
[0112]
Here, the first to fourth control units 110a to 110d first write the input image data transmitted from the image processing device 10 to one of two storage areas of the line memory. Next, the written input image data is read and transmitted in parallel to each data line drive circuit. During the process of reading and transmitting the input image data, a process of writing new input image data to the other storage area is performed. Thereafter, a process of reading data from one of the storage areas and transmitting the data to the corresponding data line driving circuit, and a process in which new input image data from the input image data acquisition unit 11e is transferred to the other while the process is being performed. The writing process is performed in parallel.
[0113]
Note that, in the present embodiment, in the first embodiment, input image data is read from the line memory 11f, and this data is transferred to each of the data line driving circuits 111a to 111d of the data line driving unit 11c via the control unit 11d. The first to fourth control units 110a to 110d of the data line driving unit 11c 'each include a line memory and a memory controller for controlling the memory, and the scanning line driving unit 11b 'also includes a timing controller for driving the scanning lines. That is, the function of the control unit 11d in the first embodiment is incorporated in the scanning line driving unit 11b 'and the data line driving unit 11c', respectively. Therefore, except that the input image data is serially transmitted from the input image data obtaining unit 11e to the data line driving unit 11c ', the second embodiment operates in the same manner as the first embodiment. Detailed description is omitted.
[0114]
Further, a comparison between the conventional transmission method of image data in the electro-optical device and the transmission method of the present invention will be made based on FIGS. FIG. 12 is a diagram illustrating an example of a conventional transmission method, and FIG. 13 is a diagram illustrating an example of a transmission method of the present invention. Here, in FIGS. 12 and 13, a display area of 320 × 240 pixels is assumed, and color data (RGB) is considered. Therefore, 320 × 3 (RGB) data is required for each scanning line.
[0115]
As shown in FIG. 12A, in the conventional method, the data line drive unit and its control unit are configured by one IC, and a plurality of ICs are provided for the panel. . Then, the electro-optical device receives input image data from the image processing device via a 32-bit data bus by an external I / F controller. Further, the electro-optical device is configured to transmit the acquired input image data to each IC via a data bus of the number of data handled by each IC. That is, when the number of ICs is 15, as shown in FIG. 12B, 32 bits of input image data is simultaneously transmitted to each IC via the 32-bit data bus, and one image worth of image data is transmitted. In order to transmit data (D0 to D959), 30 accesses of 1st (D0 to D31) to 30th (D928 to D959) are required as shown in the figure. Further, since it is necessary to form the wiring pattern of the substrate so that the 32-bit data bus is connected to each of the 15 ICs, the wiring pattern of the substrate becomes extremely complicated. Here, the wiring by the bus is, for example, as shown in FIG. 12C in the case of a 4-bit data bus.
[0116]
On the other hand, in the method shown in FIG. 13, the data line drive section and its control section are constituted by one IC as in the conventional example, and a plurality of ICs are provided for the panel. . Then, the electro-optical device receives input image data from the image processing device via a 15-bit data bus by an external I / F controller. Further, on the electro-optical device side, the acquired input image data is serially transmitted to each IC. In this case, 64 accesses are required to transmit the data (D0 to D959) for one image. At the time of serial transmission, the image processing apparatus divides input image data for each scanning line into data handled for each IC and performs serial transmission, as shown in FIG. Rearrange them in a suitable order. For example, if the serial data for each of IC0 to IC14 is SD0 to SD14, SD0 is "D0 to D63", SD1 is "D64 to D127", SD2 is "D128 to D191" ... SD14 is "D896 to D959". Become. As shown in FIG. 13B, the first data is “D0, D64, D128, D192... D768, D832, D896”, and the second data is “D1, D65, D129, D193,. .. 64th data are rearranged in an order suitable for serial transmission such as “D63, D127, D191, D255... D831, D895, D959”. By serially transmitting the input image data in this manner, it becomes possible to simplify the wiring pattern of the board as compared with the above-described transmission by the bus.
[0117]
As described above, on the image processing apparatus 10 side, the image data is rearranged in advance according to the selection order of the scanning lines in the non-sequential scanning, and the input image data for each scanning line is divided into data handled for each IC, Furthermore, by rearranging the divided data in an order suitable for serial transmission and transmitting the data to the electro-optical device 11, the electro-optical device 11 does not need to perform image data extraction processing in accordance with non-sequential scanning. In addition, the input image data can be easily transmitted serially to the data line driving unit.
[0118]
Further, since the input image data is transmitted to the electro-optical device for each input image data for each scanning line, and the scanning line number is associated with each transmission data, the memory capacity of the electro-optical device 11 is reduced. It is possible to reduce the number of scanning lines to be selected, and it becomes unnecessary to determine the scanning line number to be selected.
Here, the input image data generation unit 10a shown in FIGS. 1 and 10 corresponds to the input image data generation unit described in the first, eighth, thirteenth, and seventeenth inventions, and the input image data division unit 10b Corresponds to the input image data dividing means described in the first, second, thirteenth, and fourteenth inventions, and the input image data transmission unit 10d includes the first, third, sixth, thirteenth, fifteenth, and fifteenth According to the input image data transmitting means described in the sixteenth aspect, the scanning line driving section 11b corresponds to the scanning line driving circuit according to the first, seventh, eighth, ninth, and twelfth aspects, The data line driving unit 11c corresponds to the data line driving circuit according to the first to fifth, ninth to eleventh, thirteenth to fifteenth, and nineteenth aspects, and the input image data obtaining unit 11e includes , Fourth, fifth, ninth, tenth, and eleventh inventions. The memory controller in the data line driver 11c 'and the timing controller in the scanning line driver 11b' described in the text shown in FIG. 11 are described in the first, fourth, ninth, and tenth aspects of the present invention. Corresponding to the control unit.
[0119]
In the above embodiment, the configuration in which image data to be displayed on the electro-optical device 11 is transmitted from an external device such as a PC has been described. However, the present invention is not limited to this, and the image processing device is built in the PC as a graphics board. Other configurations may be used, such as a configuration in which the functions of the image processing apparatus are implemented as software (device driver) operating on a PC.
[0120]
Further, the method of determining the selection order of the scanning lines in the non-sequential scanning described in the above embodiment is not limited to the above method, and another method may be used.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an image display system according to the present invention.
FIG. 2 is a block diagram illustrating a detailed configuration of a data line driving unit 11c, a control unit 11d, and a line memory 11f.
FIG. 3A is a diagram illustrating a manner in which a scanning line is selected when the number of scanning lines in a display area is 14 and gradation data is 4 bits, and FIG. 3B is a diagram illustrating each scanning line. FIG. 7 is a diagram showing how to count display data in FIG.
FIG. 4 is a diagram showing the relationship between the selection order of scanning lines in non-sequential scanning and pixel data.
FIG. 5 is a diagram showing input image data blocks in which input image data is rearranged in an order suitable for serial transmission according to the number of data line driving circuits of the electro-optical device 11 for each scanning line. .
FIG. 6 is a flowchart showing transmission data generation processing and transmission data transmission processing in the image processing apparatus 10;
FIG. 7 is a flowchart illustrating a process of writing input image data to a line memory 11f in the electro-optical device 11.
FIG. 8 is a flowchart illustrating a process of writing input image data to a line memory 11f in the electro-optical device 11.
FIG. 9 is a flowchart showing a process of displaying an image by non-sequential scanning in the electro-optical device 11.
FIG. 10 is a block diagram illustrating a configuration of an image display system 2 according to a second embodiment.
FIG. 11 is a block diagram illustrating a detailed configuration of a data line driving unit 11c ′.
FIG. 12 is a diagram illustrating an example of a conventional transmission method.
FIG. 13 is a block diagram illustrating a detailed configuration of a data line driving unit 11c and a control unit 11d.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Image display system, 10 ... Image processing apparatus, 10a ... Input image data generation part, 10b ... Input image data division part, 10c ... Frame memory, 10d ... Input image data transmission part, 11 ... Electro-optical device, 11a ... Panel .., 11b, 11b ′... Scanning line drive unit, 11c, 11c ′... Data line drive unit, 11d... Control unit, 11e... Input image data acquisition unit, 11f. , 111a to 111d... First to fourth data line drive circuits, 111a ′ to 111d ′... First to fourth data line drive circuits, 112a... Line memory A, 112b.

Claims (19)

An image display system that includes an image processing device and an electro-optical device, and displays an input image from the image processing device on the electro-optical device,
The electro-optical device,
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 operations of the scanning line driving circuit and the data line driving circuit;
Input image data acquiring means for acquiring input image data transmitted from the image processing apparatus, wherein the plurality of data lines are divided into groups of a predetermined number, and the data line driving circuit comprises: It is provided for each,
A non-sequential scanning that scans in a non-continuous order with respect to the arrangement order of the scanning lines based on the input image data and gradation data having a predetermined bit length corresponding to the number of light emission gradations of the optical element; By controlling the effective time of the optical element, the input image is displayed in a gray scale in a display area including a predetermined number of the scanning lines and the data lines,
The image processing device,
Input image data for generating the input image data by rearranging pixel data constituting image data to be input to the electro-optical device in accordance with a selection order of scanning lines corresponding to the non-sequential scanning in the electro-optical device; Generating means;
Input image data dividing means for dividing the input image data generated by the input image data generating means for each pixel data handled by each of the plurality of data line driving circuits;
An image display system, comprising: input image data transmission means for transmitting the input image data divided by the input image data division means to the electro-optical device for each of the divided data. The input image data dividing means divides the input image data for each scan line, for each data of the number of pixels of the one scan line, and inputs the divided input image data for each scan line. Is rearranged in a predetermined order for each group, thereby generating a data block including pixel data for one scanning line corresponding to each of the plurality of data line driving circuits. The image display system according to claim 1, wherein The input image data transmission unit may transmit the input image data divided for each of the plurality of data line driving circuits to the electro-optical device in parallel based on the arrangement order of the pixel data in each of the data blocks. The image display system according to claim 2, wherein: The control unit serially transmits the input image data acquired by the input image data acquiring unit to each of the plurality of data line driving circuits based on the predetermined order for each data block. The image display system according to any one of claims 1 to 3, wherein: The input image data acquiring unit is configured to serially transmit the acquired input image data to each of the plurality of data line driving circuits based on the predetermined order for each data block. The image display system according to claim 1, wherein: The plurality of scanning lines are associated with serial numbers according to the arrangement order of the scanning lines,
The input image data transmitting means, when transmitting the divided input image data to the electro-optical device, transmits serial number data indicating the scanning line corresponding to each of the divided input image data. The image display system according to any one of claims 1 to 5, wherein: An addition number, which is generated based on the grayscale data having a bit length N and is obtained by adding 1 to the number of scanning lines in the display area, is calculated as ²ⁿ values (n = 0, Each optical line 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 of (1, 2,..., (N-1)). Each time the element is selected, the scanning line is selected according to a numerical value selected from the numerical value group in a predetermined order. The image display system according to claim 1, wherein non-sequential scanning is performed. The input image data generating means includes:
A bit length N of gradation data indicating a light emission gradation of the optical element;
An addition number obtained by adding 1 to the total number of the scanning lines is obtained from 2 ⁿ values (n = 0, 1, 2,..., (N−1)) of the number of bits of the bit string constituting the gradation data. While obtaining a numerical group divided into numerical values according to the ratio
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;
A second process for driving the scanning line driving circuit to drive the scanning line of the selected number each time the scanning line is selected;
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 third process of updating the value to the minimum value of the serial number when
And a fourth unit for selecting a scan line corresponding to a value associated with each bit of the gradation data after the third process in the same order as the first process. ,
The second to fourth processes are repeated until all the scanning lines in the display area are selected for each bit of the bit string constituting the gradation data, thereby determining the selection order of the scanning lines. The image display system according to any one of claims 1 to 7, wherein the input image data is generated based on the determined selection order. The electro-optical device in the image display system according to claim 1,
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 operations of the scanning line driving circuit and the data line driving circuit;
Input image data acquiring means for acquiring input image data transmitted from the image processing apparatus, wherein the plurality of data lines are divided into groups of a predetermined number, and the data line driving circuit comprises: It is provided for each,
A non-sequential scanning that scans in a non-continuous order with respect to the arrangement order of the scanning lines based on the input image data and gradation data having a predetermined bit length corresponding to the number of light emission gradations of the optical element; An electro-optical device, wherein the input image is displayed in a gray scale in a display area including a predetermined number of the scanning lines and the data lines by controlling the effective time of the optical element. The control unit serially transmits the input image data acquired by the input image data acquiring unit to each of the plurality of data line driving circuits based on the predetermined order for each data block. The electro-optical device according to claim 9, wherein: The input image data acquiring unit is configured to serially transmit the acquired input image data to each of the plurality of data line driving circuits based on the predetermined order for each data block. The electro-optical device according to claim 9. An addition number, which is generated based on the grayscale data having a bit length N and is obtained by adding 1 to the number of scanning lines in the display area, is calculated as ²ⁿ values (n = 0, Each optical line 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 of (1, 2,..., (N-1)). Each time the element is selected, the scanning line is selected according to a numerical value selected from the numerical value group in a predetermined order. The electro-optical device according to claim 9, wherein non-sequential scanning is performed. The image processing device in the image display system according to claim 1,
Input image data for generating the input image data by rearranging pixel data constituting image data to be input to the electro-optical device in accordance with a selection order of scanning lines corresponding to the non-sequential scanning in the electro-optical device; Generating means;
Input image data dividing means for dividing the input image data generated by the input image data generating means for each pixel data handled by each of the plurality of data line driving circuits;
An image processing apparatus comprising: an input image data transmitting unit that transmits the input image data divided by the input image data dividing unit to the electro-optical device for each of the divided data. The input image data dividing means divides the input image data for each scan line, for each data of the number of pixels of the one scan line, and inputs the divided input image data for each scan line. Is rearranged in a predetermined order for each group, thereby generating a data block including pixel data for one scanning line corresponding to each of the plurality of data line driving circuits. The image processing apparatus according to claim 13, wherein: The input image data transmission unit may transmit the input image data divided for each of the plurality of data line driving circuits to the electro-optical device in parallel based on the arrangement order of the pixel data in each of the data blocks. The image processing apparatus according to claim 14, wherein: The plurality of scanning lines are associated with serial numbers according to the arrangement order of the scanning lines,
The input image data transmitting means transmits serial number data indicating the scanning line corresponding to each of the divided input image data when transmitting the divided input image data to the electro-optical device. The image processing apparatus according to any one of claims 13 to 15, wherein: The input image data generating means includes:
A bit length N of gradation data indicating a light emission gradation of the optical element;
An addition number obtained by adding 1 to the total number of the scanning lines is obtained from 2 ⁿ values (n = 0, 1, 2,..., (N−1)) of the number of bits of the bit string constituting the gradation data. While obtaining a numerical group divided into numerical values according to the ratio
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;
A second process for driving the scanning line driving circuit to drive the scanning line of the selected number each time the scanning line is selected;
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 third process of updating the value to the minimum value of the serial number when
And a fourth unit for selecting a scan line corresponding to a value associated with each bit of the gradation data after the third process in the same order as the first process. ,
The second to fourth processes are repeated until all the scanning lines in the display area are selected for each bit of the bit string constituting the gradation data, thereby determining the selection order of the scanning lines. 17. The image processing apparatus according to claim 13, wherein the input image data is generated based on the determined selection order. A computer-executable program for controlling the electro-optical device according to claim 9,
Based on the input image data and gradation data of a predetermined bit length corresponding to the number of light emission gradations of the optical element, non-sequential scanning in which the scanning lines are arranged in a discontinuous order with respect to the arrangement order of the scanning lines. An electro-optical device control program, wherein the input image is displayed in a gray scale in a display area including a predetermined number of the scanning lines and the data lines by controlling an effective time. A program for controlling the image processing apparatus according to claim 13,
Input image data for generating the input image data by rearranging pixel data constituting image data to be input to the electro-optical device in accordance with a selection order of scanning lines corresponding to the non-sequential scanning in the electro-optical device; Generating step;
A data dividing step of dividing the input image data generated in the input image data generating step into pixel data handled by each of the plurality of data line driving circuits;
An input image data transmission step of transmitting the input image data divided in the data division step to the electro-optical device for each of the divided data.

Images