JP2008262018A - Drive circuit of image display device and image display method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image display device achieving electric power saving by decreasing the light emission quantity of a backlight, in which further electric power saving is made possible by reducing the light emission quantity of the backlight when pixels with relatively low luminance are present in a large number and the luminance degrades. <P>SOLUTION: A drive circuit of an image display device displaying an image by irradiating a display screen with light from a backlight is provided, which has a backlight control section 104 including: a histogram counting section 201 counting display data 208 to obtain a histogram and determining a value at a specified position of the histogram as a selected data value 211; a display data extension section 202 extending the display data 208 based on the selected data value 211; and a backlight voltage regulation section 104 regulating the emission voltage of the backlight based on the selected data value 211. The histogram counting section 201 counts to obtain a weighted histogram by using a weighted value according to the value of the display data 208. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a drive circuit and an image display method for an image display device, and more particularly to a drive circuit and an image display for an image display device that displays an image by irradiating a backlight on a display screen such as a liquid crystal display or a projector. The present invention relates to a technique effective when applied to a method.

  In recent years, liquid crystal displays are mounted on battery-operated information devices and mobile phones. Most of these liquid crystal displays are transmissive and transflective types that require a backlight, but at present, much of the power consumption of the liquid crystal display is now occupied by the backlight, reducing this power consumption. The device to do is needed. In particular, in mobile phones, it is possible to view moving images on a television or the like, and it is necessary to drive the battery for a long time while displaying the display.

  As a device for reducing the power consumption of the backlight, there is a method presented in JP-A-11-65531 (Patent Document 1). For example, if the backlight emits 100% and 80% is transmitted through the front liquid crystal cell, 80% of the light is visible. In this case, the light amount is reduced by 20% in the liquid crystal cell even though the backlight emits 100%.

  On the other hand, when the backlight is made to emit 80% and the liquid crystal cell is made 100% transmissive, what can be seen is 80% of the light, but the emission of the backlight can be suppressed to 80%. The backlight control method presented in Patent Document 1 uses these differences to reduce power consumption by suppressing the light emission amount of the backlight.

  In a histogram of display data of a certain image, when a pixel with 80% luminance has the maximum luminance, the backlight is reduced to 80% light emission, which is 4/5 times, to display this image. By expanding the display data values of all the pixels of the display image by 5/4 times, the same image can be displayed with the backlight emission amount of 80%.

  Furthermore, paying attention to the pixels in the order of the top few percent of the histogram, for example, when this portion has a luminance of 60%, the light emission amount of the backlight is suppressed to 60% of 3/5, and the display image A substantially similar image can be obtained by expanding the display data values of all pixels to 5/3 times. In this case, it is possible to display with a smaller amount of light emitted from the backlight as compared with the method using the maximum luminance in the image.

However, in this case, for pixels having a value higher than 3/5 of the maximum value of the display data value (pixels in the upper few% of the above-mentioned histogram), when the display data is expanded 5/3 times The value is saturated to the maximum value. For this reason, these pixels become darker than the original luminance when the amount of light emitted from the backlight is suppressed to 3/5, resulting in a certain degree of image quality degradation.
JP-A-11-65531

  The above-described image quality degradation cannot be avoided by the backlight control method using the histogram presented in Patent Document 1, but power consumption is reduced by suppressing the amount of light emitted from the backlight within a range where this image quality degradation can be tolerated. Is realized.

  Here, for example, even when two images have the same luminance or more and the same number of pixels have undergone luminance deterioration, the recognition of image quality deterioration given to the viewer as the entire image may be different between the two images.

  Among the pixels that have deteriorated in luminance, when there are many pixels with high luminance and the luminance has deteriorated, and when there are many pixels with relatively low luminance and the luminance has deteriorated, the pixels with high luminance are Since the difference between the original display data value and the display data value that is actually saturated and deteriorated becomes larger, it is considered that image quality deterioration is more easily recognized when the number of pixels with high luminance is deteriorated. .

  Conversely, if there are many pixels with relatively low luminance and the luminance is deteriorated, it is considered difficult to recognize the deterioration of the image quality, and there is a possibility that a slight deterioration in the image quality is acceptable. This means that the amount of light emitted from the backlight can be reduced a little, and there is a possibility of further power saving.

  However, in the backlight control method presented in Patent Document 1, it is impossible to distinguish between the case where the number of pixels having high luminance deteriorates and the case where the number of pixels having relatively low luminance deteriorates. Thus, it is not possible to perform further power saving.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an image display apparatus that can save power by allowing a reduction in the amount of light emitted from the backlight, while allowing a certain level of image quality deterioration. And when the brightness of many pixels with relatively low brightness deteriorates, and when the brightness of many pixels with relatively low brightness deteriorates, the amount of light emitted from the backlight is further reduced to maintain image quality. It is another object of the present invention to provide an image display device driving circuit and an image display method that enable further power saving.

  The above and other objects and novel features of the present invention will be apparent from the description of this specification and the accompanying drawings.

  Of the inventions disclosed in the present application, the outline of typical ones will be briefly described as follows.

  The present invention is a drive circuit and an image display method for an image display apparatus that displays an image by irradiating a backlight on a display screen, and has the following characteristics.

  That is, the drive circuit counts display data of each pixel in frame units of an image to obtain a histogram, calculates a display data value at a specific position above the histogram, and determines it as a selected data value. A counting unit; a display data expansion unit that expands display data of each pixel based on the selection data value; and a backlight voltage adjustment unit that adjusts the light emission voltage of the backlight based on the selection data value. A backlight control unit, and the histogram counting unit acquires a weighted histogram counted using a weighting value corresponding to a value of display data of each pixel when the histogram is acquired. To do.

  Among the inventions disclosed in the present application, effects obtained by typical ones will be briefly described as follows.

  According to the present invention, when the histogram of the display data of the display image is counted, for example, a pixel with high luminance is subjected to large weighting and a pixel with relatively low luminance is subjected to small weighting depending on the value of the display data. A distinction is made between the case where many pixels with high luminance deteriorate and the case where many pixels with relatively low luminance deteriorate, and when many pixels with relatively low luminance deteriorate, processing to further reduce the amount of light emitted from the backlight is performed. As a result, it is possible to further reduce power consumption within a range where image quality deterioration is not noticeable.

  At the same time, an unweighted histogram is counted, and when many pixels with high luminance deteriorate, power consumption and image quality similar to those of the prior art can be maintained by using the unweighted histogram.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Note that components having the same function are denoted by the same reference symbols throughout the drawings for describing the embodiment, and the repetitive description thereof will be omitted.

  Also, a liquid crystal display device will be described as an example of an image display device that displays an image by irradiating a backlight to the display screen, but the present invention is not limited to this.

<Embodiment 1>
Below, the drive circuit of the liquid crystal display device of Embodiment 1 of this invention is demonstrated using FIGS.

  FIG. 1 is a diagram showing a configuration of a liquid crystal display device including a liquid crystal driving circuit of the present embodiment. The liquid crystal display device includes a liquid crystal driving circuit 101, a liquid crystal panel 114, a backlight module 115, a backlight power supply circuit 116, and a control processor 117.

  The control processor 117 creates image display data and outputs it to the liquid crystal drive circuit 101. The backlight power supply circuit 116 generates a desired voltage based on the information of the backlight control signal 112 output from the liquid crystal driving circuit 101 and supplies it to the backlight power supply line 113. The liquid crystal panel 114 receives the liquid crystal source signal 110 and the liquid crystal gate signal / common signal 111 from the liquid crystal driving circuit 101 and displays an image. The backlight module 115 is supplied with power through the backlight power line 113, and lights the backlight with a desired brightness to illuminate the liquid crystal panel 114. Thereby, the image displayed on the liquid crystal panel 114 can be seen as visible light.

  The liquid crystal drive circuit 101 includes a system interface 102, a control register 103, a backlight control unit 104, a graphic RAM 105, a timing generation circuit 106, a gradation voltage generation circuit 107, a source line drive circuit 108, and a liquid crystal drive level generation circuit 109. It has become.

  The system interface 102 is an interface unit with the outside in the liquid crystal driving circuit 101, and exchanges display data and write data to the control register 103 described later with the outside. The control register 103 is a set of registers for controlling each part of the liquid crystal driving circuit 101.

  The backlight control unit 104 is a central block in the liquid crystal driving circuit 101 of the present embodiment, and receives display data from a graphic RAM 105 described later, performs display data expansion processing described later, and drives source line driving described later. Display data is output to the circuit 108.

  The graphic RAM 105 serves as a buffer that inputs and accumulates display data via the system interface 102 and outputs the display data to the source line driver circuit 108 via the backlight control unit 104. The timing generation circuit 106 generates the operation timing of the entire liquid crystal driving circuit 101 based on the contents of the control register 103.

  The gradation voltage generation circuit 107 generates a gradation voltage used in the source line driver circuit 108. The source line driver circuit 108 uses the display data output from the backlight control unit 104, selects a specific voltage from the gradation voltages generated by the gradation voltage generation circuit 107, and serves as the liquid crystal source signal 110. Output to the liquid crystal panel 114. The liquid crystal drive level generation circuit 109 generates a liquid crystal gate signal / common signal 111 used for driving the liquid crystal panel 114 and outputs the liquid crystal gate signal / common signal 111 to the liquid crystal panel 114.

  An outline of the operation of the liquid crystal drive circuit 101 having the above-described configuration will be described below. The liquid crystal drive circuit 101 takes in display data from the outside via the system interface 102 and stores it in the graphic RAM 105. The timing generation circuit 106 generates a read timing of the graphic RAM 105 and inputs display data to the backlight control unit 104 at that timing.

  The backlight control unit 104 performs display data expansion processing described later, and outputs display data to the source line driver circuit 108. The source line driver circuit 108 selects a voltage from the gradation voltage generated by the gradation voltage generation circuit 107 based on the input display data, and outputs it as a liquid crystal source signal 110 to the liquid crystal panel 114. Further, the liquid crystal drive level generation circuit 109 generates a liquid crystal gate signal / common signal 111 using the timing generated by the timing generation circuit 106 and outputs it to the liquid crystal panel 114.

  In response to the backlight control signal 112 from the backlight control unit 104, a voltage is generated by the backlight power supply circuit 116 and applied to the backlight power supply line 113, thereby turning on the backlight module 115. The lit backlight module 115 illuminates the liquid crystal panel 114, so that a display image can be seen.

  Next, the operation content in the backlight control unit 104 will be described. FIG. 2 is a diagram illustrating the configuration of the backlight control unit 104. The backlight control unit 104 includes a histogram counting unit 201, a display data expansion unit 202, and a backlight voltage adjustment unit 207.

  The histogram counting unit 201 counts the display data 208 in consideration of weighting, and creates a histogram. A selection data value 211 used for performing the backlight control is calculated from the histogram, and is output to the display data expansion unit 202 and the backlight voltage adjustment unit 207.

  In calculating the selection data value 211, the position of the display data 208 in the histogram to be used is set by a threshold value 210 described later, and the display data 208 at the set position is present in which entry of the histogram. The value of the entry is calculated as the selection data value 211. This selection data value 211 serves as a reference for the expansion process of the display data 208 and the dimming process of the backlight module 115. When the display data expansion coefficient 212 described later is calculated based on the selection data value 211, the display data 208 is expanded. And the brightness of the backlight module 115 is determined by generating a backlight voltage selection signal 214 (to be described later).

  The frame SYNC209 is used to operate the histogram counting unit 201 for each frame. When the frame SYNC 209 is off, the histogram counting unit 201 continues to register the input display data 208 in the histogram, calculates the selection data value 211 at the timing when the frame SYNC 209 is on, clears the histogram, and moves to the next frame. Preparation for histogram counting of the display data 208 is performed.

  The threshold value 210 is a parameter that determines which position of the display data 208 in the histogram is to be used as the selection data value 211. When performing backlight control using a histogram that is not weighted as in the prior art, the threshold value 210 is set as the threshold value 210, and the number of pixels of several percent of the total number of pixels in the display image that allows image quality degradation is set. The value of the display data 208 corresponding to the position of the threshold value 210 from the top is the selection data value 211.

  In a histogram without weighting, one unit of the histogram is one pixel, and the total sum of the histogram matches the total number of pixels. Therefore, the ratio of the sum total of data at positions higher than the threshold value 210 on the histogram to the total sum of the histogram. Is consistent with the above few percent. However, in the histogram weighted by the drive circuit according to the present embodiment, one unit of the histogram is not one pixel as a result of the weighting, and the histogram total does not match the total number of pixels. In the above, the ratio of the sum of the data at positions higher than the threshold value 210 does not match the above-mentioned several percent.

  The display data expansion unit 202 includes a display data expansion coefficient calculation unit 203, a display data calculation unit 204, a saturation calculation processing unit 205, and a fractional part truncation unit 206. The display data expansion unit 202 expands the display data 208 based on the selected data value 211. Perform data expansion processing.

  In the display data expansion processing, first, the display data expansion coefficient calculation unit 203 calculates the display data expansion coefficient 212 by calculating 255 / (selection data value 211) with the selection data value 211 as an input. Next, the display data calculation unit 204 multiplies the display data 208 by the display data expansion coefficient 212 with the display data 208 as an input. Next, the saturation calculation processing unit 205 performs a saturation calculation of 255 when the result of the above multiplication exceeds 255, which is the maximum value that the display data 208 can take. Lastly, the fractional part truncation unit 206 truncates the fractional part of the result of the saturation operation described above, and outputs the obtained result as expanded display data 213.

  As a result, the pixel whose display data 208 value is the same as the selection data value 211 is expanded to 255, which is the maximum value that the display data 208 can take, and the display data 208 value is greater than the selection data value 211. All the high pixels are saturated to 255, which is the maximum value that the value of the display data 208 can take, and become pixels whose luminance deteriorates.

  The backlight voltage adjustment unit 207 receives the selection data value 211 calculated by the histogram counting unit 201 as an input, and selects and outputs the backlight voltage selection signal 214 from the voltage selection table 216.

  Assuming that the ratio of the expanded display data 213 to the display data 208 is the display data expansion ratio 215, the relationship between the backlight voltage selection signal 214 and the display data expansion ratio 215 for the selected data value 211 is as shown in the voltage selection table 216. When the display data expansion rate 215 changes from 100% to 104%, 108%,..., 154%, the backlight voltage selection signal 214 changes from 100% to 96%, 92%,. The voltage decreases at a rate of 64%. As a result, when both magnifications are multiplied, the brightness of the image displayed on the liquid crystal panel 114 does not change from the original brightness.

  In this embodiment, the backlight voltage selection signal 214 for the selected data value 211 is determined using the voltage selection table 216. However, the backlight voltage is calculated by a function using the selected data value 211 as an input. A configuration in which the selection signal 214 is determined is also possible.

  The overall processing flow in the backlight control unit 104 having the above-described configuration is as follows. First, the histogram counting unit 201 receives the display data 208, the frame SYNC 209, and the threshold value 210 as input, and the histogram of the display data 208 for each frame. And the selection data value 211 is calculated using the threshold value 210. Next, the selection data value 211 is input to the display data decompression unit 202, display data decompression processing is performed on the display data 208, and decompressed display data 213 is output. In addition, the selection data value 211 is input to the backlight voltage adjustment unit 207, and the backlight voltage selection signal 214 corresponding to the selection data value 211 is selected and output, thereby performing the process of adjusting the light emission amount of the backlight. .

  Next, the operation content in the histogram counting unit 201 will be described. FIG. 3 is a diagram illustrating the configuration of the histogram counting unit 201. The histogram counting unit 201 includes a threshold value 301, a comparator A302, a weighted histogram unit 313, an unweighted histogram unit 314, a small value selection selector 308, and a weighted value register 309.

  The weighted histogram unit 313 includes an edge detection unit A303, a selector 304, a counter 305, a comparator B306, and an edge detection unit B307. The unweighted histogram unit 314 includes the counter 305, the comparator B306, and the edge detection unit B307. Composed.

  The threshold 301 holds a value indicating a histogram interval. The comparator A302 compares the input display data 208 and the corresponding threshold value 301, and outputs true if the input display data 208 is equal to or greater than the corresponding threshold value 301, otherwise Outputs false. One output is obtained for each comparator A302, and the output of the comparator A302 as a whole is true when the value of the corresponding threshold 301 is low, false when it is high, and one change point from true to false. The output will only exist. This change point represents the section of the histogram to which the display data 208 belongs. Further, this output is output to the counter 305 as a count up signal 310.

  As will be described in detail later, the edge detection unit A303 binarizes (binary) the output of the comparator A302, detects the above-described change point from true to false, and weights the value corresponding to this change point The selection signal 311 is output to the selector 304. The selector 304 uses the weighting selection signal 311 to select one from weighting values 312 held in a weighting value register 309 described later and outputs the selected one to the counter 305. The counter 305 adds a weight value 312 or 1 when the count-up signal 310 is true. When the frame SYNC209 is input, the counter 305 outputs the held counter value to the comparator B306 and clears the counter value.

  The comparator B306 compares the counter value output from the counter 305 with the threshold value 210, and outputs true if the input counter value is equal to or greater than the threshold value 210, and outputs false otherwise. One output is obtained for each comparator B306, and the output of the comparator B306 as a whole is true when the value of the corresponding threshold 301 is low, false when it is high, and one change point from true to false. The output will only exist. This change point represents a section of the histogram to which the threshold value 210 belongs.

  As will be described in detail later, the edge detection unit B307 binarizes (binary) the output of the comparator B306, detects the above-described change point from true to false, and selects a value corresponding to the change point as selection data. The value 211 is output to the small value selection selector 308 as a candidate. The small value selection selector 308 compares two input candidate selection data values 211 with each other, selects the lower one, and outputs it as the selection data value 211.

  The weight value register 309 holds a set of weight values 312 that vary depending on the value of the display data 208, and can be changed from the outside. The weighting value 312 is set to a value of 1 or more in order to give a high weighting to the display data 208 with a high value even in the display data 208 in a range where luminance degradation is expected, and to the display data 208 with a relatively low value. In order to perform small weighting, a value less than 1 is set.

  The flow of processing in the entire histogram counting unit 201 having the configuration described above is as follows. First, the display data 208 is received, and the comparison with the threshold value 301 is performed by the comparator A302. With this result as an input, the weighting histogram unit 313 detects the section of the histogram to which the display data 208 belongs by the edge detection unit A303 and outputs a weighting selection signal 311. With this weight selection signal 311 as an input, the selector 304 selects one of the weight values 312 and outputs it to the counter 305. The value of the weight value 312 is a weighted addition value of the display data 208.

  The output of the comparator A303 is directly input to the counter 305 as the count up signal 310. Since the portion corresponding to the value of the display data 208 is true in the count-up signal 310, the counter 305 corresponding to that portion adds a weighted value 312 that is a weighted value.

  This process is repeated for all display data 208 for one frame, and a frame SYNC 209 is input to obtain a histogram for that frame. The counter 305 outputs the counter value at that time to the comparator B306, and then resets the counter value.

  In the comparator B306, the counter value output from the counter 305 is compared with the threshold value 210, and if the input counter value is equal to or greater than the threshold value 210, it is determined to be true, and otherwise, it is output to the edge detection unit B307. . The edge detection unit B307 receives the comparison result from the comparator B306, detects a section of the histogram to which the threshold value 210 belongs, and calculates a candidate for the selected data value 211. As described above, candidates for the selection data value 211 using the weighted histogram are obtained.

  Further, in the unweighted histogram section 314, the counter 305 additionally adds the weighting values to the above-described count-up signal 310 in a state where all of the weighting values are 1 (no weighting), and repeats this for one frame. Output to. After that, the comparator B306 compares the threshold value 210 with the same procedure as described above, and the edge detection unit B307 calculates a candidate for the selected data value 211. As described above, candidates for the selection data value 211 using the unweighted histogram are obtained.

  Of these two selection data value 211 candidates, the lower value selection selector 308 selects a lower value and outputs it as the selection data value 211. In this manner, the selection data value 211 can be calculated by using each of the weighted histogram and the non-weighted histogram, and the optimum selected data value 211 can be output by selecting a lower value.

  FIG. 4 is a diagram illustrating an example of an input / output table in the edge detection unit A303 and the edge detection unit B307 described above. In FIG. 4, an input 401 is a value obtained by binarizing (binary digitizing) the input from each comparator A302 or each comparator B306. In the example of FIG. 4, it indicates that there is a 15-bit input. This input 401 has a location (edge) where the MSB side is 1 and the LSB side is 0, except when the bits are all 0s or all 1s, and changes from 1 to 0 only once between MSB and LSB. Data. When all bits are 0, it is considered that there is an edge outside the MSB, and when all bits are 1, there is an edge outside the LSB.

  The output 402 is obtained by assigning a value from 0h to fh to the input 401. The output 402 is data indicating the position of the edge where the bit of the input 401 changes from 1 to 0.

  Next, the effect when the weighted histogram is used will be described with reference to FIG. In FIG. 5, a graph 501 is a histogram when the display data 208 having a relatively low value is large in the range of values higher than the threshold value 210 described above, and a graph 502 is a histogram when the display data 208 having a high value is large. Represents an example.

  The weighting value 503 represents an example of a set of weighting values 312 when weighting is performed, and one or more values are set for the display data 208 having a high value to give a large weighting, and a relatively low value. The display data 208 is set to a value less than 1 in order to perform small weighting. The weighting value 504 represents the case of no weighting (normal), and the values are all 1.

  The results obtained by counting the data of the graphs 501 and 502 with the weighting values 503 and 504 are the histograms of the weighted histogram 505 to the unweighted histogram 508. In the unweighted histograms 507 and 508, the sum of the data is the same for both the unweighted histogram 507 when there are many relatively low value display data 208 and the unweighted histogram 508 when there are many high value display data 208. The result is 56.0.

  However, in the weighted histograms 505 and 506, in the weighted histogram 505, which is a case where the display data 208 having a relatively low value is large, the sum is reduced to 42.0 with respect to the unweighted histogram 507, while the display data having a high value is displayed. In the weighting histogram 506 when 208 is large, the value increases to 58.8.

  Considering this situation as an image, if “color collapse”, which is a phenomenon in which the data value is saturated by the decompression processing of the display data 208, occurs, both are saturated at the same display data 208 value and color collapse occurs. Then, compared with the case where a lot of high-value display data 208 is saturated, when the display data 208 of a relatively low value is saturated a lot, the change in luminance due to color collapse becomes small. In other words, it is considered that the image quality degradation is difficult to understand, and it is considered that the image can save more power than a case where a large amount of high-value display data 208 is saturated.

  The weighted histogram 505 is a case where the sum is low and a relatively low value of display data 208 is saturated, and is an image that can save more power. When the above-described selection data value 211 is calculated using the weighted histogram 505, more actual pixels can be assigned to a range of values higher than the threshold value 210 than when the unweighted histogram 507 is used. A power-saving selection data value 211 can be calculated.

  On the other hand, when a large amount of high-value display data 208 is saturated, the sum may be higher than in the case of the unweighted histogram 508 as seen in the example of the weighted histogram 506. In this case, if the selection data value 211 is calculated as it is, the value becomes higher than that in the case of no weighting. Therefore, in such a case, the selection data value 211 using the unweighted histogram 508 is used to suppress an increase in power consumption.

  In the driving circuit according to the present embodiment, when the sum of the weighted histograms is higher than the sum of the unweighted histograms, the selection data value 211 using the unweighted histograms is used in order to save power. However, for example, a register for setting whether to prioritize image quality or power saving is provided, and the selection data value 211 to be used is determined by the value of the register. There may be.

  As described above, the histogram of the display data 208 is counted by two methods of weighting and weighting depending on the value of the display data 208, the candidate of the selected data value 211 is calculated for each histogram, and the lower one is selected. By using the data value 211, it is possible to further reduce the amount of light emitted from the backlight only in an image in which it is difficult to recognize image quality deterioration, and further power saving can be achieved.

  Note that a series of processing such as histogram counting, selection data value 211 calculation, display data 208 decompression, and the like performed by the backlight control unit 104 in the drive circuit of this embodiment is performed outside the control processor 117 or the like. It is also possible to adopt a configuration in which calculation is performed by a processor.

<Embodiment 2>
Hereinafter, a driving circuit of the liquid crystal display device according to the second embodiment of the present invention will be described with reference to FIG. The configuration of the liquid crystal display device including the liquid crystal driving circuit of the present embodiment is the same as the configuration of FIG. In addition, the configuration of the backlight control unit 104 in the liquid crystal driving circuit of the present embodiment is also the same as the configuration of FIG.

  FIG. 6 is a diagram showing the configuration of the histogram counting unit 201 in FIG. 2 in the present embodiment. In contrast to the configuration of the histogram counting unit 201 of the first embodiment shown in FIG. The weighted histogram portion 2 (605) is used so that the weighted histogram can be counted in the same manner as the weighted histogram portion 1 (604). Further, a weight adjustment unit 601 and a weight value selection table 602 are added instead of the weight value register 309. Other components have the same functions as those shown in FIG. 3, and thus the description thereof is omitted here.

  The weighting adjustment unit 601 receives from the small value selection selector 308 a selection signal 603 indicating which output of the weighting histogram units 1 and 2 (604 and 605) is used as the selection data value 211. The set of weight values 312 to be used next is determined according to this value, and the weight value 312 to be used next is selected from the weight value selection table 602 and output to each selector 304. As a result, the weighting value 312 can be dynamically changed.

  Next, the operation content in the histogram counting unit 201 will be described. In the weighted histogram sections 1 and 2 (604 and 605), the same operation as the operation of the weighted histogram section 313 in FIG. 3 of the first embodiment is performed, and each candidate of the selected data value 211 is calculated. At this time, the output from the weight value selection table 602 is used as the weight value 312.

  Next, the selection data value 211 is determined and output by the small value selection selector 308. At this time, which selection data value 211 is selected is output by a selection signal 603. Upon receiving the selection signal 603, the weight adjustment unit 601 determines a set of weight values 312 to be used next, selects the weight value 312 from the weight value selection table 602, and outputs it to the selector 304.

  At this time, the weighting value selection table 602 prepares a set of weighting values 312 stepwise from a value with no weighting to a value with strong weighting, and outputs it to the weighting histogram units 1 and 2 (604, 605). The weighting value 312 is set to a value different by one step.

  For example, the weighting value 312 output to the weighting histogram unit 1 (604) is selected so that the weighting is 3 steps higher than the weighting value 312 output to the weighting histogram unit 2 (605). When the selection data value 211 calculated by the weighting histogram unit 1 (604) is selected, the next weighting value 312 has a one-step weighting stronger than both the weighting histogram units 1 and 2 (604, 605). A weighting value 312 is output. On the contrary, when the selection data value 211 calculated by the weighting histogram unit 2 (605) is selected, the weighting value 312 that makes the one-step weighting weaker for both the weighting histogram units 1 and 2 (604, 605). Output.

  By performing the control as described above, the weight value 312 can be dynamically changed. In addition, by adjusting the selected weighting value 312 to an optimum value according to the characteristics of the image, it is possible to realize backlight control with less power consumption and no deterioration in image quality.

  Although the present embodiment has two weighted histogram sections, the number is not limited to two. Further, as in the first embodiment, it is also possible to make a configuration such that the comparison with the selection data value 211 calculated by the unweighted histogram is performed.

  As mentioned above, the invention made by the present inventor has been specifically described based on the embodiment. However, the present invention is not limited to the embodiment, and various modifications can be made without departing from the scope of the invention. Needless to say.

  The present invention can be used for power saving by backlight control in an image display device such as a liquid crystal display or a projector. Further, the liquid crystal display can be used not only for a mobile phone liquid crystal display but also for various devices such as a small media player such as a DVD using the liquid crystal display.

It is a figure showing the structure of the liquid crystal display device containing the liquid crystal drive circuit which is Embodiment 1 of this invention. It is a figure showing the structure of the backlight control part in Embodiment 1 of this invention. It is a figure showing the structure of the histogram counting part in Embodiment 1 of this invention. It is a figure showing an example of the input-output table in the edge detection part in Embodiment 1 of this invention. It is a figure explaining the effect at the time of using the weighting histogram in Embodiment 1 of this invention. It is a figure showing the structure of the histogram counting part in Embodiment 2 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 101 ... Liquid crystal drive circuit, 102 ... System interface, 103 ... Control register, 104 ... Backlight control part, 105 ... Graphic RAM, 106 ... Timing generation circuit, 107 ... Gradation voltage generation circuit, 108 ... Source line drive circuit, 109 Liquid crystal drive level generation circuit 110 Liquid crystal source signal 111 Liquid crystal gate signal / common signal 112 Backlight control signal 113 Backlight power line 114 Liquid crystal panel 115 Backlight module 116 Backlight Light power supply circuit, 117... Control processor,
DESCRIPTION OF SYMBOLS 201 ... Histogram count part, 202 ... Display data expansion | extension part, 203 ... Display data expansion coefficient calculation part, 204 ... Display data calculation part, 205 ... Saturation calculation processing part, 206 ... Decimal point truncation part, 207 ... Backlight voltage adjustment part 208, display data, 209, frame SYNC, 210, threshold value, 211, selection data value, 212, display data expansion coefficient, 213, expansion display data, 214, backlight voltage selection signal, 215, display data expansion ratio, 216 ... Voltage selection table,
301 ... Threshold value 302 ... Comparator A, 303 ... Edge detection unit A, 304 ... Selector, 305 ... Counter, 306 ... Comparator B, 307 ... Edge detection unit B, 308 ... Small value selection selector, 309 ... Weight value register 310 ... Count-up signal, 311 ... Weighted selection signal, 312 ... Weighted value, 313 ... Weighted histogram section, 314 ... Unweighted histogram section,
401 ... input, 402 ... output,
501 ... Histogram when there is a lot of display data with relatively low values, 502 ... Histogram when there is a lot of display data with high values, 503 ... Weighting value with weighting, 504 ... Weighting value without weighting (normal) 505: Weighted histogram (when there is a lot of low value display data), 506 ... Weighted histogram (when there is a lot of high value display data), 507 ... Unweighted histogram (when there is a lot of low value display data), 508 ... Weighting None histogram (when there is a lot of high value display data),
601... Weighting adjustment unit, 602... Weighting value selection table, 603... Selection signal, 604.

Claims (11)

A drive circuit for an image display device that displays an image by irradiating a backlight to a display screen,
The drive circuit obtains a histogram by counting display data of each pixel in frame units of an image, calculates a value of display data at a specific position above the histogram, and determines it as a selected data value. A display data expansion unit that expands display data of each pixel based on the selection data value, and a backlight voltage adjustment unit that adjusts the light emission voltage of the backlight based on the selection data value Having a control unit,
The drive circuit of an image display device, wherein the histogram counting unit obtains a weighted histogram counted using a weighting value corresponding to a display data value of each pixel when obtaining the histogram. The drive circuit of the image display device according to claim 1,
The histogram counting unit obtains the weighted histogram and also obtains an unweighted histogram counted without weighting, the display data value of the specific position calculated based on the weighted histogram, and the unweighted A drive circuit for an image display device, wherein a lower value of the display data values at the specific position calculated based on a histogram is determined as the selection data value. The drive circuit of the image display device according to claim 1 or 2,
The drive circuit for an image display device, wherein the histogram counting unit includes a register for storing the set of weight values, and the weight values can be changed from the outside. The drive circuit of the image display device according to claim 1,
The histogram counting unit acquires the weighted histograms counted using different sets of the weighted values, and among the values of the display data of the specific position calculated based on the weighted histograms, A drive circuit for an image display device, wherein the lowest value is determined as the selection data value. In the drive circuit of the image display device according to claim 4,
The drive circuit for an image display device, wherein the histogram counting unit includes a register for storing a table for holding a plurality of sets of weight values, and the weight values can be changed from the outside. In the drive circuit of the image display device according to claim 4 or 5,
The histogram counting unit obtains the next weighted histogram based on which of the display data values of the specific position calculated based on each weighted histogram is determined as the selected data value. A drive circuit for an image display device, characterized in that the set of weight values used at the time is changed. The drive circuit of the image display device according to claim 6,
The drive circuit for an image display device, wherein the histogram counting unit includes a register for storing a change method when changing the set of weight values, and the change method can be changed from the outside. An image display method for displaying an image by irradiating a backlight to a display screen,
A process of counting display data of each pixel in frame units of an image by a processor or a drive circuit to obtain a histogram, calculating a value of display data at a specific position above the histogram, and determining it as a selected data value; Performing a process of expanding display data of each pixel based on the selected data value and a process of adjusting a light emission voltage of the backlight based on the selected data value;
An image display method characterized in that when the display data of each pixel is counted to obtain the histogram, a weighted histogram counted using a weight value corresponding to the value of the display data of each pixel is obtained. . The image display method according to claim 8, comprising:
When the display data of each pixel is counted and the histogram is acquired, the weighted histogram is acquired, and an unweighted histogram counted without weighting is also acquired, and the identification calculated based on the weighted histogram An image display characterized in that the lower one of the display data value at the position and the display data value at the specific position calculated based on the unweighted histogram is determined as the selected data value. Method. The image display method according to claim 8, comprising:
When the display data of each pixel is counted and the histogram is obtained, the weighted histogram counted using each of a plurality of different sets of weight values is obtained and calculated based on the weighted histogram. The image display method characterized by determining the lowest value among the display data values at the specific position as the selection data value. The image display method according to claim 10,
When the display data of each pixel is counted and the histogram is acquired, which of the display data values of the specific position calculated based on the weighted histogram is determined as the selection data value And changing the set of weight values used in the next acquisition of the weighted histogram.

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