JP2005284266A - Display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display device, whose lifetime is prolonged by preventing deterioration of image quality by reducing image persistence. <P>SOLUTION: A display device 10 includes a static image region detecting unit 3 for detecting static image data from video data 53. In addition, a detection unit 7 for detecting, as an edge portion, a pair of pixels, having a level difference of image data larger than a preset level difference, of a plurality of pair of adjacent pixels for the static image data. Furthermore, a level-adjusting unit 13 for adjusting the level of the image data of a group of pixels, including the edge portion and arranged consecutively and outputting the image data after the adjustment to a drive unit 5. The level-adjusting unit 13 is for adding/subtracting a random noise to/from the image data of the group of pixels. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a display device that displays an image including both a moving image and a still image.

  A display control method for a display device that clearly displays a moving image without impairing the life of the display device is disclosed (see Patent Document 1). Patent Document 1 discloses a CRT (Cathode-Ray Tube) as a display device (display device). Hereinafter, the display device described in Patent Document 1 is referred to as a CRT display device.

  Conventionally, since a CRT display device for a computer often displays a still image for a long time, a long afterglow phosphor is used as the phosphor. The long afterglow phosphor has a feature that even if the electron beam hits the same position of the phosphor for a long time, the phosphor paint fatigue does not remain. Further, in the CRT display device for computers, the luminance of the image is set to be low.

  On the other hand, in a CRT display device for television, a short afterglow phosphor is used as a phosphor because it mainly displays moving images. The short afterglow phosphor is characterized by minimizing the influence of the irradiation beam. In addition, since a television CRT display device mainly displays moving images, the brightness of the image is set higher than that of a computer CRT display device.

  In recent years, it has become possible to display a moving image on a CRT display device using a computer, and an image in which a still image and a moving image are mixed is displayed on the CRT display device. When an image in which a still image and a moving image are mixed is displayed on a CRT display device, burn-in may occur. Burn-in refers to a phenomenon in which a specific portion (referred to as a still image area) of a CRT display device on which a still image is displayed is consumed, and a consumed trace remains in the still image area. When burn-in occurs, the life of the CRT display device is shortened.

  Therefore, the display control method described in Patent Document 1 controls image output with respect to a display device (CRT display device) for displaying still images and / or moving images. In this display control method, first, it is determined whether or not an image to be displayed has a still image region. Next, when there is no still image area and only a moving image area exists in the image, this image is displayed as it is on the display device. When a moving image area and a still image area exist, black dots are added to the still image area. Randomly added to display an image on the display device. Japanese Patent Application Laid-Open No. H10-228561 describes that this can prevent burn-in in a still image region.

JP-A-10-161629

  However, the conventional techniques described above have the following problems. If a moving image area and a still image area exist in an image, even if black dots are randomly added to the still image area, black dots are added to areas that are likely to be burned in the still image area. Is not limited. For this reason, the big effect of reduction of image sticking cannot be expected. Therefore, the image quality of the display device is deteriorated as viewed from the viewer due to burn-in.

  The present invention has been made in view of such problems, and an object of the present invention is to provide a display device capable of preventing image quality deterioration by reducing burn-in and extending its life.

  A display device according to the present invention is a display device that displays an image based on video data input from the outside, and a plurality of pixels each having a plurality of sub-pixels having different colors or a single sub-pixel are arranged. A display unit, a drive unit that drives the display unit based on the video data, a still image region detection unit that detects a still image region from the video data, and a burn-out reduction treatment for a sub-pixel located in the still image region And a seizure mitigation treatment section for applying

  Another display device according to the present invention is a display device that displays an image based on video data input from the outside, and a plurality of pixels each composed of a plurality of sub-pixels having different colors or a single sub-pixel of a single color are arranged. A display unit, a drive unit that drives the display unit based on the video data, a static character region detection unit that detects a static character region from the video data, and a sub-pixel located in the static character region And a seizure mitigation treatment section for performing a mitigation treatment.

  According to the present invention, image sticking can be reduced by performing the image sticking reduction treatment on the sub-pixels located in the still image region. Thereby, it is possible to prevent deterioration of the image quality of the display device and extend its life.

  Hereinafter, embodiments of the present invention will be specifically described with reference to the accompanying drawings.

(First embodiment)
First, a first embodiment of the present invention will be described. FIG. 1 is a block diagram showing a configuration of a display device according to the first embodiment of the present invention. A display device 10 shown in FIG. 1 is used as a display device for a television and a computer (not shown). The television includes an operation switch, a remote terminal, a decoder, and a tuner (not shown). The computer includes an operation switch (not shown) (example: keyboard, pointing device) and a computer main body (example: hard disk, memory).

  The display device 10 includes a video signal processing unit 1, a switch 2, a still image region detection unit 3, a switch 4, a drive unit 5, a display device body 6, a switch 16, and a still image level adjustment unit 17. Examples of the display device body 6 include a plasma display, an LCD (Liquid Crystal Display), an EL (Electroluminescence) display, and a CRT (Cathode-Ray Tube). In this embodiment, the display device body 6 is a plasma display, and FIG. 1 shows a plasma display panel (PDP) as the front side of the display device body 6 (plasma display). The still image level adjustment unit 17 includes a CPU (Central Processing Unit) 15. In the display device body 6, a plurality of pixels are arranged in a matrix, for example. When the display device body 6 is a color display device, each pixel is composed of a plurality of sub-pixels having different colors. For example, one pixel is composed of three sub-pixels of red (R), green (G), and blue (B). When the display device body 6 is a monochrome display device, each pixel is composed of a single sub-pixel of a single color. The drive unit 5 drives the display device body 6.

  The video signal processing unit 1 converts a video signal 100 input from the outside, for example, a television decoder or a computer main body, into video data 53 suitable for the drive unit 5 to drive the display device main body 6. It is. The still image area detection unit 3 checks whether or not the video data 53 output from the video signal processing unit 1 includes still image data. Further, the still image level adjustment unit 17 in the still image data included in the video data 53, among a plurality of adjacent pixel pairs, a pixel pair in which the level difference of the image data is greater than or equal to a preset set level difference. Is detected as an edge part, the level of image data of pixel groups arranged continuously including this edge part is adjusted, and the adjusted image data is output to the drive unit 5.

  The display device 10 can switch between the normal mode and the level adjustment operation mode. When the display device 10 executes the normal operation mode, the video data 53 output from the video signal processing unit 1 is directly transferred to the drive unit 5, and the drive unit 5 moves the display device main body 6 based on the video data 53. To drive. On the other hand, when the display device 10 executes the level adjustment operation mode, the video data 53 output from the video signal processing unit 1 is input to the still image region detection unit 3. When the still image area detection unit 3 detects still image data in the video data 53, the video data 53 is input from the video signal processing unit 1 to the still image level adjustment unit 17 via the switch 2, and the still image is detected. The level adjustment unit 17 adjusts the level of the image data of the pixel group including the edge portion, and outputs the adjusted video data to the drive unit 5. The drive unit 5 drives the display device body 6 based on the video data 53. The video signal transfer path is controlled by switching the switches 2, 4 and 16.

  The switch 2 is switched by a signal from the CPU 15 in the still image level adjustment unit 17. The CPU 15 is supplied with a level adjustment operation setting signal 61 or a normal operation setting signal 62 in accordance with an instruction from the viewer (example: operation switch, operation of a remote terminal).

  When the level adjustment operation setting signal 61 is supplied to the CPU 15, the CPU 15 connects the video signal processing unit 1 and the still image region detection unit 3 via the switch 2 in accordance with the level adjustment operation setting signal 61. The switch 2 is controlled so that the video signal processing unit 1 and the drive unit 5 are connected via the switch 2 and the switch 16. That is, when the level adjustment operation setting signal 61 is input to the display device 10, the display device 10 enters the level adjustment operation mode, and the video signal processing unit 1 is connected to the still image region detection unit 3 by the switch 2.

  When the normal operation setting signal 62 is supplied to the CPU 15, the CPU 15 switches the switch 2 so that the video signal processing unit 1 and the drive unit 5 are connected via the switch 2 in accordance with the normal operation setting signal 62. To control. That is, when the normal operation setting signal 62 is input to the display device 10, the display device 10 enters the normal operation mode, and the video signal processing unit 1 is connected to the drive unit 5 by the switch 2.

  The switch 4 is switched by a signal from the still image area detection unit 3. The still image area detection unit 3 and the still image level adjustment unit 17 are connected via a switch 4. When a signal from the still image region detection unit 3 is supplied to the switch 4, the still image region detection unit 3 and the drive unit 5 are connected via the switch 4 and the switch 16.

  The switch 16 is switched by a signal from the still image level adjustment unit 17. When a signal from the still image level adjustment unit 17 is supplied to the switch 16, the still image level adjustment unit 17 and the drive unit 5 are connected via the switch 16.

  In the normal operation mode, the video signal processing unit 1 outputs the video data 53 to the driving unit 5. The drive unit 5 drives the display device body 6 so that the video data 53 is displayed. The viewer can view the video data 53 displayed on the display device body 6.

  In the level adjustment operation mode, the video signal processing unit 1 outputs the video data 53 to the still image region detection unit 3 and outputs the video data 53 to the drive unit 5 via the switch 16. The still image area detection unit 3 checks whether the video data 53 includes still image data. Note that image data refers to data corresponding to an image for one screen or a part thereof, and video data refers to data corresponding to a plurality of temporally continuous screens. In other words, the video data is a collection of a plurality of pieces of image data, and is data representing a moving image.

  When the video data 53 does not include still image data, a signal for connecting the still image region detection unit 3 and the drive unit 5 is supplied to the switch 4. The drive unit 5 drives the display device body 6 so that the video data 53 is displayed. The viewer can view the video data 53 (moving image data) displayed on the display device body 6.

  When the video data 53 includes still image data, the still image area detection unit 3 outputs the video data 53 to the still image level adjustment unit 17 via the switch 4. When outputting the video data 53, the still image level adjustment unit 17 supplies a signal for connecting the still image level adjustment unit 17 and the drive unit 5 to the switch 16. As will be described later, the still image level adjustment unit 17 adjusts the level of image data in an area including a pixel pair in which a difference in level of the image data is large between adjacent pixel pairs in the still image data included in the video data 53. Then, the video data 53 is output to the drive unit 5 via the switch 16. When the display device main body 6 is a color display device and each pixel of the display device main body 6 is composed of a plurality of sub-pixels having different colors, the still image level adjusting unit 17 is arranged between the sub-pixels of the same color. The level difference of the image data is calculated. The drive unit 5 drives the display device body 6 so that the video data 53 is displayed. The viewer can view the video data 53 (still image data, moving image data) displayed on the display device body 6.

  When video data 53 including still image data is displayed on the display device main body 6, a specific portion (still image region) of the display device main body 6 on which the still image data is displayed is consumed, and a consumed trace remains in the still image region. The phenomenon may occur. That is, image sticking occurs. According to the display device 10 of the present embodiment, when the video data 53 includes still image data, it is possible to reduce burn-in by adjusting the level of the still image data. By reducing the burn-in, the life of the display device body 6 (display device 10) can be made longer than that of the conventional device.

  The still image level adjustment unit 17 includes a detection unit 7 and a level adjustment unit 13. The level adjustment unit 13 includes a first noise generation unit 14 and a CPU 15 described later. The detection unit 7 calculates the level difference C between the image data of adjacent pixel pairs from the still image data included in the video data 53, and checks whether the level difference C exceeds a preset set level difference. It is. The detection unit 7 outputs a control signal based on the level difference C to the level adjustment unit 13.

  When the level difference C is equal to or less than the set level difference, the detection unit 7 controls the switch 16 so that the video data 53 output from the video signal processing unit 1 is output to the drive unit 5. On the other hand, when the level difference C exceeds the set level difference, the level adjustment unit 13 adjusts the image data level of each pixel in the still image area based on the level difference C, and the video data 53 via the switch 16. Is output to the drive unit 5.

  If the level difference C exceeds the set level difference, burn-in may occur. According to the display device 10 of the present embodiment, when the level difference C exceeds the set level difference, the burn-in is performed by adjusting the image data level of the adjacent pixels of each pixel of the still image data included in the video data 53. Can be reduced.

  FIG. 2 is a graph showing the spatial distribution of image data levels in this embodiment, with the position on the horizontal axis and the level of image data on the vertical axis. The still image level adjustment unit 17 in the display device 10 will be described in detail with reference to FIGS. The detection unit 7 of the still image level adjustment unit 17 includes an HPF (High Pass Filter) 9 and a coring 11. The video data 53 from the still image area detection unit 3 is passed through the HPF 9. The HPF 9 calculates the level difference C between adjacent pixel pairs from the still image data included in the video data 53 and outputs it to the coring 11 together with the position information of this pixel pair. At this time, among a pair of pixels adjacent to each other, a pixel having a high level value of image data, that is, a level value of image data in a relatively bright pixel is A, and a pixel having a low level value of image data, When the level value of image data in a relatively dark pixel is B, the level difference C between the pair of pixels is represented by C = A−B.

  When the display device 10 is a color display device and each pixel of the display device body 6 is composed of three RGB sub-pixels, the level difference C is obtained between the sub-pixels of the same color. That is, the level difference between the image data level of, for example, the red sub-pixel of one pixel and the image data level of, for example, the red sub-pixel of the other pixel, of the pair of adjacent pixels described above. calculate. Similarly, in other parts of the present embodiment and other embodiments described later, the processing of image data is performed using sub-pixels as a basic unit. However, in the following description, in order to simplify the description, only “ It may be referred to as “pixel image data”.

  The coring 11 compares the above-described level difference C of the pixel pair with a preset set level difference, and detects a pair of pixels whose level difference C exceeds the set level difference as the edge portion 60. The first pixel having a level value A among the pair of pixels constituting the edge portion 60 and the second pixel having a level value B of the pair of pixels constituting the edge portion 60 A predetermined number of pixels continuously arranged in a direction away from the first pixel group 51, and the predetermined number of pixels including the second pixel and continuously arranged in a direction away from the first pixel. The second pixel group 52 is assumed. Then, this detection result, that is, a control signal based on the level difference C and the positional information of the first pixel group 51 and the second pixel group 52 is output to the level adjustment unit 13.

  Based on the level difference C, the level adjustment unit 13 adjusts image data levels of pixels belonging to the first pixel group 51 and the second pixel group 52 (hereinafter collectively referred to as a pixel group). Thereafter, the adjusted video data 53 is output to the drive unit 5 via the switch 16.

  The burn-in tends to be conspicuous in the edge portion 60 that is a pixel pair adjacent to each other across the boundary between the first pixel group 51 and the second pixel group 52 of the still image data included in the video data 53 and in the vicinity of the edge portion 60. According to the display device 10 of the present invention, when the level difference C exceeds the set level difference, the edge portion 60 that is an adjacent pixel across the boundary between the first pixel group 51 and the second pixel group 52 of the still image data, And it can make it inconspicuous by adjusting the level of the image data in the vicinity of the edge portion 60.

  The adjustment signal 63 is supplied to the CPU 15 by an instruction from the viewer (operation switch, operation of the remote terminal). In response to the adjustment signal 63, the CPU 15 outputs a control signal 66 to an adjustment unit (described later) of the level adjustment unit 13. The adjustment unit of the level adjustment unit 13 generates an adjustment value for adjusting the level difference C according to the control signal 66. Here, the adjustment value is represented by (α × C), where α represents a random coefficient (adjustment coefficient) and is a positive number satisfying 0 ≦ α ≦ 1. Based on the adjustment value (α × C), the adjustment unit (described later) of the level adjustment unit 13 includes an edge portion 60 that is an adjacent pixel across the boundary between the first pixel group 51 and the second pixel group 52, and The level of the image data in the vicinity of the edge portion 60 is adjusted, and the video data 53 is output to the drive unit 5 via the switch 16. In the arrangement direction of the pixel pairs constituting the edge portion 60, the length of the first pixel group 51 is L1, and the length of the second pixel group 52 is L2. Also, let L be the width of the entire pixel group. L = L1 + L2.

  The adjustment unit of the level adjustment unit 13 includes a first noise generation unit 14. Since the first noise generating unit 14 needs the level values A and B of the original image data in addition to the level difference C when adjusting the level of the pixel group, the video signal from the video signal processing unit 1 is necessary. 53 is entered. The first noise generator 14 generates an adjustment value (α × C) by multiplying the level difference C by a random coefficient α according to the control signal 66, and the spatial width is a predetermined width L (L1 + L2). Noise 70 whose intensity is an adjustment value (α × C) is generated. The first noise generation unit 14 adds noise 70 to the pixel group, that is, the edge portion 60 that is an adjacent pixel across the boundary between the first pixel group 51 and the second pixel group 52, and the vicinity of the edge portion 60. To do. At this time, the first noise generating unit 14 adjusts the level of the image data of the first pixel group 51 and the level of the image data of the second pixel group 52 based on the adjustment value (α × C).

  Here, as described above, it is assumed that the first level value A representing the level of the image data of the first pixel group 51 is higher than the second level value B representing the level of the image data of the second pixel group 52. In this case, when the first noise generation unit 14 adjusts the level of the image data of the first pixel group 51, the first noise generation unit 14 adjusts the adjustment value (α × C) to the first level value A that represents the level of the image data of the first pixel group 51. ) Is subtracted to generate the first adjustment level value (A−α × C). Further, when the first noise generation unit 14 adjusts the level of the image data of the second pixel group 52, the first noise generation unit 14 adjusts the adjustment value (α × C) to the second level value B representing the level of the image data of the second pixel group 52. Are added to generate a second adjustment level value (B + α × C). Thereby, the first noise generating unit 14 adjusts the levels of the image data of the first pixel group 51 and the second pixel group 52. Thereby, it is possible to prevent image sticking from occurring in the pixel group including the edge portion 60.

  However, by adjusting the level of the still image data included in the video data 53, the adjusted still image data may be recognized by the viewer as having deteriorated image quality compared to the moving image. There is sex. Therefore, the viewer can adjust the predetermined width L (L1 + L2) that gives noise.

  The CPU 15 is supplied with any of the adjustment signal 63, the short distance adjustment signal 64, and the long distance adjustment signal 65 according to an instruction from the viewer (operation switch, operation of the remote terminal).

  When the adjustment signal 63 is supplied to the CPU 15, the CPU 15 outputs a control signal 66 to the first noise generator 14 in accordance with the adjustment signal 63. In response to the control signal 66, the first noise generator 14 generates noise 70 having a spatial width equal to the predetermined width L (L1 + L2) and the image data level equal to the adjustment value (α × C). Occur.

  When the short distance adjustment signal 64 is supplied to the CPU 15, the CPU 15 outputs a short distance control signal 67 to the first noise generator 14 in accordance with the short distance adjustment signal 64. In response to the short distance control signal 67, the first noise generation unit 14 has a first predetermined width La (L1a + L2a) whose spatial width is smaller than the above-described predetermined width L (L1 + L2) (example: La = 0.8 ×). L), and the level of the image data is the noise 70 having the adjustment value (α × C) described above.

  When the long distance adjustment signal 65 is supplied to the CPU 15, the CPU 15 outputs a long distance control signal 68 to the first noise generator 14 according to the long distance adjustment signal 65. In response to the long-distance control signal 68, the first noise generator 14 has a second predetermined width Lb (L1b + L2b) whose spatial width is larger than the above-described predetermined width L (L1 + L2) (example: Lb = 1.2 ×). L), and the level of the image data is the noise 70 having the adjustment value (α × C) described above.

  In this way, by controlling the width for adjusting the image data level, it is possible to minimize deterioration in image quality viewed from the viewer.

  In the display device 10, for example, in order for the still image region detection unit 3 to detect a still image region, it is necessary to investigate video data for a certain time, and accordingly, a certain time is required. Further, a certain time is required for the detection unit 7 to detect the edge portion, and a certain time is also required for the first noise generation unit 14 to add noise to the image data. Accordingly, the image data that has passed through these circuits is delayed as compared with the image data that bypasses these circuits. For this reason, the display device 10 is provided with delay circuits (not shown) for adjusting the timing of the image data at various places. For example, a delay circuit is provided between a node between the switch 2 and the still image area detection unit 3 and the first noise generation unit 14 and between the node and the switch 16. The delay circuit is composed of, for example, a buffer memory or a relay.

  An operation of the display device 10 according to the present embodiment will be described. The display device 10 executes (I) mode setting processing, (II) normal operation mode, (III) level adjustment operation mode by the CPU 15, and (IV) level adjustment operation mode.

  FIG. 3 is a flowchart showing (I) mode setting processing as the operation of the display device 10 according to the present embodiment.

  The viewer turns on the power to the display device 10 using the operation switch or the remote terminal (the power source of the display device 10, the power source of the television connected to the display device 10, and the power source of the computer connected to the display device 10). In this case, the level adjustment operation setting signal 61 is supplied to the CPU 15 from the operation switch or the remote terminal. Further, when the viewer supplies the level adjustment operation setting signal 61 to the display device 10 that is executing the (II) normal operation mode using the operation switch or the remote terminal, the level adjustment operation setting signal is sent to the CPU 15. 61 is supplied. In response to the level adjustment operation setting signal 61, the CPU 15 controls the switch 2 so that the video signal processing unit 1 and the still image region detection unit 3 are connected (step S1-YES). When the video signal processing unit 1 and the still image region detection unit 3 are connected, the display device 10 executes (IV) level adjustment operation mode (step S2).

  On the other hand, when the viewer supplies the normal operation setting signal 62 to the display device 10 executing the (IV) level adjustment operation mode using the operation switch or the remote terminal, the CPU 15 causes the normal operation setting signal 62 to be supplied. Accordingly, the switch 2 is controlled so that the video signal processing unit 1 and the drive unit 5 are connected (steps S1-NO, S3). When the video signal processing unit 1 and the drive unit 5 are connected, the display device 10 executes (II) normal operation mode (step S4).

  FIG. 4 is a flowchart showing (II) normal operation mode as the operation of the display device 10 of the present invention.

  The video signal processing unit 1 converts the video signal 100 from the outside (television decoder, computer) into video data 53 suitable for the drive unit 5 to drive the display device body 6 (video data conversion process; Step S5). The video data 53 converted to the video signal processing unit 1 is output to the driving unit 5. The drive unit 5 drives the display device body 6 so that the video data 53 is displayed (display processing; step S6). The video data 53 displayed on the display device body 6 is visually recognized by the viewer.

  FIG. 5 is a flowchart showing (III) level adjustment operation mode by the CPU 15 as the operation of the display device 10 of the present invention.

  When the viewer supplies the adjustment signal 63 to the display device 10 using the operation switch or the remote terminal, the adjustment signal 63 is supplied to the CPU 15 (YES in step S11). The CPU 15 outputs a control signal 66 to the first noise generator 14 in response to the adjustment signal 63 (step S12). The first noise generator 14 generates noise 70 having the above-described predetermined width L (L1 + L2) and the above-described adjustment value α × C in response to a control signal 66 from the CPU 15.

  When the viewer supplies the short distance adjustment signal 64 to the display device 10 using the operation switch or the remote terminal, the short distance adjustment signal 64 is supplied to the CPU 15 (steps S11-NO and S13-YES). In response to the short distance adjustment signal 64, the CPU 15 outputs a short distance control signal 67 to the first noise generator 14 (step S14). The first noise generating unit 14 has the above-described first predetermined width La (L1a + L2a) (La = 0.8 × L) and the above-described adjustment value α × C according to the short distance control signal 67 from the CPU 15. Noise 70 is generated.

  When the viewer supplies the long distance adjustment signal 65 to the display device 10 using the operation switch or the remote terminal, the long distance adjustment signal 65 is supplied to the CPU 15 (steps S11-NO, S13-NO, S15). ). In response to the long distance adjustment signal 65, the CPU 15 outputs a long distance control signal 68 to the first noise generator 14 (step S16). The first noise generation unit 14 has the above-described second predetermined width Lb (L1b + L2b) (Lb = 1.2 × L) and the above-described adjustment value α × C according to the long distance control signal 68 from the CPU 15. Noise 70 is generated.

  FIG. 6 is a flowchart showing the (IV) level adjustment operation mode as the operation of the display device 10 of the present invention.

  The video signal processing unit 1 executes the above-described video data conversion process (step S5). The video data 53 converted to the video signal processing unit 1 is output to the still image region detection unit 3. The still image area detection unit 3 checks whether still image data is included in the video data 53 (step S21).

  When the video data 53 does not include still image data, a signal for connecting the still image area detection unit 3 and the drive unit 5 is supplied to the switch 4, and the video data 53 is driven via the switch 4 and the switch 16. It outputs to the part 5 (step S21-NO). The drive unit 5 performs the above-described display process (step S6). The video data 53 displayed on the display device body 6 is visually recognized by the viewer.

  When the video data 53 includes still image data, the still image area detection unit 3 outputs the video data 53 to the detection unit 7 in the still image level adjustment unit 17 via the switch 4 (step S21—YES). When the video data 53 is input, the detection unit 7 supplies a signal for connecting the still image level adjustment unit 17 and the drive unit 5 to the switch 16. Video data 53 from the still image area detection unit 3 is passed through the HPF 9 in the detection unit 7. The HPF 9 in the detection unit 7 calculates the level difference C between the image data of adjacent pixel pairs in the still image data included in the video data 53 and outputs the level difference C to the coring 11 in the detection unit 7 (level difference calculation processing; Step S22).

  The coring 11 switches so that the video data 53 output from the video signal processing unit 1 is output to the drive unit 5 when the level difference C is equal to or less than the set level difference in all pixel pairs in the still image region. 16 is controlled (step S23-NO). The drive unit 5 drives the display device body 6 so that the video data 53 is displayed as the above-described display process (step S6). The video data 53 displayed on the display device body 6 is visually recognized by the viewer.

  When the level difference C of the image data of any pixel pair exceeds the set level difference (step S23-YES), the coring 11 detects this pixel pair as the edge portion 60, and detects the level difference C and the first pixel group. A control signal based on the position information of 51 and the second pixel group 52 is output to the first noise generation unit 14 in the level adjustment unit 13 (edge portion detection process; step S24). After the edge portion detection process (step S24) is executed, the first noise generation unit 14 executes a first noise addition process (step S25).

  When the control signal 66 is supplied from the CPU 15 to the first noise generation unit 14, in the first noise addition process (step S25), the first noise generation unit 14 has the spatial width described above according to the control signal 66. Noise 70 having a predetermined width L (L1 + L2) and an intensity of the adjustment value (α × C) is generated. That is, the first noise generating unit 14 adds the noise 70 to the pixel group (the first pixel group 51 and the second pixel group 52) having a width L. At this time, the first noise generating unit 14 subtracts the adjustment value (α × C) from the level value A of the first pixel group 51 to generate a first adjustment level value (A−α × C), and the second An adjustment value (α × C) is added to the level value B of the pixel group 52 to generate a second adjustment level value (B + α × C). The first noise generating unit 14 sends the video data 53 in which the level of the image data of the first pixel group 51 and the level of the image data of the second pixel group 52 are adjusted to the driving unit 5 via the switch 16. Output. The drive unit 5 performs the above-described display process (step S6). The video data 53 displayed on the display device body 6 is visually recognized by the viewer.

  When the short distance control signal 67 is supplied from the CPU 15 to the first noise generation unit 14, the first noise generation unit 14 performs spatial processing according to the short distance control signal 67 in the first noise addition process (step S <b> 25). Noise 70 having a width of the first predetermined width La (L1a + L2a) (La = 0.8 × L) and an intensity of the adjustment value (α × C) is generated. In this case, the first noise generation unit 14 adds noise 70 to the edge portion 60 that is an adjacent pixel across the boundary between the first pixel group 51 and the second pixel group 52 and to the vicinity of the edge portion 60. At this time, the first noise generating unit 14 subtracts the adjustment value (α × C) from the level value A of the first pixel group 51 to generate a first adjustment level value (A−α × C), and the second An adjustment value (α × C) is added to the level value B of the pixel group 52 to generate a second adjustment level value (B + α × C). The first noise generating unit 14 sends the video data 53 in which the level of the image data of the first pixel group 51 and the level of the image data of the second pixel group 52 are adjusted to the driving unit 5 via the switch 16. Output. The drive unit 5 performs the above-described display process (step S6). The video data 53 displayed on the display device body 6 is visually recognized by the viewer.

  When the long-distance control signal 68 is supplied from the CPU 15 to the first noise generation unit 14, the first noise generation unit 14 performs spatial processing according to the long-distance control signal 68 in the first noise addition process (step S 25). Noise 70 having a width of the above-mentioned second predetermined width Lb (L1b + L2b) (Lb = 1.2 × L) and an intensity of the above-described adjustment value (α × C) is generated. The first noise generator 14 adds noise 70 to the edge portion 60 that is adjacent to the boundary between the first pixel group 51 and the second pixel group 52 and to the vicinity of the edge portion 60. At this time, the first noise generating unit 14 subtracts the adjustment value (α × C) from the level value A of the first pixel group 51 to generate a first adjustment level value (A−α × C), and the second An adjustment value (α × C) is added to the level value B of the pixel group 52 to generate a second adjustment level value (B + α × C). The first noise generating unit 14 sends the video data 53 in which the level of the image data of the first pixel group 51 and the level of the image data of the second pixel group 52 are adjusted to the driving unit 5 via the switch 16. Output. The drive unit 5 performs the above-described display process (step S6). The video data 53 displayed on the display device body 6 is visually recognized by the viewer.

  As described above, according to the display device 10 according to the present embodiment, by generating the noise 70 having the predetermined width L and the adjustment value α × C using the first noise generation unit 14, the video data 53 is generated. The level of the image data of the first pixel group 51 and the second pixel group 52 of the still image data included is adjusted. As a result, burn-in can be reduced (not noticeable), and deterioration of the image quality of the display device body 6 can be prevented.

  Moreover, according to the display apparatus 10 which concerns on this embodiment, the lifetime of the display apparatus main body 6 (display apparatus 10) can be made longer than that of the past by reducing burn-in.

(Second Embodiment)
Next, a second embodiment of the present invention will be described. 7 is a block diagram showing the configuration of the display device 20 according to the second embodiment of the present invention, and FIG. 8 is a view seen from the front side (viewer side) showing the display device body 6. FIG. (A) And (b) is a figure which shows the character pattern displayed on the display apparatus main body 6. FIG. In the display device 20, the same description as that of the display device 10 is omitted.

  The display device 20 further includes a distance measuring unit 22 with respect to the configuration of the display device 10. The distance measuring unit 22 measures a distance 69 between the display device body 6 and the viewer and outputs the distance 69 to the CPU 15 in the level adjusting unit 13.

  The level adjustment unit 13 further includes a still image pattern thickness detection unit 21 with respect to the configuration of the level adjustment unit 13 of the display device 10. The coring 11 outputs the video data 53 to the still image pattern thickness detector 21 when the level difference C of the image data exceeds the set level difference. The still image pattern thickness detection unit 21 includes, for each color, a pixel to which a sub-pixel having a relatively high image data level belongs, that is, a pixel belonging to the first pixel group 51 among the pixel pairs constituting the edge portion 60. , A pixel to which a sub pixel having a relatively low image data level belongs, that is, a plurality of pixels continuously arranged in a direction away from the pixels belonging to the second pixel group 52, and the image data level of the sub pixel is The number of pixels higher than the set value is detected as the length of the high level region, or the pixels belonging to the second pixel group 52 are included in the pixel pairs constituting the edge portion 60, and the first pixel group 51 A plurality of pixels arranged continuously in a direction away from the pixel to which the pixel belongs, and the number of pixels whose image data level of the sub-pixel is lower than a set value is It is used to detect and Satoshi. The still image pattern thickness detection unit 21 detects the image pattern formed by each pixel of the still image data included in the video data 53 in this way, and outputs an image pattern value representing the thickness of the image pattern to the CPU 15. .

  In the display device 20, for example, ultrasonic waves are used to measure the distance 69 between the display device body 6 and the viewer. As shown in FIG. 7, the distance measuring unit 22 includes an ultrasonic transmitter 23, an ultrasonic detector 24, and a measuring device 25. The ultrasonic transmitter 23 and the ultrasonic detector 24 are provided in front of the display device body 6 (see FIG. 8). The ultrasonic transmitter 23 oscillates the ultrasonic wave 75 toward the viewer existing in front of the display device body 6. The ultrasonic detector 24 detects a reflected wave 76 representing the ultrasonic wave 75 reflected by the viewer existing in front of the display device body 6. The measuring device 25 determines the distance between the display device body 6 and the viewer based on the time from when the ultrasonic wave 75 is oscillated by the ultrasonic wave transmitter 23 until the reflected wave 76 is detected by the ultrasonic wave detector 24. 69 is measured and output to the CPU 15.

  The viewer can recognize the details of the picture displayed on the screen 6 ′ of the display device body 6 as the display device body 6 is closer, but at the same time, the visual sensitivity to the noise 70 increases. . As a result, on the display device 10, the viewer may appear as if the image quality in the vicinity of the edge portion 60 and the edge portion 60 is deteriorated.

  Therefore, in the display device 20, if the distance 69 between the viewer and the display device body 6 is short, the width of the noise 70 is narrowed {the predetermined width L (L1 + L2) is set to the first predetermined width La (L1a + L2a)}. If the distance 69 from the display device body 6 is large, the width of the noise 70 is increased {the predetermined width L (L1 + L2) is set to the second predetermined width Lb (L1b + L2b)}. Thereby, in the display device 20, the viewer does not recognize that the edge portion 60 and the image quality in the vicinity of the edge portion 60 have deteriorated.

  However, in the display device 10, when the first noise generating unit 14 adds the noise 70 having the same width {predetermined width L (L1 + L2), adjustment value (α × C)} in the vicinity of the edge portion 60 and the edge portion 60, As the thickness of the image pattern of the still image data is smaller, the viewer may have difficulty in recognizing the image pattern due to the noise 70. Therefore, when the thickness of the image pattern 54 of the still image data is small, the noise width is reduced. In this case, even if the distance 69 from the display device body 6 is long, the noise width is not widened and is kept constant. When the thickness of the image pattern 54 of the still image data is large, the width of the noise is controlled according to the distance 69 from the display device body 6.

  As shown in FIG. 9A, in the display device 20, if the thickness of the image pattern 54 of the still image data is small, the width {predetermined width L (L1 + L2)} of the noise 70 is reduced and the first predetermined width is obtained. By generating noise 71 having La (L1a + L2a) and an adjustment value (α × C), the viewer does not recognize that the image quality of the edge portion 60 and the vicinity of the edge portion 60 has deteriorated. Thus, in the display device 20, when the thickness of the image pattern 54 of the still image data is small, the width of the noise 70 is determined by the thickness of the image pattern 54 of the still image data.

  As shown in FIG. 9B, in the display device 20, if the thickness of the image pattern 55 of the still image data is large, the width of the noise 70 {predetermined width L (L1 + L2)} is the viewer and the display device body 6. The width of the noise is controlled according to the distance between the two.

  The operation of the display device 20 of the present invention will be described. The display device 20 includes (I) mode setting process, (II) normal operation mode, (III-1) level adjustment operation mode by the distance measurement unit 22, (III-2) level adjustment operation mode by the CPU 15, and (IV) level. Execute the adjustment operation mode. The (I) mode setting process of the display device 20 is the same as the (I) mode setting process of the display device 10, and the (II) normal operation mode of the display device 20 is the same as the (II) normal operation mode of the display device 10. The same.

  FIG. 10 is a flowchart showing (III-1) level adjustment operation mode by the distance measuring unit 22 as the operation of the display device 20 of the present invention.

  The viewer turns on the power to the display device 20 using the operation switch or the remote terminal (the power source of the display device 20, the power source of the television connected to the display device 20, and the power source of the computer connected to the display device 20). To do. In this case, the ultrasonic transmitter 23 oscillates the ultrasonic wave 75 toward the viewer existing in front of the display device body 6 (step S31). The ultrasonic wave 75 oscillated from the ultrasonic transmitter 23 is reflected by a viewer present in front of the display device body 6. The ultrasonic detector 24 detects the reflected wave 76 reflected by the viewer (step S32).

  The measuring device 25 counts the time from when the ultrasonic wave 75 is oscillated by the ultrasonic wave transmitter 23 until the reflected wave 76 is detected by the ultrasonic wave detector 24. The measuring device 25 measures the distance 69 between the display device body 6 and the viewer based on the count value (step S33), and outputs the distance 69 as data to the CPU 15 (step S34).

  FIG. 11 is a flowchart showing (III-2) level adjustment operation mode by the CPU 15 as the operation of the display device 20 of the present invention. Based on the image pattern value from the still image pattern thickness detection unit 21, the CPU 15 determines whether the image pattern thickness (image pattern value) of the still image data is less than a certain value (set image pattern value). (Step S41).

  When the image pattern thickness of the still image data is less than a certain value (step S41—YES), the CPU 15 generates the short distance control signal 67 based on the image pattern value from the still image pattern thickness detection unit 21. It outputs to the 1st noise generation part 14 (step S42). In this case, the first noise generating unit 14 generates the noise 70 having the above-mentioned first predetermined width La (L1a + L2a) and the above-described adjustment value (α × C) in response to the short distance control signal 67 from the CPU 15. To do.

  When the thickness of the image pattern of the still image data is equal to or larger than a certain value (step S41—NO), the CPU 15 checks whether or not the distance 69 from the measuring instrument 25 is a set distance (set distance range) ( Step S47).

  As a result, when the distance 69 is the set distance (step S47—YES), the CPU 15 outputs a control signal 66 to the first noise generator 14 based on the distance 69 (step S48). In this case, the first noise generation unit 14 generates noise 70 having the first predetermined width L (L1 + L2) and the adjustment value (α × C) in accordance with the control signal 66 from the CPU 15.

  If the distance 69 is shorter than the set distance (steps S47-NO, S43-YES), the CPU 15 outputs a short distance control signal 67 to the first noise generating unit 14 based on the distance 69 from the measuring instrument 25. (Step S44). In this case, the first noise generating unit 14 generates the noise 70 having the above-mentioned first predetermined width La (L1a + L2a) and the above-described adjustment value (α × C) in response to the short distance control signal 67 from the CPU 15. To do.

  Further, when the distance 69 is longer than the set distance (steps S47-NO, S43-NO, S45), the CPU 15 sends the long-distance control signal 68 to the first noise generator 14 based on the distance 69 from the measuring instrument 25. (Step S46). The first noise generating unit 14 generates noise 70 having the above-described second predetermined width Lb (L1b + L2b) and the above-described adjustment value (α × C) in response to the long distance control signal 68 from the CPU 15.

  FIG. 12 is a flowchart showing the (IV) level adjustment operation mode as the operation of the display device 20 of the present invention.

  (IV) In the level adjustment operation mode, the display device 20 executes the same steps S5 (video data conversion processing), S21, and S22 (level difference calculation processing) as the display device 10.

  When the level difference C of the image data is equal to or smaller than the set level difference, the coring 11 controls the switch 16 so that the video data 53 is output to the drive unit 5 (step S23—NO). The drive unit 5 executes the same display process (step S6) as the display device 10. The video data 53 displayed on the display device body 6 is visually recognized by the viewer.

  When the level difference C of the image data exceeds the set level difference, the coring 11 outputs a control signal based on the level difference C and the position information of the pixel group to the first noise generating unit 14 and the video data 53 as a still image. It outputs to the pattern thickness detection part 21 (step S23-YES). The still image pattern thickness detection unit 21 detects an image pattern formed by each pixel of still image data included in the video data 53 and outputs an image pattern value to the CPU 15 (still image pattern thickness detection processing; step S51). ).

  After the edge part detection process (step S24) and the still image pattern thickness detection process (step S51) are executed, the first noise generation unit 14 executes the same first noise addition process (step S25) as that of the display device 10. Then, the drive unit 5 performs the same display process (step S6) as the display device 10. The video data 53 displayed on the display device body 6 is visually recognized by the viewer.

  As described above, according to the display device 20 of the present invention, in addition to the effect of the display device 10, the viewer does not recognize that the image quality of the edge portion 60 and the vicinity of the edge portion 60 has deteriorated. When the distance between the display device body 6 and the user (viewer) is shorter than the set distance, the visual sensitivity of the viewer is increased. For this reason, in the display device 10 according to the first embodiment described above, the viewer can degrade the image quality of the first pixel group 51 and the second pixel group 52 of the still image data included in the video data 53 due to the addition of noise. There is a possibility that it will appear. On the other hand, when the distance between the display device main body 6 and the user (viewer) is longer than the set distance, the visual sensitivity of the viewer decreases. For this reason, in the display device 10 described above, the viewer may have difficulty in recognizing the image pattern of the still image data included in the video data 53. According to the display device 20 of the present invention, the predetermined width L (L1 + L2) is adjusted according to the distance between the display device body 6 and the user (viewer) and the thickness of the image pattern of the still image data. Thus, according to the display device 20 of the present invention, the viewer does not recognize that the edge portion 60 and the image quality in the vicinity of the edge portion 60 have deteriorated.

(Third embodiment)
Next, a third embodiment of the present invention will be described. FIG. 13 is a block diagram showing a configuration of the display device 30 according to the third embodiment of the present invention. FIG. 14 shows image data in which the horizontal axis indicates the position on the screen and the vertical axis indicates the level of the image data. FIG. 15 is a graph showing the probability distribution of the random coefficient α, with the random coefficient α on the horizontal axis and the probability on the vertical axis. In the display device 30, the same description as that of the display device 10 is omitted.

  The display device 30 will be described with reference to FIGS. 13, 14, and 15. In the display devices 10 and 20, the probability distribution with respect to the value of the random coefficient α is uniform regardless of the position (pixel). In the display device 30, different probability distributions are prepared depending on the position (pixel) for the value of the random coefficient α. For example, as a technique using a probability distribution, as shown in FIG. 14, a random coefficient α is set to 0 to 0.1 at a position a (position f) within a predetermined width L1 (L2) away from the edge portion 60. A value between them (see FIG. 15) is set in the noise generation unit 31 described later. At a position b (position e) within a predetermined width L1 (L2) between the edge portion 60 and the position a (position f), a value between 0 and 0.5 (see FIG. 15) will be described later as the random coefficient α. The noise generator 31 is set in advance. At a position c (position d) which is the edge portion 60, a value between 0 and 1 (see FIG. 15) is set as a random coefficient α in the noise generator 31 described later.

  By using this method, the random coefficient α is in the range of 0 to 0.1 at the position a (position f), and the random coefficient α is in the range of 0 to 0.5 at the position b (position e). When the image data level of the predetermined width L is time-averaged when the random coefficient α is in the range from 0 to 1 at the position c (position d), as shown in FIG. The position change of the image data level in the second pixel group 52 becomes gradual. As a result, according to the display device 30 according to the present embodiment, compared with the display devices 10 and 20 according to the first and second embodiments described above, still image data having the same image pattern for a long time is displayed on the display device main body. Even when the image is displayed in FIG. 6, burn-in can be more reliably prevented.

  As illustrated in FIG. 13, the adjustment unit of the level adjustment unit 13 includes a second noise generation unit 31 instead of the first noise generation unit 14 in the display device 10. Since the second noise generating unit 31 needs the original level values A and B in addition to the level difference C when adjusting the image data levels in the first pixel group 51 and the second pixel group 52, the image data The video signal 53 from the signal processing unit 1 is input.

  The second noise generator 31 determines a predetermined width L (L1 + L2) and an adjustment value (α × C) according to the control signal 66. The adjustment value (α × C) determined by the second noise generation unit 31 is the adjustment value (α × C) of the first position in the predetermined width L (L1 + L2) of the first pixel group 51 and the second pixel group 52. ) Representing the first distribution adjustment value (α1 × C), and the adjustment value (α × 2) of the second position that is the edge portion 60 that is an adjacent pixel across the boundary between the first pixel group 51 and the second pixel group 52. And a second distribution adjustment value (α2 × C) representing C). The first position includes the positions a, b, e, and f. When the first position is the position a (position f), the random coefficient α1 is in the range of 0 to 0.1, and when the first position is the position b (position e), the random coefficient α1 is 0 to 0. Within the range of .5. The second position is position c (position d), and the random coefficient α2 is in the range of 0 to 1.

  As described above, the first level value A representing the image data level of the first pixel group 51 is higher than the second level value B representing the image data level of the second pixel group 52. In this case, when the second noise generating unit 31 adjusts the image data level of the position a of the first pixel group 51, the first distribution adjustment is performed to the first level value A that represents the level of the position a of the first pixel group 51. The first distribution adjustment level value (A−α1 × C) is generated by subtracting the value (α1 × C) (α1 = 0 to 0.1). When the second noise generating unit 31 adjusts the image data level at the position b of the first pixel group 51, the first distribution adjustment value is set to the first level value A representing the image data level at the position b of the first pixel group 51. The first distribution adjustment level value (A−α1 × C) is generated by subtracting (α1 × C) (α1 = 0 to 0.5). When the second noise generating unit 31 adjusts the image data level of the position c that is the edge portion 60 of the first pixel group 51, the second noise generating unit 31 sets the first level value A that represents the image data level of the position c of the first pixel group 51. The second distribution adjustment value (α2 × C) (α2 = 0 to 1) is subtracted to generate a second distribution adjustment level value (A−α2 × C). When the second noise generating unit 31 adjusts the image data level at the position d which is the edge portion 60 of the second pixel group 52, the second noise generating unit 31 sets the second level value B representing the image data level at the position d of the second pixel group 52. The second distribution adjustment value (α2 × C) (α2 = 0 to 1) is added to generate a third distribution adjustment level value (B + α2 × C). When the second noise generation unit 31 adjusts the image data level at the position e of the second pixel group 52, the second noise generation unit 31 sets the first distribution adjustment value to the second level value B representing the image data level at the position e of the second pixel group 52. (Α1 × C) (α1 = 0 to 0.5) is added to generate a fourth distribution adjustment level value (B + α1 × C). When the second noise generating unit 31 adjusts the image data level at the position f of the second pixel group 52, the second noise generation unit 31 sets the first distribution adjustment value to the second level value B representing the image data level at the position f of the second pixel group 52. (Α1 × C) (α1 = 0 to 0.1) is added to generate a fourth distribution adjustment level value (B + α1 × C). Thereby, the second noise generating unit 31 adjusts the image data levels of the first pixel group 51 and the second pixel group 52.

  The operation of the display device 30 of the present invention will be described. The display device 30 executes (I) mode setting processing, (II) normal operation mode, (III) level adjustment operation mode by the CPU 15, and (IV) level adjustment operation mode. The (I) mode setting process of the display device 30 is the same as the (I) mode setting process of the display device 10, and the (II) normal operation mode of the display device 30 is the same as the (II) normal operation mode of the display device 10. The same.

  FIG. 16 is a flowchart showing (III) level adjustment operation mode by the CPU 15 as the operation of the display device 30 of the present invention. The adjustment value (α × C) and the predetermined width L (L1 + L2) can be adjusted by the viewer.

  When the viewer supplies the adjustment signal 63 to the display device 30 using the operation switch or the remote terminal, the adjustment signal 63 is supplied to the CPU 15 (YES in step S11). The CPU 15 outputs a control signal 66 to the second noise generating unit 31 according to the adjustment signal 63 (step S61). The second noise generating unit 31 determines the predetermined width L (L1 + L2) and the adjustment value (α × C) according to the control signal 66 from the CPU 15. In response to a control signal 66 from the CPU 15, the second noise generating unit 31 sets the positions a and b and the positions e and f to a first pixel group 51 having a width L 1 and a second pixel group 52 having a width L 2. To decide on.

  When the viewer supplies the short distance adjustment signal 64 to the display device 30 using the operation switch or the remote terminal, the short distance adjustment signal 64 is supplied to the CPU 15 (steps S11-NO and S13-YES). In response to the short distance adjustment signal 64, the CPU 15 outputs a short distance control signal 67 to the second noise generator 31 (step S62). The second noise generating unit 31 determines the first predetermined width La (L1a + L2a) (La = 0.8 × L) according to the short distance control signal 67 from the CPU 15. In response to the short distance control signal 67 from the CPU 15, the second noise generating unit 31 sets the positions a and b and the positions e and f to the first pixel group 51 having a width L1a and the second pixels having a width L2a. Decide within group 52. At this time, the range of the random coefficient α in each pixel is also adjusted in accordance with the positions a to f.

  When the viewer supplies the long distance adjustment signal 65 to the display device 30 using the operation switch or the remote terminal, the long distance adjustment signal 65 is supplied to the CPU 15 (steps S11-NO, S13-NO, S15). ). The CPU 15 outputs a long distance control signal 68 to the second noise generating unit 31 in response to the long distance adjustment signal 65 (step S63). The second noise generating unit 31 determines the above-described second predetermined width Lb (L1b + L2b) (Lb = 1.2 × L) according to the long distance control signal 68 from the CPU 15. In response to the long distance control signal 68 from the CPU 15, the second noise generating unit 31 sets the positions a and b and the positions e and f to a first pixel group 51 having a width L1b and a second pixel having a width L2b. Decide within group 52. At this time, the range of the random coefficient α in each pixel is also adjusted in accordance with the positions a to f.

  FIG. 17 is a flowchart showing the (IV) level adjustment operation mode as the operation of the display device 30 of the present invention. In the (IV) level adjustment operation mode, the display device 30 performs steps S5 (video data conversion processing), S21, S22 (level difference calculation processing), S23, S24 (edge) of the (IV) level adjustment operation mode of the display device 10. Part detection processing). After the edge part detection process (step S24) is executed, the second noise generation part 31 executes a level adjustment process (step S71).

  In the level adjustment process (step S71), the second noise generating unit 31 determines the predetermined width L (L1 + L2) and the adjustment value (α × C) according to the control signal 66 from the CPU 15. Yes. In this case, the second noise generation unit 31 adds the first distribution adjustment value (α1 × C) (α1 = 0 to 0.1 to the first level value A indicating the level of the image data at the position a of the first pixel group 51. ) Is generated to generate a first distribution adjustment level value (A−α1 × C), and the first distribution adjustment value (α1) is added to the first level value A representing the level of the image data at the position b of the first pixel group 51. XC) (α1 = 0 to 0.5) is subtracted to generate the first distribution adjustment level value (A−α1 × C). The second noise generating unit 31 subtracts the second distribution adjustment value (α2 × C) (α2 = 0 to 1) from the first level value A representing the level of the image data at the position c of the first pixel group 51. A second distribution adjustment level value (A−α2 × C) is generated. The second noise generator 31 adds the third distribution adjustment value (α2 × C) (α2 = 0 to 1) to the second level value B representing the level of the image data at the position d of the second pixel group 52. A third distribution adjustment level value (B + α2 × C) is generated. The second noise generator 31 adds the first distribution adjustment value (α1 × C) (α1 = 0 to 0.5) to the second level value B representing the level of the image data at the position e of the second pixel group 52. The fourth distribution adjustment level value (B + α1 × C) is generated, and the first distribution adjustment value (α1 × C) (α1) is set to the second level value B representing the level of the image data at the position f of the second pixel group 52. = 0 to 0.1) is added to generate a fourth distribution adjustment level value (B + α1 × C). The second noise generating unit 31 outputs the video data 53 in which the levels of the image data of the first pixel group 51 and the second pixel group 52 are adjusted to the driving unit 5 via the switch 16. The drive unit 5 executes the same display process (step S6) as the display device 10. The video data 53 displayed on the display device body 6 is visually recognized by the viewer.

  In the level adjustment process (step S71), the second noise generator 31 determines the first predetermined width La (L1a + L2a) (La = 0.8 × L) according to the short distance control signal 67 from the CPU 15. doing. In this case, the second noise generating unit 31 sets the first distribution adjustment value (α1 × C) (α1 = 0 to 0.1) to the first level value A representing the image data level at the position a of the first pixel group 51. Is subtracted to generate a first distribution adjustment level value (A−α1 × C), and the first distribution adjustment value (α1 × C) is added to the first level value A representing the image data level at the position b of the first pixel group 51. ) (Α1 = 0 to 0.5) is subtracted to generate the first distribution adjustment level value (A−α1 × C). The second noise generation unit 31 subtracts the second distribution adjustment value (α2 × C) (α2 = 0 to 1) from the first level value A representing the image data level at the position c of the first pixel group 51. Two distribution adjustment level values (A−α2 × C) are generated. The second noise generating unit 31 adds the second distribution adjustment value (α2 × C) (α2 = 0 to 1) to the second level value B representing the image data level at the position d of the first pixel group 51, and adds the second distribution adjustment value (α2 × C) (α2 = 0 to 1). Three distribution adjustment level values (B + α2 × C) are generated. The second noise generator 31 adds the first distribution adjustment value (α1 × C) (α1 = 0 to 0.5) to the second level value B representing the image data level at the position e of the second pixel group 52. The third distribution adjustment level value (B + α1 × C) is generated, and the first distribution adjustment value (α1 × C) (α1 = 0) is set to the second level value B representing the image data level at the position f of the second pixel group 52. ˜0.1) are added to generate a third distribution adjustment level value (B + α1 × C). The second noise generator 31 is an image in which the edge portion 60 of the first pixel group 51 and the image data level of the predetermined width L1a and the image data level of the edge portion 60 of the second pixel group 52 and the predetermined width L2a are adjusted. Data 53 is output to the drive unit 5 via the switch 16. The drive unit 5 executes the same display process (step S6) as the display device 10. The video data 53 displayed on the display device body 6 is visually recognized by the viewer.

  In the level adjustment process (step S71), the second noise generating unit 31 determines the second predetermined width Lb (L1b + L2b) (Lb = 1.2 × L) according to the long distance control signal 68 from the CPU 15. doing. The second noise generator 31 subtracts the first distribution adjustment value (α1 × C) (α1 = 0 to 0.1) from the first level value A representing the image data level at the position a of the first pixel group 51. The first distribution adjustment level value (A−α1 × C) is generated, and the first distribution adjustment value (α1 × C) (α1) is set to the first level value A representing the image data level at the position b of the first pixel group 51. = 0 to 0.5) is subtracted to generate the first distribution adjustment level value (A-α1 × C). The second noise generation unit 31 subtracts the second distribution adjustment value (α2 × C) (α2 = 0 to 1) from the first level value A representing the image data level at the position c of the first pixel group 51. Two distribution adjustment level values (A−α2 × C) are generated. The second noise generating unit 31 adds the second distribution adjustment value (α2 × C) (α2 = 0 to 1) to the second level value B representing the image data level at the position d of the first pixel group 51, and adds the second distribution adjustment value (α2 × C) (α2 = 0 to 1). Three distribution adjustment level values (B + α2 × C) are generated. The second noise generator 31 adds the first distribution adjustment value (α1 × C) (α1 = 0 to 0.5) to the second level value B representing the image data level at the position e of the second pixel group 52. The fourth distribution adjustment level value (B + α1 × C) is generated, and the first distribution adjustment value (α1 × C) (α1 = 0) is set to the second level value B representing the image data level at the position f of the second pixel group 52. ˜0.1) are added to generate the fourth distribution adjustment level value (B + α1 × C). The second noise generator 31 is an image in which the edge portion 60 of the first pixel group 51 and the image data level of the predetermined width L1b and the image data level of the edge portion 60 of the second pixel group 52 and the predetermined width L2b are adjusted. Data 53 is output to the drive unit 5 via the switch 16. The drive unit 5 executes the same display process (step S6) as the display device 10. The video data 53 displayed on the display device body 6 is visually recognized by the viewer.

  As described above, according to the display device 30 according to the present embodiment, the video data 53 is determined by determining the predetermined width L (L1 + L2) and the adjustment value (α × C) using the second noise generating unit 31. The image data levels of the first pixel group 51 and the second pixel group 52 of the still image data included in the image data are adjusted. As a result, according to the display device 30 of the present invention, it is possible to reduce burn-in (make it inconspicuous) and prevent deterioration of the image quality of the display device body 6.

  Further, according to the display device 30 of the present invention, the lifetime of the display device body 6 (display device 30) can be made longer than that of the conventional device by reducing the burn-in.

(Fourth embodiment)
Next, a fourth embodiment of the present invention will be described. FIG. 18 is a block diagram showing a configuration of a display device 40 according to the fourth embodiment of the present invention. In the display device 40, the same descriptions as those of the display devices 10, 20, and 30 are omitted.

  The level adjustment unit 13 further includes a still image pattern thickness detection unit 21, a second noise generation unit 31, and a switch 41 with respect to the configuration of the level adjustment unit 13 of the display device 10. The switch 41 is switched by a signal from the still image pattern thickness detection unit 21.

  The detection unit 7 detects pixels adjacent to each other with the boundary between the first pixel group 51 and the second pixel group 52 as the edge portion 60, and outputs the video data 53 to the still image pattern thickness detection unit 21. The still image pattern thickness detector 21 detects an image pattern formed by each pixel of still image data included in the video data 53, and generates an image pattern value representing the thickness of the image pattern. When the image pattern value is greater than or equal to the set image pattern value, the still image pattern thickness detection unit 21 outputs the video data 53 to the first noise generation unit 14, and the first noise generation unit 14 and the drive unit 5 are switched. The switch 41 is controlled so as to be connected via the switch 16. When the image pattern value is smaller than the set image pattern value, the still image pattern thickness detection unit 21 outputs the video data 53 to the second noise generation unit 31, and the second noise generation unit 31 and the drive unit 5 switch 16 The switch 41 is controlled so as to be connected via the switch.

  When the first noise generation unit 14 and the second noise generation unit 31 adjust the level of the image data in the first pixel group 51 and the second pixel group 52, in addition to the level difference C, the original level value A, Since B is necessary, the video signal 53 from the video signal processing unit 1 is input.

  In the display device 10 according to the first embodiment described above, the first noise generation unit 14 has the same probability distribution noise in the edge portion 60 and the portions other than the edge portion 60 in the first pixel group 51 and the second pixel group 52. 70, that is, noise whose level can be expressed by an adjustment value (A−αC) or an adjustment value (B + αC) is added. However, in this case, the smaller the thickness of the image pattern of the still image data, the more difficult it is for the viewer to recognize the image pattern due to the noise 70.

  Therefore, in the display device 40 according to the present embodiment, if the thickness of the image pattern of the still image data is smaller than a certain value (set image pattern value), the first noise generator 14 causes the edge portion 60 and the edge portion 60 to move. The second noise generating unit 31 adjusts the image data level in the vicinity of the edge portion 60 and the edge portion 60 without adding noise to the vicinity of the image to prevent burn-in.

  FIG. 22 is a graph showing the spatial distribution of image data levels, with the horizontal axis representing the position on the screen and the vertical axis representing the image data level. The second noise generating unit 31 will be described with reference to FIG. The second noise generating unit 31 has a function of moderating a sudden change in the position of the image data level of the edge portion 60. As a specific method, the level difference C of the edge portion 60 is multiplied by the adjustment coefficient α and subtracted from the first level value A, and added to the second level value B. Here, α is a positive number between 0 and 0.5, and is determined between positions a, b, c, d, e, and f. For example, α = 0.05 at position a (position f), α = 0.25 at position b (position e), and α = 0.5 at position c (position d). The position change of the image data level is moderated. Here, α is fixed to a constant value over time without changing randomly.

  An operation of the display device 40 according to the present embodiment will be described. The display device 40 executes (I) mode setting processing, (II) normal operation mode, (III) level adjustment operation mode by the CPU 15, and (IV) level adjustment operation mode. The (I) mode setting process of the display device 40 is the same as the (I) mode setting process of the display device 10, and the (II) normal operation mode of the display device 40 is the same as the (II) normal operation mode of the display device 10. The same.

  FIG. 19 is a flowchart showing (III) level adjustment operation mode by the CPU 15 as the operation of the display device 40 according to the present embodiment.

  When the viewer supplies the adjustment signal 63 to the display device 40 using the operation switch or the remote terminal, the adjustment signal 63 is supplied to the CPU 15 (YES in step S11). The CPU 15 outputs the control signal 66 to the first noise generator 14 and the second noise generator 31 in accordance with the adjustment signal 63 (step S81). The first noise generating unit 14 generates noise 70 having the above-described predetermined width L (L1 + L2) and the above-described adjustment value (α × C) in response to a control signal 66 from the CPU 15. The second noise generator 31 determines a predetermined width L (L1 + L2) and an adjustment value (α × C) according to the control signal 66 from the CPU 15. The second noise generating unit 31 determines the positions a, b, d, and e within a predetermined width L (L1 + L2) by a control signal 66 from the CPU 15. However, α in the second noise generating unit 31 is fixed according to the position without being randomly changed.

  When the viewer supplies the short distance adjustment signal 64 to the display device 40 using the operation switch or the remote terminal, the short distance adjustment signal 64 is supplied to the CPU 15 to the CPU 15 (steps S11-NO, S13-YES). ). In response to the short distance adjustment signal 64, the CPU 15 outputs a short distance control signal 67 to the first noise generator 14 and the second noise generator 31 (step S82). In response to the short distance control signal 67 from the CPU 15, the first noise generator 14 includes the first predetermined width La (L1a + L2a) (La = 0.8 × L) and the adjustment value (α × C). The noise 70 having the following is generated. The second noise generating unit 31 determines the first predetermined width La (L1a + L2a) described above in response to the short distance control signal 67 from the CPU 15. The second noise generating unit 31 determines the positions a, b, e, and f within the range of the first predetermined width La (L1a + L2a) based on the short distance control signal 67 from the CPU 15.

  When the viewer supplies the long distance adjustment signal 65 to the display device 40 using the operation switch or the remote terminal, the long distance adjustment signal 65 is supplied to the CPU 15 to the CPU 15 (steps S11-NO, S13-NO). , S15). The CPU 15 outputs a long distance control signal 68 to the first noise generator 14 and the second noise generator 31 in response to the long distance adjustment signal 65 (step S83). In response to the long distance control signal 68 from the CPU 15, the first noise generator 14 includes the second predetermined width Lb (L1b + L2b) (Lb = 1.2 × L) and the adjustment value (α × C) described above. The noise 70 having the following is generated. The second noise generating unit 31 determines the above-described second predetermined width Lb (L1b + L2b) according to the long distance control signal 68 from the CPU 15. The second noise generating unit 31 determines the above-described positions a, b, e, and f within the range of the second predetermined width Lb (L1b + L2b) by the long distance control signal 68 from the CPU 15.

  20 and 21 are flowcharts showing the (IV) level adjustment operation mode as the operation of the display device 40 of the present invention. In the (IV) level adjustment operation mode, the display device 40 executes steps S5 (video data conversion processing), S21, S22 (level difference calculation processing), and S23 of the (IV) level adjustment operation mode of the display device 10. The detection unit 7 detects a pixel pair whose level difference C exceeds the set level difference as an edge portion 60 and outputs the video data 53 to the still image pattern thickness detection unit 21 in the level adjustment unit 13 (edge detection). Processing; step S24). The still image pattern thickness detection unit 21 detects an image pattern formed by each pixel of still image data included in the video data 53 and generates an image pattern value (still image pattern thickness detection processing; step S51). The still image pattern thickness detection unit 21 checks whether or not the image pattern value is greater than or equal to the set image pattern value (step S91).

  When the image pattern value is greater than or equal to the set image pattern value, the still image pattern thickness detection unit 21 outputs the information to the first noise generation unit 14, and the first noise generation unit 14 and the drive unit 5 switch 16. The switch 41 is controlled so as to be connected via (step S91-YES). In this case, the first noise generation unit 14 performs the same first noise addition process as that of the display device 10 (step S25).

  When the image pattern value is smaller than the set image pattern value, the still image pattern thickness detection unit 21 outputs the information to the second noise generation unit 31, and the second noise generation unit 31 and the drive unit 5 switch the switch 16. The switch 41 is controlled so as to be connected via the terminal (step S91-NO). The second noise generating unit 31 executes level adjustment processing (step S71).

  As described above, according to the display device 40 of the present embodiment, the first noise generation unit 14 or the second noise generation unit 31 is used depending on the thickness of the image pattern of the still image data included in the video data 53. . According to the display device 40 of the present embodiment, when the image pattern value is equal to or larger than the set image pattern value, the first noise generating unit 14 is used to have the predetermined width L (L1 + L2) and the adjustment value (α × C). By generating the noise 70, the level of the image data of the pixel group including the edge portion 60, that is, the first pixel group 51 and the second pixel group 52 among the still image data included in the video data 53 is adjusted. In the display device 10 described above, when the first noise generator 14 adds the noise 70 having the same width {predetermined width L (L1 + L2), adjustment value (α × C)} in the vicinity of the edge portion 60 and the edge portion 60, As the thickness of the image pattern of the still image data is smaller, the viewer may have difficulty in recognizing the image pattern due to the noise 70. Therefore, according to the display device 40 of the present invention, when the image pattern value is smaller than the set image pattern value, the predetermined width L (L1 + L2) and the adjustment value (α × C) are determined using the second noise generating unit 31. By doing so, the edge portion 60 that is adjacent pixels across the boundary between the first pixel group 51 and the second pixel group 52 of the still image data included in the video data 53, and the image data level in the vicinity of the edge portion 60 Adjust. As a result, according to the display device 40 of the present invention, it is possible to reduce burn-in (make it inconspicuous) and prevent deterioration of the image quality of the display device body 6.

  Further, according to the display device 40 of the present invention, the lifetime of the display device body 6 (display device 40) can be made longer than the conventional one by reducing the burn-in.

(Fifth embodiment)
Next, a fifth embodiment of the present invention will be described. FIG. 23 is a block diagram showing a configuration of a display device 50 according to the fifth embodiment of the present invention. In the display device 50, the same description as that of the display devices 10, 20, 30, and 40 is omitted.

  As shown in FIG. 23, the level adjustment unit 13 of the display unit 50 according to the present embodiment is different from the configuration of the level adjustment unit 13 of the display device 10 in that the still image pattern thickness detection unit 21 and the reverse enhancer unit 32. And a switch 41. The switch 41 is switched by a signal from the still image pattern thickness detection unit 21.

  The detection unit 7 detects, as an edge portion 60, a pixel pair in which the level difference C of the image data is equal to or greater than the set level difference, and includes a pixel on the low level side including the high level side pixel (first pixel) in this pixel pair. A predetermined number of pixels arranged continuously in a direction away from the (second pixel) is defined as a first pixel group 51, and the low-level side pixel (second pixel) in this pixel pair is included on the high-level side. A predetermined number of pixels arranged continuously in a direction away from the pixel (first pixel) is defined as the second pixel group 52, and the video data 53 of the first pixel group 51 and the second pixel group 52 is defined as a still image pattern thickness. To the height detection unit 21.

  The still image pattern thickness detector 21 detects an image pattern formed by each pixel of still image data included in the video data 53, and generates an image pattern value representing the thickness of the image pattern. When the image pattern value is equal to or larger than the set image pattern value, the still image pattern thickness detection unit 21 outputs the information to the first noise generation unit 14, and the first noise generation unit 14 and the drive unit 5 switch 16. The switch 41 is controlled so as to be connected via the switch. When the image pattern value is smaller than the set image pattern value, the still image pattern thickness detection unit 21 outputs the information to the reverse enhancer unit 32, and the reverse enhancer unit 32 and the drive unit 5 are connected via the switch 16. Thus, the switch 41 is controlled.

  When the first noise generating unit 14 and the reverse enhancer unit 32 adjust the levels of the image data of the first pixel group 51 and the second pixel group 52, the original level values A and B are added to the level difference C. Since it is necessary, the video signal 53 from the video signal processing unit 1 is input.

  In the display device 10 according to the first embodiment described above, the first noise generation unit 14 has the same probability distribution noise in the edge portion 60 and the portions other than the edge portion 60 in the first pixel group 51 and the second pixel group 52. 70, that is, noise whose level can be expressed by an adjustment value (A−α × C) or an adjustment value (B + α × C). However, in this case, the smaller the thickness of the image pattern of the still image data, the more difficult it is for the viewer to recognize the image pattern due to the noise 70.

  Therefore, in the display device 50, if the thickness of the image pattern of the still image data is smaller than a certain value (set image pattern value), the first noise generation unit 14 sets the first pixel group 51 and the second pixel group 52. The reverse enhancer 32 adjusts the image data levels of the first pixel group 51 and the second pixel group 52 without adding noise, thereby preventing burn-in.

  The level adjustment process performed by the reverse enhancer 32 will be described. The reverse enhancer 32 has a function of gradually changing the position of the edge portion 60 at the image data level. As a specific method, this change is moderated by using a low-pass filter to cut a high-frequency component from a change with respect to the position of the image data level of the first pixel group 51 and the second pixel group 52. The lower the lower limit value of the frequency range to be cut, the slower the image data level change.

  An operation of the display device 50 according to the present embodiment will be described. The display device 50 executes (I) mode setting processing, (II) normal operation mode, (III) level adjustment operation mode by the CPU 15, and (IV) level adjustment operation mode. The (I) mode setting process of the display device 50 is the same as the (I) mode setting process of the display device 10, and the (II) normal operation mode of the display device 50 is the same as the (II) normal operation mode of the display device 10. The same.

  FIG. 24 is a flowchart showing (III) level adjustment operation mode by the CPU 15 as the operation of the display device 50 of the present invention.

  When the viewer supplies the adjustment signal 63 to the display device 50 using the operation switch or the remote terminal, the adjustment signal 63 is supplied to the CPU 15 (YES in step S11). The CPU 15 outputs the control signal 66 to the first noise generating unit 14 and the reverse enhancer unit 32 in accordance with the adjustment signal 63 (step S84). The first noise generating unit 14 generates noise 70 having the above-described predetermined width L (L1 + L2) and the above-described adjustment value (α × C) in response to a control signal 66 from the CPU 15. The reverse enhancer 32 determines a first cutoff frequency n for cutting the edge portion 60 and the high-frequency component of the image data level in the vicinity of the edge portion 60 in accordance with the control signal 66 from the CPU 15. The first cut-off frequency n is a lower limit value of a frequency range to be cut, and the reverse enhancer 32 cuts a frequency equal to or higher than the first cut-off frequency n.

  When the viewer supplies the short distance adjustment signal 64 to the display device 50 using the operation switch or the remote terminal, the short distance adjustment signal 64 is supplied to the CPU 15 (steps S11-NO and S13-YES). In response to the short distance adjustment signal 64, the CPU 15 outputs a short distance control signal 67 to the first noise generator 14 and the reverse enhancer 32 (step S85). In response to the short distance control signal 67 from the CPU 15, the first noise generator 14 includes the first predetermined width La (L1a + L2a) (La = 0.8 × L) and the adjustment value (α × C). The noise 70 having the following is generated. The reverse enhancer 32 determines a second cutoff frequency na (na> n) larger than the first cutoff frequency n in response to the short distance control signal 67 from the CPU 15.

  When the viewer supplies the long distance adjustment signal 65 to the display device 50 using the operation switch or the remote terminal, the long distance adjustment signal 65 is supplied to the CPU 15 (steps S11-NO, S13-NO, S15). ). In response to the long distance adjustment signal 65, the CPU 15 outputs a long distance control signal 68 to the first noise generator 14 and the reverse enhancer 32 (step S86). In response to the long distance control signal 68 from the CPU 15, the first noise generator 14 includes the second predetermined width Lb (L1b + L2b) (Lb = 1.2 × L) and the adjustment value (α × C) described above. The noise 70 having the following is generated. The reverse enhancer 32 determines a third cutoff frequency nb (nb <n) smaller than the first cutoff frequency n in response to the long distance control signal 68 from the CPU 15.

  20 and 25 are flowcharts showing the (IV) level adjustment operation mode as the operation of the display device 50 of the present embodiment. In the (IV) level adjustment operation mode, the display device 50 executes steps S5 (video data conversion processing), S21, S22 (level difference calculation processing), and S23 of the (IV) level adjustment operation mode of the display device 10. The detection unit 7 detects adjacent pixels as the edge portion 60 across the boundary between the first pixel group 51 and the second pixel group 52 where the level difference C of the image data exceeds the set level difference, and the video data 53 is leveled. It outputs to the still image pattern thickness detection part 21 in the adjustment part 13 (edge part detection process; step S24). The still image pattern thickness detection unit 21 detects an image pattern formed by each pixel of still image data included in the video data 53 and generates an image pattern value (still image pattern thickness detection processing; step S51). The still image pattern thickness detection unit 21 checks whether or not the image pattern value is greater than or equal to the set image pattern value (step S91).

  When the image pattern value is greater than or equal to the set image pattern value, the still image pattern thickness detection unit 21 outputs the information to the first noise generation unit 14, and the first noise generation unit 14 and the drive unit 5 switch 16. The switch 41 is controlled so as to be connected via (step S91-YES). In this case, the first noise generation unit 14 performs the same first noise addition process as that of the display device 10 (step S25).

  When the image pattern value is smaller than the set image pattern value, the still image pattern thickness detection unit 21 outputs the information to the reverse enhancer unit 32, and the reverse enhancer unit 32 and the drive unit 5 are connected via the switch 16. Thus, the switch 41 is controlled (step S91—NO). The reverse enhancer unit 32 executes a reverse enhancer unit level adjustment process (step S72).

  In the reverse enhancer unit level adjustment process (step S72), the reverse enhancer unit 32 determines the first cutoff frequency n described above in accordance with the control signal 66 from the CPU 15. In this case, the reverse enhancer 32 sends the video data 53 in which the image data level in the vicinity of the edge portion 60 and the edge portion 60 is adjusted based on the first cutoff frequency n to the driving unit 5 via the switch 16. Output. The drive unit 5 executes the same display process (step S6) as the display device 10. The video data 53 displayed on the display device body 6 is visually recognized by the viewer.

  In the reverse enhancer unit level adjustment process (step S <b> 72), the reverse enhancer unit 32 determines the second cutoff frequency na described above according to the short distance control signal 67 from the CPU 15. In this case, the reverse enhancer 32 sends the video data 53 in which the image data level in the vicinity of the edge portion 60 and the edge portion 60 is adjusted based on the second cutoff frequency na to the driving unit 5 via the switch 16. Output. The drive unit 5 executes the same display process (step S6) as the display device 10. The video data 53 displayed on the display device body 6 is visually recognized by the viewer.

  In the reverse enhancer unit level adjustment process (step S <b> 72), the reverse enhancer unit 32 determines the above-described third cutoff frequency nb according to the long distance control signal 68 from the CPU 15. The reverse enhancer 32 outputs the video data 53 in which the image data level in the vicinity of the edge portion 60 and the edge portion 60 is adjusted based on the third cutoff frequency nb to the drive unit 5 via the switch 16. The drive unit 5 executes the same display process (step S6) as the display device 10. The video data 53 displayed on the display device body 6 is visually recognized by the viewer.

  As described above, according to the display device 50 according to the present embodiment, the first noise generating unit 14 or the reverse enhancer unit 32 is used depending on the thickness of the image pattern of the still image data included in the video data 53. According to the display device 50 of the present invention, when the image pattern value is equal to or greater than the set image pattern value, the noise having the predetermined width L (L1 + L2) and the adjustment value (α × C) using the first noise generation unit 14. 70, the edge portion 60 that is adjacent to the boundary between the first pixel group 51 and the second pixel group 52 of the still image data included in the video data 53, and the vicinity of the edge portion 60 Adjust the image data level. In the display device 10 according to the first embodiment described above, the first noise generator 14 adds the same noise 70 in the vicinity of the edge portion 60 and the edge portion 60. In this case, however, the image pattern of still image data The smaller the thickness, the more difficult it is for the viewer to recognize the image pattern due to the noise 70. Therefore, in the display device 50 according to the present embodiment, when the image pattern value is smaller than the set image pattern value, the still image included in the video data 53 is determined by determining the cutoff frequency n using the inverse enhancer 32. Image data level in the vicinity of the edge portion 60 of the first pixel group 51 and the second pixel group 52 of the data and the edge portion 60 that is an adjacent pixel across the boundary between the first pixel group 51 and the second pixel group 52 Adjust. Thereby, according to the display device 50 according to the present embodiment, the burn-in can be reduced (not noticeable) and the image quality of the display device body 6 can be prevented from being deteriorated even when the width of the image pattern is small. .

  Moreover, according to the display apparatus 50 which concerns on this embodiment, the lifetime of the display apparatus main body 6 (display apparatus 50) can be made longer than that of the past by reducing burn-in.

  In the third to fifth embodiments described above, when the still image pattern thickness is large and the image pattern value is equal to or larger than the set image pattern value, random noise is given to the pixel group including the edge portion. When the still image pattern thickness is small and the image pattern value is smaller than the set image pattern value, the image data level is gradually changed with respect to the position in order to prevent the viewer from recognizing that the image quality has deteriorated. It was. For example, in the third embodiment, when the image pattern value is smaller than the set image pattern value, an example in which a gradual change is realized when the random coefficient α is changed depending on the position and the image data level is time-averaged is shown. It was. In the fourth embodiment, the example in which the level of the image data is gradually changed with respect to the position by fixing the level of the image data has been described. Furthermore, in the fifth embodiment, an example has been described in which the level of image data is gradually changed with respect to the position by using a low-pass filter. However, the present invention is not limited to this, and the image data level may always be gradually changed with respect to the position regardless of the size of the image pattern value.

  The display devices according to the first to fifth embodiments described above may be monochrome display devices or color display devices.

(Sixth embodiment)
Next, a sixth embodiment of the present invention will be described. FIG. 26 is a block diagram showing the configuration of a display device according to the sixth embodiment of the present invention. In FIGS. 27A to 27C, the horizontal axis indicates the position and the vertical axis indicates the level of the image data. FIG. 4 is a graph showing a spatial distribution of image data levels, (a) showing image data before ternarization processing, (b) showing image data after ternarization processing, and (c). The image data after level adjustment is shown. Note that, among the components of the present embodiment, the same components as those of the first embodiment described above are denoted by the same reference numerals, and detailed description thereof is omitted.

  The display device according to the present embodiment is, for example, a plasma display device used as a computer display device. As shown in FIG. 26, in the display device 110 according to the present embodiment, the video signal processing unit 1, the still character region detection unit 113, the ternarization unit 114, the level adjustment unit 13, the drive unit 5, and the PDP (display device) (Main body) 6 is provided. The display device 110 according to the present embodiment is provided with a still character region detection unit 113 instead of the still image region detection unit 3 (see FIG. 1), as compared with the display device 10 according to the first embodiment. The difference is that a ternary unit 114 is provided instead of the detection unit 7 (see FIG. 1). The present embodiment is characterized in that the level adjustment is performed only for the character area in the still image area, not the level adjustment for the entire still image area as in the first to fifth embodiments described above. . This is because the character area is burned in comparison with an area other than the character area, that is, a plain area or an area displaying a photograph or a figure (hereinafter, the area other than the character area is also collectively referred to as a picture area). This is because image quality is likely to occur, and even if the image level is adjusted in the character area, it is less noticeable than the image level is adjusted in the picture area. Further, the present embodiment is characterized in that the edge portion is detected by ternarizing the image data. Other configurations in the present embodiment are the same as those in the first embodiment.

  The video signal processing unit 1 converts a video signal 100 input from the outside, for example, a television decoder or a computer main body, into video data 53 in a format suitable for the drive unit 5 to drive the PDP 6. is there. The drive unit 5 drives the PDP 6 based on the video data 53 and displays an image on the PDP 6. The PDP 6 is a general plasma display panel.

  The static character area detecting unit 113 checks whether or not the image represented by the video data 53 output from the video signal processing unit 1 includes a static character area. The still character area is an area that is a still image area and a character area. The still character area detection unit 113 divides the entire screen into a plurality of blocks, and determines whether each block is a still image area. Next, in each block determined to be a still image region, the image data is classified into three levels of a high level, an intermediate level, and a low level according to the level. That is, as shown in FIG. 27A, the level x (0 ≦ x ≦ 1) of the standardized image data is compared with the reference values a and b (0 ≦ a <b ≦ 1), and b < A case where x is a high level, a case where a ≦ x ≦ b is an intermediate level, and a case where x <a is a low level. Then, it is determined that a block having a small intermediate level ratio is a static character area. The difference (b−a) between the reference values a and b corresponds to the set level difference in the first to fifth embodiments described above.

  When the display device 110 is a color display device and the video signal 100 includes, for example, image data of three colors of R (red), G (green), and B (blue), still character region detection is performed. The unit 113 determines whether each block determined to be a still image region is a character region for each color of RGB. Alternatively, each block determined to be a still image area is divided into three sub blocks for each color, and it is determined whether or not the sub block is a character area.

  In the character area, the background color and the character color are different, and usually the image data level of the background color and the image data level of the character color are greatly different. For example, when black characters are shown on a white background, the image data level of the background color (white) is high and the image data level of the character color (black) is low. Therefore, when the image data level of such an area is divided into three levels as described above, the ratio of the intermediate level is reduced. On the other hand, since many types of colors and gradations are generally mixed in the picture area, the ratio of the intermediate level increases when the image data level of such an area is divided into three levels. For this reason, by determining the ratio of the intermediate level, it is possible to determine whether the block is a character area or a picture area.

  It should be noted that the area displaying characters in color may be determined not to be a character area because the image data level of the background color and / or the character color becomes an intermediate level. There is no problem because the level difference of the image data between the background color and the character color is small and burn-in hardly occurs. In some cases, the ratio of the intermediate level is small in an area displaying a photograph or a graphic. In this case, since burn-in easily occurs in this area, such an area is also treated as a character area. Furthermore, in the plain area, when the background color image data level is high or low, it is determined that the area is a character area because the ratio of the intermediate level is small. Since it does not exist, level adjustment is not performed. Therefore, there is no problem even if the character area is determined.

  The ternarization unit 114 receives the video data 53 from the static character area detection unit 113 and performs a ternarization process on data corresponding to the static character area in the video data 53. As shown in FIGS. 27A and 27B, the ternary processing is a case where the level x of the image data is set to 1 when the level x of the image data is high, that is, b <x ≦ 1, for example. When the level x of the image data is an intermediate level, that is, a ≦ x ≦ b, the level x of the image data is replaced with, for example, 0.5, and the level x of the image data is low, that is, 0 ≦ When x <a, the level x of the image data is replaced with, for example, 0, and the level x in the range of 0 to 1 is replaced with, for example, three values of 0, 0.5, and 1.

  In addition, the ternary unit 114 detects a portion where the high level region and the low level region are in direct contact with each other without passing through the intermediate level region, and sets the edge of the pixel pair that forms the boundary between the high level region and the low level region. Recognized as part 60. Further, the high level region, the intermediate level region and the low level region are arranged in one direction in this order, and a portion where the width of the intermediate level region in the one direction is a predetermined value or less is detected, A pixel pair positioned at the center of the intermediate level region in the one direction is recognized as the edge portion 60. In this way, the ternarization unit 114 detects the edge portion 60 in the static character region. Then, the level difference C in the pixel pair constituting the edge portion 60 is calculated based on the image data before the ternarization processing. However, in order to simplify the data processing, the level difference C may be set to C = b−a by using the above-described reference values a and b.

  Further, the ternarization unit 114 includes a high-level side pixel (first pixel) in a pixel pair constituting the detected edge portion 60 and moves away from the low-level side pixel (second pixel). A predetermined number of pixels arranged in series are set as a first pixel group 51, and the pixel pair includes a low-level pixel (second pixel) and moves away from a high-level pixel (first pixel). A predetermined number of pixels arranged continuously in the direction is defined as a second pixel group 52. The first pixel group 51 and the second pixel group 52 are collectively referred to as a pixel group. Then, the ternarization unit 114 outputs a control signal based on the position information of the pixel group and the level difference of the edge portion 60 to the level adjustment unit 13.

  The configuration of the level adjustment unit 13 is the same as that in the first embodiment described above. That is, the first noise generating unit 14 and the CPU 15 (see FIG. 1) are provided, and the video data 53 output from the video signal processing unit 1 is directly input. As shown in FIG. 27C, the first noise generator 14 generates the first pixel group 51 and the first pixel based on the level difference C (see FIG. 2) between the pixel pairs constituting the edge portion 60 and the random coefficient α. Noise 70 (see FIG. 2) is added to the image data of the two-pixel group 52 to adjust the image data level. That is, the first noise generation unit 14 replaces the image data level of the first pixel group 51 with (A−α × C), and replaces the image data level of the second pixel group 52 with (B + α × C). At this time, the random coefficient α may be 0 ≦ α ≦ 1 as in the first embodiment, but may be 0 ≦ α ≦ 0.5 as shown in FIG. In FIG. 27C, in order to clarify the correspondence with FIG. 27B and to simplify the drawing, data after ternarization processing is shown as image data. The image data level is adjusted for the image data that has not been subjected to the ternary processing.

  Further, the display device 110 has a switch 2 for switching whether the video signal processing unit 1 is connected to the still character region detecting unit 113 or the driving unit 5 based on a control signal output from the level adjusting unit 13. Is provided. Further, based on a control signal output from the static character area detection unit 113, a switch 4 for switching whether the static character area detection unit 113 is connected to the ternary unit 114 or to the drive unit 5 via the switch 16. Is provided. Further, a switch 16 is provided for switching whether the drive unit 5 is connected to the level adjustment unit 13 or to the still character region detection unit 113 via the switch 4.

  Next, the operation of the display device according to this embodiment configured as described above will be described. The display device 110 can execute by switching between the normal mode and the level adjustment operation mode. The mode can be selected by the viewer using an operation switch or a remote terminal.

  First, the operation of the display device 110 in the normal mode will be described with reference to FIG. In the normal mode, the switch 2 connects the output of the video signal processing unit 1 to the input of the drive unit 5. In this state, the video signal 100 is input to the video signal processing unit 1 of the display device 110 from the outside, for example, a television decoder or a computer main body. The video signal processing unit 1 converts the video signal 100 into video data 53 suitable for the driving unit 5 to drive the PDP 6 and outputs the video data 53 to the driving unit 5 via the switch 2. The drive unit 5 drives the PDP 6 based on the video data 53 and causes the PDP 6 to display an image based on the video data 53. As a result, the viewer can view an image based on the video data 53.

  Next, the operation of the display device 110 in the level adjustment operation mode will be described. FIG. 28 is a flowchart showing the operation in the level adjustment operation mode of the display device according to the present embodiment. Hereinafter, a description will be given with reference to FIGS. 26, 27A to 27C and FIG. In the level adjustment operation mode, the switch 2 connects the output of the video signal processing unit 1 to the input of the still character region detection unit 113. In the initial state, the switch 16 connects the switch 4 to the drive unit 5.

  First, as shown in step S101 of FIG. 28, the video signal 100 is input to the video signal processing unit 1 of the display device 110 from the outside, for example, a television decoder or a computer main body.

  Next, as shown in step S102, the video signal processing unit 1 converts the video signal 100 into video data 53 suitable for the driving unit 5 to drive the PDP 6, and detects a stationary character area via the switch 2. Output to the unit 113.

  Next, as shown in step S103, the still character region detection unit 113 divides the image for one screen represented by the video data 53 into a plurality of blocks, and determines whether each block is a still image region. To do. If all the blocks are not still image areas, the process proceeds to step S108, where the still character area detecting unit 113 switches the switch 4 so that the output of the still character area detecting unit 113 is connected to the switch 16, and then the video. Data 53 is output. As a result, the video data 53 output from the static character area detection unit 113 is input to the drive unit 5 via the switches 4 and 16. Then, as shown in step S109, the drive unit 5 drives the PDP 6 based on the video data 53 and causes the PDP 6 to display an image based on the video data 53. As a result, the viewer can view an image based on the video data 53.

  On the other hand, if any block is a still image area, the process proceeds to step S104, and the image data of this block is classified into three levels of high level, intermediate level, and low level according to the level. That is, as shown in FIG. 27A, the level x (0 ≦ x ≦ 1) of the standardized image data is compared with the reference values a and b (0 ≦ a <b ≦ 1), and b < A case where x is a high level, a case where a ≦ x ≦ b is an intermediate level, and a case where x <a is a low level. Then, it is determined that a block whose intermediate level ratio is smaller than a predetermined ratio is a still character area.

  Note that when the video signal 100 includes, for example, image data of three colors of R (red), G (green), and B (blue), the still character region detection unit 113 determines that it is a still image region. It is determined whether each block is a character area for each color of RGB. Alternatively, each block determined to be a still image area is divided into three sub blocks for each color, and it is determined whether or not the sub block is a character area.

  If no static character area has been detected for all the blocks, the process proceeds to step S108, where the static character area detection unit 113 connects the switch 4 to the output of the static character area detection unit 113. Then, video data 53 is output. Thereby, as shown in step S109, the drive unit 5 drives the PDP 6 based on the video data 53 to display an image.

  On the other hand, when a static character area is detected in any block, the static character area detection unit 113 causes the switch 4 to connect the output of the static character area detection unit 113 to the input of the ternarization unit 114. Then, video data 53 is output. As a result, the video data 53 is input to the ternary unit 114.

  Next, as shown in step S <b> 105, the ternarization unit 114 performs ternization processing on the data corresponding to the still character area in the input video data 53. That is, as shown in FIGS. 27A and 27B, when the level x of the image data included in the video data 53 is high, that is, when b <x ≦ 1, the level x of the image data is set to, for example, When the level x of the image data is an intermediate level, that is, a ≦ x ≦ b, the level x of the image data is replaced with 0.5, for example, and the level x of the image data is low, that is, 0 When ≦ x <a, the level x of the image data is replaced with 0, for example.

  Next, as shown in step S106, the ternarization unit 114 detects a portion where the high level region and the low level region are in direct contact with each other without passing through the intermediate level region, and the high level region and the low level region are detected. Are recognized as edge portions 60. Further, the high level region, the intermediate level region and the low level region are arranged in one direction in this order, and a portion where the width of the intermediate level region in the one direction is a predetermined value or less is detected, A pixel pair positioned at the center of the intermediate level region in the one direction is also recognized as the edge portion 60. In this way, the ternarization unit 114 detects the edge portion 60 in the static character region.

  When the ternary unit 114 does not detect the edge portion 60 in the still character area, the process proceeds to step S108, and the still character area detecting unit 113 outputs the video data 53 to the driving unit 5. Thereby, as shown in step S109, the drive unit 5 drives the PDP 6 based on the video data 53 to display an image.

  On the other hand, in the case where the edge portion 60 is detected in the static character area in the ternary unit 114, the ternary unit 114 outputs a pixel on the high level side (the first pixel) among the pixel pairs constituting the detected edge portion 60. 1 pixel) and a predetermined number of pixels continuously arranged in a direction away from the low level side pixel (second pixel) are set as the first pixel group 51, and the low level side of the pixel pair is set. A predetermined number of pixels that are continuously arranged in a direction away from the high-level side pixel (first pixel) including the second pixel (second pixel) are set as the second pixel group 52. Then, the ternary unit 114 outputs the position information of the pixel groups (the first pixel group 51 and the second pixel group 52) and the level difference information of the edge portion 60 to the level adjustment unit 13.

  Next, as shown in step S107, the first noise generation unit 14 of the level adjustment unit 13 is similar to the first embodiment described above in that the level difference C between the pixel pairs constituting the edge portion 60 (see FIG. 2). ) And the random coefficient α, noise 70 (see FIG. 2) is added to the image data of the first pixel group 51 and the second pixel group 52. That is, the first noise generation unit 14 uses the image data level of the first pixel group 51 for the video data 53 input from the video signal processing unit 1 via the switch 2, that is, the data that has not been subjected to the ternary processing. Is replaced with (A−α × C), and the image data level of the second pixel group 52 is replaced with (B + α × C). At this time, the random coefficient α may be 0 ≦ α ≦ 1 as in the first embodiment, or may be 0 ≦ α ≦ 0.5 as shown in FIG.

  Then, as shown in step S <b> 108, the first noise generation unit 14 outputs image data corresponding to the pixel group (first pixel group 51 and second pixel group 52) after level adjustment to the drive unit 5. To do. At this time, the static character area detection unit 113 outputs image data corresponding to pixels other than the pixel group, that is, image data that has not been subjected to level adjustment processing, to the drive unit 5. At this time, the CPU 15 (see FIG. 1) switches the switch 16 so that the image data corresponding to the pixel group, that is, the image data after the level adjustment is input from the first noise generating unit 14 to the driving unit 5. In addition, image data corresponding to pixels other than the pixel group, that is, image data that has not been subjected to level adjustment is input from the static character region detection unit 113 to the drive unit 5. Then, as shown in step S109, the PDP 6 is driven based on the video data to display an image. Thereby, the viewer can appreciate the image based on the video data.

  Next, the effect of this embodiment will be described. In the present embodiment, a still character region is detected in the still image region, and the image data level is adjusted only for the still character region. Therefore, compared to the case where the level adjustment process is performed for the entire still image region, Processing can be performed at high speed. Also, the static character area has a high contrast between the background portion and the character portion, and burn-in occurs in comparison with a region other than the static character region, that is, a plain region or a region displaying a photograph or a figure. It's easy to do. Further, even if the image level is adjusted in the character area, it is less noticeable than the image level is adjusted in the area displaying a photograph or the like. For this reason, by performing the level adjustment process only for the still character region, it is possible to efficiently prevent burn-in while suppressing a decrease in image quality.

  In the present embodiment, the edge portion can be efficiently detected by performing the ternary processing. The effects of the present embodiment other than those described above are the same as those of the first embodiment described above.

  Next, a first modification of the sixth embodiment will be described. 29A to 29C are graphs showing the spatial distribution of the image data level, with the position on the horizontal axis and the level of the image data on the vertical axis, and FIG. 29A is an image before level adjustment. (B) shows image data after level adjustment in the first modified example, and (c) shows image data after level adjustment in a second modified example described later.

  In the sixth embodiment described above, the width of the pixel group for which the level adjustment is performed is constant regardless of the distribution of the image data. On the other hand, in this modification, the width of the high-level region is detected using the image data after the ternarization processing, and the pixel group (the first pixel group 51 and the second pixel is detected according to the width. Adjust the width of the group 52). That is, as shown in FIG. 29A, the width W1 of the high level region 121 is larger than the width W2 of the high level region 122. For this reason, as shown in FIG. 29B, the width S1 of the pixel group in the high level region 121 is made larger than the width S2 of the pixel group in the high level region 122. Other configurations and operations in the present modification are the same as those in the above-described sixth embodiment.

  The effect of this modification is to make the level adjustment process inconspicuous when the still image pattern thickness is small. In the second embodiment, the width of the pixel group is set based on the still image pattern thickness. It is the same as the adjusted effect. However, in the present modification, since the image data after the ternarization processing is used, the width of the high level region can be easily detected.

  Next, a second modification of the above-described sixth embodiment will be described. In the above-described sixth embodiment and the first modification thereof, the image data level is adjusted for both the first pixel group 51 that is the high-level region and the second pixel group 52 that is the low-level region. It is carried out. On the other hand, in the second modified example, as shown in FIG. 29C, the image data level is adjusted only for the first pixel group 51 which is the high level side region. Other configurations and operations in the present modification are the same as those in the first modification described above.

  Usually, the deterioration of the pixels due to the deterioration of the phosphor or the like is more remarkable in the high level side region than in the low level side region. Further, the deterioration of image quality due to the level adjustment of the image data is less noticeable in the high level side region. Furthermore, by performing the level adjustment only in the high level side region, the width of the region to which the level adjustment is performed can be narrowed to make the deterioration of the image quality unnoticeable. As described above, in this modification, by performing level adjustment only in the high-level region, it is possible to effectively prevent image sticking while suppressing deterioration in image quality associated with level adjustment.

  In the above-described sixth embodiment and the first and second modifications thereof, the level adjustment is performed according to the distance between the display device and the viewer as shown in the above-described second embodiment. You may adjust the width | variety of the pixel group to perform. In the sixth embodiment and the first and second modifications thereof, as an example of the level adjustment method, an example in which uniform noise is added to a pixel group as in the first embodiment described above. Although shown, the present invention is not limited to this, and as shown in the third to fifth embodiments, the image data level may be gradually changed with respect to the position. That is, as in the third embodiment, the random coefficient α may be changed depending on the position to realize a gradual change in the time average value of the image data level. The level may be fixed and the level of the image data may be gradually changed with respect to the position. By using a low-pass filter as in the fifth embodiment, the level of the image data is gradually changed with respect to the position. It may be changed to.

  Further, as in the third to fifth embodiments described above, when the still image pattern thickness is large and the image pattern value is equal to or larger than the set image pattern value, random noise is applied to the pixel group including the edge portion. If the still image pattern thickness is small and the image pattern value is smaller than the set image pattern value, the image data level may be gradually changed with respect to the position as described above. Furthermore, instead of the PDP, an LCD, EL, or CRT may be used as the display device body.

(Seventh embodiment)
Next, a seventh embodiment of the present invention will be described. FIGS. 30A and 30B are graphs showing the spatial distribution of image data levels, with the position on the horizontal axis and the level of image data on the vertical axis, and FIG. 30A shows RGB before level adjustment. The image data of each color is shown, and (b) shows the image data of each color of the RBG after level adjustment. In addition, the vertical axis | shaft of Fig.30 (a) and (b) has shown the normalized value of the image data level. The present embodiment is an embodiment of a color display device.

  As shown in FIG. 30A, in the image data before level adjustment, the level value of the first pixel group 51 in the red sub-pixel (R) is 1, and the level value of the second pixel group 52 is 0. is there. Further, the level value of the first pixel group 51 in the green sub-pixel (G) is 1, and the level value of the second pixel group 52 is 0.5. Further, the level value of the first pixel group 51 in the blue sub-pixel (B) is 0, and the level value of the second pixel group 52 is 0. Note that the luminance of the image is determined by a combination of level values of the sub-pixels.

In the present embodiment, the level difference C is calculated independently for each of the RGB colors. On the other hand, the random coefficient α uses a common value for the sub-pixels of each RGB color for each pixel. That is, in FIG. 30 (a), the level difference _{C R} in the red pixel is 1, the level difference _{C G} in the green pixel and 0.5, and 0 the level difference _{C B} in the blue pixel. The random coefficient α is selected randomly within a range of 0 ≦ α ≦ 0.5, for example. The random coefficient α is applied to the red subpixel belonging to a certain pixel, and is applied to the green subpixel belonging to this pixel. The random coefficient α to be applied and the random coefficient α applied to the blue sub-pixel belonging to this pixel have the same value.

  Thereby, noise 73 as shown in FIG. 30B is added to the image data of each color. In the present embodiment, since the common random coefficient α is used for each pixel for each of the RGB colors, the color balance is not greatly shifted microscopically. For this reason, the level-adjusted portion is inconspicuous and there is little deterioration in image quality. The configuration, operation, and effects of the present embodiment other than those described above are the same as those of the sixth embodiment described above. That is, as shown in the above-described sixth embodiment, a still character area is detected, the level of image data is adjusted only in this still character area, and an edge portion is detected by performing a ternary process.

  Note that this embodiment may be applied to the display devices according to the first to fifth embodiments described above. That is, as shown in the second embodiment, the width L of the pixel group for which the level adjustment is performed may be adjusted according to the distance between the display device and the viewer. Further, as described in the third to fifth embodiments, the image data level may be changed gradually with respect to the position. Further, as in the first modified example of the sixth embodiment described above, the width of the pixel group that performs level adjustment may be adjusted according to the thickness of the character. As in the modification, the level adjustment may be performed only in the first pixel group that is the high-level region.

(Eighth embodiment)
Next, an eighth embodiment of the present invention will be described. FIGS. 31A and 31B are graphs showing the spatial distribution of image data levels, with the position on the horizontal axis and the level of the image data on the vertical axis, and FIG. 31A shows RGB before level adjustment. The image data of each color is shown, and (b) shows the image data of each color of the RBG after level adjustment. In addition, the vertical axis | shaft of Fig.31 (a) and (b) has shown the normalized value of the image data level. The present embodiment is an embodiment of a color display device.

  As shown in FIG. 31A, in the image data before level adjustment, the level value of the first pixel group 51 in the red sub-pixel (R) is 1, and the level value of the second pixel group 52 is 0. is there. Further, the level value of the first pixel group 51 in the green sub-pixel (G) is 1, and the level value of the second pixel group 52 is 1. Further, the level value of the first pixel group 51 in the blue sub-pixel (B) is 0.5, and the level value of the second pixel group 52 is 1.

  In this embodiment, the level value of the RGB image data is multiplied by a common random coefficient α for each pixel. The value of the random coefficient α is selected randomly within a range of 0 ≦ α ≦ 1, for example. The random coefficient α applied to the red subpixel belonging to a certain pixel and the random coefficient α applied to the green subpixel belonging to this pixel And the random coefficient α applied to the blue subpixel belonging to this pixel have the same value. That is, when the level value of the first pixel group 51 before adjustment is A and the level value of the second pixel group 52 is B, the level value of the first pixel group 51 after adjustment is (α × A), The level value of the second pixel group 52 after adjustment is (α × B). As described above, in the present embodiment, unlike the above-described seventh embodiment, addition and subtraction based on the level difference C of the image data is not performed on the level value (A or B) of the image data. . As a result, the level of the image data after the level adjustment is as shown in FIG.

For example, when the image data level of each sub-pixel before adjustment takes the value shown in FIG. 31A, if α = 0.1 in a certain pixel, the level A of the red sub-pixel of the first pixel group 51 _R is A _R = α × A = 0.1 × 1 = 0.1, and the level A _G of the green sub-pixel is A _G = α × A = 0.1 × 1 = 0.1, and the blue sub-pixel The pixel level A _B is A _B = α × A = 0.1 × 0.5 = 0.05, and the RGB ratio is A _R : A _G : A _B = 1: 1: 0.5, The ratio before adjustment is maintained. The level _{B R} of the red sub-pixel of the second pixel group _{52, B R = α × B =} 0.1 × 0 = 0 , and the level _{B G} of the green _{sub-pixel, B G = α × B =} 0 1 × 1 = 0.1, and the level B _B of the blue sub-pixel is B _B = α × B = 0.1 × 1 = 0.1, and the RGB ratio is B _R : B _G : B _B = 0: 1: 1, and the ratio before adjustment is maintained.

If α = 0.5, the level A _R of the red sub-pixel of the first pixel group 51 is A _R = α × A = 0.5 × 1 = 0.5, and the level A of the green sub-pixel _G is A _G = α × A = 0.5 × 1 = 0.5, and the level A _B of the blue sub-pixel is A _B = α × A = 0.5 × 0.5 = 0.25, The ratio of RGB is A _R : A _G : A _B = 1: 1: 0.5, and the ratio before adjustment is maintained. The level _{B R} of the red sub-pixel of the second pixel group _{52, B R = α × B =} 0.5 × 0 = 0 , and the level _{B G} of the green _{sub-pixel, B G = α × B =} 0 .5 × 1 = 0.5, and the level B _B of the blue sub-pixel is B _B = α × B = 0.5 × 1 = 0.5, and the RGB ratio is B _R : B _G : B _B = 0: 1: 1, and the ratio before adjustment is maintained.

  As described above, in this embodiment, the color balance is substantially maintained before and after the level adjustment, and the color balance of the pixel group after the level adjustment is in an area on both sides of the pixel group, that is, an area where the level adjustment is not performed. There is no significant deviation from the color balance. In addition, since a common random coefficient α is used for each pixel for each color of RGB, the color balance is not greatly shifted microscopically. For this reason, the level-adjusted portion is inconspicuous and there is little deterioration in image quality. The configuration, operation, and effects of the present embodiment other than those described above are the same as those of the sixth embodiment described above. That is, as shown in the above-described sixth embodiment, a still character area is detected, the level of image data is adjusted only in this still character area, and an edge portion is detected by performing a ternary process.

  Note that this embodiment may be applied to the display devices according to the first to fifth embodiments described above. For example, as shown in the second embodiment described above, the width L of the pixel group that performs level adjustment may be adjusted according to the distance between the display device and the viewer. Furthermore, as in the first modification of the above-described sixth embodiment, the width of the pixel group that performs level adjustment may be adjusted according to the width of the high-level region, and the second of the sixth embodiment. As in the modified example, level adjustment may be performed only in the first pixel group that is the high-level region.

  In each of the above-described embodiments, the level adjustment of the image data is preferably performed in both the horizontal direction and the vertical direction of the screen, but may be performed only in the horizontal direction. By performing level adjustment only in the horizontal direction, processing of image data becomes easy. In each of the embodiments described above, the width L of the pixel group for which the level adjustment is performed and the value of the adjustment coefficient α may be adjusted according to the value of the level difference C between the pair of pixels constituting the edge portion. For example, as the level difference C increases, the width L of the pixel group may be increased. At this time, the value or range of the adjustment coefficient α is changed stepwise or continuously to change the pixel data in the pixel group. The level value may change gradually with respect to the position.

  The present invention can be suitably used for display devices such as PDP, LCD, EL, and CRT, and particularly suitably used for display devices such as computers that often display a mixture of still images and moving images. can do.

1 is a block diagram illustrating a display device according to a first embodiment of the present invention. It is a graph which shows the spatial distribution of the image data level in this embodiment, with the position on the horizontal axis and the level of the image data on the vertical axis. It is a flowchart which shows (I) mode setting process as operation | movement of the display apparatus which concerns on this embodiment. It is a flowchart which shows (II) normal operation mode as operation | movement of the display apparatus which concerns on this embodiment. It is a flowchart which shows the level adjustment operation mode by (III) CPU as operation | movement of the display apparatus which concerns on this embodiment. It is a flowchart which shows (IV) level adjustment operation mode as operation | movement of the display apparatus which concerns on this embodiment. It is a block diagram which shows the display apparatus which concerns on the 2nd Embodiment of this invention. It is the figure seen from the front side (viewer side) which shows the display apparatus main body in this embodiment. (A) And (b) is a figure which shows the character pattern displayed on a display apparatus main body. It is a flowchart which shows the level adjustment operation mode by the (III-1) distance measurement part as operation | movement of the display apparatus which concerns on this embodiment. It is a flowchart which shows the level adjustment operation mode by (III-2) CPU as operation | movement of the display apparatus which concerns on this embodiment. It is a flowchart which shows (IV) level adjustment operation mode as operation | movement of the display apparatus which concerns on this embodiment. It is a block diagram which shows the display apparatus which concerns on the 3rd Embodiment of this invention. It is a graph which shows the spatial distribution of an image data level by taking the position on a screen on a horizontal axis, and taking the level of image data on a vertical axis | shaft. It is a graph showing the probability distribution of the random coefficient α, with the random coefficient α on the horizontal axis and the probability on the vertical axis. It is a flowchart which shows the level adjustment operation mode by (III) CPU15 as operation | movement of the display apparatus which concerns on this embodiment. It is a flowchart which shows (IV) level adjustment operation mode as operation | movement of the display apparatus which concerns on this embodiment. It is a block diagram which shows the display apparatus which concerns on the 4th Embodiment of this invention. It is a flowchart which shows the level adjustment operation mode by (III) CPU as operation | movement of the display apparatus which concerns on this embodiment. It is a flowchart which shows (IV) level adjustment operation mode as operation | movement of the display apparatus which concerns on this embodiment. It is a flowchart which shows (IV) level adjustment operation mode as operation | movement of the display apparatus which concerns on this embodiment. It is a graph which shows the spatial distribution of an image data level by taking the position on a screen on a horizontal axis, and taking the level of image data on a vertical axis | shaft. It is a block diagram which shows the display apparatus which concerns on the 5th Embodiment of this invention. It is a flowchart which shows the level adjustment operation mode by (III) CPU as operation | movement of the display apparatus which concerns on this embodiment. It is a flowchart which shows (IV) level adjustment operation mode as operation | movement of the display apparatus which concerns on this embodiment. It is a block diagram which shows the structure of the display apparatus which concerns on the 6th Embodiment of this invention. (A) thru | or (c) is a graph which shows a spatial distribution of an image data level by taking a position on a horizontal axis and taking the level of image data on a vertical axis | shaft, (a) is an image before ternarization processing. (B) shows image data after ternarization processing, and (c) shows image data after level adjustment. It is a flowchart which shows the operation | movement in the level adjustment operation mode of the display apparatus which concerns on this embodiment. (A) thru | or (c) is a graph which shows a spatial distribution of an image data level by taking a position on a horizontal axis and taking a level of image data on a vertical axis | shaft, (a) is image data before level adjustment. (B) shows the image data after level adjustment in the first modification of the sixth embodiment, and (c) shows the image data after level adjustment in the second modification. (A) And (b) is a graph which shows the spatial distribution of the image data level in the 7th Embodiment of this invention, taking a position on a horizontal axis and taking a level of image data on a vertical axis | shaft, (a ) Shows image data of each color of RGB before level adjustment, and (b) shows image data of each color of RBG after level adjustment. (A) And (b) is a graph which shows the spatial distribution of the image data level in the 8th Embodiment of this invention, taking a position on a horizontal axis and taking a level of image data on a vertical axis | shaft, (a ) Shows image data of each color of RGB before level adjustment, and (b) shows image data of each color of RBG after level adjustment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1; Video | video signal processing part 2; Switch 3; Still image area | region detection part 4; Switch 5; Drive part 6; Display apparatus main body 6 '; Screen 7;
10; Display device 11; Coring 13; Level adjustment unit 14; First noise generation unit 15; CPU
16; switch 17; still image level adjusting unit 20; display device 21; still image pattern thickness detecting unit 22; distance measuring unit 23; ultrasonic oscillator 24; ultrasonic sensor 25; measuring device 30; Noise generating unit 32; reverse enhancer 40; display device 41; switch 50; display device 51; first pixel group 52; second pixel group 53; video data 54 and 55; image pattern 56; )
60; edge portion 61; level adjustment operation setting signal 62; normal operation setting signal 63; adjustment signal 64; short distance adjustment signal 65; long distance adjustment signal 66; control signal 67; short distance control signal 68; Distance 70, 71, 72, 73; noise 75; ultrasonic wave 76; reflected wave 100; video signal 110; display device 113; stationary character region detection unit 114; ternarization unit 121, 122;

Claims (25)

In a display device that displays an image based on video data input from the outside, a display unit in which a plurality of pixels each having a different color or a single sub-pixel is arranged, and the video data A drive unit that drives the display unit based on the above, a still image region detection unit that detects a still image region from the video data, a burn reduction treatment unit that performs a burn reduction treatment on the sub-pixels located in the still image region, A display device comprising: The burn-in reduction processing unit includes the first color sub-pixel of one pixel or the image data level of a single color sub-pixel of the pixel pair adjacent to each other in the still image region and the first pixel of the other pixel. A first edge portion detection unit that detects, as a first edge portion, a pixel pair having a difference from the image data level of a color subpixel or a single color subpixel that is greater than a set value; and an image of the first edge portion The display device according to claim 1, further comprising: a level adjusting unit that adjusts a data level and outputs the data level to the driving unit. The first edge portion detection unit includes a pixel to which a first sub-pixel having a relatively high image data level belongs among a pair of pixels constituting the first edge portion, and the image data level is relatively A first pixel group including a first pixel group composed of a plurality of pixels continuously arranged in a direction away from a pixel to which the second low-subpixel belongs, and a pixel to which the second sub-pixel belongs. Detecting a second pixel group composed of a plurality of pixels arranged continuously in a direction away from the pixel to which the pixel belongs, and the level adjustment unit corresponds to the first pixel group and the second pixel group The display device according to claim 2, wherein the level of image data is adjusted. The first edge portion detection unit includes a pixel to which a first sub-pixel having a relatively high image data level belongs among a pair of pixels constituting the first edge portion, and the image data level is relatively A first pixel group including a first pixel group composed of a plurality of pixels continuously arranged in a direction away from a pixel to which the second low-subpixel belongs, and a pixel to which the second sub-pixel belongs. Detecting a second pixel group composed of a plurality of pixels arranged continuously in a direction away from the pixel to which the pixel belongs, and the level adjusting unit adjusts the level of image data corresponding to the first pixel group The display device according to claim 2, wherein: A plurality of pixels arranged continuously in a direction away from the pixel including the second sub-pixel including the pixel to which the first sub-pixel belongs, and the image data level of the sub-pixel of the first color Has a first pattern thickness detector that detects the number of pixels higher than a set value as the length of the high level region, and the first edge portion detector has a long length of the high level region. 5. The display device according to claim 3, wherein the number of pixels of the first pixel group and the second pixel group is increased. A plurality of pixels arranged continuously in a direction away from the pixel including the first sub-pixel including the pixel to which the second sub-pixel belongs, and the image data level of the sub-pixel of the first color Has a second pattern thickness detection unit that detects the number of pixels lower than the set value as the length of the low level region, and the first edge portion detection unit has a long length of the low level region. The display device according to claim 3, wherein the number of pixels of the first pixel group and the second pixel group is increased. The first edge portion detection unit may increase the number of pixels of the first pixel group and the second pixel group as the level difference of the image data between the first subpixel and the second subpixel increases. The display device according to claim 3, wherein the number of the display devices is increased. In a display device that displays an image based on video data input from the outside, a display unit in which a plurality of pixels each having a different color or a single sub-pixel is arranged, and the video data A drive unit that drives the display unit based on the above, a still character region detection unit that detects a static character region from the video data, and a burn reduction treatment unit that performs a burn reduction treatment on the sub-pixels located in the still character region, A display device comprising: The still character region detection unit divides a plurality of pixels constituting the display unit into a plurality of blocks, and sets image data corresponding to sub-pixels in each block to be based on a first reference value and the first reference value. Compared with a low second reference value, the block whose image data level is not less than the second reference value and the ratio of sub-pixels that are intermediate levels that are not more than the first reference value is not more than a predetermined value The display device according to claim 8, wherein the display device is determined to be a static character region. The burn-in reduction processing unit includes a high-level pixel to which the first color sub-pixel or single-color sub-pixel whose image data level is higher than the first reference value and the image data level of the high-level pixel belong to the second reference value. A pixel pair consisting of the high-level pixel and the low-level pixel is defined as a second edge when the first-color sub-pixel or the low-level pixel to which the single-color sub-pixel lower than the value belongs. A predetermined number of intermediate level pixels to which the first color sub-pixel or the single-color sub-pixel whose image data level is the intermediate level belong to between the high-level pixel and the low-level pixel. A pixel pair located at the center in the direction from the high level pixel to the low level pixel among the intermediate level pixels is detected as the second edge portion, And a level adjusting unit that adjusts the level of the image data output from the second edge part detecting unit and outputs the level to the driving unit. Item 10. The display device according to Item 9. The second edge portion detection unit includes a pixel to which a first sub-pixel having a relatively high image data level belongs among a pair of pixels constituting the second edge portion, and the level of the image data is relatively A first pixel group including a plurality of pixels continuously arranged in a direction away from a pixel to which the second sub pixel belongs to, and a pixel to which the second sub pixel belongs. Detecting a second pixel group composed of a plurality of pixels arranged continuously in a direction away from the pixel to which the pixel belongs, wherein the level adjusting unit is an image corresponding to the first pixel group and the second pixel group. The display device according to claim 10, wherein the display device adjusts a data level. The second edge portion detection unit includes a pixel to which a first sub-pixel having a relatively high image data level belongs among a pair of pixels constituting the second edge portion, and the level of the image data is relatively A first pixel group including a plurality of pixels continuously arranged in a direction away from a pixel to which the second sub pixel belongs to, and a pixel to which the second sub pixel belongs. Detecting a second pixel group composed of a plurality of pixels arranged continuously in a direction away from the pixel to which the pixel belongs, and the level adjusting unit adjusts the level of image data corresponding to the first pixel group The display device according to claim 10, wherein the display device is a device. A plurality of pixels arranged consecutively in a direction away from the pixel including the second sub-pixel including the pixel to which the first sub-pixel belongs, and the image data level of the sub-pixel of the first color is A first pattern thickness detection unit that detects the number of pixels higher than a set value as the length of the high-level region; and the second edge portion detection unit has a longer length of the high-level region. The display device according to claim 11, wherein the number of pixels of the first pixel group and the second pixel group is increased. A plurality of pixels arranged continuously in a direction away from the pixel including the first sub-pixel including the pixel to which the second sub-pixel belongs, and the image data level of the sub-pixel of the first color is A second pattern thickness detector that detects the number of pixels lower than a set value as the length of the low-level region, and the second edge portion detector has a longer length of the low-level region. The display device according to claim 11, wherein the number of pixels of the first pixel group and the second pixel group is increased. The second edge portion detection unit may increase the number of pixels of the first pixel group and the second pixel group as the level difference of the image data between the first subpixel and the second subpixel increases. The display device according to claim 11, wherein the number of the display devices is increased. And a distance measuring unit configured to measure a distance between the display unit and a viewer, wherein the edge portion detecting unit increases the first pixel group and the first pixel as the distance measured by the distance measuring unit increases. 16. The display device according to claim 3, wherein a length in a direction from the first pixel toward the second pixel in the two-pixel group is increased. 17. . The distance measuring unit oscillates an ultrasonic wave, an ultrasonic sensor detects the ultrasonic wave reflected by the viewer, a time when the ultrasonic wave oscillated the ultrasonic wave, and the ultrasonic wave The display device according to claim 16, further comprising: a distance measuring unit that measures a distance between the display unit and the viewer based on a time difference from a time at which the ultrasonic sensor receives the ultrasonic wave. The level of image data of the first sub-pixel is A, the level of image data of the second sub-pixel is B, and the level of image data between the first sub-pixel and the second sub-pixel is When the level difference is C (C = A−B) and the random coefficient taking a random value in the range of 0 to 1 is α, the level adjustment unit is configured to adjust the first color of the first pixel group. The level of the image data of the sub-pixel is replaced with (A−α × C), and the level of the image data of the sub-pixel of the first color in the second pixel group is replaced with (B + α × C). The display device according to any one of claims 3 to 7 and claims 11 to 15. The level adjustment unit is configured such that, among pixels belonging to the first pixel group and the second pixel group, a value closer to the pixel pair to which the first sub-pixel and the second sub-pixel belong is assigned to the value of the random coefficient. The display device according to claim 18, wherein the display device is set to be small. The display device according to claim 18, wherein the display device displays a color image, and the burn-in reduction treatment unit calculates the level difference independently for each color. 21. The display device according to claim 20, wherein the level adjustment unit uses a common value for each pixel for each color as the random coefficient. The level adjustment unit changes the level of the image data of the first color sub-pixel belonging to the first pixel group and the second pixel group from the pixel to which the first sub-pixel belongs to the second sub-pixel. The display device according to claim 3, wherein the display device is adjusted so as to be continuously lowered along a direction toward a pixel to which the pixel belongs. The level adjustment unit includes the level of image data of the first color sub-pixel belonging to the first pixel group and the second pixel group and the first sub-pixel of the sub-pixel to the first sub-pixel to the first pixel group. The image data level of the first color sub-pixel is adjusted based on a function obtained by applying a low-pass filter to a function in the direction toward the pixel to which the two sub-pixels belong. The display device according to any one of claims 3 to 7 and claims 11 to 15. A color image is displayed, and the level of the image data of the first sub-pixel is A, the level of the image data of the second sub-pixel is B, and takes a random value in the range of 0 to 1. When the random coefficient is α, the level adjustment unit replaces the level of the image data of the first color of the first pixel group with (α × A), and the first color of the second pixel group 16. The display device according to claim 3, wherein the level of the image data is replaced with (α × B). The display device according to claim 24, wherein the level adjustment unit uses a common value for each pixel for each color as the random coefficient.

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