JP4763661B2 - Image quality evaluation method, program, and apparatus - Google Patents

Description

The present invention relates to an image quality evaluation method, program, and apparatus for a display device such as a liquid crystal television, and more particularly to an image quality evaluation method, program, and apparatus for evaluating the afterimage feeling of a moving image caused by response speed.

  Conventionally, various image quality improvement techniques have been developed in order to improve the image quality of flat-screen TVs typified by liquid crystal televisions, and a method for objectively evaluating the degree of image quality improvement has been demanded.

  A liquid crystal panel used in a flat-screen television has a characteristic that response speed is slow, and the afterimage feeling of a fast moving image is a problem. Evaluation of moving images is generally more difficult than evaluation of still images, and an objective evaluation method is required.

As a method for measuring the response performance of a liquid crystal panel, there is a response speed measurement device based on the MPRT method (Moving Picture Response Time). In the MPRT method, as shown in FIG. 22, the horizontal scroll display of the test pattern of the vertical stripe pattern is tracked by the camera, the luminance distribution 104 of the captured display image 102 is obtained, and the time when the black level changes to the white level is evaluated. Measured as T. This evaluation time T corresponds to the response time of the liquid crystal panel, and it can be estimated that the shorter the evaluation time, the shorter the response time and the less the afterimage feeling.
Japanese Patent Laid-Open No. 2004-144831

  However, such a conventional response speed measuring device using the MPRT method can objectively detect the response time of the liquid crystal panel to a moving image, but the evaluation time measured by the device is not necessarily detected by human eyes. Even if it is estimated that there is an afterimage feeling from the evaluation time, the afterimage feeling may not be felt by the human eye, and a sensory test is required to judge the presence or absence of the afterimage feeling by the human eye It becomes.

  As a sensory inspection method for afterimage feeling, a pattern having a constant movement speed may be shown to a person to determine whether or not afterimage feeling has occurred. However, this method requires several types of patterns with different moving speeds to be inspected by showing the moving pattern images multiple times, which increases the measurement time and subtle changes in moving speed. There was a problem that the judgment by became unstable.

An object of the present invention is to provide an image quality evaluation method, program, and apparatus that can stably obtain a sensory test for afterimage feeling by a person in a shorter time and with better evaluation accuracy.

(Image quality evaluation method)
The present invention provides an image quality evaluation method using a speed change moving image. That is, the image quality evaluation method of the present invention is
A speed change video display step of displaying (preferably repeatedly displaying) a speed change video in which the moving speed changes according to the movement position on the screen of the moving object on the display device to be evaluated;
A determination operation detection step of detecting a determination operation signal when the evaluator watching the speed change video determines the afterimage feeling of the moving object;
When a determination operation signal is detected, a speed map moving step is displayed to switch the speed change video to a speed map screen displaying a speed scale indicating a speed corresponding to the moving position on the screen of the moving object;
It is provided with.

In another form of the image quality evaluation method using the speed change video of the present invention,
A speed change video display step for displaying a speed change video in which the moving speed changes according to the moving position on the screen of the moving body on the display device to be evaluated;
A determination position detection step of detecting a determination position on the screen from a determination operation signal when the evaluator watching the speed change video determines the afterimage feeling of the moving object;
An afterimage feeling generation speed detection unit that detects an afterimage feeling generation speed of the moving body based on the detected determination position;
It is provided with.

The present invention provides an image quality evaluation method using a luminance change moving image. That is, the image quality evaluation method of the present invention is
A luminance change video display step for displaying a luminance change video in which the luminance changes according to the movement position on the screen of the moving body on the display device to be evaluated;
A determination operation detection step of detecting a determination operation signal when the evaluator watching the luminance change video determines the afterimage feeling of the moving body;
A luminance map display step of switching and displaying the luminance change moving image on the luminance map screen displaying the luminance scale indicating the luminance corresponding to the moving position on the screen of the moving body when the determination operation signal is detected;
It is provided with.

In another form of the image quality evaluation method using the luminance change video of the present invention,
A luminance change video display step for displaying a luminance change video in which the luminance changes according to the movement position on the screen of the moving body on the display device to be evaluated;
A determination position detection step of detecting a determination position on the screen from a determination operation signal when the evaluator watching the brightness change video determines the afterimage feeling of the moving object;
An afterimage feeling generation luminance detection unit for detecting the afterimage feeling generation luminance of the moving body based on the detected determination position;
It is provided with.

The present invention provides an image quality evaluation method using a saturation change moving image. That is, the image quality evaluation method of the present invention is
A saturation change video display step for displaying a saturation change video in which the saturation changes according to the movement position on the screen of the moving object on the display device to be evaluated;
A determination operation detection step of detecting a determination operation signal when the evaluator watching the saturation change video determines the afterimage feeling of the moving object;
When detecting a determination operation signal, a saturation map moving step for displaying a saturation change video by switching to a saturation map screen displaying a saturation scale indicating the saturation corresponding to the moving position of the moving object on the screen;
It is provided with.

In another form of the image quality evaluation method using the saturation change video of the present invention,
A saturation change video display step for displaying a saturation change video in which the saturation changes according to the movement position on the screen of the moving object on the display device to be evaluated;
A determination position detection step of detecting a determination position on the screen from a determination operation signal when the evaluator who is watching the saturation change video determines the afterimage feeling of the moving object;
An afterimage-sensing saturation detector that detects afterimage-sensing saturation of the moving object based on the detected determination position;
It is provided with.

  In the image quality evaluation using the speed change moving image of the present invention, a speed change moving image in which a moving body moves around the screen while changing the speed, for example, a speed changing moving image in which a round figure accelerates from the left to the right and moves through is moved. By repeatedly displaying, it is possible to accurately determine the afterimage feeling by reproducing the state close to the actual moving image display.

  Also, since the speed is uniquely determined according to the position of the moving body moving on the screen by displaying the speed change video, a speed map screen with a speed scale that graphs the relationship between the position and speed of the moving body is prepared and evaluated. When the user determines the position where the afterimage feeling occurs from the speed change movie, the display changes from the movie to the speed map, and the evaluator reads the scale value corresponding to the position where the afterimage feeling occurs, It is possible to easily and accurately read the moving speed of the moving body at the occurrence position, that is, the afterimage feeling generating speed.

  Further, by selecting the automatic reading mode as necessary, the afterimage feeling generation speed can be automatically obtained from the position where the evaluator determines the afterimage feeling.

  In addition to the moving speed, the cause of the afterimage feeling in the moving body may be the influence of the luminance difference value from the background and the difference values of various color values. Therefore, in the present invention, luminance change and saturation change movies in which the brightness and saturation change according to the moving position of the moving body are displayed and the brightness and saturation at which afterimage is generated are measured and evaluated. be able to.

Also in this case, a map screen having a luminance scale or a saturation change scale in which the relationship between the position of the moving object and the luminance or saturation is graphed is prepared and displayed by switching to a moving image. By reading the scale value corresponding to, it is possible to easily and accurately read the luminance or saturation of the moving body at the position where the afterimage feeling occurs, that is, the afterimage feeling determination brightness or saturation.

  FIG. 1 is an explanatory diagram of an image quality evaluation environment showing a first embodiment of an image quality evaluation apparatus according to the present invention. In this first embodiment, the image quality is evaluated using a speed change moving image. It is characterized by.

  In FIG. 1, a room or facility for image quality evaluation in this embodiment is an image quality evaluation environment 10, and the image quality evaluation environment 12 includes an image quality evaluation apparatus 12-1 in the first embodiment of the present invention and a video used for image quality evaluation. A moving image player 14 for reproduction and a liquid crystal television 16 as a display device to be evaluated are provided. The liquid crystal television 16 includes a liquid crystal panel 18.

  The image quality evaluation according to the present embodiment is evaluated by the evaluator 22 visually, and a determination input device 20 is provided to input the evaluation determination of the evaluator 22 to the image quality evaluation apparatus 12-1. As the determination input device 20, for example, when a personal computer is used as the image quality evaluation apparatus 12-1, a keyboard, a mouse, or the like can be used, or a dedicated push button switch can be used.

  The position of the evaluator 22 with respect to the liquid crystal television 16 to be evaluated determines the measurement conditions such as 2.0 meters in front of the liquid crystal panel.

  An external host 24 is connected to the image quality evaluation apparatus 12-1 installed in the image quality evaluation environment 10 via a network. In the present embodiment, on the host 24 side, the image quality evaluation apparatus 12-1 creates speed change moving images, speed map images, moving image management information, and the like used for image quality evaluation by preparatory work, and the image quality evaluation apparatus via the network. 12-1 is used for image quality evaluation.

  For this reason, the host 24 is provided with an evaluation moving image creating unit 26-1, and the evaluation moving image creating unit 26-1 creates a moving image management table 28-1, a speed change moving image file 30-1, and a speed map image file 32-1. The

  Information necessary for the image quality evaluation is transferred from the host 24 to the image quality evaluation apparatus 12-1 via the network via the control unit 34-1, and similarly, the moving image management table 28-1, the speed change moving image file 30-1, and It is stored as a speed map image file 32-1.

  The image quality evaluation device 12-1 includes a speed change moving image display unit 36-1, a speed map image display unit 38-1, a determination operation detection unit 40-1, a determination position detection unit 42-1, and an afterimage feeling generation speed detection unit 44. -1 is provided.

  The speed change video display unit 36-1 reads a speed change video whose movement speed changes according to the movement position on the screen of the moving body from the speed change video file 30-1, and outputs the speed change video to the video player 14. The speed change moving image is repeatedly displayed on the liquid crystal panel 18 of the liquid crystal television 16 by the device 14.

  When the evaluator 22 looks at the moving body whose moving speed changes according to the moving position displayed on the liquid crystal television 16 and confirms the occurrence of an afterimage feeling that causes the moving body to blur, a marker such as a mouse cursor is positioned at that position. Is moved and pointed to, a determination operation signal indicating that the afterimage feeling of the moving body has been determined by a mouse, keyboard, or push button operation of the determination input device 20 is sent to the image quality evaluation apparatus 12-1.

  The determination operation signal from the determination input device 20 is input to the determination operation detection unit 40-1 and the determination position detection unit 42-1. In the present embodiment, the user reading mode in which the determination operation detection unit 40-1 is enabled and the automatic reading mode in which the determination position detection unit 42-1 and the afterimage feeling generation speed detection unit 44-1 are enabled. There are two modes, and one of the modes can be selected by an initial setting operation on the control unit 34-1.

  When the user reading mode is set in the control unit 34-1, the determination operation detecting unit 40-1 operates effectively. When the determination operation detection unit 40-1 detects a determination operation signal that is operated when determining the afterimage feeling of the evaluator 22 who has viewed the speed change video repeatedly displayed on the liquid crystal panel 18 of the liquid crystal television 16, the speed map A detection output is generated in the image display unit 38-1, and is operated.

  The speed map image display unit 38-1 reads the speed map image from the speed map image file 32-1, stops the speed change moving image that has been displayed so far, and the speed map that is a still image via the moving image player 14. The image is switched and displayed on the liquid crystal television 16.

  The speed map image displays a speed scale indicating the speed corresponding to the moving position on the screen of the moving body, and the position at which the evaluator 22 determines the afterimage feeling with the determination input device 20 is, for example, a cursor on the liquid crystal panel 18. Therefore, the afterimage feeling determination speed at which the afterimage feeling of the moving object is determined can be easily read from the speed scale where the marker of the speed map image is located.

  On the other hand, when the automatic reading mode is set by the control unit 34-1, the determination position detection unit 42-1 and the afterimage feeling generation speed detection unit 44-1 are enabled. The determination position detection unit 42-1 is pointed by a marker on the screen from the determination operation signal when the evaluator 22 who is watching the speed change video repeatedly displayed on the liquid crystal television 16 determines the afterimage feeling of the moving object. The determination position is detected.

  The afterimage feeling generation speed detection unit 44-1 detects the afterimage feeling generation speed of the moving body by referring to the moving image management table 28-1 based on the determination position detected by the determination position detection unit 42-1. If there is, it is displayed at one corner of the liquid crystal panel 18 and recorded as data in a memory (not shown).

  FIG. 2 is an explanatory diagram showing a creation process of a moving image management table, a speed change moving image, and a speed map image in the first embodiment of FIG. In the first embodiment of FIG. 1, when creating a speed change moving image, the moving image management table 28-1 is first prepared. Of course, the preparatory work for creating the speed change moving image in the embodiment of FIG. 1 is performed on the host 24 side.

  The moving picture management table 28-1 manages the speed change moving picture by dividing it into frame numbers FL1 to FLn indicating frames corresponding to the moving picture time. When creating a speed change image, first, a moving object of interest is determined, and then a moving path P (t) of the moving object on the screen is determined.

  This movement path P (t) is a path that moves linearly from the left end to the right end, for example. Subsequently, for example, a constant acceleration α is determined as a parameter for changing the moving speed according to the moving position of the moving body on the screen. When the acceleration α is determined in this manner, the moving body increases at a constant acceleration while moving from the left to the right on the screen.

  If the moving path of the moving body and the acceleration α of the speed change are determined, the moving body positions P1 to Pn of each frame specified by the frame numbers FL1 to FLn are determined. The moving body positions P1 to Pn are specifically two-dimensional coordinates P (x, y) of the screen.

  If the moving image management table 28-1 can be created, based on this, as shown below, a speed change moving image 46 composed of frames 46-1 to 46-n corresponding to the frame numbers FL1 to FLn is displayed. create. In this embodiment, the moving bodies 48-1 to 48-n of the frames 46-1 to 46-n are indicated by black circles.

  The frames 46-1 to 46-n constituting the speed change moving image 46 display the moving images by switching the frames at a period of 1/30 seconds, for example. Therefore, the frame switching time t is a fixed time of t = (1/30) seconds.

If the moving body 48-1 at the position P1 of the first frame 46-1 is stopped at the start position, the speed V of the moving body 48-2 of the next frame 46-2 and the moving distance L12 to the position P2 are as follows. It is obtained as follows. Here, it is assumed that the moving speed of the moving body changes at a constant acceleration α.
V = αt
L12 = αt ²

  Then, as shown sequentially from the third frame 46-3, the speed of the moving body increases as the frame switching proceeds, and the moving distance also increases as the speed increases, such as L23, L24.

  If the speed change moving image 46 composed of such frames 46-1 to 46-n can be created, the speed scale 52 having the moving body positions P1 to Pn in the frames 46-1 to 46-n as scales is provided. A speed map image 50 is created.

  The speed scale 52 of the speed map image 50 can be created by merging the positions P1 to Pn of the moving bodies 48-1 to 48-n of the frames 46-1 to 46-n in the speed change moving image 46.

  Note that the speed scale 52 in FIG. 2 indicates the speed with respect to the scale of the moving body position at every fixed frame switching time, but actually, the speed scale 52 is provided with a scale of equal intervals and moved to each scale. The speed is displayed according to the position.

  FIG. 3 is an explanatory diagram showing measurement processing for image quality evaluation in the first embodiment of FIG. In FIG. 3, the speed change moving image 46 and the speed map image 50 are created on the host 24 side as shown in FIG. 1, and the speed change moving image file 30-1 and the speed map image file 32-1 are stored in the image quality evaluation apparatus 12-1. It is stored together with the moving image management table 28-1.

  The speed change video 46 is an image in which a moving body 48 indicated by, for example, a white circle moves from the left side to the right side while increasing the moving speed at an acceleration α, and this is repeatedly output to the liquid crystal television 16 to be evaluated. As shown in the moving image display screen 54, the speed change moving image is repeatedly displayed.

  As shown in this moving image display screen 54, in a state where the speed change moving image 46 is repeatedly displayed, the evaluator 22 observes the moving body while increasing the speed from the right to the left on the screen, and the moving body is blurred. When the afterimage feeling occurrence position is recognized, for example, a marker 55 indicated by an arrow is set at that position, and a determination operation signal is supplied to the image quality evaluation apparatus 12-1 by operating the determination input device 20 shown in FIG.

  If the control unit 34-1 has set the user reading mode, a speed map image 50 having a speed scale 52 prepared in advance from the moving image display screen 54 is received in response to a determination operation signal from the evaluator 22. The speed map screen 56 shown in FIG.

  At this time, since the marker 55 set by the evaluator 22 in accordance with the position of the moving body where the afterimage feeling is generated remains as it is, when the screen is switched to the speed map screen 56, the position of the marker 55 indicating the afterimage feeling occurrence position is changed. By reading the speed from the speed scale 52, the evaluator 22 can easily know the afterimage feeling generation speed.

  FIG. 3 shows an example of the user reading mode. In the case of the automatic reading mode, the evaluator 22 sees the moving body position from the determination switch operation when the moving body appears blurred when looking at the moving image display screen 54, for example, The moving picture frame number at that time is detected, the afterimage feeling occurrence speed is detected from the moving picture management table 28-1 and logged in the screen display or memory, and the switching display to the speed map screen 56 is not performed. Switching display may be performed.

  FIG. 4 is a block diagram showing a hardware environment of a computer in which the image quality evaluation apparatus 12-1 in the first embodiment of FIG. 1 is realized. In FIG. 4, the computer has a CPU 58, and a device interface 68 for connecting a RAM 62, a ROM 64, a hard disk drive 66, a keyboard 70, a mouse 72, a display 74, and a network adapter 76 are connected to a bus 60 of the CPU 58.

  The hard disk drive 66 is used to evaluate the image quality of the program necessary for the image quality evaluation process of the present embodiment and the moving image management table 28-1, the speed change moving image file 30-1 and the speed map image file 32-1 shown in FIG. Necessary data is stored.

  When the computer is started, an OS is loaded from the hard disk drive 66 to the RAM 62 and executed through a boot process by executing the boot code of the ROM 64, and subsequently, a program for realizing an image quality evaluation function from the hard disk drive 66 along with the execution of the OS, and File data such as a speed change moving image is loaded into the RAM 62, and the CPU 58 executes a program for realizing the image quality evaluation function.

  FIG. 5 is a flowchart showing the evaluation moving image creating process in the first embodiment of FIG. 1, and is a process that is a preparatory work on the host 24 side. In FIG. 5, the evaluation moving image creation process of the first embodiment determines a moving body to be focused on in step S <b> 1, and then creates a movement path P (t) on the screen of the focused moving body.

  Subsequently, in step S2, the moving speed V (x, y) of the moving body having the created moving path P (t) is detected. Specifically, as shown in FIG. 2, the moving path of the moving body is a straight path that moves from the left to the right of the screen, and the moving speed according to the moving position of the moving body increases at a constant acceleration α. It is.

Accordingly, the moving body positions P1 to Pn for each frame constituting the speed change video are determined as in the movement management table 28-1 in FIG. 2, and when the moving body positions P1 to Pn are determined, the switching time for each frame is the frame period. Since t = (1/30) second, the moving speed V is V = αt
The moving distance L for determining the moving position is L = αt ²
It is obtained as

  In step S3, a moving image management table 28-1 in which P1 to Pn and speeds V1 to Vn are registered is created corresponding to the frame number as shown in FIG.

  Next, in step S4, a speed change moving image 46 is created based on the moving image management table 28-1 as shown by a continuous scene in units of frames in FIG. In step S5, a speed map image 50 having a speed scale 52 is created from the positions of the moving bodies 48-1 to 48-n of the frames 46-1 to 46-n in the speed change moving image 46 and their speeds.

  FIG. 6 is a flowchart showing an evaluation image creation process using an existing moving image according to the first embodiment. In the embodiment of FIG. 5, a case where a dedicated moving image is created as an evaluation image is taken as an example. However, the embodiment of FIG. 6 is characterized in that an evaluation image is created using an existing moving image. To do.

  In FIG. 6, a moving image used for evaluation is read in step S1. As a moving image used for this evaluation, a moving image such as a bird flying while changing the speed in the screen or an animal moving in the screen can be used. Subsequently, in step S2, a moving body to be noted for image quality evaluation is determined from the read moving image. For example, a bird flying in the screen is determined as a moving object of interest.

  In step S3, the moving speed V (x, y) of the moving object in the moving image is calculated. In calculating the moving speed V, the moving body position is obtained for each frame, and the moving body actually moves on the screen by dividing the moving distance L on the screen by the frame period t = (1/30) second. Calculate the speed.

  Next, in step S4, for example, a moving image management table 28-1 in which the moving body position and speed are registered corresponding to the frame number as shown in FIG. 2 can be created. Further, in step S5, a speed map image 50 for displaying the speed scale 52 is created from the position on the screen and the speed obtained for the moving object of interest in the existing moving image. Note that the speed scale when the existing moving image is used is a scale indicating a random speed calculated with respect to the position, without the moving speed of the moving body changing continuously with the change of the position.

  FIG. 7 is a flowchart showing measurement processing for image quality evaluation in the first embodiment of FIG. 1 in the user reading mode. In FIG. 7, in the user reading mode measurement process, the speed change moving image display unit 36-1 reads the speed change moving image from the speed change moving image file stored in the image quality evaluation apparatus 12-1 by transfer from the host 24 in step S1. The video is output to the video player 14 and the speed change video is repeatedly displayed on the liquid crystal panel 18 of the liquid crystal television 16 to be evaluated.

  In this state, for example, the evaluator 22 observes the moving body while increasing the speed from the left to the right in the display state of the moving image display screen 54 as shown in FIG. When the occurrence position is recognized, a marker 55 is set at that position as shown in the moving image display screen 54 in FIG. 3, and a determination operation detection signal is output to the image quality evaluation apparatus 12-1 by operating the cursor determination input device 20.

  Subsequently, whether or not the evaluation is completed is checked in step S3. If an afterimage feeling determination operation signal is obtained, it is determined that the evaluation is completed. In step S4, a moving image is displayed as shown in the speed map screen 56 of FIG. Switching from the screen 54 displays the speed scale 52.

  At this time, since the marker 55 indicating the afterimage feeling determination position remains, the evaluator 22 can easily read the afterimage feeling occurrence speed determined by the evaluator 22 from the position of the speed scale 52 indicated by the marker 55. In the actual image quality evaluation, the user reading mode measurement process shown in FIG. 7 is repeated several times, and the average value of the reading values of the speed scale on the speed map screen switched from the speed screen is obtained, so that a stable afterimage generation speed is obtained. Can be detected.

  FIG. 8 is a flowchart showing the measurement process in the first embodiment of FIG. 1 in the automatic reading mode. In the measurement process in the automatic reading mode, a speed change image for evaluation is displayed in step S1, the signal of the determination input device 20, for example, an afterimage feeling determination switch is read in step S2, and the signal of the afterimage feeling determination switch is displayed in step S3. If it is obtained, it is recognized that the evaluation is completed. In step S4, the afterimage feeling occurrence position P on the screen where the user operated the afterimage feeling determination switch is read. In step S5, the moving object position P is used to correspond from the moving image management table 28-1. The afterimage feeling generation speed V to be detected is detected.

  Specifically, the frame number when the operation signal of the afterimage feeling determination switch is detected in step S4 is acquired from the speed change moving image being reproduced, and the moving image management table 28-1 in FIG. 2 is referred to by this frame number. Thus, the corresponding speed can be automatically detected.

  The afterimage feeling generation speed automatically detected in step S5 may be numerically displayed at the corner of the screen on the liquid crystal television 16, or the detected afterimage feeling movement speed may be stored as log information in the memory of the image quality evaluation apparatus 12-1, for example. It may be recorded together with the ID of the evaluator 22 and transferred to the host 24 after measurement and processed.

  FIG. 9 is an explanatory view showing a second embodiment of the image quality evaluation apparatus according to the present invention using a luminance change image. In FIG. 9, the image quality evaluation environment 10 is provided with an image quality evaluation device 12-2 according to the second embodiment, a video player 14, and a liquid crystal television 16 that is a display device to be evaluated. It has. In addition, a determination input device 20 is provided for inputting the evaluation determination of the evaluator 22 to the image quality evaluation apparatus 12-2.

  A host 24 is connected to the image quality evaluation apparatus 12-2 installed in the image quality evaluation environment 10 via a network. In this embodiment, the host 24 is provided with an evaluation moving image creating unit 26-2, and the moving image management table 28-2, the luminance change moving image file 30-2, and the luminance map image file 32-2 are used as preparation work. I try to create it.

  The image quality evaluation apparatus 12-2 is provided with a control unit 34-2, and the control unit 34-2 can set either one of the user reading mode and the automatic reading mode as in the first embodiment of FIG. . The image quality evaluation apparatus 12-2 transfers and holds a moving image management table 28-2, a luminance change moving image file 30-2, and a luminance map image file 32-2 created by the host 24 via a network.

  The image quality evaluation apparatus 12-2 includes a luminance change video display unit 36-2, a luminance map image display unit 38-2, a determination operation detection unit 40-2, and a determination position detection unit for image quality evaluation using a luminance change video. 42-2 and an afterimage sensation generation luminance detection unit 44-2 are provided.

  When the user reading mode is set by the control unit 34-2, the luminance change video display unit 36-2 is displayed on the liquid crystal television 16 to be evaluated on the screen of the moving object stored in the luminance change video file 30-2. A luminance change moving image whose luminance changes according to the moving position is output to the moving image player 14, and is repeatedly displayed on the liquid crystal television 16 by the moving image player 14.

  The determination operation detection unit 40-2 is a movement in which the evaluator 22 looks at the luminance change video repeatedly displayed on the liquid crystal television 16 and moves at a constant speed while moving from the left to the right of the screen at a constant speed, for example. When the body is observed and a position where an afterimage is generated that causes blurring behind the moving direction of the moving body is recognized, a marker such as a mouse cursor such as an arrow is positioned at that position and output by operating the determination input device 20 A determination operation signal to be detected is detected.

  The determination operation detected by the determination operation detection unit 40-2 is output to the luminance map image display unit 38-2, and the luminance map image display unit 38-2 moves the moving object on the screen from the luminance map image file 32-2. The luminance map screen displaying the luminance scale indicating the luminance corresponding to the position is read out, the reproduction of the luminance change moving image by the moving image reproducing device 14 is stopped, and the display is switched to the luminance map image display. By changing the display of the brightness map image, the evaluator 22 can read the afterimage feeling occurrence brightness from the scale of the brightness scale indicated by the marker that has determined the afterimage feeling.

  On the other hand, when the automatic reading mode is set by the control unit 34-2, the repeated display of the moving moving image on the liquid crystal television 16 by the luminance change moving image display unit 36-2 is the same as the user reading mode. On the screen, the determination position detection unit 42-2 detects the determination operation position when the afterimage feeling is recognized and operated with respect to the luminance change of the moving body moving on the screen, and is detected by the afterimage feeling generation luminance detection unit 44-2. Referring to the moving image management table 28-2 based on the determination position, for example, the frame number of the determination position, the corresponding afterimage feeling occurrence luminance is detected and displayed on the screen corner of the liquid crystal television 16, or the detected afterimage feeling occurrence luminance is detected. Is recorded together with the ID of the evaluator 22 in the memory and transferred to the host 24 after the measurement.

  FIG. 10 is an explanatory diagram showing the creation processing of the moving image management table, the luminance change moving image, and the luminance map image in the second embodiment of FIG. 9, and is created as preparation work on the host 24 side of FIG.

  In FIG. 10, first, a moving image management table 28-2 used for creating a luminance change moving image is created. The moving image management table 28-2 has frame numbers FL1 to FLn corresponding to the number of frames over the moving image reproduction time of the luminance change moving image, and stores the luminances B1 to Bn corresponding to the moving body positions P1 to Pn, respectively.

  The moving object position determines the moving path of the moving object on the screen, and changes from, for example, a bright state to a dark state corresponding to the moving positions P1 to Pn of each frame when the moving object moves along the moving path at a constant speed, for example. The changing luminances B1 to Bn are set.

  Based on the moving picture management table 28-2, the brightness change moving picture 78 shown below can be created. The luminance change moving image 78 has frames 78-1 to 78-n, and moving bodies 80-1 to 80-n indicated by black circles move on the screen at a constant speed, and the luminance changes for each of the moving body positions P1 to Pn. It changes to B1-Bn.

  Here, the speed on the screen of the moving bodies 80-1 to 80-n is determined in the vicinity of a speed at which an afterimage feeling is likely to occur in a speed change moving image as shown in FIG.

  The brightness map image 82 creates a brightness scale 84 from the positions of the moving bodies 80-1 to 80-n in the frames 78-1 to 78-n of the brightness change moving image 78 and the brightness thereof.

  FIG. 11 is an explanatory view showing image quality evaluation measurement processing in the second embodiment of FIG. In FIG. 11, a brightness change moving picture 78 prepared in advance is output on the screen, and as shown in the moving picture display screen 86, for example, a circular figure displayed as a moving body with black as a background moves from a stationary state at a constant speed to maximize the brightness. A luminance change moving image 78 changing between luminance and black is repeatedly displayed.

  In the display of the luminance change moving image 78, when the luminance falls below a certain value on the moving image display screen 86, the evaluator 22 loses the boundary behind the object that is a circular figure and appears to be blurred. An afterimage is generated. Therefore, the evaluator 22 remembers the position where the afterimage feeling has occurred and indicates it with the marker 88, for example, and performs the determination operation of the determination input device 20 assuming that the image quality evaluation result has been obtained.

  When the evaluator 22 performs, for example, an afterimage feeling occurrence determination operation on the luminance change moving image, the position is indicated by the marker 88. Accordingly, the determination operation signal is received, and the display is switched to the luminance map screen 90 by display switching shown on the right side. The brightness scale 84 is displayed, and by looking at the position indicated by the marker 88 of the brightness scale 84, the brightness at which an afterimage feeling is generated can be read.

  FIG. 11 shows an example of the user reading mode. In the automatic reading mode, the evaluator 22 looks at the moving image display screen 86 and the moving body position, for example, from the determination switch operation when the moving body appears blurred. The moving image frame number at that time is detected, and the afterimage feeling occurrence luminance is detected from the moving image management table 28-2 and logged in the screen display or memory, and the switching display to the luminance map screen 90 is not performed. Switching display may be performed.

  FIG. 12 is a flowchart of the evaluation moving image using the luminance change moving image in the second embodiment of FIG. 9, and is created as a preparation work on the host 24 side.

  In FIG. 12, the evaluation moving image creation process creates a movement path P (t) on the display screen that provides a constant speed V of the moving object of interest in step S1. This is, for example, a movement path for linearly moving the screen from left to right. Of course, an appropriate trajectory can be set regardless of whether the movement path is a straight line or a curved line.

  Subsequently, in step S2, a luminance change B (x, y) of the moving body is created based on the movement path P (t). Here, since the moving speed of the moving body is a constant speed V, as shown in FIG. 10, the moving distance L on the screen of the moving body every frame switching time t = (1/30) second is L = Vt. Thus, the movement positions P1 to Pn are uniquely determined, and for each position, for example, as shown in FIG. 11, a luminance change B (x, y) that changes from the maximum luminance toward black is set and created.

  Subsequently, in step S3, a moving image management table 28-2 in which the moving body positions P1 to Pn and the luminances B1 to Bn are registered corresponding to the frame numbers as shown in FIG. 10 is created.

  Subsequently, in step S4, based on the moving image management table 28-2, a luminance change moving image 78 composed of frames 78-1 to 78-n as shown below is created. In step S5, a luminance map image 82 for displaying the luminance scale 84 is created.

  FIG. 13 is a flowchart showing an evaluation moving image creation process in the second embodiment of FIG. 9 using an existing moving image. In FIG. 13, a moving image such as a bird flying for use in the evaluation is read in step S <b> 1, and a moving body to be noticed in the moving image, for example, a moving bird is determined in step S <b> 2.

  In step S3, a luminance change corresponding to the moving position of the moving body is created. Specifically, the moving position of the moving body is obtained for each frame, and the luminance of the moving body is detected and set for each moving position. Subsequently, in step S4, the moving image management table 28-2 in which the moving body position and the luminance are registered corresponding to the frame number as shown in FIG. 10 is generated. In step S5, a brightness map image 82 displaying the brightness scale 84 as shown in FIG. 10 is created.

  FIG. 14 is a flowchart showing the measurement process in the second embodiment of FIG. 9 in the user reading mode. In FIG. 14, in the user reading mode measurement process, a luminance change moving image for evaluation is displayed on the liquid crystal television 16 to be evaluated as shown in FIG. 9 in step S1, and in this state, the determination input device 20 in step S2 is displayed. For example, the signal of the afterimage feeling determination switch is read.

  When the evaluator determines afterimage feeling, a marker is set at that position and the afterimage feeling determination switch is operated. Therefore, when a determination operation is detected by reading the afterimage feeling determination switch signal, completion of determination is determined in step S3. In step S6, the brightness map image is switched and displayed, and the afterimage feeling determination brightness can be read from the marker indicating the afterimage feeling determination position of the switched brightness scale.

  On the other hand, even if the luminance change moving image is repeatedly displayed in steps S1 to S3, the evaluator 22 may not be able to recognize the occurrence of afterimage for a moving body that changes its luminance moving on the screen. In this case, the process proceeds to step S4. When it is determined that the evaluation is impossible from the operation of the determination input device 20 indicating that the evaluation is impossible, the luminance change moving image having a different moving speed is changed in step 5 and the luminance change moving image is displayed from step S1. repeat.

  That is, when the afterimage of the moving body cannot be recognized from the initially displayed luminance changing moving image, the moving image is changed to a luminance changing moving image with a higher speed, for example, and the luminance changing moving image is repeatedly displayed. If the moving speed of the moving body increases, an afterimage feeling is likely to appear even if the brightness changes the same. Therefore, a determination is made by recognizing the occurrence of an afterimage for a moving body that moves on the screen and changes its brightness. Thus, the afterimage feeling generation speed can be read from the luminance scale of the luminance map image.

  FIG. 15 is a flowchart showing a measurement process in the second embodiment of FIG. 9 in the automatic reading mode. The processing in steps S1 to S5 in the automatic reading mode measurement processing in FIG. 15 is the same as the measurement processing in the user reading mode in FIG. 14, but if evaluation completion is determined in step S3, the process proceeds to step S6 to generate afterimage feeling. Recognizing from the operation of the recognized afterimage feeling determination switch on the screen, the afterimage feeling occurrence position P is detected. The detection of the afterimage feeling occurrence position P is the moving image frame number when the afterimage feeling determination switch is operated. Subsequently, in step S7, for example, the luminance corresponding to the frame number indicating the moving body position is read from the moving image management table 28-2 of FIG.

  FIG. 16 is an explanatory view showing a third embodiment of the image quality evaluation apparatus according to the present invention using a saturation change image. In FIG. 16, the image quality evaluation environment 10 is provided with an image quality evaluation device 12-3 according to the third embodiment, a video player 14, and a liquid crystal television 16 that is a display device to be evaluated. It has. Further, a determination input device 20 is provided for inputting an evaluation determination of the evaluator 22 to the image quality evaluation apparatus 12-3.

  A host 24 is connected to the image quality evaluation apparatus 12-3 via a network, and an evaluation moving image creating unit 26-3 is provided on the host 24 side, and a moving image management table 28-3, a saturation change moving image are prepared as preparation work. The file 30-3 and the saturation map image file 32-3 are created and stored, and are transferred to the image quality evaluation apparatus 12-3 via the network after the creation, and the same movie management table 28-3, saturation change movie The file 30-3 and the saturation map image file 32-3 are stored.

  The image quality evaluation apparatus 12-3 includes a saturation change video display unit 36-3, a saturation map image display unit 38-3, a determination operation detection unit 40-3, a determination position detection unit 42-3, and an afterimage-sensing saturation. The detection unit 44-3 is provided, and is basically the same as the case of the speed change image in FIG. 1 except that the processing target is a saturation change moving image and a saturation map image. The control unit 34-3 can be operated by setting one of the user reading mode and the automatic reading mode during image evaluation.

  When the user reading mode is set by the control unit 34-3, the saturation change moving image display unit 36-3 causes the liquid crystal television 16 which is a display device to be evaluated to correspond to the moving position on the screen of the moving body. Repeatedly display a saturation change video in which the saturation changes.

  The determination operation detection unit 40-3 operates when the user reading mode is set by the control unit 34-3, and outputs a determination operation signal when the evaluator 22 recognizes the afterimage feeling occurrence saturation from the determination input device 20. When detected, the saturation map image output to the saturation map image display unit 38-3, the saturation change moving image displayed so far is stopped, and the saturation map image having the saturation scale read from the saturation map image file 32-3. Switch to the display.

  In addition, when the automatic reading mode is set by the control unit 34-3, the determination position detection unit 42-3 detects an afterimage feeling generation saturation determination input signal by the evaluator 22, for example, an operation signal of an afterimage feeling determination switch. The afterimage feeling generation saturation detecting unit 44-3 detects the afterimage feeling generation saturation corresponding to the frame number of the moving image at the determination position from the moving image management table 28-3, displays it on the liquid crystal television 16, and logs it in the memory. Thus, the evaluation result is transferred to the host 24 after the measurement.

  FIG. 17 is an explanatory diagram showing a creation process of a movie management table, a saturation change movie, and a saturation map image in the third embodiment of FIG. The creation process of FIG. 17 is performed as preparation work on the host 24 side as shown in FIG. 16, and the moving image management table 28-3 is created first.

  The moving image management table 28-3 defines a moving path in which the moving body moves, for example, from left to right on the screen, and registers frame numbers FL1 to FLn determined by the number of frames over the moving image playback time according to the moving path, Assuming that the moving body moves at a constant speed, the moving body positions P1 to Pn according to the moving path are obtained from the moving speed V and the frame switching time t = (1/30) second.

  In the frames 92-1 to 92-n, the moving distance for each frame switching is the same distance as L = Vt because the moving speed V is constant and the frame switching time is t = (1/30) seconds. P1 to Pn are uniquely determined.

  Subsequently, saturations C1 to Cn that change at a certain ratio are registered for each of the moving body positions P1 to Pn. As the change of the colors C1 to Cn, for example, the color is changed by changing the wavelength stepwise from a short wavelength to a long wavelength in the human visible wavelength band or vice versa.

  Next, a saturation change moving image 92 is created based on the moving image management table 28-3. In the frames 92-1 to 92-n of the saturation change moving image 92, the saturation of the moving body that moves at a constant speed on a predetermined background color changes at a constant speed corresponding to the passage of time, that is, the movement position. It is a set of frame images that make up a moving image.

  Further, a saturation map image 94 having a saturation scale 96 having a scale indicating saturation according to the moving position of the moving body is created.

  FIG. 18 is a flowchart showing the evaluation image creation process in the third embodiment of FIG. 16, which is a process performed as a preparatory work on the host 24 side. In FIG. 18, the evaluation image creating process determines a moving body of interest in step S1, creates a moving path P (t) on the screen of the moving body at a constant speed V, and then moves the moving path P (t in step S2. ) To create a saturation change C (x, y) of the moving object.

  Specifically, the moving distance L for each frame switching is obtained from the frame period t of the display moving image and the constant moving speed V, and if the moving distance L is obtained, the moving positions P1 to Pn on the screen are obtained. A saturation change C that changes at a certain rate is set for each moving position.

  By the processing of step S2, the moving image management table 28-3 in which the moving body positions P1 to Pn and the saturations C1 to Cn are registered corresponding to the frame numbers as shown in FIG. 17 in step S3 can be created.

  Subsequently, in step S4, based on the moving image management table 28-3, as shown in FIG. 17, a saturation change moving image 92 including frames 92-1 to 92-n is created. In step S5, a saturation map image 94 having a saturation scale 96 is created as shown in FIG.

  FIG. 19 is a flowchart showing an evaluation moving image creation process using a saturation change moving image in the third embodiment of FIG. 16 using an existing moving image. In FIG. 19, in the evaluation moving image creating process using an existing moving image, a moving image used for evaluation is read in step S1, and a moving body to be noted in the moving image is determined in step S2.

  Subsequently, in step S3, a saturation change C (x, y) corresponding to the moving position of the moving body is detected, and in step S4, a moving image management table 28-3 as shown in FIG. 17 is created. In step S5, a saturation map image for displaying a saturation scale is created based on the moving image management table 28-3.

  FIG. 20 is a flowchart showing the measurement process in the third embodiment of FIG. 16 in the user reading mode, which will be described below with reference to FIG.

  In the user reading mode measurement process, the saturation change movie display unit 36-3 of the image quality evaluation device 12-3 reads the saturation change movie from the saturation change movie file 30-3 and outputs it to the movie player 14 in step S1. The saturation change video is repeatedly displayed on the liquid crystal television 16.

  When the evaluator 22 observes the moving body whose saturation changes while moving on the screen in the reproduction state of the saturation changing video, and recognizes the afterimage feeling in which the moving body is blurred, a marker is set at the determination position. Then, for example, an afterimage feeling determination switch is operated as the determination input device 20.

  Step S2 reads the signal of the afterimage feeling determination switch. If a determination switch signal is obtained, it is determined that the evaluation is completed in step S3, and a saturation map image having a saturation scale is displayed in step S6.

  When the evaluator 22 determines the afterimage feeling, since the marker is set at the moving position of the moving body, the afterimage feeling occurrence saturation is easily and from the saturation scale indicated by the marker when switching to the saturation map image. Easy to read.

  On the other hand, if the evaluator 22 cannot recognize the afterimage feeling even when the saturation change video is repeatedly reproduced in steps S1 to S3, an operation that cannot be evaluated is performed by operating the determination input device 20 or the like. Therefore, this is determined in step S4, and in step S5, it is changed to a saturation change moving image having a different moving speed, and the display of the saturation change moving image from step S1 is repeated.

  In other words, if the moving image cannot be recognized in the initially displayed saturation change video, the moving speed of the moving object may be too slow. A change video is displayed so that the evaluator 22 can easily feel an afterimage from a change in saturation of a moving body moving on the screen. In addition to increasing the speed of the moving body, it may be changed to a saturation change moving image with a different background color.

  FIG. 21 is a flowchart showing the measurement process in the third embodiment of FIG. 16 in the automatic reading mode. In this automatic reading mode measurement process, steps S1 to S5 are the same as the measurement process in the user reading mode of FIG. 20, but when the evaluation completion is determined in step S3, the determination position detection of FIG. 16 is performed in step S6. The moving body position where the afterimage feeling generated saturation is captured by the unit 42-3 is detected as, for example, the frame number of the moving image, and the afterimage feeling generated saturation detecting unit 44-3 determines, for example, from the moving image management table 28-3 in step S7. Saturation corresponding to the position (determination frame number) is read out and displayed on the screen, or logged together with the evaluator ID in the memory, and then transferred to the host 24 for processing. Also in this automatic reading mode, the saturation map image may be switched and displayed as necessary, similarly to the user reading mode.

  The present invention also provides a program for image quality evaluation that is executed by each of the image quality evaluation apparatuses 12-1, 12-2, and 12-3 in the embodiments of FIGS. This program has the contents shown in FIGS. 7 and 8 for the first embodiment, FIGS. 14 and 15 for the second embodiment, and FIGS. 20 and 21 for the third embodiment.

  In the second embodiment and the third embodiment in the above embodiment, the moving body is moved at a constant speed on the screen, but the speed may be changed. Absent.

  In the above embodiment, for example, in the first embodiment, a speed change moving image in which the moving speed increases at a constant acceleration, for example, at a position on the screen is displayed while increasing the speed. It is good also as a moving image display displayed while reducing the moving speed of a moving body by fixed acceleration by reproducing a change moving image in the reverse direction.

  The same applies to the luminance change movie and the saturation change movie. First, the change movie in one frame order is reproduced, and then the movie changing in the reverse direction is displayed and this is repeated. Good.

  In the above embodiment, an evaluation video in which the moving speed, luminance, and saturation are individually changed is taken as an example. However, it is also possible to change any combination of speed, luminance, and saturation. Or, it may be a moving image in which all of speed, luminance, and saturation are combined.

  Further, the present invention includes appropriate modifications that do not impair the object and advantages thereof, and is not limited by the numerical values shown in the above embodiments.

Here, the features of the present invention are enumerated as follows.
(Appendix)

(Appendix 1) (Method: Speed change video)
A speed change video display step for displaying a speed change video in which the moving speed changes according to the moving position on the screen of the moving body on the display device to be evaluated;
A determination operation detection step of detecting a determination operation signal when the evaluator watching the speed change video determines the afterimage feeling of the moving body;
When the determination operation signal is detected, a speed map display step of switching and displaying the speed change moving image on a speed map screen displaying a speed scale indicating a speed corresponding to a moving position on the screen of the moving body;
An image quality evaluation method characterized by comprising: (1)

(Appendix 2) (Automatic speed detection)
In the image quality evaluation method described in Appendix 1,
A speed change video display step for displaying a speed change video in which the moving speed changes according to the moving position on the screen of the moving body on the display device to be evaluated;
A determination position detection step of detecting a determination position on the screen from a determination operation signal when the evaluator watching the speed change video determines the afterimage feeling of the moving body;
An afterimage feeling generation speed detection unit that detects an afterimage feeling generation speed of the moving body based on the detected determination position;
An image quality evaluation method characterized by comprising: (2)

(Appendix 3) (Brightness change movie)
A luminance change video display step for displaying a luminance change video in which the luminance changes according to the movement position on the screen of the moving body on the display device to be evaluated;
A determination operation detection step of detecting a determination operation signal when the evaluator watching the luminance change video determines the afterimage feeling of the moving body;
When the determination operation signal is detected, a luminance map display step of switching and displaying the luminance change moving image on a luminance map screen displaying a luminance scale indicating luminance corresponding to a moving position on the screen of the moving body;
An image quality evaluation method characterized by comprising: (3)

(Appendix 4) (Automatic speed detection)
A luminance change video display step for displaying a luminance change video in which the luminance changes according to the movement position on the screen of the moving body on the display device to be evaluated;
A determination position detection step of detecting a determination position on the screen from a determination operation signal when the evaluator watching the luminance change video determines the afterimage feeling of the moving body;
An afterimage feeling generation luminance detecting unit that detects an afterimage feeling generation luminance of the moving body based on the detected determination position;
An image quality evaluation method characterized by comprising:

(Appendix 5) (Saturation change video)
A saturation change video display step for displaying a saturation change video in which the saturation changes according to the movement position on the screen of the moving object on the display device to be evaluated;
A determination operation detection step of detecting a determination operation signal when the evaluator watching the saturation change video determines the afterimage feeling of the moving body;
When the determination operation signal is detected, a saturation map display that switches and displays the saturation change moving image on a saturation map screen that displays a saturation scale corresponding to the moving position on the screen of the moving object. Steps,
An image quality evaluation method characterized by comprising: (4)

(Appendix 6) (Automatic speed detection)
A saturation change video display step for displaying a saturation change video in which the saturation changes according to the movement position on the screen of the moving object on the display device to be evaluated;
A determination position detection step of detecting a determination position on the screen from a determination operation signal when an evaluator watching the saturation change video determines the afterimage feeling of the moving body;
An afterimage sensation generation saturation detector that detects an afterimage sensation generation saturation of the moving body based on the detected determination position;
An image quality evaluation method characterized by comprising:

(Appendix 7) (Program: Speed change video)
Computer
A speed change video display unit for displaying a speed change video in which the moving speed changes according to the moving position on the screen of the moving body on the display device to be evaluated,
A determination operation detection unit that detects a determination operation signal when an evaluator watching the speed change video determines the afterimage feeling of the moving body, and when the determination operation signal is detected, the speed change video is moved. A speed map display section for switching to a speed map screen displaying a speed scale indicating a speed corresponding to a moving position on the body screen,
An image quality evaluation program characterized by functioning as

(Appendix 8) (Automatic speed detection)
Computer
A speed change video display unit for displaying a speed change video in which the moving speed changes according to the moving position on the screen of the moving body on the display device to be evaluated,
A determination position detection unit that detects a determination position on the screen from a determination operation signal when the evaluator watching the speed change video determines the afterimage feeling of the moving body; and
An afterimage feeling generation speed detection unit that detects an afterimage feeling generation speed of the moving body based on the detected determination position;
An image quality evaluation program characterized by functioning as

(Appendix 9) (Brightness change movie)
Computer
A luminance change video display unit that displays a luminance change video in which the luminance changes according to the movement position on the screen of the moving object on the display device to be evaluated,
A determination operation detection unit that detects a determination operation signal when an evaluator watching the luminance change video determines an afterimage feeling of the moving body; and
When the determination operation signal is detected, a luminance map display unit that displays the luminance change moving image by switching to a luminance map screen that displays a luminance scale indicating luminance corresponding to a movement position on the screen of the moving body,
An image quality evaluation program characterized by functioning as

(Appendix 10) (Automatic speed detection)
Computer
A luminance change video display unit that displays a luminance change video in which the luminance changes according to the movement position on the screen of the moving object on the display device to be evaluated,
Based on the determination position detection unit that detects the determination position on the screen from the determination operation signal when the evaluator watching the saturation change video determines the afterimage feeling of the moving body, and based on the detected determination position An afterimage feeling generation luminance detecting unit for detecting an afterimage feeling generation luminance of the moving body;
An image quality evaluation program characterized by functioning as

(Appendix 11) (Saturation change video)
Computer
A saturation change video display unit that displays a saturation change video in which the saturation changes according to the movement position on the screen of the moving body on the display device to be evaluated,
A determination operation detection unit that detects a determination operation signal when the evaluator watching the saturation change video determines the afterimage feeling of the moving body, and
When the determination operation signal is detected, a saturation map display that switches and displays the saturation change moving image on a saturation map screen that displays a saturation scale corresponding to the moving position on the screen of the moving object. Part,
An image quality evaluation program characterized by functioning as

(Appendix 12) (Automatic speed detection)
Computer
A saturation change video display unit that displays a saturation change video in which the saturation changes according to the movement position on the screen of the moving body on the display device to be evaluated,
A determination position detection unit that detects a determination position on a screen from a determination operation signal when an evaluator watching the saturation change video determines an afterimage feeling of the moving body; and
An afterimage sensation generation saturation detector that detects an afterimage sensation generation saturation of the moving body based on the detected determination position;
An image quality evaluation program characterized by functioning as

(Supplementary note 13) (Device: Speed change video)
A speed change video display unit that displays a speed change video in which the moving speed changes according to the moving position on the screen of the moving body on the display device to be evaluated;
A determination operation detection unit that detects a determination operation signal when the evaluator watching the speed change video determines the afterimage feeling of the moving body;
When the determination operation signal is detected, a speed map display unit that displays the speed change video by switching to a speed map screen that displays a speed scale indicating a speed corresponding to a moving position on the screen of the moving body;
An image quality evaluation apparatus comprising:

(Appendix 14) (Automatic speed detection)
A speed change video display unit that displays a speed change video in which the moving speed changes according to the moving position on the screen of the moving body on the display device to be evaluated;
A determination position detection unit that detects a determination position on the screen from a determination operation signal when the evaluator watching the speed change video determines the afterimage feeling of the moving body;
An afterimage feeling generation speed detection unit that detects an afterimage feeling generation speed of the moving body based on the detected determination position;
An image quality evaluation apparatus comprising:

(Appendix 15) (Brightness change movie)
A luminance change video display unit that displays a luminance change video in which the luminance changes according to the movement position on the screen of the moving body on the display device to be evaluated;
A determination operation detection unit that detects a determination operation signal when the evaluator watching the luminance change video determines the afterimage feeling of the moving body;
When the determination operation signal is detected, a luminance map display unit that displays the luminance change moving image by switching to a luminance map screen that displays a luminance scale indicating luminance corresponding to a movement position on the screen of the moving body;
An image quality evaluation apparatus comprising:

(Appendix 16) (Automatic brightness detection)
A luminance change video display unit that displays a luminance change video in which the luminance changes according to the movement position on the screen of the moving body on the display device to be evaluated;
A determination position detection unit that detects a determination position on a screen from a determination operation signal when an evaluator watching the luminance change video determines an afterimage feeling of the moving body;
An afterimage feeling generation luminance detecting unit that detects an afterimage feeling generation luminance of the moving body based on the detected determination position;
An image quality evaluation apparatus comprising:

(Supplementary Note 17) (Saturation Change Movie)
A saturation change video display unit that displays a saturation change video in which the saturation changes according to the movement position on the screen of the moving body on the display device to be evaluated;
A determination operation detection unit that detects a determination operation signal when an evaluator watching the saturation change video determines the afterimage feeling of the moving body;
When the determination operation signal is detected, a saturation map display that switches and displays the saturation change moving image on a saturation map screen that displays a saturation scale corresponding to the moving position on the screen of the moving object. And
An image quality evaluation apparatus comprising:

(Supplementary note 18) (Automatic saturation detection)
A saturation change video display unit that displays a saturation change video in which the saturation changes according to the movement position on the screen of the moving body on the display device to be evaluated;
A determination position detection unit that detects a determination position on the screen from a determination operation signal when the evaluator watching the speed change video determines the afterimage feeling of the moving body;
An afterimage sensation generation saturation detector that detects an afterimage sensation generation saturation of the moving body based on the detected determination position;
An image quality evaluation apparatus comprising:

Explanatory drawing which showed 1st Embodiment of the image quality evaluation apparatus by this invention using a speed change image. Explanatory drawing which showed the production process of the moving image management table, speed change moving image, and speed map image in 1st Embodiment of FIG. Explanatory drawing which showed the measurement process of the image quality evaluation in 1st Embodiment of FIG. 1 is a block diagram showing a hardware environment of a computer in which the image quality evaluation apparatus of the present embodiment is realized. The flowchart which showed the production process of the evaluation moving image in 1st Embodiment of FIG. A flowchart showing the creation process of an evaluation video in the first embodiment of FIG. 1 using an existing video. A flowchart showing a measurement process in the first embodiment of FIG. 1 in the user reading mode. A flowchart showing the measurement process in the first embodiment of FIG. 1 in the automatic reading mode. Explanatory drawing which showed 2nd Embodiment of the image quality evaluation apparatus by this invention using a brightness change image. FIG. 9 is an explanatory diagram showing a moving image management table, a luminance change moving image, and a luminance map image creation process in the second embodiment Explanatory drawing which showed the image quality evaluation measurement process in 2nd Embodiment of FIG. The flowchart which showed the creation process of the evaluation moving image in 2nd Embodiment of FIG. A flowchart showing a process for creating an evaluation video in the second embodiment of FIG. 9 using an existing video. A flowchart showing measurement processing in the second embodiment of FIG. 9 in the user reading mode. A flowchart showing a measurement process in the second embodiment of FIG. 9 in the automatic reading mode. Explanatory drawing which showed 3rd Embodiment of the image quality evaluation apparatus by this invention using a saturation change image. Explanatory drawing which showed the production | generation process of the moving image management table, saturation change moving image, and saturation map image in 3rd Embodiment of FIG. The flowchart which showed the creation process of the evaluation moving image in 3rd Embodiment of FIG. Flowchart showing an evaluation moving image creation process in the third embodiment of FIG. 16 using an existing moving image. The flowchart which showed the measurement process in 3rd Embodiment of FIG. 16 by user reading mode. A flowchart showing a measurement process in the third embodiment of FIG. 16 in the automatic reading mode. Explanatory drawing of measurement processing by conventional MPRT method

Explanation of symbols

10: Image quality evaluation environment 12-1 to 12-3: Image quality evaluation device 14: Movie player 16: Liquid crystal television 18: Liquid crystal panel 20: Determination input device 22: Evaluator 24: Hosts 26-1 to 26-3: Evaluation Movie creation units 28-1 to 28-3: Movie management table 30-1: Speed change movie file 30-2: Luminance change movie file 30-3: Saturation change movie file 32-1: Speed map image file 32-2 : Luminance map image file 32-3: Saturation map image files 34-1 to 34-3: Control unit 36-1: Speed change video display unit 36-2: Luminance change video display unit 36-3: Saturation change video Display unit 38-1: Speed map image display unit 38-2: Luminance map image display unit 38-3: Saturation map image display units 40-1 to 40-3: Determination operation detection units 42-1 to 42-3: Determination position detector 4 -1: Afterimage sensation generation speed detection unit 44-2: Afterimage sensation generation luminance detection unit 44-3: Afterimage sensation generation saturation detection unit 46: Speed change moving images 46-1 to 46-n, 78-1 to 78-n , 92-1 to 92-n: frames 48-1 to 48-n, 80-1 to 80-n, 94-1 to 94-N: moving body 50: speed map image 52: speed scale 54, 86: moving image Display screen 55, 88: Marker 56: Speed map screen 58: CPU
60: Bus 62: RAM
64: ROM
66: Hard disk drive 68: Device interface 70: Keyboard 72: Mouse 74: Display 76: Network adapter 78: Brightness change movie 82: Brightness map image 84: Brightness scale image 90: Brightness map image 92: Saturation change movie 94: Saturation Map image 96: Saturation scale

Claims (4)

A speed change video display step for displaying a speed change video in which the moving speed changes according to the moving position on the screen of the moving body on the display device to be evaluated;
A determination operation detection step of detecting a determination operation signal when the evaluator watching the speed change video determines the afterimage feeling of the moving body;
When the determination operation signal is detected, a speed map display step of switching and displaying the speed change moving image on a speed map screen displaying a speed scale indicating a speed corresponding to a moving position on the screen of the moving body;
An image quality evaluation method characterized by comprising:
In the image quality evaluation method according to claim 1,
And determining the position detecting step is evaluator looking at the front Symbol rate change video detecting the determination position on the screen from the determination operation signal when it is determined the afterimage of the moving body,
An afterimage feeling generation speed detection step of detecting an afterimage feeling generation speed of the moving body based on the detected determination position;
An image quality evaluation method characterized by comprising: A luminance change video display step for displaying a luminance change video in which the luminance changes according to the movement position on the screen of the moving body on the display device to be evaluated;
A determination operation detection step of detecting a determination operation signal when the evaluator watching the luminance change video determines the afterimage feeling of the moving body;
When the determination operation signal is detected, a luminance map display step of switching and displaying the luminance change moving image on a luminance map screen displaying a luminance scale indicating luminance corresponding to a moving position on the screen of the moving body;
An image quality evaluation method characterized by comprising:
A saturation change video display step for displaying a saturation change video in which the saturation changes according to the movement position on the screen of the moving object on the display device to be evaluated;
A determination operation detection step of detecting a determination operation signal when the evaluator watching the saturation change video determines the afterimage feeling of the moving body;
When the determination operation signal is detected, a saturation map display that switches and displays the saturation change moving image on a saturation map screen that displays a saturation scale corresponding to the moving position on the screen of the moving object. An image quality evaluation method comprising the steps of:

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