JP2005221876A - Image processor and image processing method and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image processor capable of easily and exactly performing the adjustment of picture quality and the comparison of images by assigning and displaying division images made by dividing one image into two images to division regions made by dividing one display screen into two regions of central and outer ones according to division boundary lines. <P>SOLUTION: The image processor 1 divides the display screen to two division regions of central and outer ones and assigns the division images divided from one image to the respective division regions. A synthetic image obtained by synthesizing a plurality of the division images based on the location and the size of the respective division regions on the display screen is transmitted to the image display device 2 and is outputted onto the display screen of the image display device 2. User can change the location and the size of the division regions displayed on the display screen by changing the respective division regions. Accordingly, by dividing the division regions to the central and outer ones, the division boundary line is prevented from being located on the center of the display screen and, therefore, it is made possible to see the images, particularly, the animations easily. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to image quality adjustment of a TV (Television) receiver or the like, and evaluation of a plurality of images subjected to predetermined processing.

  Normally, when adjusting image quality such as color setting with a TV receiver or the like, if the user adjusts the corresponding parameter, the entire screen changes depending on the parameter, so the image before adjustment and the image after adjustment are 1 Cannot be compared on two display screens. Therefore, it has been difficult for the user to appropriately determine whether or not the image after adjustment is optimal.

  In order to solve this problem, when adjusting the image quality with a TV receiver or the like, a method of dividing the display screen and combining and displaying the image before adjustment and the image after adjustment is known (for example, Patent Document 1). According to this, since the image before adjustment and the image after adjustment can be viewed on one display screen, the user can easily and appropriately adjust the image quality while comparing the two images. be able to.

  However, in the conventional method, since the division of the display screen is fixed, a specific portion of a predetermined image is viewed at any time before or after image quality adjustment. Therefore, it is difficult to accurately compare specific parts. Further, since the division is to divide the display screen into two or more left and right, the division boundary line is always at the center, and the image is difficult to view. Therefore, when the image before the image quality adjustment and the image after the adjustment are displayed on one display screen and the image quality is adjusted while watching a movie or the like by the image, the dividing boundary line is positioned at the center. Being an obstacle is an obstacle.

  Furthermore, in the conventional method, even if an image with an image quality setting that seems to be optimal is selected and switched to display on the entire display screen, the display screen is equally divided, so that it is sensuous to see which image has been switched to. It is difficult to understand. Therefore, there is a problem that even if an operation is incorrect and another image that is not an image with the optimum image quality setting is displayed on the entire display screen, it is difficult to understand intuitively.

JP 2001-268475 A

  The present invention has been made in view of the above points, and assigns a divided image obtained by dividing one image into two to a divided region obtained by dividing one display screen into a central area and an outer area by dividing boundaries. It is an object of the present invention to provide an image processing apparatus that can easily and accurately adjust image quality and compare images by displaying the images.

  In one aspect of the present invention, an image processing device capable of transmitting and receiving data to and from an image display device that displays an image on a display screen, wherein the display screen is divided by a dividing boundary line that divides the display screen into a center and an outside. Dividing means for dividing the image into two divided areas, assigning means for assigning two divided images obtained by dividing one image to each divided area based on the position of the divided area on the display screen, and the assigning means, Composite image transmission means for combining the allocated divided images so as to be displayed in each divided region on the display screen and transmitting the combined images to the image display device.

  An image processing method according to a similar aspect includes a dividing step of dividing the display screen into two divided areas by a dividing boundary line dividing the display screen included in the image display device into a center and an outside, and a display on the display screen. An assigning step of assigning two divided images obtained by dividing one image to each divided region based on the position of the divided region, and the divided image assigned by the assigning unit are displayed in each divided region on the display screen. A combined image transmission step of combining and transmitting to the image display device.

  In the image processing apparatus or method configured as described above, the image processing apparatus is an apparatus capable of data communication with an image display apparatus, specifically, a TV receiver or a DVD (Digital Video Disc, Digital Versatile Disc) player. Etc. The image display device is a device that includes a display screen such as a monitor, a projector, and a display for displaying an image, and displays an image received from the image processing device on the display screen.

  The image processing apparatus divides the display screen into two divided areas at the center and the outside, and assigns divided images obtained by dividing one image to each divided area. Then, based on the position and size of each divided area on the display screen, a combined image obtained by combining a plurality of divided images is transmitted to the image display device, and is output on the display screen included in the image display device. According to this, the user can view two divided images simultaneously on one screen. In addition, by setting the divided areas at the center and the outside, the divided boundary line is not positioned at the center of the display screen, so that an image, particularly a moving image can be easily seen. Also, since people generally tend to focus on the center image, it is possible to display the image in consideration of which one you want to focus on, such as assigning the image you want to focus on to the center divided area. Become.

  In one aspect of the present invention, the image processing apparatus includes, in addition to the above-described means, fluctuating means that fluctuates at least one of the size and position of the divided area divided by the dividing means by changing the dividing boundary line. It is characterized by providing. According to this, the user can freely change the position and size of the divided area displayed on the display screen by changing each divided area.

  In another aspect of the present invention, image processing in which the assigning unit performs predetermined processing on the divided image assigned to the central divided region and does not perform the processing on the divided image assigned to the outer divided region. Means are further provided. According to this, it is possible to display the divided image before the image quality adjustment and the divided image after the image quality adjustment on one display screen by performing, for example, the process of adjusting the image quality on the central divided image. It becomes. Therefore, when adjusting the image quality, the user can easily compare the pre-adjustment image and the post-adjustment image on one display screen, so that the optimum image quality setting can be easily determined. In addition, since the researchers can have the subject evaluate the image located in the center where the predetermined processing is performed and the image located outside where the predetermined processing is not performed on one display screen, Evaluation can be easily performed by eliminating individual differences of image display devices. In addition, since the image that has undergone the predetermined processing is naturally displayed in the center where the subject is likely to pay attention, it is possible to recognize the effect of performing the predetermined processing by performing a comparative evaluation in a short time. Become.

  In another aspect of the present invention, image processing for performing a predetermined process on the divided image assigned to the central divided region by the assigning unit and performing another process on the divided image assigned to the outer divided region. Means are further provided. According to this, for example, a process for adjusting the image quality to luminance A is performed on the central divided image, and a process for adjusting the image quality to luminance B is performed on the outer divided image on one display screen. The divided image adjusted to the luminance A and the divided image adjusted to the luminance B can be displayed. Therefore, when the user adjusts the image quality, the image of the image quality setting A and the image of the image quality setting B can be compared on one display screen, so that the optimum image quality setting can be easily determined. Can do. In addition, since the researcher can have the subject evaluate the image that has undergone the process A and the image that has undergone the process B on one display screen, it eliminates individual differences in the image display devices. Evaluation can be performed easily.

  In another aspect of the present invention, the image processing apparatus further includes exchange means for exchanging a divided image assigned to one divided area by the assigning means with a divided image assigned to the other divided area. According to this, the user can easily change the divided image by exchanging the divided image assigned to the central divided region and the divided image assigned to the outer divided region without changing the boundary line. The position and size can be varied.

  In another aspect of the present invention, a display image creating unit that creates a display image based on a setting of a divided image assigned to a central divided region by the assigning unit, and a display image created by the display image creating unit, Display image transmitting means for transmitting to the image display device so as to display on the display screen. According to this, the user can easily display an image with the same setting as the divided image assigned to the central divided region to which the natural attention is paid on the entire display screen.

  In yet another aspect of the present invention, information relating to the processing content is transmitted to the image display device so that the processing content of the divided image assigned to the central divided region by the assigning unit is displayed on the display screen. Processing content information transmission means. According to this, since the processing content of the divided image assigned to the central divided region is displayed on the display screen, the user can easily and accurately 1 while recognizing the processing applied to the divided image. Two images displayed on one display screen can be compared and evaluated.

  According to another aspect of the present invention, there is provided a program executed by a computer capable of transmitting and receiving data to and from an image display device that displays an image on a display screen, and the division boundary line that divides the display screen into a center and an outside Dividing means for dividing the display screen into two divided areas, allocating means for assigning two divided images obtained by dividing one image to each divided area based on the position of the divided area on the display screen, The computer is caused to function as combined image transmission means for combining the divided images assigned by the assigning means so as to be displayed in the respective divided areas on the display screen and transmitting them to the image display device.

  By executing the program by a computer, the above-described image processing apparatus and image processing method can be realized. Further, each aspect of the above-described image processing apparatus and image processing method can be realized in the same manner.

[Image processing system]
First, the image processing system of the present invention will be described. FIG. 1 is a diagram showing a schematic configuration of the image processing system 100. The image processing system 100 assigns and displays a divided image obtained by dividing one image into two to a divided region obtained by dividing one display screen into two at the center and outside by a divided boundary line, and displays the divided boundary line. The size and position of the divided area and the divided image can be changed based on the change.

  As shown in FIG. 1, the image processing system 100 includes an image processing device 1 and an image display device 2. Here, the image display device 2 is a device that includes a display screen such as a monitor, a projector, and a display for displaying an image, and displays an image received from the image processing device 1 on the display screen. In the present embodiment, the image processing device 1 and the image display device 2 are different devices. However, the present invention is not limited to this, and the image processing device 1 may be configured to include a display screen such as a monitor or a display. Absent. In other words, the image processing apparatus 1 can be a digital camera or a mobile phone that includes a display screen.

  As shown in FIG. 1, the image processing apparatus 1 includes an operation unit 10, a system control unit 11, an image storage unit 12, an image reading unit 13, an image processing unit 14, and an image composition unit 15. This is an apparatus for outputting the image synthesized by the synthesis unit 15 to the image display apparatus 2 connected so as to be capable of data communication. Specifically, examples of the image processing apparatus 1 include a TV receiver and a DVD player. Here, the configuration of the image processing apparatus 1 will be described in detail.

  The operation unit 10 transmits an operation signal input by a user using a controller or the like connected to the image processing apparatus 1 to the system control unit 11. Based on the received operation signal, the system control unit 11 adjusts the image quality, size, and position of a predetermined image as requested by the user, and displays the adjusted image on the display screen of the image display device 2. The image storage unit 12, the image reading unit 13, the image processing unit 14, and the image composition unit 15 are controlled.

  The image storage unit 12 stores an image to be displayed on the display screen of the image display device 2. The image stored in the image storage unit 12 may be a still image or a moving image. Specifically, the image storage unit 12 in the case where the image processing apparatus 1 is a DVD player is a disc on which image and audio data are recorded after being compressed and encoded.

  The image reading unit 13 reads an image requested by the user from the image storage unit 12 based on the operation signal. Specifically, the image reading unit 13 when the image processing apparatus 1 is a DVD player reads an image requested by the user from the disk with an optical head based on the operation signal.

  The image processing unit 14 performs processing for adjusting the image quality and size of the image read by the image reading unit 13 as requested by the user based on the operation signal. Although the details will be described later, the display screen is divided into two divided areas by dividing boundaries that can be arbitrarily changed by the user. Each divided area is assigned a divided image obtained by dividing one image into two according to the position on the display screen. The image processing unit 14 adjusts image quality and size for each divided image assigned to each divided region. That is, the image processing unit 14 includes two image processing units A and B that are the same as the number of divided regions in order to adjust image quality and size for each divided image. Each image processing unit includes, for example, an image memory having a predetermined capacity, and can store images corresponding to different image quality adjustments set by the user. For example, when the user adjusts the luminance, the image processing unit A can store the image before adjustment, and the image processing unit B can store the image after adjustment.

  Here, the image quality adjustment may be any adjustment such as RGB balance adjustment, contrast adjustment, brightness adjustment, brightness adjustment, ON / OFF of automatic adjustment, and the degree of strength of automatic adjustment. That is, the present invention does not specify image quality adjustment processing. For example, when the user adjusts the luminance on the display screen, the image processing unit 14 extracts a parameter related to the luminance set by the user from the operation signal, and calculates the luminance of a predetermined divided image based on the parameter. Perform the adjustment process.

  The size adjustment means that the size of the divided area is calculated based on the position of the divided boundary line changed by the user on the display screen, and is allocated to the divided area so as to match the calculated size. The size of the divided image is adjusted. For example, when the user changes the dividing boundary line on the display screen, the image processing unit 14 extracts position information related to the dividing boundary line changed by the user from the operation signal, and based on the position information, The size of the divided area is calculated. Then, the image processing unit 14 performs a process of adjusting the size of the divided image assigned to each divided region so as to match the calculated size of each divided region.

  The image synthesis unit 15 synthesizes the two divided images adjusted by the image processing unit 14 based on the operation signal, and outputs the synthesized image to the image display device 2. That is, the divided images combined by the image combining unit 15 are displayed on the display screen provided in the image display device 2. For example, when the user changes the dividing boundary line on the display screen, the image composition unit 15 extracts position information regarding the dividing boundary line changed by the user from the operation signal, and each of the position information based on the position information. The position of the divided area on the display screen is calculated. Then, the image composition unit 15 synthesizes the two divided images adjusted by the image processing unit 14 based on the calculated positions of the divided regions on the display screen, and outputs them to the image display device 2.

  In addition to the above, the image processing apparatus 1 including a DVD player and the like includes various components for executing original operations in the DVD player and the like such as processing audio data, but directly with the present invention. For the sake of convenience, the description of the unrelated parts is omitted.

  The image processing system 100 including the image processing device 1 and the image display device 2 as described above divides one image into two into divided regions obtained by dividing one display screen into two by dividing boundaries. By assigning and displaying the divided images and changing the size and position of the divided regions and the divided images based on the change of the dividing boundary line, it is possible to easily and accurately perform image quality adjustment and image comparison. .

[Image display method]
Next, in the present system, in order to accurately adjust the image quality and compare the images, one display screen is divided into two divided areas at the center and the outside by dividing boundaries, and the two assigned to each divided area are displayed. A method for simultaneously displaying two images will be described with reference to FIGS. FIG. 2 shows an example of a display screen divided into two divided areas at the center and the outside.

  FIG. 2A shows an example in which an image 40 is displayed on a display screen such as a display provided in the image display device 2. In the image processing system 100, the user can browse an arbitrary still image or moving image by operating the image processing apparatus 1 to display the image 40 on the display screen of the image display apparatus 2. When adjusting the image quality of the image displayed on the display screen, for example, adjusting the brightness, the user sets the display screen to the adjustment mode by operating a predetermined controller, and arbitrarily sets parameters related to the brightness. . Then, the operation unit 10 of the image processing apparatus 1 transmits an operation signal input by the user operating the controller to the system control unit 11. Based on the received operation signal, the system control unit 11 divides the display screen into two divided areas by a dividing boundary line dividing the display screen into the center and the outside, and the adjusted image adjusted to the brightness set by the user and the pre-adjustment image In order to display the images in the central divided region and the outer divided region, the image storage unit 12, the image reading unit 13, the image processing unit 14, and the image composition unit 15 are controlled.

  The image reading unit 13 specifies an image that the user is browsing from the operation signal, and reads the specified image from the image storage unit 12. Then, the image processing unit 14 recognizes from the operation signal that the division boundary line has not yet changed because the user has just switched to the adjustment mode, and the division boundary line 41a as shown in FIG. Calculate location information. Furthermore, the image processing unit 14 recognizes that the display screen is divided into two divided areas on the center and the outer side, as shown in FIG. 2B, based on the position information of the divided boundary line 41a. The size of each divided area is calculated. Then, the image processing unit 14 divides and adjusts the image read by the image reading unit 13 so as to match the calculated size of each divided region, and creates divided images 40a and 40b.

  Furthermore, the image processing unit 14 assigns the divided image 40a to the divided region at the center of the display screen, and assigns the divided image 40b to the divided region outside the display screen. Then, the image processing unit 14 extracts information on the parameter related to the brightness set by the user from the operation signal, and performs a process of adjusting the brightness of the divided image 40a based on the parameter. Here, the process of adjusting the brightness of the image will be described in detail. FIG. 4 is a diagram illustrating an example of correction characteristics (input / output characteristics) when adjusting the luminance. The image processing unit 14 specifies correction characteristics for adjusting the average luminance of the image based on the parameters extracted from the operation signal. For example, when the curve 60a shown in FIG. 4 is specified based on the parameters extracted from the operation signal, the image processing unit 14 performs a process of correcting the luminance data of the divided image 40a according to the correction characteristics as shown by the curve 60a. Do.

  Then, the image synthesis unit 15 synthesizes the two divided images based on the position information of the divided boundary line 41a calculated from the operation signal so that the divided image 40a is the center and the divided image 40b is the outer side, and the synthesized image Is transmitted to the image display device 2 and output. At this time, the division boundary line 41a is also output so as to be displayed on the display screen. Further, the processing contents of the divided image assigned to the central divided area are output so as to be displayed. Specifically, in the above-described embodiment, since the process of adjusting the luminance is performed on the divided image 40a assigned to the central divided region, the “brightness adjustment is performed” is displayed together with the black arrow indicating the divided image 40a. Characters are displayed. Therefore, as shown in FIG. 2B, the divided image 40a after adjusting the luminance together with the processing content of the divided image is in the center of the divided boundary line 41a, and the divided image 40b before adjusting the luminance is the divided boundary line 41a. The image is displayed so as to be located outside the. In the above-described embodiment, only the processing content of the divided image assigned to the central divided region is displayed. However, the present invention is not limited to this, and is assigned to the outer divided region. It is also possible to set to display the processing content of the divided image.

  In addition, when the user wants to adjust the image quality of the image displayed on the display screen, for example, to adjust the brightness and set the optimum brightness, the user can operate the predetermined controller to set the brightness parameter. Is newly set. Further, when the user wants to display the image after adjusting the brightness larger than the image before the adjustment, the user can freely change the position and size of the division boundary line 41a by operating a predetermined controller. Let The dividing boundary line 41a serves as a reference for the position and size of the divided area on the display screen, and can be arbitrarily changed by the user. FIG. 5 is a diagram illustrating an example of a controller that moves the dividing boundary line. The division boundary line 41a as shown in FIG. 2B can be changed arbitrarily by the user by operating the joystick 27 of the controller 25 as shown in FIG. In other words, the position and size of the divided area can be freely changed by the user. FIG. 2C shows a state in which the division boundary line 41a is moved to the division boundary line 41b indicated by a broken line in order to display an image after adjusting the luminance larger than the image before adjustment.

  The operation unit 10 of the image processing apparatus 1 transmits an operation signal input by a user operating a controller or the like to the system control unit 11. Based on the received operation signal, the system control unit 11 divides the display screen into two divided areas by a dividing boundary line 41b that divides the display screen into two at the center and outside, and after adjusting the luminance adjusted by the user In order to display the image and the pre-adjustment image in the central divided region and the outer divided region, the image storage unit 12, the image reading unit 13, the image processing unit 14, and the image composition unit 15 are controlled.

  The image reading unit 13 specifies an image that the user is browsing from the operation signal, and reads the specified image from the image storage unit 12. Then, the image processing unit 14 calculates position information of the division boundary line 41b from the operation signal. Further, the image processing unit 14 calculates the size of each divided region based on the position information of the divided boundary line 41b. Then, the image processing unit 14 divides and adjusts the image read by the image reading unit 13 so that the calculated size of each divided region matches, and newly creates divided images 40a and 40b.

  Furthermore, the image processing unit 14 assigns the divided image 40a to the divided region at the center of the display screen, and assigns the divided image 40b to the divided region outside the display screen. Then, the image processing unit 14 extracts information on a parameter related to luminance set by the user from the operation signal, and specifies a correction characteristic for adjusting the average luminance of the image based on the parameter. For example, when the curve 60b shown in FIG. 4 is specified based on the parameters extracted from the operation signal, the image processing unit 14 performs a process of correcting the luminance data of the divided image 40a according to the correction characteristics as shown by the curve 60b. Do.

  Then, the image composition unit 15 synthesizes the two divided images based on the position information of the divided boundary line 41b calculated from the operation signal so that the divided image 40a is the center and the divided image 40b is the outer side, and the combined image Is transmitted to the image display device 2 and output. At this time, the division boundary line 41b is also output so as to be displayed on the display screen. Further, the processing contents of the divided image assigned to the central divided area are output so as to be displayed. Therefore, the image is displayed such that the divided image 40a after adjusting the luminance is positioned in the center of the divided boundary line 41 indicated by the broken line, and the divided image 40b before adjusting the luminance is positioned on the right side of the divided boundary line 32b.

  Further, when the user wants to exchange the positions of the divided image 40a and the divided image 40b displayed on the display screen, it can be realized by operating a predetermined controller. That is, as shown in FIG. 2B, a display screen in which the divided image 40a after brightness adjustment is displayed at the center and the divided image 40b before adjustment is displayed on the outside is shown in FIG. As shown, the divided image 40a after the brightness adjustment is displayed on the outside, and the display screen can be changed to the display screen on which the divided image 40b before the adjustment is displayed. In this case, the image processing apparatus 1 again performs the adjustment processing of the luminance, size, and position of the divided image 40a and the divided image 40b based on the position information of the divided boundary line 41b by the above-described method. In this case, the display of the processing content of the divided image is also changed with the exchange of the positions of the divided images 40a and 40b.

  Finally, when the user determines that the divided image assigned to the divided region at the center of the display screen is optimal, the user performs a determination operation using a predetermined controller. Here, the determination operation is an operation in which the user presses a determination button provided in the controller or the like, and the operation method can be arbitrarily set. When the determination operation is performed by the user, the operation unit 10 of the image processing apparatus 1 transmits an operation signal input by the user operating the controller to the system control unit 11. The system control unit 11 displays the entire image adjusted by the image quality setting of the divided image assigned to the central divided region on the display screen based on the received operation signal. 13. The image processing unit 14 and the image composition unit 15 are controlled.

  The image reading unit 13 specifies an image that the user is browsing from the operation signal, and reads the specified image from the image storage unit 12. Then, the image processing unit 14 extracts the setting of the image quality of the divided image finally assigned to the central divided region from the operation signal. Specifically, the image processing unit 14 extracts the luminance parameter set in the divided image 40a. Further, the image processing unit 14 specifies a correction specification for adjusting the average luminance of the image based on the extracted parameters, and corrects the luminance data of the image read by the image reading unit 13 according to the correction characteristics. Do. Then, the image processing unit 14 transmits the image to the image display device 2 and outputs it. Therefore, an image having the same image quality setting as that of the divided image assigned to the central divided region can be displayed on the entire display screen.

  According to this, the user can browse the image before adjusting the image quality and the image after adjusting the image quality on one display screen, and by arbitrarily changing the dividing boundary line Since an image subjected to image quality adjustment for an arbitrary portion of the image can be observed while being compared with an image that has not been applied, the optimum image quality setting can be selected and set more accurately. In addition, since one display screen is divided into two divided areas, the center and the outside, by a dividing boundary line, the division boundary line exists in the center of the display screen, which can solve the problem that it is difficult to see the image. it can. That is, the image quality can be adjusted while viewing a moving image or the like in a natural state.

  In the above-described embodiment, it is assumed that the division boundary line does not fluctuate immediately after switching to the adjustment mode. However, the present invention is not limited to this, and the user can control the controller when switching the adjustment mode. The division boundary line may be arbitrarily changed by operating the above.

  In the above embodiment, the controller and the like are shown in FIG. 5, but the present invention is not limited to this, and various interfaces such as a mouse can be used.

  Further, in the above embodiment, the divided area outside the display screen is assigned to be the divided image before the image quality adjustment and the central divided area is the divided image after the adjustment, but the present invention is limited to this. Instead, the divided images assigned to both the central and outer divided regions may be adjusted based on user operations. That is, predetermined processing can be performed on each divided image displayed on the display screen.

  In the above embodiment, for the sake of convenience of explanation, the luminance is adjusted based on the user's operation. However, when the image quality adjustment is performed for a plurality of image quality adjustment items such as adjusting the luminance and brightness. Enables adjustment processing for a plurality of image quality adjustment items at the same time by the above-described method. After performing adjustment processing for one image quality adjustment item by the above-described method, the same method is used for the next image quality adjustment item. Arbitrary settings are made such that adjustment processing can be performed.

  In the above embodiment, when the user performs a determination operation using a predetermined controller, the divided image assigned to the central divided area is displayed on the entire display screen. However, the present invention is not limited to this. Instead, the user may perform a determination operation to select one of the two images assigned to the two divided areas and display the selected image on the entire display screen.

  In the above-described embodiment, the example in which the dividing boundary line is a quadrangle has been described. However, the present invention is not limited to this, and the display screen may be divided into two parts, the center and the outside. As shown in FIG. 3, the dividing boundary line may be an ellipse or the like. That is, the shape of the dividing boundary line can be arbitrarily set.

[Image display processing]
Next, an image display process executed by the image processing system 100 will be described. FIG. 6 is a flowchart of the image display process.

  First, the user operates a predetermined controller or the like to adjust the image quality on the display screen. The image processing apparatus 1 acquires an operation signal input by the user, and acquires image quality setting information adjusted by the user from the operation signal (step S1). Here, the image quality setting information is specifically information on a parameter relating to luminance. Further, the user operates a predetermined controller or the like to change the size and position of the dividing boundary line on the display screen. The image processing apparatus 1 acquires an operation signal input by the user, and acquires position information of the divided boundary line changed by the user from the operation signal as divided position information (step S2). Then, the image processing apparatus 1 calculates the sizes of the two divided areas obtained by dividing the display screen based on the division position information. Furthermore, the image processing apparatus 1 specifies an image to be browsed by the user from the operation signal, and reads the image. Then, the image processing apparatus 1 performs image quality adjustment and division processing on the read image based on the calculated size of each divided region and the image quality setting information acquired in step S1, and is assigned to each divided region. Two divided images are created (step S3).

  Next, the image processing apparatus 1 calculates position information of a plurality of divided regions obtained by dividing the display screen based on the divided position information. Further, the image processing apparatus 1 generates a composite image by combining the plurality of divided images generated in step S4 based on the calculated position information (step 4). Then, the image processing apparatus 1 outputs the composite image created together with the image processing content to the image display apparatus 2 (step S5). Thereby, the user can view the image after being adjusted to the image quality setting arbitrarily set together with the image processing content and the image before the adjustment on one display screen, so that it is easy and accurate. Two images can be compared.

  When the user determines that the divided image assigned to the central divided region of the display screen has the optimum image quality setting, the user performs a determination operation using a controller or the like. On the other hand, when it is determined that the divided image assigned to the center divided area of the display screen is not the optimum image quality setting, the user operates the controller or the like to adjust the new image quality or change the divided area. Change the dividing boundary line. In step S6, when it is not possible to confirm that the determination operation has been performed from the operation signal (step S6; No), the image processing apparatus 1 repeatedly performs the processes of steps S1 to S6. Therefore, the user can determine the optimum image quality setting by performing comparative observation of the displayed divided images by arbitrarily changing the image quality adjustment of each divided image while freely moving the dividing boundary line. it can. Then, when the optimum image quality setting is determined, a determination operation is performed using the controller.

  If it is confirmed from the operation signal that the determination operation has been performed (step S6; Yes), the image processing apparatus 1 extracts the image quality setting of the determined image and creates a display image based on the image quality setting. Further, the image processing apparatus 1 outputs the created display image to the image display apparatus 2 (step S7), and the image display process is completed. As a result, the user can select an image with an image quality setting that seems to be optimal as a result of comparing images with a plurality of image quality settings on one display screen. That is, it is possible to easily and accurately adjust the optimum image quality.

  Note that the user can view and browse the image with the optimum image quality setting determined in the adjustment mode on the entire display screen in the normal mode.

  In the above-described embodiment, a predetermined image is divided in advance, and the divided images are synthesized after processing is performed so that the image quality setting adjusted by the user is performed on each divided image. Is not limited to this, and after dividing the image so as to match the position and size of each divided area after processing so that the image quality setting adjusted by the user is applied to the image before division May be synthesized. That is, various methods for combining two divided images with image quality settings adjusted by the user are conceivable, but the present invention is not limited to the processing procedure.

  According to the present invention, the display screen is divided into the center and the outside by the boundary line, so that the boundary line is not located at the center of the screen, and two divided images displayed simultaneously on the display screen can be easily seen. Can do. That is, it is possible to easily adjust the image quality by displaying the divided images while browsing the images, particularly the moving images. In addition, according to the present invention, when the user determines that the image quality setting of the divided image assigned to the central divided area of the display screen is optimal, the image with the image quality setting of the divided image is displayed on the display screen. Displayed throughout. Therefore, the user can easily determine whether or not the image quality setting of the divided image is optimal based on the easy-to-view divided image assigned to the central divided region. Furthermore, the switching after the image quality adjustment can be clearly recognized as compared with the case where the divided areas are always equally divided into the left and right. That is, when an operation is wrong, the error can be easily recognized.

[Modification]
In the above embodiment, the case where the user adjusts the image quality and determines the optimum image quality setting is described, but the present invention is not limited to this, and a researcher or the like performs a predetermined process. The present invention can also be applied when two subjects are compared and evaluated by a subject.

  In this case, the researcher or the like performs a predetermined process on each of the two divided images allocated to the two divided areas obtained by dividing the display screen into the center and the outside. Here, the predetermined processing is specifically processing for adjusting image quality, and processing for performing all adjustments such as RGB balance adjustment, contrast adjustment, luminance adjustment, and brightness adjustment is conceivable. That is, the present invention does not specify a process to be performed on an image.

  A researcher or the like displays an image subjected to various processes on the display screen as a divided image. The subject can easily and accurately evaluate the optimum image by comparing the two divided images displayed at the center and the outside on one display screen in the same manner as described above. .

  As described above, according to the present invention, since two images that have been subjected to various processes are displayed as divided images on the display screen of one image display device, individual differences among the image display devices can be eliminated in the evaluation. Can do.

  In addition, since one display screen is divided into two divided areas, the center and the outside, the division boundary line exists in the center of the display screen, so that the problem that the image is difficult to see can be solved. That is, the subject can evaluate the image while browsing a moving image or the like in a natural state.

  In addition, since one display screen is divided into two divided areas, the center and the outer area, for example, a conventional image is assigned to the outer divided area, and an improved image is assigned to the central divided area. It is possible to compare and evaluate the two images while paying attention to the image that the user wants to see. This is because when one display screen is divided into the center and the outside, the subject's consciousness tends to concentrate on the center and it is possible to make a strong impression. That is, the weights of the two divided areas at the center and the outside are different from each other. Therefore, according to the present invention, it is possible to perform not only a simple comparison of images but also an evaluation in consideration of which one is desired. Furthermore, the researcher or the like can have the subject recognize the effect of the image improved as compared with, for example, a conventional image in a short time.

  As described above, according to the present invention, the image is divided at the center and outside so that the dividing line of the image does not come to the center. It becomes possible to select. In addition, when the function of moving the boundary line is added, the images can be compared more accurately.

1 is a diagram showing a schematic configuration of an image processing system of the present invention. The example of a display screen divided | segmented into two of the center and the outer side by the square division | segmentation boundary line is shown. The example of the display screen divided | segmented into two of the center and the outer side by the division | segmentation boundary line of an ellipse is shown. It is a figure which shows an example of the correction characteristic in the case of adjusting a brightness | luminance. It is a figure which shows the example of the controller which fluctuates a division | segmentation boundary line. It is a flowchart of the image processing in this embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Image processing apparatus, 2 Image display apparatus, 10 Operation part, 11 System control part, 12 Image memory | storage part, 13 Image reading part, 14 Image processing part, 15 Image composition part

Claims (9)

An image processing device capable of transmitting and receiving data to and from an image display device that displays an image on a display screen,
A dividing unit that divides the display screen into two divided areas by dividing boundary lines that divide the display screen into a center and an outside;
Allocating means for allocating two divided images obtained by dividing one image to each divided region based on the position of the divided region on the display screen;
An image processing apparatus comprising: a combined image transmitting unit configured to combine the divided images assigned by the assigning unit so as to be displayed in each divided region on the display screen and to transmit the combined images to the image display device.   The image processing apparatus according to claim 1, further comprising a changing unit that changes at least one of a size and a position of the divided area divided by the dividing unit by changing the dividing boundary line.   The image processing device further includes an image processing unit that performs predetermined processing on the divided image assigned to the central divided region by the assigning unit and does not perform the processing on the divided image assigned to the outer divided region. The image processing apparatus according to claim 1.   The image processing device further includes an image processing unit that performs a predetermined process on the divided image assigned to the central divided region by the assigning unit and performs another process on the divided image assigned to the outer divided region. The image processing apparatus according to claim 1.   5. The image processing apparatus according to claim 3, further comprising an exchange unit configured to exchange a divided image assigned to one divided region by the assigning unit with a divided image assigned to the other divided region. . Display image creating means for creating a display image based on the setting of the divided image assigned by the assigning means to the central divided region;
6. A display image transmitting means for transmitting the display image created by the display image creating means to the image display device so as to be displayed on the display screen. The image processing apparatus according to item.   Processing content information transmitting means for transmitting information related to the processing content to the image display device so that the processing content of the divided image assigned to the central divided region by the assigning means is displayed on the display screen. The image processing apparatus according to any one of claims 1 to 6. A dividing step of dividing the display screen into two divided regions by a dividing boundary line dividing the display screen included in the image display device into the center and the outside;
An assigning step of assigning two divided images obtained by dividing one image to each divided region based on the position of the divided region on the display screen;
An image processing method comprising: a combined image transmission step of combining the divided images assigned by the assigning unit so as to be displayed in each divided area on the display screen and transmitting the combined images to the image display device. A program executed by a computer capable of transmitting and receiving data to and from an image display device that displays an image on a display screen,
A dividing means for dividing the display screen into two divided areas by a dividing boundary line dividing the display screen into a center and an outside;
Allocating means for allocating two divided images obtained by dividing one image to each divided region based on the position of the divided region on the display screen;
A program for causing the computer to function as a combined image transmission unit that combines the divided images allocated by the allocation unit so as to be displayed in each divided area on the display screen and transmits the combined images to the image display device. .

Images