JP2008096565A - Image display program and image display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide image display processing for confirming an image having the same file name and high possibility of being same as a received image. <P>SOLUTION: An image display program makes a computer execute read-in processing for reading in image data from a loaded first storage medium 301, recording processing for recording the image data read in through the read-in processing to a second storage medium 114 different from the first storage medium 301, decision processing for comparing the file name of the read-in image data with the file name of the image data already stored in the second storage medium 114 to decide whether the file names match each other, and display processing for displaying on a screen an image based upon the image data read in through the read-in processing and an image based upon the image data stored in the second storage medium 114 and decided as image data having the same file name through the decision processing when it is decided that the file names match each other. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an image display program and an image display apparatus.

An image transfer apparatus that transmits and receives an image on a network is known. A conventional image transfer apparatus selects an image to be transmitted / received based on a list for managing a unique ID code corresponding to each image (for example, Patent Document 1).
US Pat. No. 6,058,428

  However, when the same image as the received image is already stored, the file name of the received image is automatically changed, so that the user cannot confirm the received image when receiving the image.

(1) An image display program according to claim 1 is a read process for reading image data from a loaded first storage medium, and the image data read by the read process is stored in a second storage medium different from the first storage medium. When the recording process to be recorded and the reading process are executed, the file name of the read image data is compared with the file name of the image data already stored in the second storage medium. If it is determined that the file name matches the determination process for determining whether or not the file name matches, the image based on the image data read in the reading process is stored in the second storage medium, and the file name is determined to match by the determination process And a display process for displaying an image based on the image data on a screen.
(2) According to the invention of claim 2, in the image display program according to claim 1, a selection instruction from a user is received and at least one image is selected from a plurality of images displayed by display processing. A selection process and a deletion process for deleting the selected image are further executed by a computer.
(3) The invention according to claim 3 is the image processing program according to claim 1, wherein the file names of the plurality of displayed images can be distinguished from each other upon receiving a file name change instruction from the user. Further, a change process for changing the file name is executed by the computer.
(4) According to a fourth aspect of the present invention, an image display device according to any one of the first to third aspects includes an execution means for executing the image display program according to any one of the first to third aspects, a second storage medium, and a file name in the determination process. If it is determined that they match, an image based on the image data read in the reading process and an image based on the image data stored in the second storage medium and determined to match the file name by the determination process are displayed on the screen. Display means.

  According to the present invention, an image having the same file name that is highly likely to be the same as the received image can be displayed in comparison with the received image.

  A viewer will be described with reference to the drawings as an embodiment of an image browsing apparatus according to the present invention. FIG. 1 is an external view of the viewer 100, and FIG. 2 is a control block diagram of the viewer 100. The features of the viewer 100 of this embodiment will be outlined.

(Image size)
The viewer 100 captures a 7 million pixel main image from an external device, for example. The viewer 100 resizes the captured main image to an image size of 2 million pixels, for example, and records it as a first reduced image on a large-capacity recording medium 114 such as an HDD. A thumbnail image (for example, 120 pixels × 160 pixels) is attached to the main image, and the viewer 100 displays a list of thumbnail images on the first LCD 103 and the second LCD 104. When the user selects at least one image from the displayed thumbnail images, the viewer 100 resizes the first reduced image resized to 2 million pixels to, for example, a VGA size (640 pixels × 480 pixels), The second reduced image is recorded on a recording medium 111 such as SDRAM (hereinafter referred to as SDRAM 111) that can be read at a higher speed than the large-capacity recording medium 114, and is displayed on the first LCD 103 and the second LCD 104.

(Image look-ahead)
The viewer 100 according to this embodiment performs prefetching of image data to speed up image display. As will be described later, the prefetch process is a process in which the RISC 110 predicts in advance a plurality of images that are likely to be instructed to be viewed next by the user, and the RISC 110 writes the plurality of predicted images to the SDRAM 111 as VGA image file data. It is. In order to perform prefetching, data characterizing the image is attached to each of the first 2 million pixel reduced images recorded in the HDD 114. For example, when one thumbnail image is selected by the user, the RISC 110 can select a plurality of first images that are highly likely to be browsed based on the feature data, and can read data at a higher speed than the HDD 114. A VGA image is recorded as a second reduced image in the SDRAM 111. At this time, the RISC 110 also records the created VGA image on the HDD 114.

(Image switching)
The viewer 100 includes a double-open liquid crystal display device that is opened and closed by a hinge 101. That is, the viewer 100 includes a plurality of double-opening pairs of the first LCD 103 and the second LCD 104, and the second LCD 104 has a touch panel. The first LCD 103 and the second LCD 104 can display a second reduced image of VGA size. In addition, the viewer 100 can divide one screen of the first LCD 103 or the second LCD 104 into two regions and collectively display one image in each region. The display image in this case is created by further resizing the second reduced image of VGA size. Furthermore, it is possible to display an image obtained by enlarging the VGA size by two times using the screens of both the first LCD 103 and the second LCD 104. In the image display process in this case, first, a rough enlarged image is created by interpolating the VGA size and displayed on the first LCD 103 and the second LCD 104. In the meantime, the resized image is reduced to create a fine enlarged image. When the fine enlarged image creation processing is completed, the fine enlarged image is displayed on the first LCD 103 and the second LCD 104 instead of displaying the coarse enlarged image.

  The user can instruct various operations by touching the screen with a finger or the like using the touch panel 122. For example, the viewer 100 can detect a finger rubbing operation on the display screen and perform image switching, that is, image scrolling. For example, when the finger is rubbed horizontally on the screen, display switching is performed by frame advance or frame reverse. Further, when the screen is rubbed along a diagonal line, the number of displayed images in one screen is switched.

(Attitude priority mode and size priority mode)
The viewer 100 can select either the posture priority mode or the size priority mode. In the posture priority mode, the viewer 100 displays the top and bottom of a plurality of images in the vertical direction of the first LCD 103 and the second LCD 104. For example, when displaying two screens of an image obtained by horizontal position shooting and an image obtained by vertical position shooting, the viewer 100 displays the top and bottom of both images so as to coincide with the vertical direction of the screen. Therefore, one image is displayed with a margin. In the size priority mode, when the viewer 100 displays two screens of an image obtained by horizontal position shooting and an image obtained by vertical position shooting, the longitudinal direction of each of the images of horizontal position shooting and vertical position shooting is the first. The display is made to coincide with the longitudinal direction of the first LCD 103 or the second LCD 104.

Hereinafter, the viewer 100 according to the present embodiment will be described in detail with reference to the drawings.
As shown in FIG. 1, the viewer 100 includes a hinge unit 101, an open / close detection switch 102, a first LCD 103, a second LCD 104, a battery 105, operation buttons 106, and a joystick 107. The viewer 100 is configured to be opened and closed by a hinge unit 101. FIG. 1A shows a state in which the viewer 100 is opened.

  FIG. 2 is a control block diagram of the viewer 100. The viewer 100 includes a RISC 110, an SDRAM 111, an SDRAM control unit 112, an image processing circuit 113, an HDD (hard disk drive) 114, an HDD drive circuit 115, an attitude sensor 116, a touch panel 122, and a memory card slot 301S. The viewer 100 also includes an attitude sensor interface 117, a first LCD interface 118, a second LCD interface 119, a memory card interface 120, an operation system interface 123, an HDMI interface 124, a USB interface 125, and a cradle interface 126. An HDMI compatible monitor 501 is detachably connected to the HDMI interface 124, a personal computer 502 is connected to the USB interface 125, and a cradle 503 is detachably connected to the cradle interface 126.

  The open / close detection switch 102 detects opening / closing of the viewer 100. When the viewer 100 is opened by the user, the open / close detection switch 102 outputs an ON signal to the RISC 110. When an ON signal is output from the open / close detection switch 102, the RISC 110 outputs a power supply instruction signal to a power supply circuit (not shown) connected to the battery 105. The power supply circuit that has received the power supply instruction signal supplies power to each component device of the viewer 100. The operation buttons 106 and the joystick 107 are operation switches for the user to perform various settings on the viewer 100. For example, the prefetch mode can be selected by operating the operation button 106 or the joystick 107, and either the metadata matching priority mode or the favorite image priority mode in the prefetch mode can be selected. The joystick 107 is a cross key switch. The image displayed on the first LCD 103 or the second LCD 104 can be switched and displayed by operating the cross key of the joystick 107.

  The RISC 110 is an arithmetic processing circuit that controls each element device of the viewer 100. The SDRAM 111 temporarily stores various data as a work area memory of the RISC 110. The SDRAM 111 records VGA image data as a prefetch image. Further, the SDRAM 111 has a function as a frame memory for displaying an image on the first LCD 103 and the second LCD 104. The SDRAM control unit 112 controls the SDRAM 111 based on an instruction signal from the RISC 110. The SDRAM 111 is a volatile semiconductor memory and can read and write data faster than the HDD 114.

  The HDD 114 is a hard disk drive that can perform nonvolatile storage. The HDD 114 stores image data and various data. The HDD 114 is driven via the HDD drive circuit 115 based on an instruction from the RISC 110, and data writing and data reading are controlled. The recording data of the HDD 114 will be described in detail later. The image processing circuit 113 executes various types of image processing on the image data recorded in the HDD 114 or the SDRAM 111 based on an instruction from the RISC 110.

  The posture sensor 116 has three types of postures of the viewer 100, that is, a horizontal position posture with the arrow AR direction shown in FIG. 1A as the top and bottom of the screen, and the viewer 100 rotates 90 degrees clockwise from the horizontal position posture indicated by the arrow CW. From the rotated +90 degree vertical position and horizontal position and orientation, a −90 degree vertical position and orientation obtained by rotating the viewer 100 by 90 degrees counterclockwise as indicated by the arrow CCW are detected. The horizontal position is a posture of the viewer 100 in which the first and second LCDs 103 and 104 are arranged side by side. The detected posture information is output to the posture sensor interface 117. The attitude sensor interface 117 drives the attitude sensor 116 based on an instruction from the RISC 110 and outputs attitude information input from the attitude sensor 116 to the RISC 110 via the data bus.

  The first LCD 103 is a display for displaying an image. When an image designation operation is performed by the user, the first LCD 103 can display an image of, for example, a VGA size (640 pixels × 480 pixels). That is, the first LCD interface 118 displays a VGA size image on the first LCD 103 based on display image data (hereinafter also simply referred to as VGA image data) written in the SDRAM 111 under the control of the RISC 110. The second LCD 104 is a display for displaying an image in the same manner as the first LCD 103. Similar to the first LCD 103, the second LCD 104 can display, for example, an image of VGA size (640 pixels × 480 pixels) when an image designation operation is performed by the user. That is, the second LCD interface 119 displays a VGA size image on the second LCD 104 based on the VGA image data written in the SDRAM 111 under the control of the RISC 110. Further, the second LCD 104 displays a menu screen for performing various settings in the viewer 100.

  A touch panel 122 is disposed on the surface of the second LCD 104. The touch panel 122 is an operation switch for the user to perform various settings in the viewer 100, like the operation button 106 and the joystick 107. In addition, the image displayed on the first LCD 103 or the second LCD 104 can be switched and displayed in the same manner as the joystick 107 by a horizontal finger rubbing operation on the touch panel 122. The switching display is to switch and display from the image of the currently displayed frame to another image by forward or backward feeding. In addition, the number of displayed images can be switched by a finger rubbing operation on the touch panel 122 in an oblique direction (diagonal direction). The operation system interface 123 receives operation signals from the operation buttons 106, the joystick 107 and the touch panel 122 and outputs them to the RISC 110.

  The memory card interface 120 is an interface for performing data communication with the memory card 301. The HDMI interface 124 is an interface for outputting image data to an external high-definition monitor 501. The USB interface 125 is an interface for performing data communication with an external device 502 such as a PC via a predetermined cable or wireless transmission path. The cradle interface 126 is an interface for performing data communication with an external cradle 503 connected to the viewer 100.

  The memory card 301 is a semiconductor memory card such as a compact flash (registered trademark) or an SD card, and is detachable from the memory card slot 301S of the viewer 100. When the memory card 301 is inserted into the memory card slot 301S, image data can be transmitted to and received from the viewer 100 via the memory card interface 120 of the viewer 100 as described above. That is, the memory card 301 functions as a storage medium for the viewer 100.

  A menu screen displayed on the second LCD 104 will be described with reference to FIG. FIG. 11 shows the structure of the menu. When the operation button 106 is operated by the user, the RISC 110 displays a menu screen on the second LCD 104. The items “image display”, “image input”, “slide show”, and “setting” are displayed by the RISC 110 as the top menu of the menu screen. “Image display” is an item for displaying an image on the first LCD 103 and the second LCD 104. “Image input” is an item for instructing the viewer 100 to capture an image from an external device. “Slide show” is an item for instructing display or creation of a slide show. “Setting” is an item for setting the number of displayed images, the display form, the sort order, and the like. Note that the user selects one of the items on the menu screen using any of the operation buttons 106, the joystick 107, and the touch panel 122.

  When “image display” in the top menu is selected, the RISC 110 displays thumbnail images on the first LCD 103 and the second LCD 104 as shown in FIG. 10 as shown in the first hierarchy in FIG. An image selected by the joystick 107 or the touch panel 122 from the thumbnail-displayed images is enlarged and displayed by the RISC 110. The number to be displayed is set from the “simultaneous display number” menu described later.

  While displaying an image such as a thumbnail image, the user can call a submenu by operating one of the operation buttons 106, the joystick 107, and the touch panel 122. When the user performs a submenu call instruction operation, the RISC 110 displays a submenu superimposed on the image on the second LCD 104. The submenu has four items: “simultaneous display number”, “enlargement”, “display priority”, and “image editing”.

  First, the “simultaneous display number” of the submenu will be described. When simultaneous display of one image is set, the RISC 110 displays an image selected from the thumbnail images using two screens of the first LCD 103 and the second LCD 104 as shown in FIG. When the simultaneous display of two images is set, the RISC 110 displays on the first LCD 103 and the second LCD 104 images having the second sort order from the images selected from the thumbnail images. That is, the RISC 110 displays one image on each of the first LCD 103 and the second LCD 104 as shown in FIGS. 9B and 9C. When the simultaneous display of four images is set, the RISC 110 displays on the first LCD 103 and the second LCD 104 images from the image selected from the thumbnail images up to the fourth image in the sort order. That is, the RISC 110 displays a total of four images, two on each of the first LCD 103 and the second LCD 104, as shown in FIGS. Note that setting the number of displayed sheets to be one is possible only when the viewer 100 is fully opened.

  “Enlarge” is an item that is set so that the size of the image displayed on the first LCD 103 and the second LCD 104 is increased. Available image sizes are 100% (640 pixels × 480 pixels), 150% (960 pixels × 720 pixels), 200% (1280 pixels × 960 pixels), and 250% (1600 pixels × 1200 pixels). is there. In “display priority”, “high priority” or “low priority” can be designated. For example, the user designates a high priority for a favorite image.

  “Image editing” is an item for setting an image to be displayed so as to have a pattern that matches the user's preference. The “image editing” further includes menus of “brightness”, “hue”, “gradation correction”, “sharpness”, “monochrome”, and “sepia”. When “brightness” is selected, the user can set the degree of brightness of the image. The user sets the degree of brightness while referring to “brightness bar display” displayed on the second LCD 104 by the RISC 110. When “Hue” is selected, the user can set the hue of the image. The user sets the hue while referring to the “red intensity bar display”, “blue intensity bar display”, and “green intensity bar display” displayed on the second LCD 104 by the RISC 110. When “gradation correction” is selected, one of “hard tone”, “standard”, and “soft tone” can be set. When “sharpness” is selected, the user can set the degree of edge enhancement of the image. The user sets the degree of edge enhancement while referring to the “strong bar display” displayed on the second LCD 104 by the RISC 110.

  When “image input” in the top menu is selected, the RISC 110 displays “image capture” and “image capture cancel” on the second LCD 104. When “image capture” is selected by the user, the RISC 110 starts capture processing of the image recorded in the external device. When “Cancel image capture” is selected, the RISC 110 ends the image capture processing from the external device.

  When “slide show” is selected from the top menu, the RISC 110 displays “display slide show” and “create slide show” on the second LCD 104. In “slide show display”, the user selects images to be used in the slide show. The user designates an image to be used in the slide show from the items “select slide show data” or “select all images”. In “slide show data selection”, the user designates images to be used in the slide show from images displayed as thumbnails by the RISC 110. When “select all images” is selected, the RISC 110 displays a slide show using all the images recorded in the HDD 114. In “create slide show”, it is possible to select an image used in the slide show, display time display effect, and set BGM.

  When “setting” in the top menu is selected, the RISC 110 displays items of “number of simultaneous display”, “display mode”, “display priority”, and “sort order” on the second LCD 104. The items “simultaneous display number” and “display priority” can be set in the same manner as the “simultaneous display number” and “display priority” items in the submenu. In the “display mode”, a display form of an image to be displayed on the first LCD 103 and the second LCD 104 can be set. When “display mode” is selected, the RISC 110 displays items of “posture priority” and “size priority” on the second LCD 104. In “posture priority”, one of “posture sensor”, “vertical opening”, and “lateral opening” is selected by the user. In the “posture sensor”, the RISC 110 displays the image so that the vertical direction of the image matches the vertical direction of the viewer 100 detected by the posture sensor 116. In “vertical opening”, the RISC 110 displays the vertical direction of the image in the vertical direction of the viewer 100 in the vertical direction as shown in FIG. In “horizontal opening”, the RISC 110 displays the image with the vertical direction of the image aligned with the vertical direction in the horizontal position and orientation of the viewer 100 as shown in FIGS. When “size priority” is selected, the RISC 110 displays the image with the longitudinal direction of the side of the image aligned with the longitudinal direction of the side of the first LCD 103 or the second LCD 104, as shown in FIGS. To do.

  The “sort order” is an item for setting the image sort order, that is, the image display order. The user selects a sort order of “file name order” or “shooting date order”. When “file name order” is selected, the RISC 110 sorts the image files in ascending order (A to Z) or descending order (Z to A) in alphabetical order according to the dictionary rules based on the file name of the image file. When “order of photographing date / time” is selected, the RISC 110 sorts the image files in ascending order (from the past to the future) or descending order (from the future to the past) based on the photographing date / time information recorded in the image file.

Data management in the HDD 114 will be described with reference to FIG.
Inside the HDD 114, a resized image file folder F1, a VGA image data folder F2, an image processing data folder F3, and a slide show data folder F4 are provided. Further, the HDD 114 is also provided with a viewer image management table T1 and a display priority table T2.

  The resized image file folder F1 is a folder for storing, for example, a resized image file of 2 million pixels (1600 pixels × 1200 pixels) and metadata. The image data of the resized image file is compressed in, for example, JPEG format. The resized image generation process will be described in detail later. The VGA image data folder F2 is a folder for storing VGA size image data created for display on the first LCD 103 and the second LCD 104. The VGA size image data is generated by the RISC 110 based on the resized image file, and is stored as a luminance color difference format (YCbCr422 format) file (VGA image file). The image processing data folder F3 is a folder for storing data indicating the contents of image processing performed on the resized image file, that is, image processing data. The slide show data folder F4 is a folder for storing slide show data.

  The viewer image management table T1 is a table for managing resized image files stored in the HDD 114 of the viewer 100. The viewer image management table T1 will be described in detail later. The display priority table T2 is a table that the RISC 110 refers to when determining the display priority of the viewer image management table T1. The display priority table T2 will also be described in detail later.

  Next, the viewer image management table T1 will be described with reference to FIG. FIG. 4 is a diagram illustrating an example of the viewer image management table T1. “No.” is a serial number added based on the order recorded in the viewer image management table T1. “Resize image file name” represents the file name of the resize image file. No. 4 in FIG. The resized image file name “DSC_0005 — 2006 — 01 — 01 — 1930.rsz” shown in FIG. 1 is given based on the following rule.

  The file name prefix DSC_0005, which is the file name prefix, is the file name DSC_0005. This is the same character string as the part excluding the extension jpg of jpg. _2006 — 01 — 01 — 1930, which is the suffix of the file name (end part), is added based on the shooting date and time of the image file. That is, in this example, since the image was taken at 19:30 on January 1, 2006, the suffix is _2006_01_01_1930.

  “VGA image file name” is the file name of the VGA image file, and is the file name obtained by replacing the extension rsz of the resized image file name with ycc. Therefore, the resized image file name and the VGA image file name are associated with each other. “Shooting date and time” represents information on the shooting date and time, that is, the date and time when the file was generated by the camera at the time of shooting. “Shooting date and time No.” is a number added in order of shooting date and time. A larger “shooting date / time No.” indicates that the image was shot later. “Display priority” is data referred to by the RISC 110 when performing the above-described image prefetching process. The larger the display priority value, the higher the display priority. As described above, the prefetch process is a process in which the RISC 110 predicts in advance a plurality of images that are likely to be browsed by the user and writes the image data of the VGA image file into the SDRAM 111. The prefetch process by the RISC 110 is performed in order to realize high-speed image display.

  Next, a display priority determination rule by the RISC 110 will be described. The display priority table T2 shown in FIG. 5 is a table that is referred to when the RISC 110 determines the display priority. The display priority table T2 is a table showing the correspondence between the image shooting date and the number of display times in the viewer 100 and the weighting value assigned to them, that is, the display priority. The RISC 110 refers to the display priority table T2 and determines that the display priority of the image shot on the last shooting date is 10. In general, the user tends to view the latest image, so the priority is set highest. The RISC 110 determines that the display priority of the images used for the slide show is 5. Since the images used in the slide show are user's favorite images, the priority is increased. The RISC 110 determines the display priority with reference to the display count of images recorded in the viewer image management table T1 and the display priority table T2. However, the display of thumbnail images is not counted by the RISC 110 as the number of display times. The RISC 110 counts the number of times of display when the image is displayed in a size larger than a predetermined size. For example, when the image display size is equal to or larger than that for the simultaneous display of four images, the RISC 110 counts the number of times of display and updates the display number field of the viewer image management table T1.

  The RISC 110 determines the display priority of the image designated as having a high priority by the user as 5 with reference to a “high priority designation” column described later in the viewer image management table T1. Therefore, since the RISC 110 refers to the display priority when performing prefetching as described above, there is a high possibility that an image for which high priority has been designated is prefetched by the RISC 110. Further, the RISC 110 fixes the display priority of an image designated as low priority by the user with reference to a “low priority designation” column described later in the viewer image management table T1. That is, the RISC 110 does not change the display priority no matter how many times an image with a low priority is displayed. Therefore, an image for which low priority is specified is less likely to be prefetched by the RISC 110. The images before and after the user's favorite image are likely to increase in the number of display times as the image is switched. However, these images are not always user's favorite images. Therefore, by fixing the display priority of such an image to 1, the RISC 110 can prefetch an image with a higher display priority.

  Returning to the description of the viewer image management table T1. “Use slide show” is information indicating whether an image is used for a slide show. When an image is used for the slide show for the first time, the RISC 110 updates the slide show use column corresponding to the image. “Specifying high priority” is information indicating whether or not an image is designated as having high priority by the user. When high priority is set by the user from the menu screen described above, the RISC 110 updates the high priority designation field. “Low priority designation” is information indicating whether or not an image has been designated by the user as having low priority. When the low priority is set by the user from the menu screen described above, the RISC 110 updates the low priority designation field.

  “Sort order” represents an image display order determined by a user sort instruction. The “sort order” is rewritten every time the user gives a sort instruction. There are two sort conditions that can be specified by the user, for example, file name order or shooting date / time order. The sorted images are ordered in the sort order on a reference axis that is arranged in the order of file name or shooting date.

  “Camera posture information” is information representing the posture of the camera at the time of shooting. There are three types of “camera posture information”: a horizontal position photographing posture, a +90 degree vertical position photographing posture, and a −90 degree vertical position photographing posture. That is, the horizontal position shooting posture in which the user holds the camera in the horizontal position, the +90 degree vertical position shooting posture in which the user holds the camera at the vertical position of +90 degrees clockwise from the horizontal position, and the clockwise position from the horizontal position. -90 degree vertical position shooting posture when shooting at a vertical position of -90 degrees. As will be described later, the camera posture information is recorded in an image file based on a signal from a posture sensor provided in the camera.

  “Image processing management information” indicates the type of image processing performed on the resized image data and the order in which the processing is performed. No. 4 in FIG. A case of 1 indicates that the tone adjustment has been performed after the gradation conversion is performed on the resized image data. “Image processing data name” is data in which parameters of image processing indicated in the image processing management information are recorded. No. 4 in FIG. In the case of 1, P000019. imp is image processing data. The image processing data is stored in the image processing data folder F3 in the HDD 114.

  “Metadata update date / time” represents information on the date / time when the metadata stored in the header of the image file was updated. “Camera identifier information” is information that identifies the camera that captured the image. Specifically, the camera manufacturer name, camera model name, and camera serial number are included.

Next, a method for generating a resized image file will be described. The resized image file is generated using the following four methods.
(1) Generated when photographing a subject image with an electronic camera (2) Generated with an electronic camera for an image acquired by shooting (3) Generated with an external device such as a personal computer (4) Generated with a viewer 100

(1) Generation of a resized image file at the time of photographing a subject image by the electronic camera FIG. 6 is a block diagram for explaining a main configuration of the electronic camera 200. The electronic camera 200 includes a photographing optical system 201, an image sensor 202, an analog processing circuit 203, an A / D conversion circuit 204, a timing generator 205, a digital processing circuit 206, a color interpolation processing unit 207, a reduced image generation unit 208, and a compression unit 209. A memory card interface 210, a CPU 211, an LCD drive circuit 212, an LCD 213, an operation unit 214, and an attitude sensor 215.

  The photographing optical system 201 is an optical system that forms a subject image on a light receiving surface of an image sensor 202 described later. The image sensor 202 is a photoelectric conversion element that converts received subject light into an image signal corresponding to its intensity. The imaging element 202 has pixels arranged in a matrix. Among them, for example, about 7 million pixels of 2304 pixels × 3072 pixels are effective imaging pixels. One of R (red), G (green), and B (blue) filters is attached to the light receiving surface of each pixel of the light receiving element of the image sensor 202 in a Bayer array. In a pixel (R pixel) to which an R filter is attached, incident light is separated into red and an image signal having a level corresponding to the brightness related to red is output. Similarly, in a pixel (G pixel) to which a G filter is attached, incident light is color-separated into green and an image signal having a level corresponding to the brightness related to green is output. In a pixel to which a B filter is attached (B pixel), incident light is color-separated into blue, and an image signal having a level corresponding to the brightness related to blue is output.

  The analog processing circuit 203 is a circuit that performs analog processing on the image signal output from the image sensor 202. Analog processing includes amplifier gain control and correlated double sampling. The gain of the amplifier is determined based on the ISO sensitivity set by the CPU 211. The A / D conversion circuit 204 is a circuit that converts the image signal output from the analog processing circuit 203 into digital image data. The timing generator 205 outputs a timing signal to the image sensor 202, the analog processing circuit 203, and the A / D conversion circuit 204 in accordance with a command from the CPU 211, and the image sensor 202, the analog processing circuit 203, and the A / D conversion circuit 204 This is a circuit for controlling the drive timing.

  The CPU 211 is an arithmetic circuit that controls each component of the electronic camera 200 and executes various data processing. That is, the CPU 211 controls the timing generator 205 and also controls a digital processing circuit 206, a color interpolation processing unit 207, a reduced image generation unit 208, a compression unit 209, a memory card interface 210, and an LCD driving circuit 212, which will be described later. The CPU 211 includes a memory (not shown), and stores various user settings input via the operation unit 214 as will be described later.

  The digital processing circuit 206 is a circuit that executes white balance processing and gamma correction processing on the image data output from the A / D conversion circuit 204. A color interpolation processing unit 207 performs color interpolation processing on the image data output from the digital processing circuit 206. By this interpolation processing, image data for each color of R, G, and B is obtained for all pixels. As described above, an image signal relating to red is output from the R pixel of the image sensor 202, but there is no information relating to green and blue. Similarly, red and blue image signals are not output from the G pixel of the image sensor 202. Also, red and green image signals are not output from the B pixel of the image sensor 202. Therefore, for example, for the R pixel, green and blue image data are generated by performing color interpolation processing based on the values of surrounding pixels. By performing the same processing on the G pixel and the B pixel, image data for each color of R, G, and B is obtained for all the pixels.

  The reduced image generation unit 208 is a circuit that reduces the image size of the main image data of about 7 million pixels as described above, and generates thumbnail image data, view image data, and resized image data. The size of the thumbnail image data is, for example, vertical 120 pixels × horizontal 160 pixels. The view image data means image data having an appropriate size to be displayed on the LCD 213 described later. The size of the view image data is, for example, 240 vertical pixels × 320 horizontal pixels. The resized image data is, for example, image data of length 1200 × width 1600.

  A compression unit 209 is a circuit that performs JPEG compression processing on the main image data. The CPU 211 generates one image data file from the thumbnail image data, the view image data, the compressed main image data, and the header information of the image data. Note that image data file generation processing by the reduced image generation unit 208, the compression unit 209, and the CPU 211 will be described in detail later.

  The memory card interface 210 is an interface for performing data communication with the above-described memory card 301 mounted on the camera. The memory card interface 210 is an interface circuit that writes an image data file to the memory card 301 or reads an image data file recorded on the memory card 301 based on the control of the CPU 211.

  The LCD drive circuit 212 is a circuit that drives the LCD 213 by outputting a drive signal to the LCD 213 based on a command from the CPU 211. The LCD 213 is a liquid crystal display panel having an aspect ratio of 3: 3. The LCD 213 performs display as a liquid crystal viewfinder and displays images based on thumbnail image data and view image data recorded on the memory card 301. The LCD 213 displays various information related to the image data file (shutter speed, aperture value, ISO sensitivity, file name, etc.). The LCD 213 displays various setting menu screens of the electronic camera 200 based on an operation of the operation unit 214 described later.

  The operation unit 214 is a switch that receives a user operation. The operation unit 214 includes a power switch, a release button, a setting menu display changeover switch, a setting menu determination button, and the like. The posture sensor 215 is a sensor that outputs information on the posture of the camera at the time of shooting. The posture sensor 215 is a horizontal position shooting in which the user holds the camera in the horizontal position, a +90 degree vertical position shooting in which the user holds the camera at a vertical position of +90 degrees clockwise from the horizontal position, and a counterclockwise rotation from the horizontal position. A posture signal for identifying photographing at a vertical position of −90 degrees in the direction for identifying photographing at −90 degrees vertical position is output. This attitude signal is written in the image file.

  Next, setting of image data size by the electronic camera 200 will be described. The image data size here means the number of pixels. The user sets the size of the main image data by operating the operation unit 214 in advance. There are two sizes of main image data that can be selected by the user: a first size and a second size. The first size is vertical 2304 pixels × horizontal 3072 pixels, and the second size is vertical 480 pixels × horizontal 640 pixels.

  The CPU 211 stores the size of the main image data input via the operation unit 214 in the internal memory. The CPU 211 refers to the image size table shown in FIG. 7 and performs image processing on the captured image signal based on the size of the input main image data. When the first size is set, an image data file is generated using the image data generated by the color interpolation processing unit 207 as main image data as it is, and is recorded in the memory card 301. When the second size is set, the reduced image generation unit 208 performs thinning processing on the image data generated by the color interpolation processing unit 207 to generate main image data. The CPU 211 generates an image data file based on the generated main image data and records it in the memory card 301.

  The user can select a shooting mode (referred to as a resized image generation shooting mode) in which the above-described resized image reduced to 2 million pixels is generated at the time of shooting by operating the operation unit 214 of the user. When the resized image generation shooting mode is instructed, the CPU 211 also sets the size of the resized image data based on the image size table. When a shooting mode other than the resized image generation shooting mode is instructed by the operation of the user operation unit 214, the CPU 211 does not set the size of the resized image data.

  As shown in the image size table of FIG. 7, the CPU 211 sets the thumbnail image data size to 120 pixels vertically × 160 pixels horizontally regardless of the first and second sizes. Further, the CPU 211 sets the view image data size to 240 vertical pixels × 320 horizontal pixels regardless of the first and second sizes. Note that the thumbnail image data size is the size of the thumbnail image data itself.

  Next, the imaging operation of the electronic camera 200 will be described. When the user operates the operation unit 214 to turn on the power and switch to the still image shooting mode, the CPU 211 sets the still image shooting mode. When the user operates the operation unit 214 in the still image shooting mode setting state and the resized image generation shooting mode is designated, the CPU 211 sets the resized image generation shooting mode. In any of the above-described shooting modes, the CPU 211 controls the timing generator 205, the digital processing circuit 206, the color interpolation processing unit 207, the reduced image generation unit 208, and the LCD driving circuit 212, thereby reducing 1/30 second. The image displayed on the LCD 213 is updated at a cycle. That is, the moving image of the subject is displayed on the LCD 213 functioning as an electronic viewfinder.

  Specifically, the CPU 211 instructs the reduced image generation unit 208 to generate view image data based on the setting. The view image data size is 240 vertical pixels × 320 horizontal pixels. The reduced image generation unit 208 generates view image data at a predetermined timing (cycle of 1/30 seconds) based on an instruction from the CPU 211.

  When the user fully presses the release switch, the CPU 211 sets the shutter speed, the aperture value, and the ISO sensitivity based on the photometric value obtained from the image sensor 202. Then, the CPU 211 sets an aperture value (not shown) to a set aperture value. The CPU 211 controls the timing generator 205 to drive the image sensor 202 so as to accumulate charges for a time corresponding to the set shutter speed. Further, the CPU 211 determines the gain of the amplifier of the analog processing circuit 203 based on the set ISO sensitivity, and sets the gain in the amplifier.

  The image signal output from the image sensor 202 is processed by the color interpolation processing unit 207 from the analog processing circuit 203 described above. The CPU 211 designates the thumbnail image data and the size of the view image data as shown in FIG. Then, the reduced image generation unit 208 generates thumbnail image data and view image data having a size designated by the CPU 211 based on the main image data.

  In the resized image generation shooting mode, the CPU 211 further designates the size of the resized image data to the reduced image generation unit 208. The reduced image generation unit 208 generates resized image data having a size designated by the CPU 211 based on the main image data, in addition to the thumbnail image data and the view image data.

  The CPU 211 generates main image data based on the set size of the main image data. When the first size is large, the CPU 211 uses the image data generated by the color interpolation processing unit 207 as it is as the main image data. When the second size is small, the reduced image generation unit 208 performs thinning processing on the image data generated by the color interpolation processing unit 207 to generate main image data. Next, the CPU 211 causes the compression unit 209 to execute compression processing of the generated main image data. In the resized image generation shooting mode, the CPU 211 also compresses the resized image data.

  The CPU 211 generates an image data file. Specifically, the CPU 211 generates one image data file from the main image data compressed by the compression unit 209 and the thumbnail image data and view image data generated by the reduced image generation unit 208. At this time, the CPU 211 records information on the thumbnail image display size and the view image display size in the header portion of the image data file. Further, the CPU 211 also records shooting information such as shutter speed, aperture value, ISO sensitivity, file name, shooting date and time in the header portion of the image data file. The CPU 211 also records address information of the data file of each image, that is, information indicating which data file is recorded at which address in the data file in the header portion of the image data file. When the resized image file has been generated, the CPU 211 records the resized header information in the header portion of the image data file. In the resized image generation shooting mode, the CPU 211 generates a resized image file separately from the above-described image data file.

  The CPU 211 drives the memory card interface 210 to write the generated image data file to the memory card 301. When there is a resized image file, the CPU 211 stores the resized image file in a folder different from the above-described image data file. If the user has selected the setting for creating a resized image file at the time of shooting, the CPU 211 creates a card image management table as shown in FIG. When the card image management table has already been created in the memory card 301, the CPU 211 updates the card image management table. In the card image management table, the file name of the main image in the memory card 301, the file name of the resized image corresponding to the main image file, and the folder name for storing the main image and the resized image are recorded. In addition, camera identifier information that identifies the camera that acquired the image is also recorded in the card image management table. The camera identifier information includes a camera manufacturer name, a camera model name, and a camera serial number.

(2) Resized image generation by electronic camera for captured image In the electronic camera 200 described above, when the user operates the operation unit 214 to turn on the power and switch to the image reproduction mode, the CPU 211 Set the playback mode. In the image reproduction mode, the CPU 211 reads the image file from the memory card 301 by driving the memory card interface 210. Based on the read image file, the CPU 211 displays an image corresponding to the thumbnail image data or view image data on the LCD 213. Note that the resized mark is superimposed on the image for which the resized image data is generated.

  The user can select an image to be resized from the images displayed on the LCD 213 by operating the operation unit 214. In order to designate an image for generating a resized image, the user can perform three instructions, ie, all image designation, one image designation, and all image release, by the operation unit 214.

  The designation of all images is to designate all images displayed on the LCD 213 as images for generating a resized image. That is, when the user performs an operation for designating all images using the operation unit 214, the CPU 211 displays all images except for images with a resized mark among images displayed on the LCD 213 as images for generating a resized image. Recognize that it was specified. Then, the CPU 211 superimposes and displays a check mark on the image displayed on the LCD 213 via the LCD driving circuit 212. At this time, the check mark is not displayed on the image already having the resized mark.

  One image designation is to individually designate an image displayed on the LCD 213 as an image for generating a resized image. That is, when the user performs an operation of selecting a favorite image using the operation unit 214, the CPU 211 recognizes that the selected image is designated as an image for generating a resized image. Then, the CPU 211 superimposes and displays a check mark on the image selected on the LCD 213 via the LCD drive circuit 212. When the user performs a release operation on the image already having a check mark using the operation unit 214, the CPU 211 cancels the designation of the resized image generation and erases the display of the check mark.

  All image cancellation refers to canceling all the resize image generation designations specified by the above-described all image designation or one image designation.

  When the user gives an instruction to create a resized image by operating the operation unit 214, the CPU 211 instructs the reduced image generation unit 208 to generate a resized image for an image with a check mark. The reduced image generation unit 208 generates resized image data based on a command from the CPU 211.

  When the resized image data is generated, the CPU 211 generates a resized image file in the same manner as the processing in the resized image generation shooting mode. The CPU 211 drives the memory card interface 210 to write the generated resized image file to the memory card 301. The CPU 211 stores the resized image file in a folder different from the existing image file in the memory card 301. Then, the CPU 211 generates a card image management table as shown in FIG. 8 and writes it in the memory card 301. When the card image management table has already been created in the memory card 301, the CPU 211 updates the card image management table.

(3) Resized image generation by an external device such as a personal computer-Processing for a memory card in which an image file acquired by an electronic camera is recorded-
FIG. 12 is a schematic control block diagram showing an example of a personal computer (hereinafter referred to as a personal computer) 400. The personal computer 400 has a CPU 401, HDD 402, memory card interface 403, operation unit 404, monitor 405, and external interface 406. When the resized image is generated by the personal computer 400, the image management software is started by the user. This image management software is stored in the HDD 402. When the user operates the operation unit 404 and is instructed to start the image management software, the CPU 401 starts the image management software. When the memory card 301 is attached, the memory card interface 403 outputs an attachment signal indicating that the memory card 301 is attached to the CPU 401. When the mounting signal is input, the CPU 401 establishes communication with the memory card 301 and outputs a signal requesting transmission of the card image management table and the thumbnail image file in the memory card 301.

  When the CPU 401 reads the card image management table and the thumbnail image file, the CPU 401 displays a thumbnail image corresponding to the input thumbnail image file on the monitor 405. When the card image management table does not exist in the memory card 301, the CPU 401 does not read the card image management table. For example, a case where a thumbnail image file acquired by the electronic camera 200 not having the resizing function is read corresponds to this case. Based on the card image management table or the resized header information, the CPU 401 superimposes and displays a mark indicating that the image has been resized on the image in which the resized image file exists.

  When the user operates the operation unit 404 to specify an image for generating a resized image, the CPU 401 generates a resized image file corresponding to the image specified by the user. In order to generate a resized image, the user can use the operation unit 404 to perform three instructions of one image designation, all image designation, and all image designation cancellation, as in the case of the electronic camera 200. The CPU 401 records the generated resized image file on the memory card 301. Further, the CPU 401 updates the card image management table. The updated card image management table is recorded in the memory card 301. When the card image management table does not exist in the memory card 301, the CPU 401 newly creates a card image management table and records it in the memory card 301. Similarly, when the personal computer 400 and the electronic camera 200 are connected via a cable such as USB via the external interface 406, the CPU 401 reads the thumbnail image file and generates the resized image file. It is.

-Resize image generation processing from images stored in the internal drive of a computer-
A case where a resized image file is generated from the image file recorded in the HDD 402 of the personal computer 400 described above will be described. When the user operates the operation unit 404 and is instructed to start the image management software, the CPU 401 starts the image management software. When the image management software is activated, the CPU 401 reads the PC image management table in the HDD 402. In the PC image management table, information regarding the presence / absence of a resized image file for the image file recorded in the HDD 402 is recorded. The PC image management table stores the same information as the card image management table.

  When the user operates the operation unit 404 to designate a folder, the CPU 401 reads thumbnail image data in an image file saved in the designated folder. When reading the thumbnail image data, the CPU 401 displays a thumbnail image corresponding to the read thumbnail image data on the monitor 405. Based on the PC image management table, the CPU 401 superimposes and displays a mark indicating that the resized image file has been resized.

  When the user operates the operation unit 404 to specify an image for generating a resized image, the CPU 401 generates a resized image file corresponding to the image specified by the user. In order to generate a resized image, the user can perform three instructions, that is, one image designation, all image designation, and all image designation cancellation, as described above. The CPU 401 records the generated resized image file in the HDD 402. Furthermore, the CPU 401 updates the PC image management table. If the PC image management table does not exist, the CPU 401 newly creates a PC image management table.

  The resized image file generated by the personal computer 400 is written to the drive designated by the user by the CPU 401. For example, when the memory card 301 is connected and the user designates the memory card 301, the resized image file is written to the memory card 301. Prior to writing to the memory card 301, the CPU 401 requests transmission of the card image management table of the memory card 301. When the card image management table is input, the CPU 401 determines which resized image file among the generated resized image files is not stored in the memory card 301. The determination is made by comparing the PC image management table with the input card image management table.

  At the time of comparison, the CPU 401 calculates the difference between the resized image file name in the PC image management table and the resized image file name in the input card image management table. Even if the resized image file name in the PC image management table and the resized image file name in the card image management table are the same, if the camera identifier information assigned to these images is different, it is recorded in the HDD 402. The image file is determined as a difference. In this case, the CPU 401 changes the file name of the image file recorded in the HDD 402 by adding a character such as “_01” at the end. By taking the difference between the resized image file names, the CPU 401 extracts a resized image file (difference image file) having a file name different from the resized image file name in the card image management table of the memory card 301. When the card image management table does not exist in the memory card 301, the CPU 401 recognizes all the resized image files in the PC image management table as difference image files. When the difference image file is extracted, the CPU 401 records a resized image file corresponding to the difference image file on the memory card 301. When the resized image file is recorded, the CPU 401 updates the card image management table and records it in the memory card 301.

(4) Resized image generation by the viewer 100 When the memory card 301 is attached to the viewer 100, the RISC 110 reads an image file stored in the memory card 301. The RISC 110 generates a resized image file using the read image file and stores it in the resized image file folder F1 of the HDD 114. Further, the RISC 110 updates the viewer image management table T1.

  When the memory card 301 is attached, the memory card interface 120 outputs an attachment signal indicating that the memory card 301 is attached to the RISC 110. Upon receiving the mounting signal, the RISC 110 establishes communication with the memory card 301 and outputs a signal requesting transmission of the card image management table in the memory card 301. Furthermore, the RISC 110 displays a warning message such as “Image data is being input. Do not remove the memory card” on the first LCD 103 via the first LCD interface 118.

-When the card image management table exists in the memory card 301-
When the card image management table exists in the memory card 301, the RISC 110 inputs the card image management table. The RISC 110 recognizes the resized image file from the input card image management table. The RISC 110 determines whether the recognized resized image file is a resized image file already recorded in the HDD 114. This determination is made by comparing the viewer image management table T1 with the input card image management table.

  At the time of comparison, the RISC 110 takes the difference between the input resized image file name in the card image management table and the resized image file in the viewer image management table T1. By taking the difference between the resized image file names, the RISC 110 extracts a resized image file (difference image file) having a file name different from the resized image file name in the viewer image management table T1 of the viewer 100. Even if the resized image file name in the card image management table and the resized image file name in the viewer image management table T1 are the same, if the camera identifier information given to these images is different, the memory card 301 is stored. The recorded image file is determined as a difference. In this case, the RISC 110 changes the file name of the image file recorded on the memory card 301 by adding a character such as “_01” at the end.

  The RISC 110 reads a resized image file corresponding to the difference image file from the memory card 301. The RISC 110 temporarily stores the read resized image file in the SDRAM 111 and then records it in the resized image file folder F 1 of the HDD 114. When the resized image file is recorded, the RISC 110 updates the viewer image management table T1. That is, the RISC 110 adds the record field of the resized image file newly recorded in the HDD 114 to the viewer image management table T1. Then, the RISC 110 records the management information of the resized image file recorded in the HDD 114 in the added record field.

  The RISC 110 searches all images in the memory card 301. As a result of the search, an unregistered image file whose file name is not recorded in the card image management table is extracted based on the main image file name recorded in the card image management table and the main image storage destination folder name. When the unregistered image file is extracted, the RISC 110 reads the unregistered image file and develops the image data of the unregistered image file in the SDRAM 111. The RISC 110 displays a thumbnail image corresponding to the thumbnail image data of the read unregistered image file on the first LCD 103. Further, the RISC 110 displays a message prompting selection such as “Do you want to create a resized image?” Or “Do you want to input an image?” On the second LCD 104.

  When the user has selected the setting for generating a resized image by operating the operation button 106, the RISC 110 generates the resized image data by resizing the image data developed in the SDRAM 111. The RISC 110 generates a resized image file based on the generated resized image data and records it in the resized image file folder F1 of the HDD 114. Then, the RISC 110 updates the viewer image management table T1. The RISC 110 adds the file name of the unregistered image to the card image management table of the memory card 301. That is, the RISC 110 adds a record field for unregistered images to the card image management table, and records management information regarding the extracted unregistered image file in the record field.

  Further, the RISC 110 displays a message such as “input of image data has been completed” on the first LCD 103 via the first LCD interface 118 for a predetermined time.

-When the card management table does not exist in the memory card 301-
When the card image management table does not exist in the memory card 301, the RISC 110 reads the image file in the memory card 301 and develops the image data of the read image file in the SDRAM 111. The RISC 110 resizes the image data developed on the SDRAM 111 to generate resized image data. The RISC 110 generates a resized image file based on the generated resized image data and records it in the resized image file folder F1 of the HDD 114. Then, the RISC 110 updates the viewer image management table T1. The RISC 110 performs the above-described resize image file generation process for all the image files in the memory card 301. When the resized image file is generated from all the image files in the memory card 301, the RISC 110 sends a message such as “input of image data is completed” to the first LCD 103 via the first LCD interface 118 in a predetermined manner. Display time. Further, the RISC 110 generates a card image management table in the memory card 301. In this card image management table, management information of an image file read by the RISC 110 from the memory card 301, that is, an image file recorded in the memory card 301 is recorded.

  The RISC 110 compares the first half of the file name of the resized image file, for example DSC0001, in the viewer image management table T1 before the update with the first half of the file name of the resized image file generated by the above-described resized image file generation process. If there is an image file with the same file name as a result of the comparison, the RISC 110 displays images corresponding to both resized image files on the first LCD 103. When two images having the same file name exist, the two images are displayed side by side on the first LCD 103. When there are three or more images having the same file name, thumbnail images are displayed. In this case, the newly read image or the generated image is displayed in reverse video.

  Further, the RISC 110 displays, for example, “1. There was an image with the same file name on the second LCD 104.“ 2. An image with the same file name was deleted. ”,“ 2. There was an image with the same file name. A message prompting selection such as “Change.”, “3. Delete all images with the same file name at once”, and “4. Change the file names of images with the same file name at once” is displayed.

  When the user operates the operation button 106 and selects “1. There was an image with the same file name. Delete the reverse display image”, the RISC 110 deletes the resized image file selected by the user from the HDD 114. To do. The user can designate an image to be deleted by operating the joystick 107 and the operation button 106. The designated image is displayed in reverse on the first LCD 103.

  When the user operates the operation button 106 and selects “2. There was an image with the same file name. Change the file name of the reverse display image”, the RISC 110 selects the newly generated resized image file. Change the file name. Specifically, a character, for example, “_01” is added to the end of the file name based on a predetermined rule. Further, the RISC 110 updates the viewer image management table T1. When the user operates the operation button 106 and selects “3. Delete all images with the same file name”, the RISC 110 deletes, for example, “Deletes the image with the same file name.” On the second LCD 104. "?" Is displayed. When the user operates the operation button 106 and selects “OK”, the RISC 110 deletes the newly generated resized image file from the HDD 114. When the user operates the operation button 106 to select “Cancel”, the RISC 110 displays a message prompting the above-mentioned selection again on the second LCD 104.

When “4. Change the file names of images with the same file name in a batch” is selected, the RISC 110 changes the file names of newly read resized images or newly created resized images. Specifically, as described above, characters are added to the end of the file name based on a predetermined rule so that the file names can be identified.
When the above processing ends, the RISC 110 updates the viewer image management table T1. That is, the RISC 110 changes the resized image file name field of the image file whose file name has been selected by the user to the changed file name. Further, the RISC 110 deletes the record field of the image file selected to be deleted by the user from the viewer management table T1.

(Input processing of image file in memory card 301)
The input process of the image file in the memory card 301 by the above-described RISC 110 will be described using the flowcharts shown in FIGS. Programs for performing the processes shown in FIGS. 13 and 14 are stored in a memory (not shown) in the RISC 110. This program is started when a mounting signal indicating that the memory card 301 is mounted is input from the memory card interface 120 and executed by the RISC 110. Alternatively, this program is started when the user selects image capture in the viewer menu by operating the joystick 107 and the operation button 106 and executed by the RISC 110. Each step in FIG. 13 and FIG. 14 is a process executed based on a command from RISC 110.

  In step S201, a warning such as “Image data is being input. Do not remove the memory card” is displayed on the first LCD 103, and the process proceeds to step S202. In step S202, the presence / absence of a card image management table in the memory card 301 is determined. If there is a card image management table, an affirmative decision is made in step S202 and the operation proceeds to step S203. If there is no card image management table, a negative determination is made in step S202, and the process proceeds to step S216.

-When there is a card image management table-
In step S203, the contents recorded in the card image management table are read and the process proceeds to step S204. In step S204, the difference between the file name of the resized image file in the card image management table and the file name of the resized image file in the viewer image management table T1 is obtained. By the process of taking the difference between the file names, a resized image file that does not exist in the viewer image management table T1 is extracted from all the resized image files in the card image management table, recognized as a difference image file, and the process proceeds to step S205.

  In step S205, the difference image file recognized in step S204 is captured, temporarily stored in the SDRAM 111, recorded in the HDD 114, and the process proceeds to step S206. In step S206, it is determined whether or not the recording process for all the difference image files recognized in step S204 has been completed. When the recording process for all the difference image files is completed, an affirmative determination is made in step S206 and the process proceeds to step S207. If the processing has not been completed for all the difference image files, a negative determination is made in step S206 and the process returns to step S205.

  In step S207, the record field of the resized image file newly recorded in the HDD 114 in step S205 is added to the viewer image management table T1, and the management information of the resized image file recorded in the HDD 114 is recorded in the record field. Proceed to S208. In step S208, the image file in the memory card 301 is searched to determine whether or not an unregistered image file not recorded in the card image management table has been extracted. When an unregistered image file is extracted, an affirmative determination is made in step S208 and the process proceeds to step S209. If an unregistered image file is not extracted, the subsequent processing is skipped and the process proceeds to step S215.

  In step S209, a thumbnail image is extracted from the unregistered image file, and the extracted thumbnail image is displayed on the first LCD 103. Further, a message such as “Do you want to generate a resized image of the displayed image?” Is displayed on the second LCD 104, and the process proceeds to step S210.

  In step S210, it is determined whether or not there is a user operation. When there is a user operation, that is, when an operation signal is input from the operation system interface 123, an affirmative determination is made in step S210 and the process proceeds to step S211. If there is no user operation, a negative determination is made in step S210, and step S210 is repeated until the user operation is performed.

  In step S211, it is determined whether or not the operation signal input in step S210 is a signal instructing generation of a resized image. In the case of a resize image generation instruction, an affirmative determination is made in step S211 and the process proceeds to step S212. In step S212, a resized image file is generated from the unregistered image file, recorded in the HDD 114, and the process proceeds to step S213. If the operation signal input in step S210 is not a signal for instructing the generation of the resized image, a negative determination is made in step S211 and step S212 is skipped and the process proceeds to step S213.

  In step S213, the record field of the unregistered image file extracted in step S208 is added to the viewer image management table T1, and management information relating to the unregistered image file extracted in step S208 is recorded in the record field, and step S214 is performed. Proceed to In step S214, the record field of the unregistered image file extracted in step S208 is added to the card image management table, management information relating to the unregistered image file extracted in step S208 is recorded in the record field, and the process proceeds to step S239. move on. That is, the management information of the unregistered image file extracted in step S208 is added to the added record column of the viewer image management table T1 and the card image management table. In step S239, it is determined whether or not the processing has been completed for all the unregistered image files extracted in step S208. If the processing has been completed for all unregistered image files, an affirmative determination is made in step S239 and the process proceeds to step S215. In step S215, a message such as “input of image data has been completed” is displayed for a predetermined time on first LCD 103, and the process proceeds to step S223 in FIG. If processing has not been completed for all unregistered image files, a negative determination is made in step S239 and the process returns to step S209.

-When there is no card image management table-
When there is no card image management table in the memory card 301, in step S 216, in which the negative determination is made in step S 202, one image file is input from the memory card 301, and the image data of the input image file is converted into the SDRAM 111. The process proceeds to step S217. In step S217, the image data expanded in the SDRAM 111 in step S216 is resized to generate resized image data. Based on the generated resized image data, a resized image file is generated, and the process proceeds to step S218. In step S218, the resized image file generated in step S217 is recorded in the HDD 114, and the process proceeds to step S219.

  In step S219, the record field of the resized image file recorded in the HDD 114 in step S218 is added to the viewer image management table T1, the management information of the resized image file recorded in the HDD 114 is recorded in the record field, and the process proceeds to step S220. . In step S220, a card image management table is created in the memory card 301, and the process proceeds to step S221. If the card image management table already exists, the card image management table is updated in step S220. In step S221, it is determined whether or not processing has been completed for all image files stored in the memory card 301. If the processing has been completed for all the image files, an affirmative determination is made in step S221 and the process proceeds to step S222. If the processing has not been completed for all the image files, a negative determination is made in step S221 and the process returns to step S216. In step S222, as in step S215, a message such as “input of image data has been completed” is displayed for a predetermined time on first LCD 103, and the process proceeds to step S223 in FIG.

  In step S223 of FIG. 14, it is determined whether or not a resized image file having the same file name as the newly recorded resized image file is already stored in the HDD 114, and the process proceeds to step S224. This determination is made with reference to the resized image file name column in the viewer image management table T1. In step S224, as a result of the determination in step S223, the presence / absence of a resized image file having a matching file name is determined. If there is a resized image file with a matching file name, an affirmative determination is made in step S224 and the process proceeds to step S225. If there is no resized image file with a matching file name, a negative determination is made in step S224, and the series of processing ends.

In step S225, a set of images having a plurality of resized image files having the same file name is displayed side by side on the first LCD 103, for example. Further, a menu screen is displayed on the second LCD 104, and the process proceeds to step S226. The menu screen is as follows, for example.
1. There was an image with the same file name. Delete the reverse image.
2. There was an image with the same file name. Change the reverse image file name.
3. Delete all images with the same file name.
4). Change the file names of images with the same file name all at once.

  In step S226, the presence / absence of a user operation is determined. When there is a user operation, that is, when an operation signal is input from the operation system interface 123, an affirmative determination is made in step S226 and the process proceeds to step S227. If there is no user operation, a negative determination is made in step S226, and step S226 is repeated until there is a user operation.

  In step S227, it is determined whether or not the operation signal input in step S226 is a signal for instructing deletion of the selected image. When a signal instructing deletion of the selected image is input, an affirmative determination is made in step S227 and the process proceeds to step S228. In step S228, the image file corresponding to the image selected by the user is deleted from HDD 114, and the process proceeds to step 229. In step S229, it is determined whether there is another set having a resized image file with a matching file name. If another set exists, an affirmative determination is made in step S229 and the process returns to step S225. If there is no other set, a negative determination is made in step S229 and the process proceeds to step S238.

  If the operation signal input in step S226 is not a signal for instructing deletion of the selected image, a negative determination is made in step S227 and the process proceeds to step S230. In step S230, it is determined whether or not the operation signal input in step S226 is a signal instructing to change the file name of the selected image. If the signal is an instruction to change the file name of the selected image, an affirmative determination is made in step S230 and the process proceeds to step S231. In step S231, the file name of the newly created resized image file is changed based on a predetermined rule, and the process proceeds to step S229.

  If the operation signal input in step S226 is not a signal for instructing to change the file name of the selected image, a negative determination is made in step S230 and the process proceeds to step S232. In step S232, it is determined whether or not the operation signal input in step S226 is a signal for collectively changing the file names of the resized image files newly generated in all sets. In the case of a signal for instructing batch change of file names, an affirmative decision is made in step S232 and the process proceeds to step S233. In step S233, the file names of all newly generated resized image files in all groups are changed based on a predetermined rule, and the process proceeds to step S238.

  If the operation signal input in step S226 is not a signal for instructing batch change of file names, that is, if the signal is for deleting all newly generated resized image files in all sets, step S232 is negatively determined. Then, the process proceeds to step S234. In step S234, a confirmation display such as "Delete image files with the same file name at once? Are you sure?" Is displayed on the screen on which the above-described menu screen is displayed, that is, the second LCD 104, and the process proceeds to step S235. move on.

  In step S235, it is determined whether or not an ON signal is input from the operation button 106. If an ON signal is input, an affirmative determination is made in step S235 and the process proceeds to step S236. In step S236, all newly generated resized image files in all sets are deleted from HDD 114, and the process proceeds to step S238. If no ON signal is input from the operation button 106, a negative determination is made in step S235, and the process proceeds to step S237. In step S237, the confirmation display displayed in step S234 is deleted, and the process returns to step S226. In step S238, the viewer image management table T1 is updated, and the series of processing ends.

According to the embodiment described above, the following operational effects can be obtained.
(1) When the card image management table exists in the memory card 301, the RISC 110 specifies the image file to be acquired based on the identifier unique to the image file recorded in the viewer image management table T1 and the card image management table. To do. That is, the RISC 110 takes the difference between the resized image file name recorded in the viewer image management table T1 and the resized image file name recorded in the card image management table. By taking the difference, the RISC 110 extracts an image file having a file name different from the resized image file name in the viewer image management table T1 as a difference image file. Then, the RISC 110 acquires the extracted difference image file from the memory card 301. If there is no card image management table in the memory card 301, the RISC 110 acquires all image files recorded in the memory card 301. Therefore, the image file recorded on the memory card 301 can be read without excess or deficiency.

(2) The RISC 110 searches all image files recorded on the memory card 301 and extracts image files not recorded in the card image management table as unregistered image files. Then, the RISC 110 reads the extracted unregistered image file from the memory card 301. Therefore, the RISC 110 can read image files that are not managed by the card image management table in the images recorded on the memory card 301, so that the image files in the memory card 301 can be read without excess or deficiency. .

(3) Further, the RISC 110 records the file name of the unregistered image file in the card image management table. Therefore, when the image file is read from the next time onward, the RISC 110 can extract the difference image based on the image file name recorded in the card image management table, so that the image file to be read can be specified at high speed. it can.

(4) When the card image management table does not exist in the memory card 301, the RISC 110 determines whether an image file having the same file name as all the read image files is recorded in the HDD 114. Also, the RISC 110 determines whether or not an image file having the same file name as an unregistered image file that has a card image management table but is not registered in the table is recorded in the HDD 114. When an image file having the same file name is recorded on the HDD 114, the RISC 110 displays the image of the read image file and the image of the image file already recorded on the HDD 114 on the first LCD 103. Furthermore, the RISC 110 displays on the second LCD 104 a menu screen for inquiring the user as to which image file of both images is to be deleted from the HDD 114. Therefore, when an image having the same file name as the image already recorded on the HDD 114 is read, the user can determine whether or not to delete the image from the HDD 114 while checking the image displayed on the first LCD 103. .

  Further, the RISC 110 displays on the second LCD 104 a menu screen for inquiring the user as to which image file name to change between the read image file and the image file already recorded in the HDD 114. In response to the selection instruction from the user, the RISC 110 adds characters such as “_01” to the end of the file name of the designated image file, and changes the file name so that they can be distinguished from each other. Therefore, when an image having the same file name as the image already recorded on the HDD 114 is read, the user determines which image file name is to be changed while checking the image displayed on the first LCD 103. be able to.

The embodiment described above can be modified as follows.
(1) When an image file is read from the memory card 301 to the viewer 100, the RISC 110 reverse-displays the thumbnail image displayed on the first LCD 103 that has been designated for deletion or file name change by the user. It was. However, the user may designate an image by checking a check box displayed together with the image, instead of inverting the designated image.

(2) It is possible to enhance the functions for existing users via the Internet or via a portable recording medium when the program is upgraded. Therefore, the programs of FIGS. 13 and 14 can be applied to such software for upgrading. For example, the programs of FIGS. 13 and 14 can be configured as an image acquisition program having the following processes (a) to (e).
(A) Reading process for reading image data from the storage medium (b) Storage process for storing the read image data (c) First image management table for managing the stored image data including an identifier unique to the image data (D) determination process for determining whether or not a second image management table for managing image data stored in the storage medium, including an identifier unique to the image data, exists in the storage medium (e) ) When the second image management table does not exist, all image data stored in the storage medium is acquired. When the second image management table exists, the identifier included in the first image management table and the second image Acquisition processing for acquiring image data specified by determining the difference from the identifier included in the management table

Further, the programs of FIGS. 13 and 14 can be configured as an image display program having the following processes (a) to (d).
(A) Reading process for reading image data from the first storage medium (b) Recording process for recording the read image data in a second storage medium different from the first storage medium (c) When executing the reading process A determination process for comparing the file name of the read image data with the file name of the image data already stored in the second storage medium to determine whether the file names match (d) File name Display process for displaying on the screen an image based on the read image data and an image based on the image data stored in the second memory and determined to have the same file name

  In addition, the present invention is not limited to the above-described embodiment as long as the characteristics of the present invention are not impaired, and other forms conceivable within the scope of the technical idea of the present invention are also within the scope of the present invention. included.

It is a figure explaining the external appearance of the viewer in embodiment of this invention. It is a block diagram explaining the principal part structure of the viewer in embodiment. It is a conceptual diagram explaining the data management in HDD of a viewer. It is a figure explaining an example of the contents of a viewer image management table. It is a figure explaining an example of the content of a display priority table. It is a block diagram explaining the principal part structure of an electronic camera. It is a figure explaining an example of the relationship between the image data produced | generated with an electronic camera, and size. It is a figure explaining an example of the card management table which manages the image in a memory card. It is a figure explaining the mode of the image display in a viewer. It is a figure explaining the mode of the thumbnail image display in a viewer. It is a figure explaining the menu structure of a viewer. It is a figure explaining the structural example of the personal computer which can produce | generate a resized image. It is a flowchart explaining the image file reading process by the viewer in an embodiment. It is a flowchart explaining the image file reading process by the viewer in an embodiment.

Explanation of symbols

100 viewer 103 first LCD 104 second LCD
110 RISC 111 SDRAM 114 HDD
301 memory card

Claims (4)

A reading process for reading image data from the attached first storage medium;
A recording process for recording the image data read by the reading process in a second storage medium different from the first storage medium;
When executing the reading process, the file name of the read image data is compared with the file name of the image data already stored in the second storage medium, and whether or not the file names match A determination process for determining
If it is determined that the file names match, the image based on the image data read in the reading process and the image data stored in the second storage medium and determined to match the file name by the determination process An image display program for executing, on a computer, display processing for displaying an image on a screen. The image display program according to claim 1,
A selection process for receiving a selection instruction from a user and selecting at least one image from a plurality of images displayed by the display process;
An image display program for further executing a deletion process for deleting the selected image on a computer. In the image processing program according to claim 1,
An image display that receives a file name change instruction from a user and further executes a change process for changing the file name so that the file names of the displayed images are different from each other. program. Execution means for executing the image display program according to any one of claims 1 to 3,
The second storage medium;
In the determination process, when it is determined that the file names match, the image based on the image data read in the reading process is stored in the second storage medium, and the determination process determines that the file names match. An image display device comprising: display means for displaying an image based on the obtained image data on a screen.

Images