JP5550292B2 - Cell image display device - Google Patents

Description

The present invention relates to a cell image display equipment for displaying the cell image.

  Conventionally, moving images for observing blood cells used in a certified blood test technician's test are obtained by observing the smear with an optical microscope and sequentially imaging multiple cells to be shown to the examinee while moving the smear. Was created by. The examinee looks at the reproduced moving image and answers the patient's medical condition. In this case, in order to grasp the patient's medical condition, it is necessary to grasp not only a plurality of main cells necessary for grasping the medical condition but also the situation of surrounding cells.

JP 2006-105695 A

  In the case of a moving image used for the examination by the certified blood laboratory technician, it is necessary to reproduce all the main cells necessary for grasping the pathological condition and the surrounding image in a predetermined time. For this reason, when imaging blood cells in a smear with a video camera via a microscope, focus on the main cells and image them while moving the smear while observing with a microscope. It was necessary to repeatedly perform operations such as moving and imaging, refocusing on the main cells, and imaging, which was very troublesome and troublesome. In addition, it is necessary to edit the moving image captured by the video camera in accordance with the question time so that the moving image can be finally used as a test question. This editing operation is also time-consuming and troublesome.

  The present invention has been made in view of the above requirements, and it is possible to easily create a cell image capable of sequentially displaying a plurality of cells necessary for grasping a disease state in a predetermined time including surrounding conditions. An object of the present invention is to provide a cell image display device that can be used.

  The cell image display device according to the first aspect of the present invention includes a display unit, a cell image display unit that displays a cell image on the display unit and scrolls the cell image in accordance with an operation input, and the display unit. A designated position receiving means for accepting setting of a designated position on the cell image displayed on the designated position, a designated position holding means for holding the designated positions received by the designated position accepting means in correspondence with each other in a transition order, and the designated position When the cell image is sequentially shifted at a predetermined speed from the designated position in the first transition order held by the holding means to the designated position in the last transition order, the cell image at the designated position in the last transition order The transition time calculation means for calculating the total transition time required until the transition to, and the total transition time calculated by the transition time calculation means are displayed. And a transition time display means that.

  According to the cell image display device according to the present aspect, it is possible to set a branch point when transitioning a cell image by setting a designated position on the displayed cell image. At this time, since the total transition time is displayed, the editor can easily confirm whether the total display time of the cell image is within the requested time during editing.

  The cell image display device according to the first aspect may be configured to further include designated position change accepting means for accepting deletion of the designated position held in the designated position holding means and change in transition order. If it carries out like this, the branch point at the time of making a cell image transition can be adjusted easily.

  Further, the cell image display device according to the first aspect is configured such that the cell image is not transferred between the two specified positions adjacent to each other in the transition order, and the cell image is not transferred between the two specified positions. It can be set as the structure further provided with the switch reception means which receives the setting for switching. In this way, the editor can select whether to change the cell image or switch the cell image between the designated positions, and therefore can perform editing that leads to more effective display of the cell image.

  In the cell image display device according to the first aspect, the transition time calculation unit displays the cell images from the designated position in the first transition order held by the designated position holding unit to the designated position in each transition order. It can be set as the structure which calculates further the designated position transition time required for making it change. At this time, the transition time display means displays the total transition time and the designated position transition time in association with the corresponding designated positions. In this way, the editor can know the total transition time and the time required for displaying the cell image at each designated position, and can proceed with the editing work more smoothly.

  In the cell image display device according to the first aspect, the cell image display device may further include partial image display means for displaying a partial image around the designated position in association with the corresponding designated position. In this case, it is preferable that the partial image and the total transition time or the designated position transition time are simultaneously displayed in association with the corresponding designated position. According to these configurations, since the partial images around each designated position are displayed in association with each designated position, the editor can easily grasp the setting status of each designated position.

  The cell image display device according to the first aspect includes a transition time changing unit that receives correction of the total transition time and the designated position transition time, and the total speed after correction of the moving speed of the cell image between the designated positions. It may be configured to further include a moving speed changing unit that changes according to the transition time or the specified position transition time. In this case, the moving speed changing means may be configured such that the designated position corresponding to the total transition time or the designated position transition time for which the correction has been received, and the designated position whose transition order is one order before the designated position. It may be configured to change the movement speed between them according to the corrected total transition time or the designated position transition time. According to these configurations, the editor can appropriately adjust the total transition time or the designated position transition time so that the total transition time can be within the requested time, thereby simplifying the editing work. be able to.

  The cell image display device according to the first aspect may further include a stationary time reception unit that receives a setting of a stationary time of the cell image at the designated position. In this way, the editor can make the cell image that he / she wants to look long stand still for a desired time and display it, and can perform editing that leads to more effective display of the cell image.

  In the cell image display device according to the first aspect, the transition time calculating means moves the cell image between two designated positions adjacent in transition order among the designated positions held by the designated position holding means. It can be set as the structure which calculates time. At this time, the transition time display means may be configured to display the movement times in association with the corresponding designated positions. Thus, the editor can know the time required for the cell image to transition between the designated positions in addition to the total transition time, and can smoothly proceed with the editing operation.

  As described above, according to the present invention, a cell image display device capable of easily creating a cell image capable of sequentially displaying a plurality of cells necessary for grasping a pathological condition within a predetermined time, including the surrounding conditions. Can be provided.

  The effects and significance of the present invention will become more apparent from the following description of embodiments. However, the embodiment described below is merely an example when the present invention is implemented, and the present invention is not limited to what is described in the following embodiment.

It is a figure which shows the structure of the virtual slide production apparatus which concerns on embodiment. It is a figure explaining the virtual slide creation method which concerns on embodiment. It is a figure which shows the structure of the cell image display apparatus which concerns on embodiment. It is a figure which shows the structure of the edit screen of the cell image which concerns on embodiment. It is a figure explaining the edit operation | movement of the cell image which concerns on embodiment. It is a figure explaining the edit operation | movement of the cell image which concerns on embodiment. It is a figure explaining the edit operation | movement of the cell image which concerns on embodiment. It is a figure explaining the edit operation | movement of the cell image which concerns on embodiment. It is a figure explaining the edit operation | movement of the cell image which concerns on embodiment. It is a figure which shows the structure of the display setting table which concerns on embodiment. It is a flowchart of the checkpoint registration process which concerns on embodiment. It is a flowchart of the display setting table change process which concerns on embodiment. It is a flowchart of the display setting table change process which concerns on embodiment. It is a figure which shows the screen used for storage of the edit file which concerns on embodiment. It is a figure explaining the file structure of the data stored in the disc concerning an embodiment. It is a flowchart which shows the display process of the cell image which concerns on embodiment. It is a figure which shows the example of a display of the cell image which concerns on embodiment. It is a figure which shows the example of a change of the edit screen of the cell image which concerns on embodiment. It is a flowchart which shows the example of a change of the checkpoint registration process which concerns on embodiment.

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

  FIG. 1 is a diagram illustrating a configuration of a virtual slide creation device according to an embodiment. As shown in the figure, the virtual slide creation apparatus includes an optical microscope 1 and a computer 2. The optical microscope 1 includes an objective lens 101, a CCD camera 102, an automatic stage 103, and a control unit 104.

  The objective lens 101 is provided to obtain an enlarged image of blood cells smeared on the slide 3. Here, a plurality of objective lenses 101 having different magnifications are arranged. The CCD camera 102 captures an enlarged image of blood cells smeared on the slide 3 via the objective lens 101.

  The automatic stage 103 can hold the slide 3 and can move the slide 3 in three directions of the X-axis direction, the Y-axis direction, and the Z-axis direction. By moving the automatic stage 103 in the Z-axis direction while the slide 3 is held on the automatic stage 103, the focal position by the objective lens 101 is changed in the smear sample depth direction (Z-axis direction) in the same field of view. Is done. As a result, images with the same visual field and at different depth positions can be picked up by the CCD camera 102 from the smear.

  Further, by moving the automatic stage 103 in the X-axis direction or the Y-axis direction while holding the slide 3, the field of view of the objective lens 101 in the plane direction with respect to the smear sample is changed. As a result, the cell image can be taken by the CCD camera 102 via the objective lens 101 over the entire area in the plane direction to be converted into a virtual slide.

  The control unit 104 is provided for controlling the position of the automatic stage 103. The control unit 104 includes a joystick 104a and is connected to the automatic stage 103 via a cable C3. By operating the joystick 104a, the automatic stage 103 is moved in the X-axis direction, the Y-axis direction, and the Z-axis direction.

The computer 2 is connected to the control unit 104 via the cable C2 and is connected to the CCD camera 102 via the cable C1. As a result, a control signal for controlling the control unit 104 is transmitted from the computer 2 to the control unit 104 via the cable C2. In addition, image data captured by the CCD camera 102 is transmitted to the computer 2 via the cable C1.

FIG. 2 is a conceptual diagram illustrating a method for creating a virtual slide.

  At the time of creating the virtual slide, a smear is set on the automatic stage 103. The smear is spread over a predetermined area on the surface of the slide glass. Next, various parameter settings are input to the computer 2. Here, first, a range to be virtual-slided (sample specimen area: distance in X direction and Y direction) is input. Next, the overlapping ratio between the continuous visual fields for image tiling (the ratio of the overlapping portions in (2) of FIG. 2) is input to the computer 2. The overlapping rate is set in the range of 10 to 40%. Finally, the focal width (distance in the Z direction) and the step size for focus synthesis are input to the computer 2. By setting the focal width and the step size, the number of images to be captured in the same field of view is determined.

  In this way, when a virtual slide creation start instruction is input after the pre-processing, the virtual slide creation processing is executed under the control of the computer 2. First, as shown in (1) of FIG. 2, the number of images determined by the above setting input for the same field of view is picked up by the CCD camera 102 while changing the focal position in the depth direction. 2 is taken in. The computer 2 creates a focus composite image based on the captured image. Here, the focus synthesis is to extract a focused pixel from each image for a plurality of images having different focal positions in the same visual field, and synthesize these to obtain a single focused image as a whole. The process to create. By performing such focus synthesis on all images captured in the same field of view, for example, as shown in FIG. 2, a focus synthesized image having a resolution of 1360 dots × 1024 dots is created. For example, the TIFF format is used as the image format of the focus composite image.

  The computer 2 creates the focus composite image for the entire range set by the setting input by repeating the above process while moving the automatic stage in the X and Y directions and changing the imaging field of view.

  When the focus composite image is created for the entire set range in this way, the computer 2 performs image tiling between the focus composite images according to the overlapping rate set by the setting input as shown in (2) of FIG. I do. At this time, the computer 2 recognizes an overlapping portion of adjacent focus composite images by a known pattern matching process, and matches the overlapping portions of the respective images to each other. Thereby, both images are combined so that the joints are not conspicuous. Thus, virtual tiling is completed by performing image tiling for all the focus composite images. As an image format of this virtual slide, for example, the BMP format is used. The size of the virtual slide created by the above processing is about 220,000 dots × 134,000 dots.

  The virtual slide created in this way is stored in a server or the like and read and used by various computers such as a client computer. In the present embodiment, the virtual slide is taken into an editing computer (corresponding to the cell image display device according to claims 1 to 10), and a cell image file used for a test by a certified blood laboratory technician is created. The

  FIG. 3 is a diagram showing the configuration of the editing computer 4.

  The editing computer 4 is composed of a personal computer, and includes a main body 400, an input unit 408, and a display unit 409. The main body 400 includes a CPU 401, ROM 402, RAM 403, hard disk 404, disk drive device 405, input / output interface 406, image output interface 407, and communication interface 410.

  The CPU 401 executes computer programs stored in the ROM 402 and computer programs loaded in the RAM 403. The RAM 403 is used for reading computer programs recorded in the ROM 402 and the hard disk 404. The RAM 403 is also used as a work area for the CPU 401 when executing these computer programs.

  The hard disk 404 is installed with various computer programs to be executed by the CPU 401 such as an operating system and application programs, and data used for executing the computer programs. That is, the hard disk 404 is installed with a program for editing the cell image file for the certified blood test technician test. In addition, virtual slide data used for editing cell images is captured from the outside and stored in the hard disk 404 by the editing computer.

  The disk drive device 405 is configured by a DVD drive or the like, can read a computer program or data from a recording medium, and can write a computer program or data from a recording medium. An input unit 408 such as a mouse or a keyboard is connected to the input / output interface 406, and data is input to the editing computer 4 when the operator uses the input unit 408. The image output interface 407 is connected to a display unit 409 configured with a display or the like, and outputs a video signal corresponding to the image data to the display unit 409. The display unit 409 displays an image based on the input video signal. The communication interface 410 enables data transmission / reception with respect to the network.

  Hereinafter, the cell image editing process will be described with reference to FIGS.

  FIG. 4 is a diagram showing the configuration of the edit screen. This editing screen is displayed by activating a cell image editing program installed in the hard disk 404 and selecting desired virtual slide data.

  As shown in FIG. 2A, the editing screen is roughly divided into an image display area 10 and an editing area 20. In the image display area 10, a cell image is displayed. In addition, in the image display area 10, a navigator 30 is displayed in an overlapping manner so that it can be seen which part of the virtual slide is an enlarged display of the currently displayed cell image.

The editing area 20 is an area used for editing a cell image. This area includes a plurality of checkpoint display areas (hereinafter referred to as “CP display areas”) 21 and one checkpoint edit area (hereinafter referred to as “CP edit area”) 22.

  Each time a checkpoint is set by the editor, the contents of the set checkpoint are displayed in the CP display area 21 in order from the top. In FIG. 5A, five CP display areas 21 are shown, but it is also possible to set six or more checkpoints. That is, when the fifth check point is set, the display of the CP display area 21 in the second to fifth stages from the top is scrolled up by one stage, and a blank CP display area 21 appears in the lowermost stage. . Similarly, when the sixth and subsequent checkpoints are set, the CP display area 21 scrolls up and a blank CP display area 21 appears.

  The configuration of the CP display area 21 is as shown in FIG. As shown in the figure, the CP display area 21 includes a movement / switch button 21a, an arrival time display setting unit 21b, a waiting time display setting unit 21c, a partial image display unit 21d, and a rank display unit 21e. . In addition, a scroll bar 21 f is arranged beside the five CP display areas 21. The scroll bar 21f is used to scroll up and down the CP display area 21 when five or more check points are set.

  The configuration of the CP editing area 22 is as shown in FIG. As shown in the figure, in the CP editing area 22, a delete tab 22a and a move tab 22e are set to be selectable. FIG. 4C shows a configuration when the delete tab 22a is selected. The deletion tab 22a is provided with a selection / deletion button 22b, a deletion range designation section 22c, and a batch deletion button 22d.

  Hereinafter, the functions of the image display area 10 and the editing area 20 will be described with reference to FIGS.

  FIG. 5 is a diagram showing an initial screen before checkpoint setting. The cell image displayed in the image display area 10 can be scrolled up, down, left, and right by using the up, down, left, and right arrow keys on the keyboard. As shown in the figure, the navigator 30 shows the entire specimen region 31a of the virtual slide and the position 31b of the currently displayed cell image on the whole specimen region.

  FIG. 6 is a diagram showing a screen when a checkpoint is first set. The editor moves the pointer 40 and right-clicks the mouse at a position to be set as a checkpoint. As a result, this position is set as the first check point, and display corresponding to the uppermost CP display area 21 of the editing area 20 is performed.

FIG. 9A is a diagram illustrating a display example of the CP display area 21 when the first checkpoint is set. As shown in the figure, in the uppermost CP display area 21, “1” indicating the first display order is displayed on the order display portion 21e. The movement / switch button 21a is set to “switch”. Further, the arrival time display setting unit 21b is masked in the state of “0”, and “0” is set in the waiting time display setting unit 21c. In addition, the partial image display unit 21d displays a partial image cut out immediately after the first check point.

  The move / switch button 21a is a button for setting in what form the display is to flow from the previous check point to the check point. If the move / switch button 21a is “move”, the cell image is displayed to be scrolled from the previous check point to the check point at a predetermined speed. When the movement / switch button 21a is “switch”, the cell image is displayed so as to be instantaneously switched from the previous check point to the check point. The editor can arbitrarily select “move” and “switch”. In FIG. 9A, since there is no previous check point, the movement / switch button 21a is set to “switch”.

  The arrival time display setting 21b displays the time (hereinafter referred to as “CP arrival time”) required for displaying the cell image at the checkpoint after the cell image is first displayed. The editor can change the CP arrival time when the move / switch button 21a is “move”. When the CP arrival time is changed, the speed at which the cell image is scrolled from the previous check point to the check point is changed accordingly. In FIG. 9A, since it is the first check point, the arrival time display setting unit 21b is masked in a state of “0”.

  The waiting time display setting unit 21c displays the time during which the cell image is continuously displayed as a still image (hereinafter referred to as “CP waiting time”) at the check point. In the waiting time display setting unit 21c, “0” is set as a default value. The editor can arbitrarily change the CP waiting time. In FIG. 5A, the default value “0” is displayed in the waiting time display setting unit 21c.

  FIG. 7 is a diagram showing a screen when the second checkpoint is set. In this screen, the cell image displayed in the image display area 10 is slightly scrolled in the upper right direction as compared with the case of FIG. The editor moves the pointer 40 to a position to be set as a checkpoint and right-clicks the mouse. As a result, this position is set as the second check point, and display corresponding to the CP display area 21 in the second row from the top of the editing area 20 is performed.

FIG. 9B is a diagram illustrating a display example of the CP display area 21 when the second checkpoint is set. As shown in the drawing, in the CP display area 21 in the second row from the top, “2” indicating the second display order is displayed in the order display portion 21e. The move / switch button 21a is set to “move”. Furthermore, “4 seconds” is displayed on the arrival time display setting unit 21b, and “0” is set on the waiting time display setting unit 21c. Further, the partial image cut out from the second check point is displayed on the partial image display unit 21d.

  When the second and subsequent checkpoints are set, the move / switch button 21a is set to “move” by default. In this case, the cell image is displayed to be scrolled at a predetermined speed from the first check point to the second check point. When it is desired to display the cell image so that the cell image is instantaneously switched from the first check point to the second check point, the editor changes the movement / switch button 21a to “switch”.

  In FIG. 9B, the arrival time display setting 21b displays that the CP arrival time at the second check point is “4 seconds”. When the CP arrival time is changed by the editor, the speed at which the cell image is scrolled from the first check point to the second check point is changed accordingly. For example, when the CP arrival time of the second check point is changed to “2 seconds”, the speed at which the cell image is scrolled from the first check point to the second check point is doubled. A method for calculating the CP arrival time and the scrolling speed of the cell image will be described later with reference to FIG.

  In FIG. 9B, “0” is set as a default value in the waiting time display setting unit 21c. In this case, when the third check point is set next, the cell image of the second check point is displayed, and immediately thereafter, the cell image is scrolled toward the third check point. The editor can arbitrarily change the CP waiting time. For example, if the CP waiting time of the second checkpoint is changed to “3 seconds”, the cell image of the second checkpoint is displayed as a still image for 3 seconds, and then the cell image scrolls toward the third checkpoint. Will come to be.

  FIG. 8 is a diagram showing a screen when the third checkpoint is set. In this screen, the cell image displayed in the image display area 10 is largely scrolled to the left as compared with the case of FIG. The editor moves the pointer 40 to a position to be set as a checkpoint and right-clicks the mouse. As a result, this position is set as the third check point, and the display corresponding to the CP display area 21 in the third row from the top of the editing area 20 is performed.

  FIG. 9C is a diagram illustrating a display example of the CP display area 21 when the third checkpoint is set. Here, although the frame F is shown in the CP display area in the second row, this frame F is not displayed when the third checkpoint is set.

As shown in the drawing, in the CP display area 21 in the third row from the top, “3” indicating the third display order is displayed in the order display portion 21e. The move / switch button 21a is set to “Move” by default. Further, “14 seconds” is displayed in the arrival time display setting unit 21b, and “0” is set in the waiting time display setting unit 21c. In addition, a partial image cut out from the nearest third check point is displayed on the partial image display unit 21d.

  Here, since the CP arrival time is “14 seconds”, it can be seen that it takes 10 seconds for the cell image to scroll from the second check point to the third check point. When the CP arrival time of the third check point is changed by the editor, the speed at which the cell image is scrolled from the second check point to the third check point is changed accordingly.

  Note that the editor can delete already set checkpoints or change the display order of checkpoints. For example, when the pointer 40 is moved from the top to the second-stage CP display area 21 and the mouse is right-clicked from the state shown in FIG. 8, the second-stage CP display area 21 from the top is set as an edit candidate. As shown in FIG. 9C, a frame is set in the CP display area 21. In this state, when the selection deletion button 22b of the CP editing area 22 in FIG. 4C is pressed, the second check point is deleted from the display target. In this case, the display order of the third check point, which was the third display order before the deletion, is changed to the second, and the CP display area 21 which is the third level from the top is moved to the second level from the top. . In response to this, the CP arrival time of the third checkpoint whose display order is third before the deletion is updated, and the display of the arrival time display setting unit 21b is changed.

  When it is desired to delete a plurality of consecutive checkpoints, the editor inputs the range of checkpoints to be deleted to the deletion range specifying unit 22c in FIG. 4 and presses the batch deletion button 22d. As a result, the check points in the selected range are deleted. For example, in the state of FIG. 8, when “2 to 3” is input to the deletion range designation unit 22 c and then the collective deletion button 22 d is pressed, the second and third display orders are second and third. The checkpoint is deleted. At this time, the editing screen is in the state shown in FIG.

  The editor can also change the display order of checkpoints. For example, in the state of FIG. 9C, after selecting the third CP display area in the display order, when the movement tab 22e in FIG. 4C is selected, the up / down key is displayed in the CP editing area 22. The The editor can change the display order of the third checkpoint by moving the displayed up / down key with the mouse. Accordingly, the CP display area 21 in the third row from the top is moved up and down, and the CP arrival time displayed in the arrival time display setting part 21b of the CP display area 21 is displayed in the display order. It changes with change.

  FIG. 10 is a diagram illustrating a configuration of a display setting table that controls display of an edited cell image. The display setting table is updated according to the checkpoint setting / change.

  As shown, the display setting table includes a display order “i”, positions “Xi”, “Yi”, distance “Li”, travel time “Ti”, travel speed “Si”, and display time “ Di "and arrival time" Ai "are held in association with each checkpoint. Here, a state in which N checkpoints are set by the editor is shown.

The display order i indicates the display order of checkpoints. The contents of the display order i are displayed on the order display part 21e in FIG. Positions Xi and Yi indicate checkpoint positions on the entire specimen region 31a of the virtual slide shown in FIG. The positions Xi and Yi are defined as coordinate points in the XY coordinate system with the upper left corner of the entire specimen region 31a as the origin.

  The distance Li indicates the distance between the positions Xi-1, Yi-1 and the positions Xi, Yi. The editing computer 4 appropriately calculates the distances between the positions Xi−1, Yi−1 and the positions Xi, Yi when setting / changing the checkpoint, and writes the calculation result in Li.

  The movement time Ti is a time required for the cell image to be scrolled from the (i−1) -th check point to the i-th check point in the display order. The movement time Ti is obtained by dividing the distance Li by the movement speed Si. The moving speed Si is a speed at which the cell image is scrolled from the (i−1) -th check point to the i-th check point in the display order. When the check point is set, a default value is set for the moving speed Si.

  The display time Di is a time for displaying the cell image at the i-th check point in the display order as a still image. The content of the display time Di is displayed as the CP waiting time in the waiting time display setting unit 21c (see FIG. 4B) of the CP display area 21 corresponding to the i-th check point in the display order. When the check point is set, a default value “0” is set for the display time Di.

  The arrival time Ai is the time required from the display of the cell image at the first checkpoint in the display order to the display of the cell image at the i-th checkpoint in the display order. The arrival time Ai is obtained by adding the display time Di-1 and the movement time Ti to the arrival time Ai-1. The content of the arrival time Ai is displayed as the CP arrival time in the arrival time display setting unit 21b (see FIG. 4B) of the CP display area 21 corresponding to the i-th check point in the display order.

  Note that the movement time Ti of the check point when the movement / switch button 21a is set to “switch” is set to “0”, and the movement speed Si is set to “NULL”.

  When the content of the arrival time display setting unit 21b is rewritten by the editor and the arrival time Ai of the i-th checkpoint is changed, the movement time Ti and the movement speed Si of the checkpoint are rewritten. That is, when arrival time Ai is reduced by time Δt, movement time Ti is reduced by Δt to become Ti−Δt. Then, the moving speed Si is obtained by Si = Li / (Ti−Δt) from the distance Li and Ti−Δt, and is rewritten. At the same time, the arrival times Ai + 1 to An of the check points whose display order is i + 1 and after are changed according to the change of the arrival time Ai.

  Further, when the content of the waiting time display setting unit 21c is rewritten by the editor and the display time Di of the i-th checkpoint is changed, the arrival time Ai + 1 of the next checkpoint is rewritten. That is, when the display time Di is increased by time Δt to become Di + Δt, the arrival time Ai + 1 is obtained by Ai + 1 = Ai + (Ti + 1) + (Di + Δt) and rewritten. At the same time, the arrival times Ai + 1 to An of the check points whose display order is i + 2 and later are changed according to the change of the arrival time Ai + 1.

  FIG. 11 is a processing flowchart at the time of checkpoint registration.

When the editing process is started, as shown in FIG. 5, an editing screen including a cell image is displayed on the display unit 409 of the editing computer 4 (S101), and 1 is set to the variable i (S102). ). Thereafter, when an arrow key on the keyboard is operated to input an instruction to move the cell screen (S103), the cell image displayed in the image display area 10 of FIG. 5 is scrolled accordingly (S104). Thereafter, when the pointer 40 is moved to a desired position of the editor on the cell image and the mouse is right-clicked (S105: YES), the position pointed to by the pointer 40 is set as a check point, and the coordinates of that position are set. Values Xi and Yi are acquired. Then, the obtained coordinate values Xi, Yi are display order of coordinate setting table shown in FIG. 10 is registered in the column of i - th (S106).

  Thus, when the i-th (here, i = 1) checkpoint is set, default values are registered for the moving speed Si and the display time Di in the display setting table of FIG. If the variable i is 1 (S108: NO) and the current checkpoint is set for the first time, “0” is registered in the distance Li, the travel time Ti, and the arrival time Ai.

In this manner, the first round of checkpoints, the registration to the display setting table is completed, to i-th (here, i = 1) registered in the display setting table display time Di and the arrival time Ai of These are displayed in the CP display area 21 whose display order is i-th (here, i = 1). Further, a partial image obtained by cutting out the vicinity area of the coordinate values Xi and Yi is displayed together with the CP display area 21 whose display order is i-th.

  Thereafter, if an instruction to confirm the editing process is not input (S115: NO), 1 is added to the variable i (S116), and the process returns to S103 to wait for the next checkpoint setting process. Thereafter, for example, when the editor sets a checkpoint on the editing screen of FIG. 7 (S105: YES), the positions Xi and Yi related to the current checkpoint are registered in the display setting table in S106 and S107 as described above. Then, default values are registered in the moving speed Si and the display time Di in the display setting table.

  Thereafter, it is determined whether the variable i exceeds 1 (S108). Since the setting of the check point this time is the second time, the process proceeds to S110 here. In S110, as described above, the distances between the positions Xi-1, Yi-1 and the positions Xi, Yi are obtained, and the obtained values are registered in the distance Li of the display setting table. Further, Li / Si is calculated based on the distance Li and the moving speed Si, and the calculation result is registered in the moving time Ti of the display setting table. Further, the calculation of (Ai-1) + Ti + Di-1 is performed based on the arrival time Ai-1 and display time Di-1 of the previous check point in the display order and the check point movement time Ti set this time. And the calculation result is registered in the arrival time Ai of the display setting table.

In this way, the second round of checkpoints, the registration to the display setting table is completed, the i-th (here, i = 2) was registered in the display setting table display time Di and the arrival time Ai is , Respectively, in the CP display area 21 whose display order is i-th (here, i = 2). Further, a partial image obtained by cutting out the vicinity area of the coordinate values Xi and Yi is displayed together with the CP display area 21 whose display order is i-th.

  A process similar to the process for the second checkpoint is repeatedly executed every time a checkpoint is set until an instruction to confirm the editing process is input. In this way, various types of data are registered in the display setting table by the number of set check points.

  Next, with reference to FIG. 12 and FIG. 13, a process for correcting the set checkpoint will be described. Note that the processes in FIGS. 12 and 13 are performed in parallel with the process in FIG.

  FIG. 12A is a diagram illustrating processing when the CP arrival time displayed in the arrival time display setting unit 21b (see FIG. 4B) is changed by the editor.

  When the CP arrival time of the kth check point in the display order is changed by the editor and the change of the arrival time Ak is accepted (S201: YES), the arrival time Ak of the display setting table is rewritten in accordance with this change. The changed arrival time Ak is displayed on the arrival time display setting unit 21c (S202). Then, the moving time Tk is changed based on the changed arrival time Ak (S203), and the moving speed Sk is changed based on the changed moving time Tk (S204). For example, when the arrival time Ak is reduced by the time Δt by an operation by the editor, the movement time Tk is reduced by Δt to become Tk−Δt. Then, the moving speed Sk is obtained from the distance Lk and Tk−Δt by Sk = Lk / (Tk−Δt) and rewritten.

  Furthermore, according to the change of the arrival time Ak, the arrival times Ak + 1 to An of the check points from the (k + 1) th to the last (nth) display order are changed (S205). Thereafter, the display of the CP arrival times corresponding to the changed arrival times Ak + 1 to An is changed in the corresponding CP display area 21 (S206).

  FIG. 12B is a diagram showing processing when the CP waiting time displayed in the waiting time display setting unit 21c (see FIG. 4B) is changed by the editor.

  When the CP waiting time of the kth check point in the display order is changed by the editor and the change of the display time Dk is accepted (S211: YES), the display time Dk of the display setting table is rewritten according to this change. The changed display time Dk is displayed on the waiting time display setting unit 21c (S212). Then, the arrival time Ak + 1 is changed based on the changed display time Dk (S213). For example, when the display time Dk is increased by the time Δt to Dk + Δt by the operation by the editor, the arrival time Ak + 1 is obtained by Ak + 1 = Ak + (Tk + 1) + (Dk + Δt) and rewritten.

  Further, according to the change of the arrival time Ak + 1, the arrival times Ak + 2 to An of the last (nth) check point in the display order are changed (S214). Thereafter, the display of the CP arrival times corresponding to the changed arrival times Ak + 1 to An is changed in the corresponding CP display area 21 (S215).

  FIG. 13A is a diagram showing processing when a checkpoint is deleted or the display order of checkpoints is changed by an operation on the CP editing area 22 (see FIG. 4C).

  When the deletion of the checkpoint is accepted by the operation of the editor (S221: YES) or the change of the display order of the checkpoints is accepted (S222: YES), each check in the display setting table is accordingly performed. The order of points is adjusted (S223).

  That is, when the k-th checkpoint in the display order is deleted, the data associated with the (k + 1) -th to n-th checkpoints in the display order is advanced one by one in the direction in which the display order is earlier. At this time, at the same time, the value of the variable i in the processing flow of FIG. 11 is reduced by one. Further, when the kth to k + 2nd checkpoints in the display order are collectively deleted, three pieces of data corresponding to the k + 3rd to nth checkpoints are displayed in the display setting table. The order is moved forward. At this time, at the same time, the value of the variable i in the processing flow of FIG. 11 is reduced by three.

  Also, when the editor performs an operation to advance the display order of the k-th checkpoint by the display order, only one piece of data is associated with the k-th checkpoint in the display setting table. The display order is moved up in the early direction, and only one piece of data associated with the (k−1) th check point is moved down in the display order. In addition, when the editor performs an operation to delay the display order of the kth checkpoint whose display order is one, only one piece of data is associated with the kth checkpoint in the display setting table. The display order is advanced in the slow direction, and only one piece of data in which the display order is associated with the (k + 1) th check point is advanced in the early display order.

  After the display setting table is adjusted in this way, the distance Lk, travel time Tk, and arrival time Ak are updated for all check points held in the adjusted display setting table (S224). The updated arrival time Ak is displayed on the corresponding arrival time display setting unit 21b (see FIG. 4B) (S225), and further displayed on the partial image display unit 21d of each CP display area 21. The partial image is updated (S226).

  FIG. 13B is a diagram showing processing when the move / switch button 21a (see FIG. 4B) is changed from “move” to “switch”.

  When the move / switch button 21a is changed from “Move” to “Switch” for the k-th check point in the display order by an operation from the editor (S231: YES), in the display setting table accordingly. The movement time Tk is changed to “0”, and the movement speed Sk is changed to “NULL” (S232). Then, the arrival time Ak on the movement setting table is rewritten based on the change of the movement time Tk to “0” (S232).

  Furthermore, according to the change of the arrival time Ak, the arrival times Ak + 1 to An of the last (nth) checkpoint in the display order are changed (S234). Thereafter, the display of the CP arrival times corresponding to the changed arrival times Ak to An is changed in the corresponding CP display area 21 (S235).

  FIG. 13C is a diagram showing processing when the move / switch button 21a (see FIG. 4B) is changed from “switch” to “move”.

  When the movement / switch button 21a is changed from “switch” to “move” for the k-th check point in the display order by the operation from the editor (S241: YES), in the display setting table accordingly. A default value is set for the moving speed Sk (242). Further, based on the set moving speed Sk and distance Ti, the moving time Tk is obtained by calculating Tk = Ti / Si, and the obtained moving time Tk is registered in the movement setting table (S243). Then, the arrival time Ak on the movement setting table is rewritten based on the change of the movement time Tk (S244).

Further, according to the change of the arrival time Ak, the arrival times Ak + 1 to An of the last (nth) check point in the display order are changed (S245). Thereafter, the display of the CP arrival time corresponding to the changed arrival times Ak to An is changed in the corresponding CP display area 21 (S24 6 ).

  As described above, by setting / deleting / changing the checkpoint and correcting the CP arrival time at each checkpoint, the editor can set the total display time of the cell image within the desired time. Cell images can be edited. Here, the total display time of the cell image can be known by viewing the time (CP arrival time) displayed on the arrival time display setting unit 21b in the CP display area 21 in the last display order of the image editing area 20. it can. For example, in the case of FIG. 9C, the total display time of the image cells is “0 minute 14 seconds” displayed in the arrival time display setting unit 21b of the CP display area 21 in the lowermost stage.

  In addition, the editor displays the time (CP arrival time) displayed in the arrival time display setting unit 21b in the corresponding CP display area 21 as the time required from the start of display until the cell image of each checkpoint is displayed. You can know by looking. Further, the travel time between checkpoints can be easily known by subtracting the time (CP arrival time) displayed in the arrival time display setting unit 21b in the corresponding two CP display areas 21. When the editor wants to change the time until reaching the display of a predetermined checkpoint, the time displayed on the arrival time display setting unit 21b in the CP display area 21 corresponding to the checkpoint is appropriately set. You can fix it. By this correction, the editor can keep the total display time of the cell image within a desired time.

  In addition, when the CP arrival time is corrected for a predetermined check point in this way, the scroll time of the cell image between the check point and the check point that is earlier in display order is set according to the corrected time. Can be changed. Therefore, the editor may adjust the CP arrival time of the corresponding check point according to whether the cell image transition between check points is to be shown slowly or quickly.

  When there is no need to show the transition of cell images between checkpoints, the move / switch button 21a may be set to “switch”, and when a cell image at a certain checkpoint is to be shown as a still image for a long time. The desired time may be input to the waiting time display setting unit 21c for the corresponding checkpoint.

  Thus, according to the present embodiment, cell images can be edited smoothly with a simple operation. After confirming the editing of the cell image, the editor can reproduce the cell image currently being edited on the screen by inputting a predetermined instruction. In this case, the editing computer 2 executes a display program according to the processing flow shown in FIG. 16 (details will be described later). Thereby, the editor can confirm the quality of the edited cell image before the confirmation process.

  After the cell image is edited as described above, when the confirmation process is performed, the virtual slide data, the movement setting table used for the editing, and the edited cell image are displayed as the virtual slide data and the movement setting table. A cell image file including a display program for display based on the above is created, and the created cell image file is stored in the hard disk 404 of the editing computer 2.

  Thus, the editor creates a plurality of cell image files based on the same or different virtual slide data, and accumulates the created cell image files in the hard disk of the editing computer 2 as needed.

  Thereafter, the editor creates a presentation file for one test by appropriately combining the accumulated cell image files. FIG. 14 is a diagram illustrating a screen for creating a test presentation file.

  In the figure, reference numeral 51 denotes a file setting area. The editor can set a desired file in the file setting area 51 by operating the reference button 52. Note that the file setting area 51 can include a still image file for displaying the start of a test, a question sentence, and the like, in addition to the cell image file created by the editing operation. The files set in the file setting area 51 are sequentially played back and displayed from the file set at the top in the presentation at the time of presentation.

  When a still image file is set in the file setting area 51, the display time of the file can be set by the display time setting unit 53. When the set file is a cell image file, the display time setting unit 53 is masked. When the display time is set in the display time setting unit 53, the time from the start of display until the display of the corresponding file is ended is displayed on the scheduled end time display unit 54.

  When the set file is a still image file, the scheduled end time display unit 54 displays a time obtained by accumulating the time set in the display time setting unit 53. When the set file is the above-described cell image file, the scheduled end time display unit 54 displays a time obtained by adding the total display time of the cell image file to the scheduled end time just before that. Here, the total display time of the cell image file is a time obtained by adding the CP waiting time at the check point to the CP arrival time at the last check point in the display order.

  In the figure, only five file setting areas 51 are shown, but six or more files can be set. That is, when the fifth file is set, the display of the four file setting areas 51 from the second to the fifth line scrolls up one by one, and the blank file setting area 51 is at the bottom. appear. At the same time, the corresponding display time and scheduled end time are scrolled up step by step. Similarly, when the sixth and subsequent files are set, the file setting area 51 scrolls up and a blank file setting area 51 appears. When five or more files are set, the scroll bar 55 can be used to scroll the file, display time, and scheduled end time up and down.

  Each set file can be displayed by double-clicking the corresponding file setting area 51. Thereby, the editor can confirm what kind of file is set.

  Thus, when the setting of the file to be incorporated into the test presentation file is completed, the editor sets the recordable DVD in the disk drive device 405 of the editing computer 2 and then operates the start button 57. As a result, the file set in the file setting area 51 is written to the DVD.

  FIG. 15 is a conceptual diagram showing writing of a presentation file on the DVD 5. As shown in the figure, the cell image file includes virtual slide data, a display setting table, and a display program. Each file is managed by a management file, and is reproduced and displayed sequentially from file 1 to file n at the time of presentation.

  When the DVD 5 shown in FIG. 15 is loaded on the test presentation client computer, the presentation file (test presentation software) shown in FIG. 15 is installed on the hard disk of the client computer. The client computer is a personal computer having the same configuration as in FIG.

  When the test presentation software installed in this way is activated by the client computer, a predetermined initial screen is displayed on the display unit of the client computer. The test provider can execute a presentation using a presentation file by inputting a reproduction instruction on the initial screen. At this time, for example, a large screen presentation can be performed by connecting a projector to a client computer. The presentation is performed according to the file setting order described with reference to FIG.

  FIG. 16 is a follow chart showing processing when a cell image file is reproduced. This processing is performed by executing the display program shown in FIG. 15 by the client computer.

  When the reproduction of the cell image file is started, 1 is set to the variable i (S301), and the positions X1 and Y1 of the first checkpoint and the display time D1 are read from the display setting table (S302). And the data of the cell image of the predetermined size centering on the position X1 and Y1 are acquired from virtual slide data, and the display based on the acquired cell image data is performed (S303). The cell image is displayed until the display time D1 elapses (S304).

  Thereafter, it is determined whether the variable i is n which is the last display order of the display setting table (S305). If the variable i is not n (S305: NO), 1 is added to the variable i (S306). ) The check point positions X2, Y2 in the next display order, the moving speed S2, and the display time D2 are read from the display setting table (S307). Then, it is determined whether or not the moving speed S2 is “NULL” (S308). If it is NULL (S308: YES), cell image data of a predetermined size centered on the positions X2 and Y2 is acquired, and The display is switched to the display of the cell image at the position (S303). The display of the cell image is performed until the display time D2 elapses (S304).

  On the other hand, if the moving speed S2 is not NULL (S308: NO), virtual slide data for scrolling the cell image from the position X1, Y1 to the position X2, Y2 is sequentially acquired, and the acquired virtual slide data is converted into the acquired virtual slide data. Based on this, display is performed in which the cell image is scrolled at the moving speed S2 toward the positions X1 and X2 (S309).

  Thus, when the scrolling of the cell image is completed, the cell images at the positions X2 and Y2, which are the next check points, are displayed (S303). The display of the cell image is performed until the display time D2 elapses (S304).

  As described above, when the cell image is displayed for the second checkpoint, it is determined whether the variable i is n which is the last display order of the display setting table (S305). If the variable i is not n (S305: NO), 1 is added to the variable i (S306), and the display of the cell image relating to the third display order checkpoint is the second display order checkpoint. Done in the same way.

  The display of the cell image is performed until the variable i is determined as i = n in S305, that is, the display of the cell image for the last check point set in the display setting table is completed. Then, when the display of the cell image for the last check point is finished (S305: YES), the display process of the cell image file is finished.

  FIG. 17 is a diagram showing a display example when the cell image file is reproduced. This display example corresponds to the display when editing is confirmed in the editing state of FIG. FIG. 17 shows check points CP1 to CP3 and arrows indicating the moving direction of the cell image for convenience, but these are not displayed on the actual screen.

  When the cell image file is reproduced, first, a cell image centered on the first check point CP1 is displayed as shown in FIG. Here, since the display time D1 (CP waiting time) is 0 second, this cell image is immediately scrolled toward the second check point CP2, as shown in FIG. Then, after scrolling for 4 seconds, a cell image centered on the second check point is displayed as shown in FIG. Again, since the display time D2 (CP waiting time) is 0 second, this cell image is immediately scrolled toward the third checkpoint CP3 as shown in FIG. Then, after scrolling for 10 seconds, a cell image centered on the third check point is displayed as shown in FIG. Again, since the display time D3 (CP waiting time) is 0 second, when this cell image is displayed, the display of the cell image file is immediately terminated.

  As described above, according to the present embodiment, by setting a check point on the cell image displayed in the image display area 10, it is possible to set a branch point when transitioning the cell image. At this time, since the time required for the display to reach the last checkpoint is displayed, the editor can easily determine whether the total display time of the cell image is within the requested time during editing. Can be confirmed.

  Further, according to the present embodiment, by operating the CP editing area 22, it is possible to delete the set checkpoints or change the display order, so that a branch point when transitioning the cell image can be easily performed. Can be adjusted.

  Further, according to the present embodiment, by operating the move / switch button 21a, it is possible to set whether the cell image is scrolled between checkpoints or immediately switched without scrolling the cell image. Editing can be performed so as to display a more effective cell image by a simple operation.

  Further, according to the present embodiment, in addition to the time required for the display to reach the last check point, the time required for the display to reach each check point is displayed. The person can proceed with the editing work smoothly.

  Further, according to the present embodiment, the partial image obtained by cutting out the vicinity of each check point is displayed on the partial image display unit 21d in association with each check point. It is possible to easily grasp which cell images have been set and in which order to display which cell image, and the editing operation can be performed efficiently.

  In addition, according to the present embodiment, the time required for the display to reach each check point can be changed by operating the arrival time display setting unit 21b. Thus, the total display time of the cell image can be easily accommodated, and the editing operation can be simplified.

  In addition, according to the present embodiment, by operating the waiting time display setting unit 21c, the rest time of the cell image at each check point can be set, so that the editor can display the cell image desired to be displayed for a desired time only. It is possible to perform the editing that can be displayed in a stationary state and can display a more effective cell image.

  In addition, according to the present embodiment, at the time of playback display, since the cell image can be displayed as a moving image by automatically scrolling the cell image with each check point as a branch point, the peripheral cells of the cell image at the check point can be displayed. Can also be displayed.

  Further, according to the present embodiment, at the time of reproduction display, the cell image scrolling speed can be changed between check points by the moving speed Si. Thus, the cell image can be effectively displayed by reducing the scrolling speed around the cell image that the examinee wants to observe in detail.

  Further, according to the present embodiment, the cell image at the checkpoint can be displayed as a still image for a predetermined time at the display speed Di at the time of playback display. The image can be displayed for a long time.

  As described above, according to the present embodiment, it is possible to smoothly edit a cell image with a simple operation, and to effectively display the edited cell image.

  Although the embodiment of the present invention has been described above, the present invention is not limited to the above embodiment. Further, the embodiment of the present invention can be variously modified in addition to the above.

  For example, in the above embodiment, the time required for the display to reach the checkpoints (CP arrival time) is displayed in the CP display area 21. For example, as shown in FIG. A travel time display setting unit 21g is arranged instead of the time display setting unit 21b, and the time required for the display to reach the check point from the previous check point is displayed on the travel time display setting unit 21g. You may do it. In this case, for example, a required time display setting unit 23 may be arranged below the CP editing area 22 and the time required for the display to reach the last check point may be displayed here. The flowchart shown in FIG. 11 is modified as shown in FIG. That is, step S113 in FIG. 11 is replaced with S120, and the movement time Ti in the display setting table shown in FIG. 10 is displayed on the movement time display setting unit 21g. In addition, the arrival time Ai of the last checkpoint is updated and displayed on the required time display setting unit 23 every time a checkpoint is set.

  Also in this case, as described above, the editor can correct the time displayed on the travel time display setting unit 21g and the time displayed on the required time display setting unit 23, and the display setting table is rewritten according to this correction. It is done. That is, when the moving time Ti in the display setting table is corrected by the editor's operation, the moving speed Si is corrected by Si = Li / Ti. Further, the arrival time Ai is corrected in accordance with the correction of the movement time Ti, and accordingly, the arrival time An of the last check point is corrected. When the arrival time An is thus corrected, the display of the required time display setting unit 23 is corrected. Further, when the arrival time An of the last check point is corrected by the editor's operation, the moving time Ti is corrected accordingly, and the display of the moving time display setting unit 21g is corrected. At this time, the moving speed Si is corrected by Si = Li / Ti.

  According to this configuration, the editor can know not only the time required for the display to reach the last checkpoint, but also the time required for the cell image to scroll between checkpoints. You can proceed with editing.

  Further, in this embodiment, when the arrival time Ak in the display table shown in FIG. 10 is changed according to the operation of the editor, only the movement time Tk and the movement speed Sk are corrected and rewritten. The times T2 to Tk and the moving speeds S2 to Sk may be corrected uniformly according to the correction of the arrival time Ak or by another correction method. In addition, the partial image may be displayed in association with each check point on another screen without being displayed in the editing area 20.

  In the above embodiment, the file edited by the editing computer is displayed on the client computer. However, both editing and display may be performed on the client computer. In this case, the editing program is installed on the client computer. The virtual slide data is acquired from the server to the client computer via a network, for example.

  Furthermore, in the above embodiment, the description has been made assuming a test such as a certified blood test technician test, but the editing method and the display method according to the present invention display cell images in scenes other than these tests. In some cases, it can be used as appropriate. It can also be used appropriately when displaying cell images other than blood.

  In addition, the embodiment of the present invention can be variously modified as appropriate within the scope of the technical idea shown in the claims.

4 ... Editing computer 401 ... CPU
405: Disc drive device 408: Input unit 409 ... Display unit 10 ... Image display region 20 ... Editing region 21 ... CP display region 21a ... Move / switch button 21b ... Arrival time display setting unit 21c ... Wait time display setting unit 21d ... part Image display part 21e ... Order display part 22 ... CP edit area 22a ... Delete tab 22b ... Selection delete button 22c ... Delete range designation part 22d ... Batch delete button

Claims (10)

A display unit;
Cell image display means for displaying a cell image on the display unit and scrolling the cell image according to an operation input;
Designated position accepting means for accepting setting of a designated position on the cell image displayed on the display unit;
Designated position holding means for holding the designated positions received by the designated position receiving means in association with each other in the order of transition;
When the cell image is sequentially shifted from the designated position in the first transition order held by the designated position holding means to the designated position in the last transition order, until the transition to the designated position in the last transition order Transition time calculating means for calculating the total transition time required for
Transition time display means for displaying the total transition time calculated by the transition time calculation means;
A cell image display device comprising: A designated position change accepting means for accepting deletion of the designated position held in the designated position holding means and a change in transition order;
The cell image display device according to claim 1. A switching acceptance means for accepting a setting for switching the cell image between the two designated positions without causing the cell image to transition at the predetermined speed between the two designated positions adjacent in the transition order;
The cell image display device according to claim 1 or 2. The transition time calculation means further includes a designated position transition time required to cause the cell image to transition from the designated position in the first transition order held by the designated position holding means to the designated position in each transition order. Calculate
The transition time display means displays the total transition time and the designated position transition time in association with the corresponding designated position, respectively.
The cell image display apparatus as described in any one of Claims 1-3. A partial image display means for displaying a partial image around the designated position in association with the corresponding designated position;
The cell image display device according to claim 4. The partial image and the total transition time or the designated position transition time are simultaneously displayed in association with the corresponding designated position.
The cell image display device according to claim 5. Transition time changing means for accepting correction of the total transition time and the designated position transition time;
A moving speed changing means for changing the moving speed of the cell image between the designated positions in accordance with the corrected total transition time or the designated position transition time;
The cell image display device according to any one of claims 4 to 6. The moving speed changing means moves between the specified position corresponding to the total transition time or the specified position transition time for which the correction has been accepted, and the specified position whose transition order is one previous from the specified position. Changing the speed according to the corrected total transition time or the specified position transition time;
The cell image display device according to claim 7. Still further comprising a stationary time receiving means for receiving a setting of a stationary time of the cell image at the designated position.
The cell image display device according to any one of claims 1 to 8. The transition time calculation means calculates the movement time of the cell image between two specified positions adjacent in the transition order among the specified positions held by the specified position holding means,
The transition time display means displays the travel time in association with the corresponding designated position, respectively.
The cell image display apparatus as described in any one of Claims 1-3.

Images