JP2015104440A - Ophthalmologic apparatus operation simulation execution program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ophthalmologic apparatus operation simulation execution program capable of making a user understand the operation of an ophthalmologic apparatus more easily and more completely.SOLUTION: A terminal can accept a direction of operation made by a user and display on a display unit an image on the basis of the image data. When the processor of the terminal executes the ophthalmologic apparatus simulation operation execution program, the terminal executes an operation image display step and a motion image display step. The operation image display step displays operation images containing one or more operation units provided on an ophthalmologic apparatus (S5). The motion image display step, when at least one of the operation units contained in an operation image is specified, displays images of motions executed by the ophthalmologic apparatus using as a trigger the actual operation of the specified operation part in the ophthalmologic apparatus.

Description

  The present invention relates to an ophthalmologic apparatus operation reproduction program that causes a terminal to execute a simulation operation of an ophthalmologic apparatus that performs at least one of eye diagnosis and surgery.

  A technique for allowing a user to easily understand the operation (for example, behavior, operation method, ease of use, usefulness, etc.) of an ophthalmic apparatus is desired. For example, the ophthalmologic apparatus disclosed in Patent Document 1 can display a description of the function of the operation switch provided around the monitor on the monitor. In this case, the user understands the explanation of the function of the operation switch displayed on the monitor and understands the behavior of the ophthalmologic apparatus, the operation method, and the like by actually operating the operation switch.

JP 2007-105130 A

  In order for users who are considering the purchase of ophthalmic devices to understand the operation of ophthalmic devices more fully, manufacturers can bring ophthalmic device bodies to exhibitions and lend ophthalmic apparatus bodies to users ( So-called “demo”). However, when carrying in or lending the ophthalmic apparatus main body, the burden of the manufacturer (for example, movement of the ophthalmic apparatus main body, ensuring the operating environment of the ophthalmic apparatus main body, securing the installation space, maintaining the ophthalmic apparatus for lending, etc.) Easy to increase. When the ophthalmic apparatus main body is not brought in or rented out, the manufacturer has to let the user understand the operation of the ophthalmic apparatus using a pamphlet or the like. The same applies when a user who understands the operation of the ophthalmologic apparatus (for example, a doctor, a visual function trainer, etc.) explains the ophthalmologic apparatus to a user who does not understand the operation.

  It is a typical object of the present invention to provide an ophthalmic apparatus simulation operation execution program that allows a user to more easily and sufficiently understand the operation of an ophthalmic apparatus.

  An ophthalmic apparatus simulation operation execution program provided by a typical embodiment is a terminal that receives an operation instruction from a user, acquires image data from an image storage unit, and displays an image on a display unit based on the acquired image data. An ophthalmologic apparatus simulation operation execution program to be executed, wherein the operation image display step causes the display means to display an operation image including one or more operation units included in the ophthalmologic apparatus when executed by the processor of the terminal. When at least one of the operation units included in the operation image is specified by the operation instruction, the specified operation unit is actually operated in the ophthalmologic apparatus. An operation image display step of causing the display means to display an operation image that is an image of an operation executed by Characterized in that to execute at the end.

  According to the ophthalmic apparatus simulation operation execution program shown by the present disclosure, it is possible to make the user understand the operation of the ophthalmic apparatus more easily and sufficiently.

2 is a block diagram showing an electrical configuration of a terminal 1. FIG. It is a flowchart of the main process which the terminal 1 performs. 4 is a diagram illustrating an example of a main menu displayed on a display 31. FIG. 6 is a diagram showing an example of a patient selection operation image displayed on a display 31. FIG. It is a flowchart of the macular combo imaging | photography operation | movement process performed by the main process. It is a figure which shows an example of the macular disease patient image displayed on the display. FIG. 10 is a diagram illustrating an example of a pre-optimize image displayed on the display 31. 6 is a diagram illustrating an example of a confirmation operation image displayed on a display 31. FIG. It is a flowchart of the analysis operation process performed in the main process. 6 is a diagram illustrating an example of a comprehensive analysis image displayed on a display 31. FIG. 4 is a diagram illustrating an example of an image of 3D analysis displayed on a display 31. FIG. It is a figure which shows an example of the macular multi analysis image displayed on the display. It is a figure which shows an example of the report operation | movement image displayed on the display. 6 is a diagram illustrating an example of a printing operation image displayed on a display 31. FIG. 6 is a diagram illustrating an example of a print preview image displayed on a display 31. FIG.

  Hereinafter, one exemplary embodiment of the present invention will be described with reference to the drawings. First, an example of a terminal 1 that operates according to an ophthalmologic apparatus simulation operation execution program will be described with reference to FIG. The terminal 1 of the present embodiment is a small terminal that can be carried by a user, and includes an image display function, an audio output function, an operation input function, a communication function, a charging function, and the like.

  The terminal 1 includes a CPU (processor) 10 that controls the terminal 1. The CPU 10 includes a ROM 11, a RAM 12, a nonvolatile memory 13, a display controller 21, a touch panel interface (I / F) 22, an operation switch I / F 23, a power controller 24, an auxiliary storage device I / F 26, and a communication I / F 27. Connected via bus. Further, the terminal 1 includes a display 31, a touch panel 32, an operation switch 33, a power supply terminal 34, and a battery 35.

  The ROM 11 stores various programs and initial values. The RAM 12 temporarily stores various information. The nonvolatile memory 13 is a non-transitory storage medium (for example, a flash ROM or the like) that can retain stored contents even when power supply is interrupted. In the present embodiment, the ophthalmologic apparatus simulation operation execution program is stored in the nonvolatile memory 13. The terminal 1 can acquire the ophthalmologic apparatus simulation operation execution program via the auxiliary storage device 36 or the network 37 (described later) and store it in the nonvolatile memory 13. The terminal 1 can also update the ophthalmologic apparatus simulation operation execution program. Note that the nonvolatile memory 13 also stores data of images (still images and moving images) displayed on the display 31 during execution of the simulated operation of the ophthalmologic apparatus. Specifically, the nonvolatile memory 13 stores a plurality of motion images in which at least one of analysis methods of cases, diagnosis methods (imaging methods in the present embodiment), and diagnosis data (imaging data in the present embodiment) is different. Has been. An operation image is an image of an operation performed by the ophthalmologic apparatus when the operation unit of the ophthalmologic apparatus is operated.

  The display controller 21 controls display of images (still images and moving images) on the display 31. As the display 31, various display devices such as a liquid crystal display device can be adopted. The touch panel I / F 22 receives an operation input from the user for the touch panel 32. The touch panel 32 is provided on the surface of the display 31. The operation switch I / F 23 receives an operation input from the user for the operation switch 33. The power supply controller 24 controls the charging of the power supplied from the power supply terminal 34 to the battery 35, and switches the power supply source used by the terminal 1 between the power supply terminal 34 and the battery 35. The power terminal 34 connects the terminal 1 to an external power source. An auxiliary storage device 36 (for example, a USB memory) is detachably attached to the auxiliary storage device I / F 26. The communication I / F 27 connects the terminal 1 to an external device (for example, a server or another terminal) via the network 37. The terminal 1 can perform wired communication or wireless communication by the communication I / F 27.

  The configuration of the terminal 1 can be changed. For example, the terminal 1 may connect a mouse for moving a pointer displayed on the display 31 instead of the touch panel 32 or together with the touch panel 32. The terminal 1 may be connected or equipped with other operation means (for example, a keyboard). Further, the terminal 1 may not include a part of the above configuration. For example, even when the display 31 is provided outside the terminal 1 and the terminal 1 connected to the display 31 controls display on the display 31, the ophthalmologic apparatus simulation operation execution program exemplified in this embodiment can be employed. The configuration for connecting the auxiliary storage device 36 may be omitted. In addition, the ophthalmic apparatus simulation operation execution program exemplified in the present embodiment may be executed by a notebook PC, a desktop PC, a smartphone, or the like. Even in this case, the manufacturer or the like can make the user understand the operation of the ophthalmologic apparatus more easily and sufficiently as in the case where the terminal 1 is used.

  With reference to FIG. 2 to FIG. 15, main processing executed by the terminal 1 according to the ophthalmologic apparatus simulation operation execution program of the present embodiment will be described. The processing described below is merely exemplary processing. Therefore, it goes without saying that processing may be added, changed, omitted, etc. with respect to the processing described below. For example, in this embodiment, the case where the simulation operation | movement of the ophthalmologic apparatus (what is called a tomographic image imaging apparatus) which can image | photograph the tomographic image of the fundus tissue of a patient's eye is illustrated. However, other ophthalmic devices (for example, an axial length measuring device, an intraocular pressure measuring device, a multi-objective eye refractive power measuring device, a subjective eye refractive power measuring device, a cataract surgical device, a vitreous surgical device, a laser photocoagulator Needless to say, at least a part of the technique exemplified in this embodiment can also be applied to the simulation operation of a laser corneal surgery apparatus or the like.

  As described above, the non-volatile memory 13 of the terminal 1 stores an ophthalmologic apparatus simulation operation execution program. CPU10 will perform the main process shown in FIG. 2 according to an ophthalmologic apparatus simulation operation execution program, if the operation instruction which starts the simulation operation | movement of an ophthalmologic apparatus is received via the touch panel 32 grade | etc.,.

  First, the main menu is displayed on the display 31 (S1). In the main menu of the present embodiment, as shown in FIG. 3, a button (“analysis simulation” button) for receiving a simulation operation start instruction is displayed together with the appearance of the ophthalmologic apparatus to be simulated.

  Next, it is determined whether or not an end instruction from the user has been input (S2). The presence / absence of an end instruction may be determined based on, for example, whether the end button displayed on the display 31 has been operated, or may be determined based on whether the operation switch 33 has been operated. If the end instruction has not been input (S2: NO), it is determined whether or not a simulation operation start instruction has been input (S3). In this embodiment, it is determined whether or not a simulation operation start instruction has been input by determining whether or not the “analysis simulation” button on the main menu (see FIG. 3) has been operated by the touch panel 32. . If no start instruction is input (S3: NO), the process returns to S1, and the determinations of S2 and S3 are repeated.

  When an end instruction is input (S2: YES), a log transmission process is performed (S4), and the main process ends. The log transmission process is a process of transmitting a log including at least information on the display history of the operation image to a management device (for example, a server) that manages the simulated operation by the terminal 1 via the network 37. The terminal 1 of this embodiment is connected to the network 37 at a timing when the ophthalmic apparatus simulation operation execution program is updated. As an example, in the present embodiment, when the terminal 1 is connected to the network 37 for program update, the log stored at that time is transmitted to the management apparatus. Accordingly, since the terminal 1 does not always need to be connected to the network 37 in order to transmit the log, the simulation operation can be executed even offline. However, the log transmission method can be changed as appropriate. For example, the terminal 1 may transmit a log each time various simulation operations of the ophthalmologic apparatus are executed. The terminal 1 may transmit a log every time it is connected to the network 37 without being limited to program update. The process for storing the log will be described later.

  When a simulation operation start instruction is input (S3: YES), the CPU 10 causes the terminal 1 to execute a simulation of the ophthalmologic apparatus. First, based on the image data stored in the nonvolatile memory 13, a patient selection operation image is displayed on the display 31 (S5). As shown in FIG. 4, the patient selection operation image is an image displayed on the display of the ophthalmologic apparatus when the user selects a patient in which past diagnosis data is stored on the ophthalmologic apparatus. The patient selection operation image illustrated in FIG. 4 includes a macular disease combo imaging application patient column 41 and a glaucoma combo imaging application patient column 42 as operation units that can be operated by the user. The macular disease combo imaging application patient column 41 is operated when selecting a patient to be imaged by an imaging method called a macular disease combo. The glaucoma combo imaging application patient column 42 is operated when selecting a patient to be imaged by an imaging method called a glaucoma combo. A user who operates the ophthalmologic apparatus selects one of the two operation units 41 and 42 with a mouse or the like. In response to this, the user who operates the terminal 1 selects one of the two operation units 41 and 42 included in the image using the touch panel 32.

  In the ophthalmologic apparatus simulated in the present embodiment, when performing diagnosis of a new patient in which past diagnosis data (imaging data, analysis data, etc.) is not stored, imaging (diagnosis) is performed after accepting a patient registration operation. ) Process. However, in this embodiment, the simulation of this process is omitted. In this way, simulation of some operations in the ophthalmic apparatus may be omitted. When the ophthalmologic apparatus accepts an instruction to select an element other than a patient (for example, a diagnostic method, a surgical method, etc.), the CPU 10 receives an instruction to select an element other than the patient so as to correspond to the ophthalmologic apparatus. An image including may be displayed.

  Next, it is determined whether or not the macular disease combo imaging application patient column 41 has been selected (S6). If not selected (S6: NO), it is determined whether the glaucoma combo imaging application patient column 42 has been selected (S7). If it is not selected (S7: NO), it is determined whether or not an end instruction is input (S8). When an end instruction is input (S8: YES), the process returns to S1, and the main menu is displayed again. If an end instruction has not been input (S8: NO), the process returns to the determination of S6, and the determinations of S6 to S8 are repeated.

  When the macular disease combo imaging application patient column 41 is selected (S6: YES), macular combo imaging operation processing is executed (S10). The macular combo photographing operation processing is processing for causing the terminal 1 to perform a simulation operation when the ophthalmologic apparatus photographs a patient's eye using a macular combo photographing method. The macular combo in this embodiment is a combination of an imaging method for performing raster scanning in the vicinity of the macula (so-called “macular multi”) and an imaging method for generating a three-dimensional image in the vicinity of the macula (so-called “macular map”). It is a shooting method.

  As shown in FIG. 5, when the macular combo imaging operation process is executed, a log for recording the execution of the simulated operation of macular combo imaging as a history is stored in the nonvolatile memory 13 (S20). . In the present embodiment, information indicating the selected operation content (that is, the display history of the selected operation image), the date and time at that time, and information for specifying the user are recorded as a log. However, it goes without saying that information to be recorded as a log can be selected as appropriate. Also, in the processing described later, a log is recorded every time an operation image is selected, but the description thereof is omitted below. The storage means for storing the log may be the same as or different from the storage means for storing the image data (nonvolatile memory 13 in this embodiment).

  Next, the macular disease patient image is displayed on the display 31 (S21). In the macular disease patient image, a thumbnail image indicating past diagnosis data of the selected macular disease combo imaging application patient is displayed. In addition, an OCT imaging button 43 for starting imaging is displayed at the top of the image.

  Next, it is determined whether or not the OCT imaging button 43 has been operated (S22). If not operated (S22: NO), the determination of S22 is repeated. When the OCT imaging button 43 is operated via the touch panel 32 (S22: YES), the macular multi flag is turned ON to indicate that the operation image of macular multi imaging is displayed (S24). . Next, an alignment operation image is displayed (S25). The alignment operation image is an image that is actually displayed on the display of the ophthalmologic apparatus when the ophthalmologic apparatus is aligned with the patient's eye.

  When the reproduction of the alignment operation image is completed, the pre-Optimize image is displayed on the display 31 (S26). The pre-optimize image is an image that is actually displayed on the display of the ophthalmic apparatus in a state in which the alignment is performed and the ophthalmic apparatus can execute the optimize. Optimize is one of the functions of the ophthalmologic apparatus, and is a function for optimizing the optical path length and focus. As shown in FIG. 7, the pre-optimize image includes an optimize operation unit 44 and a release operation unit 45. In the example illustrated in FIG. 7, “Optimize START” is displayed to indicate that the Optimize simulation is possible, but this display may be omitted.

  Next, it is determined whether or not the Optimize button 44 has been operated (S27). If not operated (S27: NO), the determination of S27 is repeated. When the Optimize button 44 is operated (S27: YES), an Optimize operation image is displayed on the display 31 (S29). The Optimize operation image is an image displayed on the display of the ophthalmic apparatus during the Optimize operation that is executed when the Optimize button 44 is actually operated in the ophthalmic apparatus.

  In S25 to 29, it is included in the operation image while it is displayed on the alignment operation image that the ophthalmologic apparatus is ready to accept the next operation (that is, while the pre-optimize image is displayed). The operation unit to be operated (that is, the Optimize button 44) is designated by the operation instruction. As a result, an image of an operation performed by the ophthalmologic apparatus (in this case, an Optimize operation image) is further displayed on the display 31 when the designated operation unit is actually operated in the ophthalmologic apparatus. In the present embodiment, the same processes as S25 to S29 are performed in other steps.

  When the playback of the Optimize operation image is completed, the pre-release image is displayed on the display 31 (S30). The pre-release image is an image that is displayed on the display of the ophthalmologic apparatus in a state where release (shooting can be started) is possible. In the present embodiment, the pre-release image is substantially the same as the pre-optimize image.

  Next, it is determined whether or not the Release button 45 has been operated (S31). If not operated (S31: NO), the determination of S31 is repeated. When the Release button 45 is operated (S31: YES), an operation image during shooting is displayed on the display 31 (S33). An operation image during photographing is an image displayed on the display of the ophthalmologic apparatus when the ophthalmologic apparatus is photographing a patient's eye. When the macular multi flag is ON, in S33, an operation image during photographing when the ophthalmologic apparatus is photographing macular multi is displayed. On the other hand, when the macular map flag, which will be described later, is ON, in S33, an operation image during photographing when the ophthalmologic apparatus is photographing the macular map is displayed.

  When the reproduction of the operation image during shooting is completed, a confirmation operation image is displayed (S34). As shown in FIG. 8, the confirmation operation image is an image displayed on the display of the ophthalmologic apparatus so that the user can confirm the captured image. The user who actually operates the ophthalmologic apparatus operates “OK” if the confirmed image is good, and operates “NG” or “re-photographing” if the confirmed image is bad. Next, it is determined whether or not “OK” has been operated (S35). If not operated (S35: NO), the determination of S35 is repeated. When “OK” is operated (S35: YES), it is determined whether or not the display of the operation image of the macular map shooting included in the macular combo shooting has already been completed (S36). If not completed (S36: NO), the macular map flag is turned ON (S37) to indicate that the operation image of the macular map is displayed. The process returns to S30, and an operation image during shooting when the macular map is shot is displayed (S33). If the display of the operation image for macular map photography has already been completed (S36: YES), the process returns to the main process. In the macular combo photographing operation process, an image of a photographing operation for one eye may be displayed, or an image of a photographing operation for both eyes may be displayed.

  Returning to the description of FIG. When the glaucoma combo imaging application patient field 42 is selected by the user (S7: YES), glaucoma combo imaging operation processing is performed (S11). The glaucoma combo imaging operation process is a process for causing the terminal 1 to perform a simulation operation when the imaging apparatus captures a patient's eye using the glaucoma combo imaging method. The glaucoma combo in this embodiment includes an imaging method for generating a three-dimensional image near the macula (macular map described above) and an imaging method for generating a three-dimensional image near the optic nerve head (so-called “papillary map”). This is a combination of shooting methods. The general flow of the glaucoma combo imaging operation processing is similar to the flow of the macular combo imaging operation processing described above. Therefore, in order to simplify the description, a detailed description of the glaucoma combo imaging operation process is omitted.

  When the macular combo imaging operation process (S10) or the glaucoma combo imaging operation process (S11) ends, an analysis data selection image is displayed on the display 31 (S13). The analysis data selection image is an image displayed on the display of the ophthalmologic apparatus when the user selects shooting data to be analyzed from one or a plurality of shooting data. For example, when glaucoma combo imaging is performed, an analysis data selection image for selecting either imaging data based on a macular map or imaging data based on a nipple map is displayed. When any shooting data is selected via the touch panel 32 (S14: YES), an analysis operation process is performed (S15), and the process returns to S1. In the analysis operation process, the operation when the ophthalmologic apparatus presents the result of the analysis of the captured data to the user is reproduced.

  The analysis operation process will be described with reference to FIG. First, a comprehensive analysis image is displayed on the display 31 (S41). As shown in FIG. 10, the comprehensive analysis image is one of a plurality of analysis images created from photographing data based on a macular map. The ophthalmic apparatus to be simulated in the present embodiment first displays the comprehensive analysis image after performing the analysis.

  The comprehensive analysis image includes an analysis image switching button 51, an analysis object switching button 52, an export button 53, a report button 54, a print button 55, a print preview button 56, and an end button 57. The analysis image switching button 51 is operated to switch an analysis image to be displayed on the display among a plurality of analysis images created from shooting data obtained by the same shooting method. The analysis target switching button 52 is operated to switch analysis target imaging data (for example, macular multi and macular map). The export button 53 is operated by the user in order to output the analysis result from the ophthalmologic apparatus to another device (for example, a PC connected to the ophthalmologic apparatus). The report button 54 is operated to cause the ophthalmologic apparatus to execute a report format display. The print button 55 is operated to input an analysis result print instruction. The print preview button 56 is operated to display a print preview image. The end button 57 is operated to end the display of the analysis result.

  Next, it is determined whether or not an instruction to switch the analysis image is input via the touch panel 32 (S42). In the present embodiment, whether or not an analysis image switching instruction is input is determined based on whether or not the analysis image switching button 51 or the analysis target switching button 52 is operated. If it has not been input (S42: NO), the process proceeds to the determination of S44 as it is. When an analysis image switching instruction is input (S42: YES), the analysis image displayed on the display 31 is switched to the analysis image specified by the switching instruction (S43), and the process proceeds to the determination of S44. To do. For example, in the state shown in FIG. 10, when the switch button to the 3D analysis image included in the analysis image switching button 51 is operated, as shown in FIG. 11, a 3D analysis image for the macular map shooting data is displayed. Is done. When the analysis object switching button 52 is operated in the state shown in FIG. 10, the analysis image for the macular map shooting data is switched to the analysis image for the macular multi shooting data, as shown in FIG.

  Next, it is determined whether or not the export button 53 has been operated (S44). If it is not operated (S44: NO), the process proceeds to the determination of S46 as it is. When the export button 53 is operated (S44: YES), an export operation image is displayed on the display 31 (S45), and the process proceeds to the determination of S46. In S45 of the present embodiment, an image for allowing the user to select the data format to be output is displayed, and when an instruction to select the data format is input, a message “Export completed successfully” is displayed. The flow of the export operation described above is the same as the flow of operations actually performed in the ophthalmologic apparatus.

  Next, it is determined whether or not the report button 54 has been operated (S46). If it has not been operated (S46: NO), the process proceeds directly to the determination of S48. When the report button 54 is operated (S46: YES), a report operation image is displayed on the display 31 (S47), and the process proceeds to the determination of S48. In S47 of the present embodiment, an image for allowing the user to select a report format is displayed, and when a format selection instruction is input via the touch panel 32, a report image (see FIG. 13) of the selected format is displayed. Is displayed.

  Next, it is determined whether or not the print button 55 has been operated (S48). If it is not operated (S48: NO), the process proceeds to the determination of S50 as it is. When the print button 55 is operated (S48: YES), as shown in FIG. 14, a printing operation image displayed when the ophthalmic apparatus transmits print data to the printing apparatus is displayed on the display 31 ( In step S49, the process proceeds to the determination in step S50.

  Next, it is determined whether or not the print preview button 56 has been operated (S50). If it is not operated (S50: NO), the process proceeds to the determination of S52 as it is. When the print preview button 56 is operated (S50: YES), as shown in FIG. 15, a print preview image that is actually displayed by the ophthalmologic apparatus is displayed on the display 31 (S51), and the process proceeds to the determination of S52. To do.

  Next, it is determined whether or not the end button 57 has been operated (S52). If not operated (S52: NO), the process returns to the determination of S42, and the determinations of S42 to S52 are repeated. When the end button 57 is operated (S52: YES), the process returns to the main process (see FIG. 2).

  As described above, according to the ophthalmologic apparatus simulation operation execution program of the present embodiment, the terminal 1 displays an image of an operation actually executed by the ophthalmic apparatus when the operation unit is designated by an operation instruction from the user. To display. That is, when the user performs the same operation as when actually operating the ophthalmologic apparatus, an image of the operation of the ophthalmologic apparatus that the user wants to reproduce is displayed at the timing that the user wants to reproduce. A manufacturer or the like explaining the operation of the ophthalmic apparatus does not need to bring the ophthalmic apparatus body. Therefore, the terminal 1 can make a user understand operation | movement of an ophthalmologic apparatus more easily and fully.

  In the present embodiment, when the ophthalmologic apparatus is ready to accept the next operation on the motion image, the user can specify an operation unit included in the motion image. When the operation unit is designated, the terminal 1 further displays an image of an operation actually executed by the ophthalmologic apparatus. In other words, in the present embodiment, the terminal 1 does not simply display one motion image, but accepts a plurality of operation instructions from the user in the same manner as an actual ophthalmologic apparatus, and the specified ophthalmic apparatus. Reproduce the behavior. Therefore, the user can more accurately grasp the behavior, operation method, ease of use, usefulness, and the like of the ophthalmologic apparatus.

  In this embodiment, the user designates at least one of a case, a diagnosis method (imaging method in this embodiment), and an analysis method of diagnosis data (imaging data in this embodiment), and performs the operation of the designated ophthalmologic apparatus. It can be reproduced by the terminal 1. Therefore, the user can grasp the operation of the ophthalmologic apparatus more accurately.

  In the present embodiment, the terminal 1 causes the storage unit to store a log including information about the display history of the operation image. Therefore, the manufacturer or the like can accurately grasp the frequency of operation of the ophthalmic apparatus reproduced by the user on the terminal 1 for each operation of the ophthalmic apparatus. In the present embodiment, the terminal 1 transmits a log including information about the display history of the operation image to the management apparatus via the network 37. Therefore, the management apparatus can more easily grasp the frequency of operation of the ophthalmologic apparatus reproduced by one or a plurality of terminals 1.

  The content disclosed in the above embodiment is merely an example. Therefore, it is possible to change the contents disclosed in the above embodiment. First, in the said embodiment, the case where the simulation operation | movement of the tomographic image imaging device which can image | photograph the tomographic image of the fundus tissue of a patient's eye was illustrated. However, at least a part of the technique exemplified in the above embodiment can also be applied when performing a simulation operation of another ophthalmologic apparatus. When the simulation operation of another ophthalmologic apparatus is executed, image data may be prepared in accordance with the mode of the ophthalmologic apparatus to be simulated. For example, when causing the terminal 1 to perform a simulated operation of the ophthalmic surgery apparatus, it is also possible to store a plurality of operation images with different surgical methods in a storage device and display the operation images in response to an operation instruction from the user. It is. In this case, the terminal 1 may display an operation unit for allowing the user to designate a surgical method on the display 31 and receive an instruction from the user.

  In the above embodiment, the operation buttons on the image that the ophthalmologic apparatus displays on the display are also displayed on the display 31 by the terminal 1 as well. However, the terminal 1 may display another operation unit such as a joystick on the display 31. The terminal 1 may display an operation unit that increases or decreases some parameter in the ophthalmic apparatus (for example, an operation unit that increases or decreases the power, the light amount, or the like). In this case, the terminal 1 may display an image of an operation performed by the ophthalmologic apparatus on the display 31 according to the increased / decreased parameter. Moreover, in the said embodiment, the case where the terminal 1 displayed the operation image and action image of an ophthalmologic apparatus according to a user's operation was illustrated. However, the terminal 1 may output sound in conjunction with the display of the operation image or the operation image.

  The operation image in the above embodiment is an image displayed on the display of the ophthalmologic apparatus when the ophthalmologic apparatus executes an operation designated by the user. However, the operation image is not limited to an image displayed on the display of the ophthalmologic apparatus. For example, when a simulation of a laser photocoagulation apparatus is executed, an image in which a laser beam is irradiated on an affected area may be used as an operation image. When the simulation of the cataract surgery device is executed, an image in a state where the lens nucleus is crushed with an ultrasonic chip or the like may be used as an operation image.

1 Terminal 10 CPU
13 Non-volatile memory 31 Display 32 Touch panel 33 Operation switch 37 Network

Claims (5)

An ophthalmic apparatus simulation operation execution program executed on a terminal that accepts an operation instruction by a user, acquires image data from an image storage unit, and displays an image on a display unit based on the acquired image data,
By being executed by the processor of the terminal,
An operation image display step of causing the display means to display an operation image including one or a plurality of operation units included in the ophthalmologic apparatus;
When at least one of the operation units included in the operation image is designated by the operation instruction, the ophthalmic device is triggered by the designated operation unit being actually operated in the ophthalmic device. An operation image display step of causing the display means to display an operation image that is an image of an operation to be executed;
Is executed by the terminal. An ophthalmologic apparatus simulation operation execution program.   In the operation image display step, at least one of the operation units included in the operation image is displayed while the operation image indicates that the ophthalmologic apparatus is ready to accept the next operation. Is displayed by the operation instruction, the operation image of the operation executed by the ophthalmic apparatus is further displayed on the display unit when the specified operation unit is actually operated in the ophthalmic apparatus. The ophthalmic apparatus simulation operation execution program according to claim 1, wherein The storage means stores a plurality of motion images in which at least one of a case, a diagnostic method, a surgical method, and a diagnostic data analysis method is different,
2. The operation unit displayed on the display unit includes an operation unit for designating at least one of the case, the diagnosis method, the operation method, and the analysis method of the diagnosis data. The ophthalmic apparatus simulation operation execution program according to 2.   The ophthalmologic apparatus simulation operation according to any one of claims 1 to 3, further comprising causing the terminal to further execute a log storage step of storing in a log storage unit a log including at least information about a display history of the operation image. Execution program.   5. The ophthalmic apparatus simulation operation execution program according to claim 4, further causing the terminal to execute a log transmission step of transmitting the log stored in the log storage unit to a management apparatus via a network.