TWI653575B - Display data generation program, display data generation method, and information processing device - Google Patents

Abstract

The information processing device generates display data which is expressed by lines in parallel with a plurality of time axes in a processing period of a plurality of programs to be included in the manufacturing program of the product. The information processing apparatus causes the time indicated by the plurality of time axes to be the time after the time indicated by the plurality of time axes plus the accumulated time of the reference processing time of the previous program as the adjustment target. The time indicated by the point on the time axis that intersects the straight line is "10:10" after 10 [minutes] advance from the time "10:00" indicated by the point on the time axis.

Description

Display data generation program, display data generation method, and information processing device

The present invention relates to a display data generation program, a display data generation method, and an information processing device.

Conventionally, there is a technique for visualizing the manufacturing conditions of each product manufactured by performing a plurality of procedures in a predetermined order. Regarding the process of visualizing the manufacturing condition, for example, a technique for displaying a point at which the start or end time of each program is displayed for each product on the time axis at which the start or end time of each product of each program is displayed is displayed. A line segment connecting the points to display the manufacturing condition. Advanced technical literature

Patent Document 1: Japanese Laid-Open Patent Publication No. 2015-108904

Problems to be Solved by the Invention However, when the processing time of each program of a product is visualized by a conventional technique, the readability of the display may be poor. For example, when there is a large difference in standard processing time between programs, the difference in time between products of each program may be difficult to understand. Therefore, for example, there is a problem that it is difficult to find an abnormality in processing time in each program.

In view of the above, it is an object of the present invention to provide a display data generation program, a display data generation method, and an information processing device which can suppress deterioration of the readability of display when the processing time of each program of the product is visualized. Means to solve the problem

According to one aspect of the present invention, there is provided a display data generating program, a display data generating method, and an information processing apparatus which are in parallel with each other during processing for generating a plurality of programs to be included in a manufacturing process of a product. A display data generating program for displaying data of each line between the time axes, so that the time corresponding to the point at which the straight line perpendicular to the plurality of time axes intersects with each time axis is adjusted according to the previous program The accumulated time of the reference processing time becomes late.

Further, according to another aspect of the present invention, there is provided a display data generating program, a display data generating method, and an information processing apparatus which are arranged such that a time allocated on the second time axis is offset with respect to a time allocated on the first time axis. And shifting so that a point on the second time axis passing through a straight line perpendicular to the first time axis parallel to the second time axis of the first time axis is larger than a time on the first time axis The point is later, and display data showing the first time axis and the second time axis are generated, and the first time axis plots the first program among the plurality of programs included in the manufacturing program of the product. At the first time on the start side, the second time axis plots the second time on the end side of the first program. Effect of the invention

According to an aspect of the present invention, it is possible to suppress the deterioration of the readability of the display when the processing time of each program of the article is visualized.

MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of a display material generating program, a display data generating method, and an information processing device according to the present invention will be described in detail with reference to additional drawings.

Fig. 1 is an explanatory view showing a display example caused by a display material generating program related to the present invention. Fig. 1 (1) shows a display example of a manufacturing condition caused by a conventional technique. FIG. 1 (2) shows a display example of the manufacturing situation caused by the information processing apparatus 100. Fig. 1 (1) and Fig. 1 (2) show an example in which the processing period of a plurality of programs included in the manufacturing process of the product is expressed by lines between a plurality of parallel time axes. The article herein is, for example, an article of manufacture.

A plurality of programs are performed in a predetermined order. The examples of Fig. 1 (1) and Fig. 1 (2) are carried out in the order of the program A, the program B, and the program C, thereby manufacturing a product. In addition, in FIG. 1, a plurality of time axes respectively indicate the passage of time from top to bottom.

As shown in Fig. 1 (1), the conventional technique adds a point at which the start or end time of each program is displayed for each product on the time axis indicating the start or end time of each program. Further, in the manufacturing state shown by the chart 101 of the prior art, a line segment in which points correspondingly added are connected is arranged. In Fig. 1 (1), the time added to each program is an example of the processing time required for each program. Incidentally, in the example of Fig. 1 (1), the point at which the display start or end time is added correspondingly to each time axis is not shown.

However, when the processing time of each program of the product is visualized by a conventional technique, the readability of the display may be poor. For example, when there is a large difference in processing time between programs, the difference in processing time between products of each program may be difficult to understand. Therefore, for example, there is a problem that it is difficult to find an abnormality in processing time in each program. In the example of Fig. 1 (1), the processing time of the program B is relatively longer than the processing time of the program A and the program C. Moreover, since the slope of the line segment for indicating the processing time of the program B is steeper than the slope of the line segment for indicating the processing time of the program A and the program C, for example, even if one of the products is the program B Processing time is abnormal and difficult to understand.

Further, for example, when there is a large difference in processing time between programs, the line for indicating the processing time of the program cannot be accommodated in one screen, and it is difficult to understand the processing time of the entire program without scrolling the animation surface. For example, some programs have a processing time of a few minutes, and some programs have a processing time of a few days. If the difference in processing time between programs is so large, the line for indicating the processing time of the program that needs to be processed for several days cannot be accommodated in one screen, and the user has to scroll the screen. Therefore, for example, it is difficult for the user to find an abnormality in the processing time in each program.

As described above, when the processing period of the product is visualized by a conventional technique, the readability of the display may be poor.

Therefore, in the present embodiment, the information processing apparatus 100 adjusts the manufacturing conditions so that each time indicated by the time axis of the start or end time of each product of each program is correspondingly processed in accordance with the previous program. The cumulative time of time is offset. Thereby, the inclination of the line segment between the plurality of time axes for indicating the processing time of each program becomes slow. Therefore, the information processing apparatus 100 can suppress the deterioration of the legibility of the display when the product is visualized during processing.

Figure 1 (2) shows parallel timelines 111~114. The time axis 111 is the start time of the program A correspondingly added. The time axis 112 is correspondingly added to the end time of the program A or the start time of the program B. The time axis 113 is correspondingly added to the end time of the program B or the start time of the program C. The time axis 114 is correspondingly added to the end time of the program C.

Further, in the example of Fig. 1 (2), each time axis indicates the start time of each program or the end time of the previous program, but the time axis is, for example, the time at which the start side of each program is displayed or the end of each program. The moment at the side is not particularly limited. The timing of the start side is, for example, the end time of the program before the program, the time of the product input to a certain program, or the start time of a certain program. The time at the end side is the start time of the program behind the program, or the product input time of the program behind the program, or the end time of the program.

First, the information processing apparatus 100 shifts the respective times indicated by the time axes 111 to 114 in response to the cumulative time of the reference processing time to be adjusted by the previous program. The reference processing time is the time set as the processing time required for each program. The reference processing time can be arbitrarily set as an example. Further, the reference processing time may be determined based on, for example, the processing time required for each of the past programs. The reference processing time will be described in detail in the description of the functional blocks in FIG. 6. Further, the reference processing time as the adjustment target is the reference processing time used when the time when the time axis is correspondingly added is adjusted. More specifically, the reference processing time as the adjustment target is the reference processing time which is regarded as the object of accumulation when the time when the time axis is correspondingly added is adjusted.

For example, the information processing apparatus 100 may use all of the processing time of the previous program as the adjustment target. Alternatively, the information processing apparatus 100 may be used as an adjustment target by using one of the reference processing times of the previous program. Regarding a part of the adjustment target, for example, the reference processing time exceeding the predetermined time in the reference processing time of the previous program is used as the adjustment target. The predetermined time is determined by the developer of the information processing device 100, the user of the information processing device 100, and the like. The predetermined time may be determined, for example, based on the reference processing time of each program. In the example of FIG. 1, the information processing apparatus 100 is, for example, all of the processing time of the previous program as the adjustment target.

Further, in Fig. 1 (2), straight lines 121 to 124 orthogonal to the plurality of time axes 111 to 114 are displayed. Hereinafter, the timing indicated by each of the time axes 111 to 114 will be described.

First, each time indicated by the time axis 111 will be described. The time axis 111 is added correspondingly to the point at which the start time of the program A is displayed. There are no more programs than Program A. The cumulative time of the reference processing time of the previous program as the adjustment target is 0 [minutes]. Therefore, each time indicated by the time axis 111 is a time at which the time axis 112 to 114 is shifted as a reference.

For example, the timing indicated by the point on the time axis 111 intersecting the straight lines 121 to 124 will be described. For example, the time indicated by the point on the time axis 111 intersecting the line 121 is "9:00". For example, the time indicated by the point on the time axis 111 intersecting the line 122 is "10:00". For example, the time indicated by the point on the time axis 111 intersecting the line 123 is "11:00". For example, the time indicated by the point on the time axis 111 intersecting the line 124 is "12:00".

Next, each time indicated by the time axis 112 will be described. The time axis 112 is added correspondingly to the point at which the end time of the display program A is displayed. Incidentally, here, the end time of the program A is the same as the start time of the program B. The cumulative time for the benchmark processing time of the previous program as the adjustment target is 10 [minutes]. The information processing device 100 has a mode in which the time on the time axis 112 intersecting the straight lines 121 to 124 is longer than the time on the time axis 111 intersecting the straight lines 121 to 124, and the time axis 112 is shown. Each time is shifted by 10 [minutes] from each time indicated by the time axis 111. More specifically, the information processing apparatus 100 causes each time indicated by the time axis 112 to be a time when 10 [minutes] is added to each time indicated by the time axis 111.

For example, the timing indicated by the point on the time axis 112 intersecting the straight lines 121 to 124 will be described. For example, the time indicated by the point on the time axis 112 intersecting the straight line 121 is "9:10" after advancing 10 [minutes] from "9:00". For example, the time indicated by the point on the time axis 112 intersecting the straight line 122 is "10:10" after 10 [minutes] advance from "10:00". For example, the time indicated by the point on the time axis 112 intersecting the line 123 is "11:10" after advancing 10 [minutes] from "11:00". For example, the time indicated by the point on the time axis 112 intersecting the straight line 124 is "12:10" after advancing 10 [minutes] from "12:00".

Next, each time indicated by the time axis 113 will be described. The time axis 113 is added correspondingly to the point at which the end time of the display program B is displayed. Incidentally, here, the end time of the program B is the same as the start time of the program C. The cumulative time of the reference processing time of the previous program as the adjustment target is 160 [minutes] in total of 10 [minutes] and 150 [minutes]. The information processing device 100 has a mode in which the time on the time axis 113 intersecting the straight lines 121 to 124 is longer than the time on the time axis 111 intersecting the straight lines 121 to 124, and the time axis 113 is shown. Each time is shifted by 160 [minutes] from each time indicated by the time axis 111. More specifically, the information processing apparatus 100 causes each time indicated by the time axis 113 to be a time when 160 [minutes] is added to each time indicated by the time axis 111.

For example, the timing indicated by the point on the time axis 113 intersecting the straight lines 121 to 124 will be described. For example, the time indicated by the point on the time axis 113 intersecting the straight line 121 is "11:40" after advancing 160 [minutes] from "9:00". For example, the time indicated by the point on the time axis 113 intersecting the straight line 122 is "12:40" after advancing 160 [minutes] from "10:00". For example, the time indicated by the point on the time axis 113 intersecting the straight line 123 is "13:40" after advancing 160 [minutes] from "11:00". For example, the time indicated by the point on the time axis 113 intersecting the straight line 124 is "14:40" after advancing 160 [minutes] from "12:00".

Next, each time indicated by the time axis 114 will be described. The time axis 114 is added correspondingly to the point at which the end time of the display program C is displayed. The cumulative time of the reference processing time of the previous program as the adjustment target is 170 [minutes] in total of 10 [minutes] and 150 [minutes] and 10 [minutes]. The information processing device 100 has a mode in which the time on the time axis 114 intersecting the straight lines 121 to 124 is longer than the time on the time axis 111 intersecting the straight lines 121 to 124, and the time axis 114 is shown. Each time is shifted by 170 [minutes] from each time indicated by the time axis 111. More specifically, the information processing apparatus 100 causes each time indicated by the time axis 114 to be a time when 170 [minutes] is added to each time indicated by the time axis 111.

For example, the timing indicated by the point on the time axis 114 intersecting the straight lines 121-124 will be described. For example, the time indicated by the point on the time axis 114 intersecting the straight line 121 is "11:50" after advancing 170 [minutes] from "9:00". For example, the time indicated by the point on the time axis 114 intersecting the straight line 122 is "12:50" after advancing 170 [minutes] from "10:00". For example, the time indicated by the point on the time axis 114 intersecting the straight line 123 is "13:50" after advancing 170 [minutes] from "11:00". For example, the time indicated by the point on the time axis 114 intersecting the straight line 124 is "14:50" after advancing 170 [minutes] from "12:00".

Then, the information processing device 100 arranges a point at which the start time or the end time of each program is displayed on each of the time axes 111 to 114 for each product, and a line segment connecting the points. Here, the processing of the arrangement point and the line segment connecting the points, for example, means generating display data having a point and a point for displaying the display start time or the end time corresponding to the adjacent time axis. Information about the segments connected between the points.

In the example of FIG. 1 (2), the line type of the line segment connecting the points is a solid line, but is not particularly limited to a straight line, a broken line, a dotted line, a wavy line, an N-dot chain line, a meander line, and the like. Although the example of Fig. 1 (2) omits the point at which each product corresponds to the start time or the end time of each program, the information processing device 100 may display these points. In the example of FIG. 1 (2), the information processing apparatus 100 arranges the point p1 of the start time "9:00" of the display program A on the time axis 111, the end time of the display program A on the time axis 112, or the program B. The line segment where p2 is connected at the beginning of the "9:12" point. In the example of Fig. 1 (2), the information processing apparatus 100 arranges a line segment connecting the point p2, the end time of the display program B on the time axis 113, or the point p3 at the start time "11:47" of the program C. In the example of FIG. 1 (2), the information processing apparatus 100 arranges a line segment connecting the point p3 at the point p3 and the end time "11:57" of the display program C on the time axis 114.

In Fig. 1 (2), in order to facilitate understanding, a dotted line indicating the time "10:00", a dotted line showing the time "11:00", and a dotted line showing the time "12:00" are arranged on the graph 102. The information processing apparatus 100 may also be such that the dotted lines are not displayed when the graph 102 is visualized. In addition, the information processing apparatus 100 may display these dotted lines as the scale of the graph 102. In addition, the information processing apparatus 100 may also allow the user to select the display and non-display of each dotted line. Further, the information processing device 100 may switch between display and non-display of each dotted line in response to a user's selection.

In addition, the information processing apparatus 100 may not display the lines 121 to 124 when visualizing. Further, the information processing device 100 may display the straight lines 121 to 124 as the scale of the graph 102. In addition, the information processing apparatus 100 may also allow the user to select the display and non-display of the lines 121 to 124. Further, the information processing device 100 may switch between display and non-display of the lines 121 to 124 in response to the user's selection. The display data may also be information that displays an image containing the chart 102.

Compared with the graph 101 shown in Fig. 1 (1), the inclination of the line during the processing period of the display manufacturing of the graph 102 shown in Fig. 1 (2) is moderate. In the example of Fig. 1 (2), the slope of the line segment indicating the processing time of the program B and the slope of the line segment indicating the processing time of the program A and the program C are the same slope. Thereby, for example, the information processing apparatus 100 can make the difference in the processing time between the products of each program easy to understand and suppress the deterioration of the legibility. Further, for example, the information processing apparatus 100 can easily store the line segments indicating the processing time of each program on one screen, and suppress deterioration of the legibility.

Fig. 2 is an explanatory diagram showing an example of a display system. System 200 is, for example, the production of a management article. The system 200 has a plurality of manufacturing apparatuses 201 to 203 and an information processing apparatus 100. The system 200 is connected to the plurality of manufacturing apparatuses 201 to 203 and the information processing apparatus 100 via the network 210.

The plurality of manufacturing apparatuses 201 to 203 are processing for executing each program. In each program, there may be one manufacturing device, or a plurality of manufacturing devices may be arranged in parallel. In the example of FIG. 2, the program A is performed by the manufacturing apparatus 201. The program B is performed by the manufacturing apparatus 202-1 and the manufacturing apparatus 202-2. The program C is performed by the manufacturing apparatus 203. Although the example of FIG. 2 is a process by a manufacturing apparatus, it is not limited to this. For example, as long as the start time and end time of each program are available, each program can also be a manual operation. Further, as shown in the procedure B of FIG. 2, each program may be performed in parallel as in the manufacturing apparatus 202-1, the manufacturing apparatus 202-2, and the like.

The information processing apparatus 100 manages the record information of the plurality of manufacturing apparatuses 201 to 203. In the present embodiment, the record information includes, for example, information indicating the start time of the start of the program for each product, the time at which the semi-product is put into the program, and the end time at which the program ends. The memory example of the record data is described later using FIG.

In addition, although the system 200 of FIG. 2 manages the recorded material by the information processing apparatus 100, it is not limited thereto. System 200 can also be constructed with a database server, for example. For example, the repository server is managed by a database server. Moreover, the information processing apparatus 100 may also acquire each record information from the record DB of the database server.

(Hardware Configuration Example of Information Processing Apparatus 100) FIG. 3 is an explanatory diagram showing an example of a hardware configuration of the information processing apparatus. The information processing device 100 includes a CPU (Central Processing Unit) 301, a ROM (Read Only Memory) 302, a RAM (Random Access Memory) 303, a disk drive 304, and a disc 305. The information processing device 100 has an I/F (Inter/Face) 306, a keyboard 307, a mouse 308, and a display 309. Further, the CPU 301, the ROM 302, the RAM 303, the disk drive 304, the I/F 306, the keyboard 307, the mouse 308, and the display 309 are connected by the cable 300, respectively.

Here, the CPU 301 is the control of the entire information processing apparatus 100. The ROM 302 is a program for storing a boot program or the like. The RAM 303 is used as a work area of the CPU 301. The disk drive 304 controls the reading/writing of data to the disk 305 in accordance with the control of the CPU 301. The disc 305 is a material that is written by the control of the disc player 304. Regarding the disc 305, for example, a magnetic disc, a disc, or the like.

The I/F 306 is connected to a network 210 such as a LAN (Local Area Network), a WAN (Wide Area Network), or the Internet through a communication return line, and is connected to other devices through the network 210. Moreover, the I/F 306 is the interface between the host network 210 and the internal interface, and controls the input and output of data from external devices. For example, the I/F 306 may be a data machine, a LAN adapter, or the like.

The keyboard 307 and the mouse 308 are interfaces for receiving various data inputs by the user's operation. The display 309 is an interface for outputting data by an instruction of the CPU 301.

Further, although not shown, the information processing device 100 may be provided with an input device for acquiring an image/movie by a camera and an input device for obtaining a sound by a microphone. Further, although not shown, the information processing device 100 may be provided with an output device such as a printer.

Further, in the present embodiment, the hardware configuration of the information processing device 100 is exemplified by a personal computer, but the present invention is not limited thereto, and may be a server or the like. When the information processing device 100 is a server, the information processing device 100 may be connected to a user operable device, the display 309, etc. via the network 210.

(Memory contents of various DBs and the like) Next, the memory contents of various DBs (Databases) included in the information processing device 100 will be described. Each of the DBs and the like is a memory unit such as a semiconductor memory (not shown) such as a ROM 302, a RAM 303, a disc 305, or a flash memory included in the information processing device 100 shown in FIG. And realized.

Fig. 4 is an explanatory diagram showing an example of the memory of the recording DB. The record DB 400 is exemplified by the product, and has record information 401 to 40x recorded by each of the manufacturing apparatuses 201 to 204. x is 1 or more. The record information 40n is, for example, a field having a product number, a program sequence, a program ID, a start time, and an end time. n is an integer from 1 to n. FIG. 4 is a detailed example showing the record information 401 and the record information 402.

The field of the product number is the product number set as the identification information of the product. The field in the program sequence is a number that sets the order in which the program to be performed at the time of manufacture of the product is displayed. The field of the program ID is identification information of a program corresponding to the order of the program performed at the time of manufacturing the product. The field at the start time is the time at which the setting program starts. The field at the end time is the time at which the setting program ends.

The record information 401 is a manufacturing record of the product number "L001". According to the record information 401, the product shown by the product number "L001" is processed in the order of the program A, the program B, and the program C. The record information 402 is a manufacturing record of the product number "L002". According to the record information 402, the product shown by the product number "L002" is manufactured in the order of the program A, the program B, the program B, and the program C. According to the record information 402, the product shown by the product number "L002" is reprocessed in the procedure B.

By recording the record information 40n in accordance with the product, the information processing device 100 can manage the history of reprocessing such as manufacturing in the product.

FIG. 5 is an explanatory diagram showing an example of setting a reference processing time. The setting information 500 is a reference processing time set according to the program. The setting information 500 is, for example, a field having a program ID and a reference processing time.

The field of the program ID is the identification information of the setting program. The field in the base processing time is the processing time set as the basis of the program. In addition, the reference processing time is the processing time of an arbitrarily set program. Alternatively, the reference processing time is, for example, a standard processing time obtained by statistically processing the past processing time of the program. According to the setting information 500, the reference processing time of the program A is 10 [minutes]. The benchmark processing time for program B is 150 [minutes]. The benchmark processing time for program C is 10 [minutes].

In the present embodiment, the information processing device 100 manages the reference processing time of the entire program by using the setting information 500 for the sake of easy understanding. However, the reference processing time is not particularly limited as long as the reference processing time can be set for each program.

(Example of Functional Configuration of Information Processing Apparatus 100) FIG. 6 is a block diagram showing an example of a functional configuration of an information processing apparatus. The information processing device 100 includes a reception input unit 601, a setting unit 602, an arrangement unit 603, a display control unit 604, a storage unit 610, and a display unit 620. The processing of the control unit 600 from the reception input unit 601 to the display control unit 604 is, for example, a program stored in a memory device such as the ROM 302, the RAM 303, the disc 305, and the like accessible to the CPU 301 shown in FIG. Further, the CPU 301 reads the program from the memory device and executes the processing of the code in the program. Thereby, the processing of the control unit is realized. The processing result of the control unit 600 is, for example, a memory device such as a semiconductor memory (not shown) that is invariant in the ROM 302, the RAM 303, the disc 305, or the flash memory.

The memory unit 610 is, for example, a memory device such as a semiconductor memory (not shown) that is invariant in the ROM 302, the RAM 303, the disc 305, and the flash memory. The memory unit 610 has a record DB 400 and setting information 500.

Further, the display unit 620 is realized by, for example, a display 309 or the like. Although the example of FIG. 6 is such that the display unit 620 is included in the information processing apparatus 100, it is not limited thereto. For example, the other device that can be contacted by the information processing device 100 may have a display portion 620. In the case where the other device has the display portion 620, the information processing device 100 transmits the display material 611 to the other device. Then, the other device displays the chart by the display unit 620 based on the received display material 611.

The arranging unit 603 generates a display material 611 which is expressed by each line between a plurality of parallel time axes in a processing period of a plurality of programs which are included in the manufacturing process of the product. Specifically, the arranging unit 603 arranging, for example, a time axis indicating one of the start time or the end time of the program for the product in parallel according to each program.

Next, the arranging unit 603 is configured to shift the time indicated by the plurality of time axes in response to the cumulative time of the reference processing time to be adjusted in the previous program. The arranging unit 603 is, for example, a process of shifting the cumulative processing time of the reference processing time to be adjusted as a process to be adjusted in advance. Alternatively, the arranging unit 603 is, for example, a process of advancing the time corresponding to the time after the reference processing time of the program of the preceding program is considered as the cumulative time.

Here, description will be made using FIG. 1 (2). As described above, each time indicated by the time axis 111 is a time when the time axis 112 to 114 is shifted. More specifically, the arranging unit 603 exemplifies that the time indicated by the time axes 112 to 114 is the time after the time indicated by the time axis 111 plus the cumulative time of the reference processing time of the previous program as the adjustment target.

Here, the timings indicated by the respective time axes 111 to 114 will be exemplified using the timing indicated by the point on the time axes 111 to 114 intersecting the straight line 122, using FIG. 1 (2). For example, the time indicated by the point on the time axis 111 intersecting the line 122 is "10:00".

More specifically, the information processing apparatus 100 causes each time indicated by the time axis 112 to be 10 [minutes] at each time indicated by the time axis 111. Thereby, the time indicated by the point on the time axis 112 intersecting the straight line 122 is "10:10" after 10 [minutes] advance from "10:00". Further, the information processing apparatus 100 causes each time indicated by the time axis 113 to be a time when the time indicated by the time axis 111 is added by 160 [minutes]. Thereby, the time indicated by the point on the time axis 113 intersecting the straight line 122 is "12:40" after advancing 160 [minutes] from "10:00". Further, the information processing apparatus 100 causes each time indicated by the time axis 114 to be a time of 170 [minutes] added to each time indicated by the time axis 111. Thereby, for example, the time indicated by the point on the time axis 114 intersecting the straight line 122 is "12:50" after the advancement of 170 [minutes] from "10:00". As described above, the time indicated by the time axes 112 to 114 is the time after the cumulative time of the reference processing time to be adjusted by the program preceding the time indicated by the time axis 111.

Further, the arrangement unit 603 may, for example, use all of the processing time of the previous program as the adjustment target. In the example of Fig. 1 (2) described above, the arrangement unit 603 is, for example, the entire processing time of the previous program as the adjustment target. Further, the configuration unit 603 may be an adjustment target by using one of the reference processing times of the previous program. Regarding a part of the adjustment target, for example, the reference processing time exceeding the predetermined time in the reference processing time of the previous program is used as the adjustment target. The predetermined time is determined by the developer of the information processing device 100, the user of the information processing device 100, and the like. Incidentally, an example in which one of the reference processing times of the previous program is used as an adjustment target will be described later using FIG. 8.

Here, the reference processing time will be described in detail. The reference processing time is the time set as the processing time required by the program. In the present embodiment, for example, the reference processing time is set by the setting unit 602 or the receiving input unit 601 and the setting unit 602. Specifically, the reception input unit 601 receives, for example, an input of a reference processing time by an input operation of a user, such as a mouse 308 or a keyboard 307, in accordance with each program. Then, the setting unit 602 sets the setting information 500 in accordance with each program as the received reference processing time. Thereby, for example, a user such as a skilled person can arbitrarily set the reference processing time. Therefore, the information processing apparatus 100 can display the manufacturing status of the product in an easy-to-view manner.

Further, the reference processing time may be, for example, a standard processing time calculated by performing statistical processing on the past processing time of each program. Specifically, the setting unit 602 is the reference recording DB 400, and recognizes the past processing time of a predetermined period or a predetermined number of processing for each program. The past processing time is, for example, the time from the end time minus the start time. Then, the setting unit 602 obtains a statistical amount by performing statistical processing of a processing time of a predetermined period or a predetermined number of processing times in accordance with each program. Regarding the statistics, for example, the average value, the mode, the median, the minimum value, the maximum value, and the like. The average value is also called the average time. The minimum value is also called the shortest time. Then, the setting unit 602 sets the calculated statistic as the reference processing time to the setting information 500.

In addition, the reference processing time may also be a statistic that is selected from various statistics by an input operation of the user. Specifically, the setting unit 602 is, for example, a statistic that calculates a plurality of types such as an average time and a shortest time. The reception input unit 601 is an input that receives a statistic from a plurality of types to select any statistic. The setting unit 602 sets the statistic corresponding to the selection received by the reception input unit 601 as the reference processing time to the setting information 500, for example.

Further, regarding the detailed processing for shifting the time, there are a first method and a second method. In the first method, the arranging unit 603 shifts the content of the record DB 400 as it is and shifts the time at which the time axis of the graph is added. In the second method, the arranging unit 603 shifts the time axis of the graph as it is, and shifts the memory at the start time and the end time of the record DB 400. As described above, the position corresponding to the start time or the end time of each program included in the record DB 400 is placed at the cumulative time of the reference processing time of the program that has advanced before, on the time axis corresponding to each program. In order to visualize the chart, the detailed processing method is not particularly limited.

Thereby, as shown in Fig. 1 (2), the point p2 at the start time "9:12" of the display program B on the time axis 112 is slower than the point of the display time "9:12" on the time axis 111. 10 [minutes] position. The point p3 at the start time "11:47" of the display program C on the time axis 113 is a position which is 160 [minutes] slower than the point of the display time "11:47" on the time axis 111. The point p4 at the end time "11:57" of the display program C on the time axis 114 is a position which is 170 [minutes] slower than the point of the display time "11:57" on the time axis 111.

Then, the arranging unit 603 is a display material 611 for generating a graph in which lines connecting the points arranged adjacent to each other on the time axis are arranged for each product. The type of the line may be a straight line, a broken line, a dotted line, a wavy line, an N-dot chain line, a meander line, etc., and is not particularly limited.

Next, the display control unit 604 displays the graph on the display device such as the display 309 based on the generated display material 611. Here, the display material 611 may be, for example, information in the form of a table that makes the display of the chart possible. Further, the display material 611 is, for example, an image data including an image of a chart. Further, the display material 611 can be variously changed in accordance with the display form of the display unit 620 as an example.

Further, the arrangement unit 603 may be arranged to display a character string indicating a start time or an end time corresponding to a point arranged on each time axis. In the example of Fig. 1 (2), the character string indicating the start time or the end time corresponding to the point of arrangement is arranged in the comment box.

Alternatively, the time at which the chart corresponds to the position on the time axis designated by the user may be arranged. Specifically, the reception input unit 601 receives any position on the time axis of display designated by the mouse 308, the keyboard 307, and the like. The arrangement unit 603 recognizes, for example, the time corresponding to the position on the time axis received by the reception input unit 601. The arranging unit 603 generates a display data 611 of a chart in which a character string for displaying the recognized time is arranged.

Further, a line on each time axis corresponding to the time designated by the user, a line segment connecting points on each time axis corresponding to the designated time, or the like may be disposed. Specifically, the reception input unit 601 is, for example, a time designated by the keyboard 307, the mouse 308, or the like. The arranging unit 603 is, for example, a point corresponding to the time specified on each time axis. Further, the arrangement unit 603 is, for example, a line segment in which points arranged in adjacent time axes are arranged.

In addition, the case where reprocessing is performed in any of the manufacturing procedures of the product will be described. The record data 402 of FIG. 4 shows an example of rework in the program B. For example, in the manufacturing process in which each program is only executed once, the same program ID is set in the field of the program ID of the product record information 40n. In this case, the arranging unit 603 determines, for example, that in the manufacture of the product, the program represented by the program ID set plural times is reworked. Incidentally, a display example of a graph in the case where reworking occurs is shown in Fig. 9. A comparative example of the case where the processing for a long processing time is reworked and the case where the processing time is short and the processing is reworked is shown in Fig. 10.

Further, the arranging unit 603 may arrange each line such that a line indicating a processing period of each program of the product in which reprocessing is performed and a line indicating a processing period of each program of the product in which no rework is performed are performed. Different types.

Next, detailed processing of each part of the functional block will be described with a view to two time axes of a plurality of time axes.

The arranging unit 603 advances the point at which the point on the second time axis passes through the line perpendicular to the first time axis and the second time axis, and the time at the point on the first time axis. The time on the second time axis is shifted with respect to the time assigned to the first time axis. Then, the arranging unit 603 generates the display material 611 for displaying the first time axis on which the first time is plotted and the second time axis on which the second time is plotted. The second time axis is an axis parallel to the first time axis.

The first time is the time on the start side of the first program among the plurality of programs included in the manufacturing program of the product. The first time is, for example, an end time of a program before the first program, or a product input time for the first program, or a start time of the first program. The second time is the time on the end side of the first program. The second time is, for example, the start time of the program after the first program, or the product input time of the program after the first program, or the end time of the first program.

The offset assigned to the time on the first time axis and the time assigned on the second time axis is the offset of the predetermined time. The predetermined time here is, for example, a time arbitrarily determined by the user.

Further, the offset between the time allocated on the first time axis and the time assigned to the second time axis is the time offset in accordance with the length of the reference processing time of the first program. Regarding the time shift in accordance with the length of the reference processing time of the first program, for example, the reference processing time ±α or the reference processing time ×k. k can also be 100 ± β [%]. α and β are margin values. α, β are exemplified by the user or the developer of system 200.

The offset assigned to the time on the first time axis and the time assigned to the second time axis is the same as the time corresponding to the reference processing time of the first program. Incidentally, FIG. 7 which will be described later shows an example in which the case where the reference processing time is the average time and the shortest time are compared.

Further, the arranging unit 603 is a display material 611 that generates a graph in which any type of line is drawn between a point corresponding to the first time and a point corresponding to the second time. The type of the line is, for example, a straight line, a broken line, a dotted line, a wavy line, an N-dot chain line, a meander line, and the like as described above, and is not particularly limited.

Here, in the case of the above-described FIG. 1 (2), the time axis 111 is taken as an example of the first time axis, and the time axis 112 is taken as an example of the second time axis. A straight line perpendicular to the time axis 111 and the time axis 112 is a straight line 121 to 124. The example of the first time is "9:00" at the start time of the program A, and the "9:12" at the end of the program A is taken as the second time.

Specifically, the arranging unit 603 generates, for example, a time axis 111 that plots the time point "9:00" at which the program A is started, and the time axis 112 on which the end time "9:12" of the program A is plotted. Display data 611. The arranging unit 603 generates, for example, a display in which any type of line is drawn between the plot corresponding to the start time "9:00" of the program A and the point corresponding to the end time "9:12" of the program A. Information 611.

The display control unit 604 is a display device that displays a graph on the display 309 or the like based on the display material 611 generated by the placement unit 603.

FIG. 7 is an explanatory diagram showing a comparative example of the case where the reference processing time is the average time and the shortest time. Fig. 7 (1) shows a display example in the case where the reference processing time is an average time of the past processing time of each of the predetermined periods or the predetermined number of processing. Incidentally, the display example of the thick solid line shown in Fig. 7 (1) is the same as the display example of the thick solid line of Fig. 1 (2) described above, and the example of Fig. 7 (1) is the above-mentioned Fig. 1 ( 2) The line during the processing period of the display product other than the thick solid line is omitted. Further, Fig. 7 (2) shows a display example in the case where the reference processing time is the shortest time of the past processing time of each of the predetermined periods or the predetermined number of processing. In Figs. 7(1) and 7(2), the time added to each program is the reference processing time.

In Fig. 7 (1), the reference processing time of the program A is 10 [minutes]. The benchmark processing time for program B is 150 [minutes]. The benchmark processing time for program C is 10 [minutes]. Further, in Fig. 7 (2), the reference processing time of the program A is 7 [minutes]. The benchmark processing time for program B is 120 [minutes]. The benchmark processing time for program C is 9 [minutes]. The graph 701 shown in Fig. 7 (2) is compared with the graph 102 shown in Fig. 7 (1), and shows that the inclination of the line during the processing of manufacturing becomes sharp.

Thus, with the reference processing time, the inclination of the line during the processing of the display manufacturing will be different. Therefore, the information processing apparatus 100 may display the graph showing the manufacturing status regardless of the number of times so that the reference processing time is changed.

Fig. 8 is an explanatory diagram showing an example in which one of the reference processing times of the previous program is used as an adjustment target. The arranging unit 603 adjusts the reference processing time equal to or longer than a predetermined time in the reference processing time of the previous program. The predetermined time is, for example, 20 [minutes]. In Fig. 8, the time added to each program is the reference processing time of each program. 8 is the same as the example of FIG. 1 (1), and the time indicated by the point on the time axes 111 to 114 intersecting the straight lines 121 to 124 is taken as an example of the time indicated by each of the time axes 111 to 114. Description.

In the programs A to C, the program whose reference processing time is longer than the predetermined time is the program B. Therefore, for example, the time indicated by the point on the time axis 111 intersecting the straight lines 121 to 124 and the time indicated by the point on the time axis 112 intersecting the straight lines 121 to 124 are the same. For example, the time indicated by the point on the time axis 113 intersecting the straight lines 121-124 and the time indicated by the point on the time axis 114 intersecting the straight lines 121-124 are the same.

Here, the specific processing performed by the arranging unit 603 will be described using the respective times indicated by the time axes 111 to 114. First, each time indicated by the time axis 111 will be described. As described above, the time axis 111 is correspondingly added to the point at which the start time of the program A is displayed. There are no more programs than Program A. The cumulative time of the reference processing time of the previous program as the adjustment target is 0 [minutes]. Therefore, as described above, each time indicated by the time axis 111 is the time taken as the reference.

In Fig. 8, the timing indicated by the point on the time axis 111 intersecting the straight lines 121-124 is the same as the example shown in Fig. 1 (2). Therefore, for example, the time indicated by the point on the time axis 111 intersecting the straight line 121 is "9:00". For example, the time indicated by the point on the time axis 111 intersecting the line 122 is "10:00". For example, the time indicated by the point on the time axis 111 intersecting the line 123 is "11:00". For example, the time indicated by the point on the time axis 111 intersecting the line 124 is "12:00".

Next, each time indicated by the time axis 112 will be described. As described above, the point at which the end time of the program A is displayed is added correspondingly to the time axis 112. The reference processing time of the program A is 10 [minutes], and is less than or equal to 20 minutes under the predetermined time. The reference processing time of the program A is not the adjustment target, and the cumulative time of the reference processing time as the adjustment target of the previous program is 0 [minutes]. The arrangement unit 603 causes each time indicated by the time axis 112 to be shifted by 0 [minutes] from each time indicated by the time axis 111. More specifically, the arrangement unit 603 exemplifies that each time indicated by the time axis 112 is a time at which 0 [minutes] is added to each time indicated by the time axis 111.

For example, the time indicated by the point on the time axis 112 intersecting the line 121 is "9:00". For example, the time indicated by the point on the timeline 112 intersecting the line 122 is "10:00". For example, the time indicated by the point on the timeline 112 intersecting the line 123 is "11:00". For example, the time indicated by the point on the timeline 112 intersecting the line 124 is "12:00".

Next, each time shown by the time axis 113 will be described. As described above, the point at which the end time of the program B is displayed is added correspondingly to the time axis 113. The benchmark processing time of the program B is 150 [minutes], which is larger than the predetermined time 20 [minutes]. The reference processing time of the program B becomes the adjustment target, and the cumulative time of the reference processing time as the adjustment target of the previous program is 150 [minutes]. The arranging unit 603 has a mode in which the point on the time axis 113 intersecting the straight lines 121 to 124 is longer than the point on the time axis 111 intersecting the straight lines 121 to 124, and the time axis 113 is shown. Each time is offset by 150 [minutes] from each time indicated by the time axis 111. More specifically, the arrangement unit 603 exemplifies that each time indicated by the time axis 113 is a time at which 150 [minutes] is added to each time indicated by the time axis 111.

For example, the time indicated by the point on the time axis 113 intersecting the straight line 121 is "11:30" after advancing 150 [minutes] from "9:00". For example, the time indicated by the point on the time axis 113 intersecting the straight line 122 is "12:30" after advancing 150 [minutes] from "10:00". For example, the time indicated by the point on the time axis 113 intersecting the straight line 123 is "13:30" after advancing 150 [minutes] from "11:00". For example, the time indicated by the point on the time axis 113 intersecting the straight line 124 is "14:30" which advances 150 [minutes] from "12:00".

Then, the respective times indicated by the time axis 114 will be described. As described above, the point at which the end time of the program C is displayed is added correspondingly to the time axis 114. The reference processing time of the program C is 10 [minutes], and is less than or equal to 20 [minutes] in the predetermined time. The reference processing time of the program C is not an adjustment target, and the cumulative processing time of the reference processing time of the previous program is 150 [minutes]. The arranging unit 603 has a mode in which the point on the time axis 114 intersecting the straight lines 121 to 124 is longer than the point on the time axis 111 intersecting the straight lines 121 to 124, and the time axis 114 is shown. Each time is offset by 150 [minutes] from each time indicated by the time axis 111. More specifically, the arrangement unit 603 exemplifies that each time indicated by the time axis 114 is a time at which 150 [minutes] is added to each time indicated by the time axis 111.

For example, the time indicated by the point on the time axis 114 intersecting the straight line 121 is "11:30" after advancing 150 [minutes] from "9:00". For example, the time indicated by the point on the time axis 114 intersecting the straight line 122 is "12:30" after advancing 150 [minutes] from "10:00". For example, the time indicated by the point on the time axis 114 intersecting the straight line 123 is "13:30" after advancing 150 [minutes] from "11:00". For example, the time indicated by the point on the time axis 114 intersecting the straight line 124 is "14:30" which advances 150 [minutes] from "12:00".

Compared with the graph 101 shown in Fig. 1 (1), in the graph 801 shown in Fig. 8, the inclination of the line during the processing period of the manufacturing process is shown to be moderate. Therefore, the deterioration of the readability of the display when the processing time of each program of the product is visualized can be suppressed.

Fig. 9 is an explanatory view showing a display example in the case where reworking is performed. FIG. 9 shows a graph 901 during the processing period of the product "L002" of the record information 402. Regarding the program B, after the processing from the start time "9:12" to the end time "11:47", there is reprocessing from the start time "11:55" to the end time "14:40". In the case of rework, the line during the processing period of the display product "L002" will be Z-shaped. In this manner, the information processing apparatus 100 allows the article to be reworked to be visually confirmed.

Fig. 10 is an explanatory diagram showing a comparative example of a case where reprocessing is performed in a program having a long processing time and a case where reprocessing is performed in a program having a short processing time. Fig. 10 (1) shows an example of visualizing the processing period of each article by a conventional technique. FIG. 10(2) shows an example in which the processing period of each product is visualized by the information processing apparatus 100.

In the graph 1001 shown in Fig. 10 (1), since there are many lines obliquely downward to the right, it is difficult to visually recognize the processing period of the reworked product. On the other hand, as shown in Fig. 10 (2), in the present embodiment, the Z-shaped line disposed in a large number of lines obliquely downward to the right is easily recognized visually. Therefore, the information processing apparatus 100 can make the reworked product easy to recognize.

Further, the graph 1002 shown in Fig. 10 (2) is provided with a line for displaying the processing period of the product which is reprocessed in a program having a long processing time, and a processing period for the product which is reprocessed by a program having a short processing time. The line to be displayed. Compared with the case where reprocessing is performed in a program with a short processing time, reprocessing at a long processing time has a large influence on the processing of the product. As shown in the graph 1002 of Fig. 10 (2), when the program having a large influence during the processing of the product is reworked, the line during the processing of the display product becomes a large Z shape. Therefore, the information processing apparatus 100 can make the article reprocessed by the program having a large influence during the processing of the entire product easy to recognize. As described above, since the information processing apparatus 100 makes it easy to identify the products having characteristics during the processing, it is easy to achieve production management.

(Example of Display Data Generation Processing Program by Information Processing Apparatus 100) FIG. 11 is a flowchart showing an example of a display material generation processing program by the information processing apparatus. First, the information processing device 100 sets the reference processing time for each program (step S1101). In step S1101, the information processing apparatus 100 may perform statistical processing of the processing time of each program in order to set the reference processing time of each program. Then, the information processing apparatus 100 may also set the statistic obtained by the statistical processing as the reference processing time. In addition, in step S1101, the information processing apparatus 100 may be configured to receive an input of a reference processing time caused by an input operation of the user, and set the received reference processing time.

Then, the information processing apparatus 100 causes the time indicated by the time axis corresponding to each program to be the time after the cumulative time of the reference processing time of the program before the program is added to the time indicated by the time axis of the reference (step S1102). . Thereby, the time indicated by the time axis corresponding to each program is the time after the cumulative time of the reference processing time of the front program of each program is advanced from the time of the reference.

Next, the information processing device 100 arranges a point corresponding to the start time and the end time and a line connecting the points on the time axis corresponding to each program for each product (step S1103). Thereby, in step S1103, the display material 611 which displays the situation of the line between the arrangement point and the connection point is generated. Then, the information processing device 100 displays the chart on the display device such as the display 309 based on the display material 611 (step S1104), and ends the series of processes.

As described above, when the information processing device 100 displays the graph indicating the manufacturing status, the time indicated by the time axis indicating the start or end time of each product of each program is added to the reference processing time of the previous program. The moment after time. Thereby, each time indicated by the time axis is the time after the cumulative time of the reference processing time of the previous program is advanced. Then, the inclination of the line showing the processing period during manufacturing becomes slow. Therefore, the difference in the processing period between the products of the respective programs becomes easy to understand, and the information processing apparatus 100 can suppress the deterioration of the legibility. Further, for example, it is easy to store the line segment indicating the processing time of each program on one screen, and the information processing apparatus 100 can suppress the deterioration of the legibility.

Further, the information processing apparatus 100 is the adjustment target for all the processing time of the previous program. Thereby, the information processing apparatus 100 can make the inclination of the line during the processing of the display article more moderate.

Further, the information processing apparatus 100 is the adjustment processing target based on the reference processing time of the previous processing time of the previous program. Thereby, the inclination of the line segment in which the processing time of the standard processing time is long is slowed down. Therefore, the deterioration of the legibility can be suppressed.

In addition, as described above, the case of focusing on two axes will be described. The information processing device 100 displays a first time axis on which the start time of the first program is plotted and a second time axis on which the start time of the second program is plotted, and a line perpendicular to the first and second time axes. The time at which the point on the second time axis passes is later than the time at the point on the first time axis. Thereby, the inclination of the line during the process of manufacturing is shown to be slow. Therefore, the information processing apparatus 100 can suppress the deterioration of the legibility.

Further, the time at which the first time axis and the second time axis are respectively assigned is the time when the offset is arbitrarily set by the user. Thereby, for example, a person skilled in production management can determine the time of the offset, and can shift the time in a manner that is easy for the user to see. Therefore, the information processing apparatus 100 can improve the readability of the display when the processing time of each program of the product is visualized.

Further, the time at which the first time axis and the second time axis are respectively allocated is the time after the offset is set to the reference processing time. Thereby, the information processing apparatus 100 does not directly apply the past processing time of the program, and can consider the margin to shift the time allocated to the two time axes. As a result, the information processing apparatus 100 can shift the time allocated to the two time axes by the time that the user can easily view it, and can improve the readability of the display when the processing time of each program of the product is visualized.

Further, the offset assigned to the time on the first time axis and the time assigned to the second time axis are equal to the time corresponding to the reference processing time of the first program.

Further, the reference processing time is a time calculated by performing statistical processing on the past processing time of the first program. For example, the calculated time is, for example, a statistic of the average time, the shortest time, the median, the mode, and the like of the past processing time. Thereby, the information processing apparatus 100 can shift the time allocated to the two time axes in consideration of the past processing time of the program. Therefore, it is possible to shift the time allocated to the two time axes so as to be easily viewed by the user, and it is possible to improve the readability of the display when the processing time of each program of the product is visualized.

Further, the information processing device 100 arranges any type of line between a point corresponding to the first time and a point corresponding to the second time. The information processing device 100 is, for example, different from the line type corresponding to the processing period of the reworked product and the line corresponding to the processing period of the product without the reworked product. Alternatively, the information processing apparatus 100 is different in that the line of the product corresponding to the difference between the reference processing time and the processing time and the line of the product corresponding to the difference between the reference processing time and the processing time are different. As described above, the information processing device 100 can change the line type so that the user can easily find the product having an abnormality during the processing. Therefore, the information processing apparatus 100 can improve the readability of the display when the processing time of each program of the product is visualized.

Further, the first time on the start side of the first program is the end time of the program before the first program, or the product input time to the first program or the start time of the first program. Further, the second time on the end side of the first program is the start time of the program after the first program, or the product input time of the program after the first program, or the end time of the first program.

Further, according to the information processing apparatus 100, the line for displaying the processing period of the product including the program in which the rework is performed is Z-shaped. The information processing apparatus 100 allows the article to be reworked to be visually confirmed. Further, in the case where the process having a large influence during the processing of the article is reworked, the line during the processing of the display article becomes a large Z-shape. Therefore, the information processing apparatus 100 can make the article reprocessed by the program having a large influence during the processing of the entire product easy to recognize. As described above, since the information processing apparatus 100 makes it easy to identify the products having characteristics during the processing, it is easy to achieve production management.

Incidentally, the display data generating method described in the embodiment can be realized by executing a display material generating program prepared in advance on a computer such as a personal computer or a workstation. The display data generating program is a computer-readable recording medium recorded on a magnetic disk, a compact disk, a USB (Universal Serial Bus) flash memory, or the like, and can be read and read from a recording medium by a computer. In addition, the display data generation program can also be distributed via a network such as the Internet.

In addition, the information processing device 100 described in the present embodiment may be an IC suitable for identification purposes such as a standard unit or an ASIC (Application Specific Integrated Circuit) (hereinafter referred to simply as "ASIC"), and an FPGA (Field Programmable). Gate Array) is implemented by PLD (Programmable Logic Device). Specifically, for example, the functions of all or a part of the above-described control unit 600 and memory unit 610 are defined by HDL (Hardware Description Language) description. Then, for example, the net list of the HDL description may be logically synthesized and given to the ASIC and the PLD, thereby manufacturing the information processing apparatus 100.

100‧‧‧Information processing device

101, 102, 120, 130, 701, 801, 901, 1001, 1002‧‧‧ charts

111, 112, 113, 114‧‧‧ timeline

121, 122, 123, 124‧‧‧ straight lines

200‧‧‧ system

201, 202-1, 202-2, 203‧‧‧ manufacturing equipment

210‧‧‧Network

300‧‧‧ cable

301‧‧‧CPU

302‧‧‧ROM

303‧‧‧RAM

304‧‧‧ disc player

305‧‧‧ discs

306‧‧‧I/F

307‧‧‧ keyboard

308‧‧‧ Mouse

309‧‧‧ display

400‧‧‧records DB

401~40x‧‧‧record information

500‧‧‧Setting information

600‧‧‧Control Department

601‧‧‧ receiving input section

602‧‧‧Setting Department

603‧‧‧Configuration Department

604‧‧‧Display Control Department

610‧‧‧Memory Department

611‧‧‧Display information

620‧‧‧Display Department

P1, p2, p3, p4‧‧ points

S1101, S1102, S1103, S1104‧‧‧ steps

Fig. 1 (1), (2), ... show an explanatory view of a display example caused by the display material generating program relating to the present invention. Fig. 2 is an explanatory diagram showing an example of the system. Fig. 3 is an explanatory view showing a hardware configuration example of the information processing device. Fig. 4 is an explanatory diagram showing a memory example of one of the records. Fig. 5 is an explanatory diagram showing a setting example of the reference processing time. Fig. 6 is a block diagram showing an example of a functional configuration of an information processing apparatus. 7(1), (2), ... are explanatory diagrams showing a comparative example of the case where the reference processing time is the average time and the shortest time. Fig. 8 is an explanatory diagram showing an example in which one of the reference processing times of the previous program is used as an adjustment target. Fig. 9 is an explanatory view showing a display example in the case where reworking is performed. Fig. 10 (1), (2), ... show an explanatory diagram of a comparative example in the case where reprocessing is performed in a program having a long processing time and in the case where reprocessing is performed in a program having a short processing time. Fig. 11 is a flow chart showing an example of a display material generation processing program of the information processing device.

Claims (15)

A display data generation program is a display data generation program for generating display data, which is a processing period of a plurality of programs to be included in a manufacturing process of a product, and is performed in parallel between a plurality of timelines of a plurality of time axes. The display data generating program is characterized in that the computer performs the following processing: the time corresponding to the point at which the straight line perpendicular to the plurality of time axes intersects with each time axis is adjusted according to the previous program of the time The accumulated time of the reference processing time of the object becomes late. The display data generation program of the request item 1 is the adjustment target for all the processing time of the previous program at that time. The display material generating program of the request item 1 is an adjustment processing target based on a reference processing time exceeding a predetermined time in the reference processing time of the previous program at that time. A display data generating program is characterized in that a computer executes a process of shifting a time allocated on a second time axis with respect to a time allocated on a first time axis so as to be parallel to the first time axis The time at which the straight line perpendicular to the second time axis of the first time axis passes through the point on the second time axis is later than the time at the point on the first time axis, and the display is displayed The display data of the first time axis and the second time axis, wherein the first time axis plots the first time on the start side of the first program among the plurality of programs included in the manufacturing program of the product, and the second time The inter-axis is plotted on the second time on the end side of the first program. The display data generating program of claim 4, wherein the relationship between the time when the first time axis is shifted from the second time axis is a predetermined time offset. The display data generating program of claim 4, wherein the relationship between the time when the first time axis is shifted from the second time axis is a time shift in accordance with the length of the reference processing time of the first program. The display data generating program of claim 4, wherein the offset between the time allocated to the first time axis and the time allocated to the second time axis is equal to the time corresponding to the reference processing time of the first program Offset. The display data generation program of claim 7, wherein the reference processing time is a standard processing time calculated by statistically processing the past processing time of the first program. The display data generating program of claim 8, wherein the reference processing time is one of an average value, a minimum value, a mode, and a median calculated by statistically processing the past processing time of the first program. . The display material generating program of claim 4, wherein any type of line is drawn between the plot corresponding to the first time and the plot corresponding to the second time. The display data generating program of claim 4, wherein the first time on the start side of the first program is a step before the first program The end time of the sequence, or the time of the product input to the first program or the start time of the first program. A display data generation method is a display data generation method for generating display data, which is a processing period of a plurality of programs to be included in a manufacturing process of a product, and is performed in parallel between a plurality of timelines of a plurality of time axes. The display data generating method is characterized in that the computer performs the following processing: the time corresponding to the point at which the straight line perpendicular to the plurality of time axes intersects with each time axis is adjusted according to the previous program of the time The accumulated time of the reference processing time of the object becomes late. A display data generating method is characterized in that a computer is configured to perform a process of shifting a time allocated on a second time axis with respect to a time allocated on a first time axis so as to be parallel to the first time axis The time at which the straight line perpendicular to the second time axis of the first time axis passes through the point on the second time axis is later than the time at the point on the first time axis, and the display is displayed The display data of the first time axis and the second time axis, wherein the first time axis plots the first time on the start side of the first program among the plurality of programs included in the manufacturing program of the product, and the second time axis The second time on the end side of the first program is drawn. An information processing apparatus, comprising: a control unit configured to generate display data, wherein the display data is to be included in a manufacturing process of the product and sequentially processed by a plurality of programs in parallel between a plurality of time axes Each line is to be expressed; The memory unit stores the display data generated by the control unit; the control unit is a time corresponding to a point at which a line perpendicular to the plurality of time axes intersects each time axis, and the previous program of the time is Adjusts the cumulative time of the base processing time of the object to become late. An information processing device comprising: a control unit that shifts a time allocated on a second time axis with respect to a time allocated on a first time axis so as to be parallel to the first time axis The time at which the straight line perpendicular to the second time axis of the first time axis passes through the point on the second time axis is later than the time at the point on the first time axis, and the first time is displayed and displayed. In the display data of the axis and the second time axis, the first time axis is marked with a first time on the start side of the first program among the plurality of programs included in the manufacturing program of the product, and the second time axis is marked with The second time on the end side of the first program; the memory unit stores the display material generated by the control unit.