JP2002132644A - Time series database system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To optimize the display of read time series data or the like at a portable terminal. SOLUTION: This system is provided with a data display control part 1 for selecting and acquiring time series data having a sample cycle suitable for the display of a portable terminal from a plurality of sampling cyclic time series data in response to a reading request from a portable terminal 4, and for converting the acquired time series data into a file format displayable at the portable terminal, and for supplying the time series data to a Web server 2.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to processing of time series data typified by trend data of industrial plants, stock prices or medical measuring instruments, etc., which operate continuously, more specifically, data reading via the Internet, The present invention relates to a time-series database system for performing data conversion, data transfer, and display.

[0002]

2. Description of the Related Art Conventionally, in an industrial plant or the like, data indicating the operation state of the plant or the like is acquired at predetermined time intervals.
This large amount of time-series data is stored in the database,
The trend (trend, trend) of time series data is displayed and analyzed. Various trend display systems having a function of displaying such time-series data trends (hereinafter, referred to as trend data) online have been proposed and used in various places.

In a conventional display system, when a large amount of data is stored over a long period of time, a process of extracting necessary data and displaying trend data is very complicated, so that it takes a long time to display the data or the display process is difficult. In the case of a monitoring system for displaying and monitoring various trend data of a plurality of plants, there is a problem that the system configuration is complicated and processing is complicated.

Therefore, the present applicant saves time-series data on a recording medium, reads out time-series data for display processing and expands it on a memory, and transfers time-series data via a network. In this case, a technology has been already filed for reducing the amount of data to be handled as much as possible and for increasing the speed of processing related to access to time-series data by enabling efficient processing (Japanese Patent Laid-Open No. 2000-48047).

Specifically, time series data of an arbitrary sampling period ΔT0 for an arbitrary object is stored, and a time series data of a sampling period ΔTi (i is an integer of 1 or more) longer than the sampling period ΔT0 for the object is stored. The data is stored and the sampling period ΔT
i. repeating the operation of storing the time-series data of at least one or more times, and storing the time-series data of a plurality of sampling periods in a recording medium in a hierarchically associated state;
And any sampling period ΔT0 for any object
Is extracted as basic data, data of a phase 0 based on a predetermined time and a sampling period n × ΔT0 (n is a power of 2), and a phase n / 2 ^m × based on the predetermined time. ΔT0, sampling period n
/ 2 ^m-1 × ΔT0 (m is an integer of 1 or more)
It is characterized in that the time-series data of a plurality of sampling periods are hierarchically arranged, and the hierarchically arranged time-series data is stored in a recording medium.

[0006]

According to the above technique, the amount of data to be handled can be reduced, and efficient data processing and display processing can be performed. Therefore, the processing related to access to time-series data is speeded up. However, since those time series data can only be confirmed on a desktop terminal connected to a wired network such as a personal computer,
If there is no desktop terminal near the plant, there is a problem that the worker has to return to an operation room or the like where the desktop terminal is located and check the time-series data.

On the other hand, in recent years, a portable telephone such as a portable telephone equipped with a browser function, a portable telephone such as a PHS (Personal Handyphone System), and a system in which the portable telephone is connected to information equipment such as a small computer called a mobile ( With the popularization of portable terminals (hereinafter collectively referred to as portable terminals), various display systems for acquiring and displaying various data using portable terminals have been proposed. However, when trying to display a large amount of data such as trend data, the data processing performed before transmission to the mobile terminal becomes complicated, and furthermore, processing for accurate display on a small screen is required.

For example, when displaying time-series data sampled at a time period in a long-term trend such as one year or five years, a display form of the display unit is selected from a large number of data in a corresponding period. For example, it is necessary to thin out and display the data to the number of data corresponding to the number of displayable dots). However, in the conventional display system, since all the time-series data is read once and necessary data is thinned out, it takes a long time for processing, and there is a problem that the display cannot be performed in some cases.

The present invention has been made in view of the above circumstances, and aims to improve the efficiency of processing relating to access to time-series data from a portable terminal and optimize display of read-out time-series data and the like on the portable terminal. The purpose is to provide a time-series database system that can be used.

[0010]

A time-series database system according to the present invention stores time-series data at a plurality of sampling periods in a recording medium (database 6) in a hierarchically associated state, and stores the time-series data in the recording medium. The stored time-series data is appropriately selected and read out from the time-series data of a plurality of sampling periods in response to the read request, and the read time-series data is provided via a mobile terminal having a browser function via the Internet (mobile terminal 4) In the time-series database system that can be displayed in (4), an Internet connection control means (Web server 2) for enabling Internet connection with the mobile terminal, and storing in the storage medium in response to a read request from the mobile terminal Out of time-series data of a plurality of sampling periods, which is suitable for display on the portable terminal. Obtains selects time-series data having a sampling period and converts the time-series data acquired viewable file format to the mobile terminal,
Data display control means (data display control unit 1) to be supplied to the Internet connection control means.

[0011] In the time-series database system having the above-described configuration, the time-series data of a predetermined optimum sampling period suitable for the display form of the display screen of the portable terminal is selected from the time-series data of the plurality of sampling periods stored in the recording medium. Since data can be selected and read, necessary data read processing is efficiently executed. As a result, the read time-series data can be displayed at high speed without being rejected due to, for example, inability to display on the portable terminal.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic configuration diagram showing a time-series database system. As shown in FIG. 1, the server computer 12 integrates a data display control unit 1, a Web server 2, a data server 5, a database 6, and a data storage control unit 7. A general-purpose personal computer or workstation can be used as the server computer. The time-series data can be monitored by the display unit 11. Also, the monitoring can be performed from the display unit 11 of the client computer 13 connected to the network.

In the system shown in FIG. 1, with respect to the processing method of storing and processing the time-series data and reading and transferring the stored time-series data, the storage of the time-series data filed by the present applicant has been described. A method, a method of processing time-series data, and a method using a time-series data system, a method of processing time-series data, and a time-series data processing system (see JP-A-2000-48047). The configuration will be described.

First, data storage will be described. The sensor 9 detects values indicating various operating conditions such as the temperature and flow rate of each part in the industrial plant 8, and the measured values are converted into digital data by the data converter 10. The measurement data sent from the data conversion device 10 in a time series at an arbitrary sampling period ΔT0 is hierarchically stored in the database 6 by the data storage control unit 7 functioning as data storage control means.

When storing a large amount of acquired time-series data (which may be raw data acquired from a plant or data which has been subjected to some processing) in the database 6, the data storage control unit 7 By the control, the input time-series data of the sampling period ΔT0 is stored in series as it is, and the period ΔT longer than ΔT0 is stored.
The data is converted into time-series data having a plurality of sampling periods of 1 to ΔTm, and each is stored independently in a hierarchical manner according to the sampling period. The time-series data of each sampling cycle is associated with data of at least one other hierarchy, such as the latest upper / lower hierarchy. That is, one layer of data has a corresponding relationship with at least one other layer of data. As the representative value obtained by the above conversion, a value such as an arithmetic average value or an intermediate value of the time-series data in the corresponding period may be calculated and applied.

Although the time-series data of a plurality of sampling periods conceptually has a hierarchical structure, for example, each is recorded as a file on a recording medium. Note that the time-series data of one sampling cycle may be divided into a plurality of files and recorded. As for the association between the data of each layer, the data storage control unit 7 for managing these time-series data may have linkable information such as time information, tag information, and file information as management information. However, each time series data itself may have linkable information.
Further, the time-series data to be stored may be recorded in a state where the data is compressed using, for example, a known differential compression method.

The time-series data is not limited to data on industrial plants, but may be any time-series data such as stock prices, changes in commodity prices, and data on medical measuring instruments. As the database 6, various media such as a magnetic disk such as a hard disk, a magneto-optical disk, an optical disk, and a magnetic tape can be used.

Next, processing for reading data from the hierarchical time-series database stored as described above will be described. When a data read request is given to the hierarchically stored time-series data, the data server 5 functioning as a data read control unit determines which sampling cycle is optimal for reading, and the data server 5, a data selection control unit (not shown) accesses and reads out a time-series data file of the optimum sampling period. The read time-series data is transferred to the data server 5 which also functions as data transfer means.
Is transferred to the data display control unit 1. Here, how the data server 5 determines the optimum sampling period may be set as necessary. For example, the data server 5 may include resolution information in a data read request transmitted from the mobile terminal 4. By doing so, the data display control unit makes a determination based on this information.

Here, a specific description will be given with reference to an example of hierarchically related data. This data is stored in layers 0 to n
It is assumed that there are multiple layers as follows. Tier 0 has raw data. Layer 1 takes out ten raw data of layer 0 and divides them into groups, and has an average value of each group. Therefore, the number of data is 1/10 of that of layer 0
It has become. Therefore, layer 2 has 1/10 the data number of layer 0. Hereinafter, similarly, the hierarchy n has data of 1/10 of the data of the hierarchy (n-1).

On the other hand, for example, since the X-axis resolution of a graph displayed in i-mode (trade name of NTT DOCOMO) is 93, one graph is formed by connecting 93 or less points with a line. . Assuming that the sampling period of a certain measurement point is 1 minute, the raw data is stored in the hierarchy 0, so that 1
Assuming that the data for 0 days is 14,400 data in 10 days × 24 hours × 60 minutes. At this time, layer 1 is layer 0
Has 1440 data of 1/10 of the
The layer 3 has four data, and the layer 3 has fourteen data. Therefore, assuming that the data display control unit 1 has requested the data server 5 "Please provide 93 data for 10 days from A to (A + 9)." Is selected, that is, the hierarchy 2 having the number of data closest to the above, and 144 data are transmitted to the data display control unit 1. The data display control unit 1 extracts 93 data items from the received 144 data items in the order closer to the sampling point and creates a graph.

A system for displaying time-series data on a portable terminal, which functions in cooperation with the basic configuration of a time-series database system for storing, reading and transferring time-series data as described above, and data The processing flow will be specifically described.

As shown in FIG. 1, the server computer 12
Is a data display control unit 1 functioning as a data display control unit, in addition to a basic database system configuration such as a data server 5, a database 6, and a data storage control unit 7 functioning as a data read control unit. It has a Web server 2 functioning as a means. The Web server 2 is an ISDN (Integrated Server)
The mobile terminal 4 is connected to a base station 3 that accommodates the mobile terminal 4 within a service area via a public line such as a vice digital network) and the Internet. The base station 3 is a communication carrier such as Nippon Telegraph and Telephone Corporation, for example, and has a mobile phone network and a function as an Internet connection provider. The mobile terminal 4 has a WWW (World Wide Web) browser function.

When a display request is received from the portable terminal, processing such as selection of a plant or a measurement point, a transfer request of time-series data, graphing of time-series data, conversion into a file that can be displayed on the portable terminal, and the like are performed. Will be These processes are executed by the data display control unit 1 according to a data display control procedure.

FIG. 2 shows a procedure of the trend display executed by the data display control unit 1. First, when a trend display request is received from the mobile terminal 4 via the Web server 2 (step S1), a plant selection screen is generated according to the number of plants registered in advance and transferred to the mobile terminal 4 (step S2). Next, when a plant designation is received from the mobile terminal 4 (step S3), a selection screen for selecting a group in the plant is generated and transferred in step S4. Further, when the group designation is received from the mobile terminal 4 (step S5), a selection screen for selecting the position of the measurement point in the group (hereinafter, referred to as a channel) is generated and transferred in step S6. The measured value of each channel is also displayed on the channel selection screen. Next, in step S7, it is determined whether or not to set a period of the trend graph. If a channel designation is received from the mobile terminal 4 without setting a period (step S8), the trend graph of the corresponding channel is set in step S9. Generate and transfer an image file. If the user wants to set the period of the trend graph, the process branches at step S7 and a display request for the period setting screen is made at step S10. At step S11, an image file of the trend graph for the corresponding period is generated and transferred.

Next, each screen display on the portable terminal 4 will be described with reference to a flowchart of a display procedure and a diagram showing an actual display screen.

FIG. 3 is a flowchart showing a procedure for displaying the plant selection screen. In step S12, when the display request of the plant selection screen is received from the mobile terminal 4 through the Web server 2, the data server 5 reads the Internet address of the plant registered in the data display control procedure of the data display control unit 1 (step S1).
3) Based on that, the file of the plant selection screen is HTM
L (step S14), and transfers the created file to the portable terminal 4 via the Web server 2 (step S15). At this time, the display screen of the mobile terminal 4
A menu screen as shown in FIG. 8A is displayed. In addition,
The Internet address of each plant referred to by the data display control procedure is stored in a file on a recording medium (not shown) in the server computer 12 in advance.

FIG. 4 is a flowchart showing a procedure for displaying a group selection screen. In step S16, when the selected plant name is received from the mobile terminal 4 via the Web server 2, the connection with the data server 5 of the specified plant is established (step S17). FIG.
In the system configuration diagram of FIG. 1, only one data server 5 is shown for simplification, but a plurality of data servers can be connected. In this case, plant selection is
This means that a predetermined data server is selected by designating the Internet address of the data server from a plurality of data servers (the same applies to the following description). Thereafter, the data server 5 requests the list of group names in the plant from the data server 5 (step S18), and the data server 5 reads the list of group names registered in the plant and transmits the list to the data display control unit 1. The data display control unit 1 receives this (step S19).
Based on that, the file of the group selection screen is converted to HTML (Hy
The file is created using a description language such as Per Text MarkUp Language (Step S20), and the created file is transferred to the portable terminal 4 through the Web server 2 (Step 21).
At this time, a menu screen as shown in FIG. 8B is displayed on the display screen of the mobile terminal 4.

FIG. 5 is a flowchart showing a procedure for displaying the channel selection screen. When the selected group name is received from the portable terminal 4 through the Web server 2 in step S22, the Internet connection is established with the data server 5 of the plant already specified (step S23).
Thereafter, the data server 5 requests the list of channels in the group to the data server 5 (step S24), and the data server 5 reads out the list of registered channels and transmits the list to the data display control unit 1, and the data display control unit 1 receives this (step S25). Further, the current measurement value of each channel is requested to the data server 5 (step S26), and the data display control unit 1 receives the current measurement value (step S27). Based on that, the screen file showing the channel selection and the current measurement value is converted to HT
It is created using ML (step S28). The created file is transferred to the portable terminal 4 through the Web server 2 (Step 29). At this time, a menu screen as shown in FIG. 8C is displayed on the display screen of the mobile terminal 4.

FIG. 6 is a flowchart showing a display procedure from the channel selection screen to the trend graph display screen. In step S30, the mobile terminal 4 sends the Web server 2
When the selected channel name is received through, an Internet connection is established with the data server 5 of the plant already specified (step S31). After that, it requests the data server 5 for time-series data of the designated channel in the corresponding period (step S32). The data server 5 functioning as a data read control unit selects time series data of a sampling cycle most suitable for the display mode of the display screen of the portable terminal and transfers the data to the data display control unit 1 in accordance with the set period (step). S33). Next, a graph is created based on the time-series data transferred to the data display control unit 1 (step S34). At this time, if the data amount is too large to be displayed on the screen, the data is deleted.
The created graph is converted into an image file by the data display control unit 1 and output to a recording medium (not shown) in the server computer 12 (step S35).
Next, the data display control unit 1 creates an HTML file linked to the image file (step S3).
6), is transferred to the portable terminal 4 through the Web server 2 (step S37). At this time, a menu screen as shown in FIG. 8D is displayed on the display screen of the mobile terminal 4.

Here, the selection of the time-series data of the optimum sampling period performed by the data server 5 functioning as the data read control means in step S33 will be described using a specific example. For example, when the display period is set to 20 days, the number of data in the corresponding period is 20 when the sampling period is 1 day, 40, 6 when the sampling period is 12 hours.
The number of data is different in the same period, such as 80 in time and 480 in 1 hour. In the method for storing or processing time-series data used in the present embodiment, time-series data having a plurality of different sampling periods as described above is stored in a recording medium in a hierarchically associated state. When the trend data is taken into the mobile terminal, in the above example, the number of dots that can be displayed in the horizontal axis direction of the display screen of the mobile terminal and the time-series data of the sampling cycle in which the number of sampling data in the corresponding period is the closest are selected and read. . As described above, in response to the read request by the data server 5 in response to the display request of the time-series data from the mobile terminal, the data of the predetermined optimal sampling period suitable for the display form such as an arbitrary time scale is selected. By reading, trend data on an arbitrary time scale from seconds to years can be instantaneously displayed. Further, in such a processing method, even if the set period is long, there is no need to thin out the data after reading all the time-series data, and a sufficient and sufficient number of time-series Since only the data needs to be read from the time-series data at an appropriate sampling period, the amount of data to be handled is small, processing can be performed efficiently, and processing relating to access to the time-series data can be speeded up.

In the setting of the period, the start and end times are entered in the year, month, day, hour, minute, and second. When the period is not set, a data request is made by a processing method designated in advance (default setting). . In the present embodiment, when the trend graph is displayed as it is from the channel selection screen, the setting is made so as to determine that the display is not performed for the period setting. In the default setting, the end time is set to the current time, the start time is not specified, and the time-series data at the lowest level of the hierarchy is selected. That is, the number of time-series data having the shortest sampling period in the hierarchy is transmitted so as to be optimal for the display mode of the mobile terminal 4. The default settings can be changed as needed.

FIG. 7 is a flowchart showing a display procedure from the period setting screen to the trend graph display screen.
Upon receiving the display request for the period setting screen from the mobile terminal 4 through the Web server 2 in step S38, the data display control unit 1 transmits an HTML file of the period setting screen to the mobile terminal 4 (step S39). The user inputs and transmits the date, month, day, hour, minute, and second in the start column and the end column displayed on the display screen of the mobile terminal 4 (step S40). The data display control unit 1 requests time-series data of the designated channel in the corresponding set period (step S41). The flow of processing from step S41 to step S46 is based on steps S32 to S37 of the display procedure from the channel selection screen to the trend graph display screen.
The description is omitted because it is the same as that described above.

A series of processing procedures in the data display control unit 1 are stored in a data display control procedure, specifically, a recording medium (not shown) in the server computer 12 as a program.

In this embodiment, HT is used as the description language.
Although the ML is used, the description may be performed in another description language, or another program may be incorporated in the description and executed by a browser application. The image file has a file format compatible with the mobile terminal.

As shown in FIG. 8, options are displayed on the portable terminal 4 in the form of icons, and a predetermined trend graph is displayed simply by inputting a key of a corresponding number in the order of plant, group, channel. It has become so. Therefore, the operation is simple, and the part for which the trend data is to be confirmed can be easily specified.

As described above, by independently storing time-series data of a plurality of sampling periods in an associated state, optimal data can be easily selected and read in response to a data display request from a portable terminal. I can put it out. As a result, unnecessary data reading processing can be prevented, and since there is no need to thin out data with a fine sampling cycle,
Processing can be executed efficiently and at high speed. Therefore, it can respond to various data display requests at high speed,
For example, it is also possible to instantaneously switch trend displays of different time scales. In addition, in the case of the system configuration as described above, it is not necessary to provide a dedicated display program or display means in the mobile terminal, and the trend display system can be easily configured using a general-purpose mobile terminal. Display becomes possible. Further, in the data display control procedure, since a specific measurement point can be accurately specified by simple key input, it is possible to improve user's workability and operability.

[0037]

As described above, according to the present invention, time-series data having a sampling period suitable for display on a portable terminal is selected from time-series data having different sampling periods, so that a single operation can be performed. Since data suitable for display on the mobile terminal can be obtained, the processing related to access to the time-series data from the mobile terminal can be made more efficient, and the display of the read time-series data and the like on the mobile terminal can be optimized.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram showing a time-series database system according to an embodiment of the present invention.

FIG. 2 is a flowchart illustrating a processing procedure of a data display control unit.

FIG. 3 is a flowchart illustrating a display procedure of a plant selection screen among processing procedures of a data display control unit.

FIG. 4 is a flowchart showing a procedure for displaying a group selection screen among processing procedures of the data display control means.

FIG. 5 is a flowchart illustrating a display procedure of a channel selection screen among processing procedures of a data display control unit.

FIG. 6 is a flowchart showing a display procedure from a channel selection screen to a trend graph display screen among processing procedures of the data display control means.

FIG. 7 is a flowchart showing a display procedure from a period setting screen to a trend graph display screen among processing procedures of the data display control means.

FIG. 8 is a schematic diagram showing an example of a display screen of a mobile terminal.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Data display control part 2 Web server 3 Base station 4 Portable terminal 5 Data server 6 Database 7 Data storage control part 8 Industrial plant 9 Sensor 10 Data conversion device 11 Display means 12 Server computer 13 Client computer

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Ken Uemura 1-12-1, Yurakucho, Chiyoda-ku, Tokyo Asahi Glass Co., Ltd. F-term (reference) 5B069 AA18 BA04 LA05 5H223 AA01 CC08 DD03 DD05 DD07 EE30 FF03 5K101 LL12 NN01 NN18 NN21

Claims (1)

[Claims] 1. A time-series data having a plurality of sampling periods is stored in a recording medium in a hierarchically associated state, and the time-series data stored in the recording medium is read out at a plurality of sampling periods in response to a read request. A time-series database system capable of appropriately selecting and reading out of the series data and displaying the read time-series data on a mobile terminal having a browser function via the Internet; enabling Internet connection with the mobile terminal; Internet connection control means, in response to a read request from the portable terminal, a time series having a sampling cycle suitable for display on the portable terminal, from time series data of a plurality of sampling cycles stored in the storage medium. Select and retrieve data,
A data display control unit for converting the acquired time-series data into a file format that can be displayed on the portable terminal and supplying the converted data to the Internet connection control unit.