JP2003139575A - Data display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To properly grasp the outline and detail of data by efficiently displaying data obtained from all external apparatuses in a limited display region. SOLUTION: This data display device is used for graphically displaying respective data obtained from a plurality of external apparatuses M1-M4. The outline of the data relative to the respective external apparatuses M1-M4 is graphically displayed as an initial image plane G1, and when the specific external apparatus M1 is designated, the detail of data relative to the specific external apparatus M1 is graphically displayed as a secondary image plane G2 instead of the initial image plane.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data display device for simultaneously displaying a plurality of data.

[0002]

2. Description of the Related Art A conventional data display device displays, for example, the signal transmission states measured by a plurality of measurement target transmission lines in each measurement module (external device) as follows. That is, all the measurement data necessary for display is acquired from all the measurement modules, and then the display position of the measurement data of the first measurement module is determined based on the absolute display position information and the display area size stored in advance and the graph is displayed. In addition, the display position of the measurement data of the second measurement module is displayed above
Set the graph so that it does not overlap with the measurement data of the measurement module of. The measurement data of the third and subsequent measurement modules are also set in positions so that the measurement data previously displayed do not overlap with each other, and the graphs are sequentially displayed.

[0003]

By the way, in the above data display method, when the number of measurement modules n and the number of measurement items m of each measurement module increase, it is difficult to graphically display all the measurement data. . Even if all measurement data can be displayed as a graph, a large number of graphs will be displayed on the screen, so you can accurately understand the values of measurement items and their changes over time for each measurement module. Is extremely difficult.

The present invention has been made in view of the above-mentioned problems. By efficiently displaying data acquired from all external devices in a limited display area, the outline and details of the data can be accurately grasped. The purpose is to do.

[0005]

In order to achieve the above object, the present invention provides, as a first means, a data display device for displaying each data obtained from a plurality of external devices as a graph, wherein each external device is a data display device. The means for displaying the outline of the data on the graph as an initial screen and displaying the details of the data on the specific external device as a secondary screen instead of the initial screen when a specific external device is designated is adopted. .

As the second means, in the first means, the external device is a measuring module for measuring the signal transmission state of the transmission path to be measured, and the data is in the signal transmission state. .

As a third means, in the above-mentioned second means, a means for displaying an abnormal occurrence time of signal transmission on the measurement object transmission line in a graph for each external device is adopted as the initial screen.

As a fourth means, in the second or third means, the secondary screen employs a means for displaying a graph of an abnormality occurrence time for each structural unit of the signal transmitted through the measurement target transmission line. .

As a fifth means, in the fourth means, when a constituent unit in which an abnormality has occurred is designated on the secondary screen, in addition to displaying a graph of the occurrence time of the abnormality, also displaying the number of occurrences of the abnormality in a graph. To adopt.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of a data display device according to the present invention will be described below with reference to the drawings.

FIG. 1 is a system configuration diagram showing the functional configuration of this embodiment. In FIG. 1, reference numeral H is a data display device, M is a transmission line measuring device, and N is a communication line (for example,
GP-IB, TCP / IP, etc.). The data display device H includes a data processing device 1, a display processing unit 2, a display device 3,
The communication device 4, the input device 5, and the storage device 6 are included. On the other hand, the transmission line measuring device M has a measuring module M1.
.About.M4 (external device), a module controller 7, a communication controller 8 and a communication device 9, and is connected to a data display device H by a communication path N.

The transmission line measuring device M will be described first. The measurement modules M1 to M4 measure the signal transmission states of the measurement target transmission lines S1 to S4 (for example, optical fibers) assigned to each of them, and the modules are used as measurement data. Control unit 6
Output to. That is, the first measurement module M1
The signal transmission state of the measurement target transmission line S1 is measured, and the signal transmission state is measured by the device number 1 (that is, the measurement target transmission line S1).
The measurement data D1 associated with 1) is output to the module controller 7.

The second measuring module M2 measures the signal transmission state of the measurement target transmission line S2, and indicates the signal transmission state of its own device number 2 (that is, the measurement target transmission line S2).
Module controller 7 as measurement data D2 associated with
The third measurement module M3 measures the signal transmission state of the measurement target transmission line S3 and outputs the signal transmission state as the measurement data D3 associated with the device number 3 (that is, the measurement target transmission line S3). The signal is output to the module control unit 7, and the fourth measurement module M4 measures the signal transmission state of the measurement target transmission line S4 and associates the signal transmission state with its own device number 4 (that is, the measurement target transmission line S4). The measured data D4 is output to the module controller 7.

Here, the measurement item of each of the measurement modules M1 to M4 is an abnormality of the transmission signal in each of the transmission lines S1 to S4 to be measured, and more specifically, the four constituent units B1 and B2 constituting the transmission signal. , MS-REI, HP-REI, the time of occurrence of abnormality (time after the start of measurement) and the number of times of occurrence of abnormality. Each measurement module M1 to M4 has a unit B
When an abnormality is detected with respect to 1, B2, MS-REI, and HP-REI, the abnormality occurrence time and the abnormality occurrence count are output to the module controller 7 as measurement data D1 to D4. In addition,
In this embodiment, the four measurement modules M1 ...
Although it has M4, the number of measurement modules is not limited to four and may be more.

The module control section 7 controls the measurement operation of each of the measurement modules M1 to M4, and each measurement data D input from each of the measurement modules M1 to M4.
1 to D4 are output to the communication control unit 8. The communication control unit 8 controls the transmission of each measurement data D1 to D4 by the communication device 9. The communication device 9 transmits each measurement data D1 to D4 to the communication device 4 under the control of the communication control unit 8.

On the other hand, the data processing device 1 in the data display device H is an arithmetic device that operates based on a data processing program stored in the storage device 6 in advance, and controls the overall operation of the data display device H. Further, the data processing device 1 processes the information of the measurement data D1 to D4 etc. based on the data processing program to display an initial screen for graphically displaying the outline state of each of the measurement object transmission lines S1 to S4. Display data and transmission lines S1 to S4 to be measured
The display data for the secondary screen for displaying the detailed state of the graph is generated and output to the display processing unit 2. The details of the processing operation of the data processing device 1 will be described later.

The display processing unit 2 converts the initial screen display data or the secondary screen display data into image data and outputs the image data to the display device 3. The display device 3 displays the initial screen or the secondary screen based on this image data.
The communication device 4 communicates with the communication device 9 of the transmission path measuring device M, and the communication device 9 transmits each measurement data D.
1 to D4 are received and output to the data processing device 1.

The input device 5 is for inputting the designation information of the initial screen or the secondary screen and the instruction information regarding each operation of the transmission path measuring device M to the data processing device 1, and is, for example, a keyboard or a mouse. The storage device 6 stores the above-mentioned data processing program and stores each measurement data D.
1 to D4 for each measurement module M1 to M4, that is, device number 1
~ 4 are classified and sequentially stored and stored.

Next, the operation of this embodiment thus constructed will be described in detail with reference to the flow chart shown in FIG. Note that this flowchart shows the processing procedure of the data processing device 1 based on the data processing program.

First, when a measurement start instruction is input to the input device 5, the data processing device 1 transmits this measurement start instruction to the transmission path measurement device M via the communication device 4 and the communication path N. When the communication device 9 receives the measurement start instruction, the communication control unit 8 of the transmission path measurement device M transfers the measurement start instruction to the module control unit 7. When the measurement start instruction is input in this way, the module control 7 outputs the measurement start instruction to each of the measurement modules M1 to M4. As a result, each measurement module M1 to M4 causes each measurement target transmission line S1 to be measured. The measurement of the signal transmission state of S4 is started. The measurement interval of the signal transmission state in each measurement module M1 to M4 is, for example, about 1 second.

That is, each measurement module M1 to M4 is
When the measurement start instruction is input, each measurement target transmission line S1 ...
Regarding S4, constituent units B1, B2, MS-R of the transmission signal
The measurement of the abnormality occurrence time and the abnormality occurrence frequency in EI and HP-REI is started.

On the other hand, the data processing device 1 receives the measurement modules M1 to M4 from the transmission line measuring device M via the communication device 4.
The measurement data D1 to D4 are sequentially acquired at a predetermined time interval (step S1), and the measurement modules M1 to M4 are classified and sequentially stored / stored in the storage device 6 (step S2). That is, a plurality of pieces of measurement data D1 to D4 acquired by the measurement modules M1 to M4 are accumulated in the storage device 6 as time elapses from the start of measurement.

Further, the data processing device 1 monitors whether or not each of the measurement data D1 to D4 indicates an abnormality in each of the measurement object transmission lines S1 to S4 (step S3). When the occurrence of the abnormality is detected (in the case of Yes), the constituent units B1, B2, MS-REI, HP-RE in which the abnormality occurs in the measurement module (for example, the measurement module M1) in which the abnormality occurs.
An error flag is set to I (step S4), and all measurement data D1 to D4 are read from the storage device 6 (step S4).
5) On the other hand, if no abnormality has occurred (No)
In step S5, all measurement data is directly read from the storage device 6.

When the data processing device 1 reads out all the measurement data D1 to D4 from the storage device 6 in this way, the display data for the initial screen and the display data for the secondary screen are generated based on this (step S6). ), The former initial screen display data is output to the display processing unit 2 (step S7). As a result, the display processing unit 2 converts the display data for the initial screen into image data and outputs the image data to the display device 3, and the initial screen G1 shown in FIG. 3 is displayed on the display device 3.

On this initial screen G1, a graph a1 is displayed, in which the horizontal axis represents the time after the start of measurement, and the vertical axis represents the abnormalities (Errors) of the device numbers 1 to 4 of the respective measurement modules M1 to M4. Operation buttons b1 to b4 for instructing the display of the secondary screen are displayed for each of the device numbers 1 to 4. Graph a1 is
As an example, from the measurement target transmission line S1 which is the measurement target of the device number 1 (measurement module M1), 30 seconds after the measurement is started, the measurement target transmission line S3 which is the measurement target of the device number 3 (measurement module M3) is measured from the measurement start This indicates that some abnormality has occurred 50 seconds later and 20 seconds after the start of measurement on the measurement target transmission line S4 that is the measurement target of the device number 4 (measurement module M4).

When the operation button b1 is operated on the initial screen G1 (step S8), the data processor 1 outputs the secondary screen display data to the display processor 2 (step S9). ), The secondary screen G2 (see FIG. 4) is displayed on the display device 3 instead of the initial screen G1. The display instruction of the secondary screen G2 instead of the initial screen G1 can be input to the data processing device 1 from the input device 5 as well.

As shown in FIG. 4, the secondary screen G2 shows details regarding the abnormality of the transmission path S1 to be measured, that is, each constituent unit B1, B2, MS-RE of the transmission signal of the transmission path S1 to be measured.
Graph c1 showing at which point in time I, HP-REI the abnormality occurred, and each structural unit B1, B2, MS-RE
Operation buttons d1 to d4 for instructing the display of the number of occurrences of abnormality for I and HP-REI are displayed. This figure shows that an abnormality has occurred in the structural unit B2 of the measurement target transmission line S1 30 seconds after the start of measurement.
A structural unit B2 in which an abnormality has occurred on such a secondary screen G2
When the operation button d2 of is operated, a graph c2 showing the number of times of occurrence of an abnormality in the structural unit B2 is additionally displayed with the secondary screen expanded downward.

By the display of the initial screen G1 and the secondary screen G2 as described above, the outline and details of the abnormal state of each of the transmission lines S1 to S4 to be measured are grasped, and when the measurement end instruction is inputted from the input device 5 (step S10), while the data processing apparatus 1 finishes all the processes, when the measurement continuation instruction is input (step S10), the process is returned to step S1 and the above-described processes are repeated.

According to this embodiment, the initial screen G1 is used to grasp the outline of the abnormal states of the respective measurement target transmission lines S1 to S4, and the secondary screen G2 displayed in place of the initial screen G1 is used to transmit each measurement target transmission. It is possible to grasp the details regarding the abnormal state of the roads S1 to S4. Also, the initial screen G1
Since the secondary screen G2 is displayed instead, the limited display area on the display device 3 can be efficiently used.

FIG. 5 shows the entire display area of the display device 3. The display device 3 includes not only the initial screen G1 and the secondary screen G2 based on the above-mentioned measurement data D1 to D4 but also a setting screen G3 to which various setting information such as measurement conditions is displayed.
G5 is displayed, and therefore measurement data D1 to D4
In addition to that, a lot of information is displayed. In such a display device 3, each measurement data D1 to D4 is displayed on the initial screen G1.
And the secondary screen G2, it is possible to display the outline and details of each of the measurement target transmission lines S1 to S4 in an extremely easy-to-understand manner while suppressing the display area for each of the measurement data D1 to D4.

[0031]

As described above, according to the present invention,
The outline of the data related to each external device is displayed in a graph as an initial screen, and when a specific external device is specified, the details of the data related to the specific external device are displayed in a graph as a secondary screen instead of the initial screen. Data acquired from an external device can be efficiently displayed in a limited display area, and an outline and details of the data can be easily grasped.

[Brief description of drawings]

FIG. 1 is a system configuration diagram of an embodiment of the present invention.

FIG. 2 is a flowchart showing a processing procedure of the data processing device according to the embodiment of the present invention.

FIG. 3 is a display example of an initial screen G1 according to the embodiment of the present invention.

FIG. 4 is a display example of a secondary screen G2 according to the embodiment of the present invention.

FIG. 5 is a diagram showing an entire display area according to an embodiment of the present invention.

[Explanation of symbols]

H: Data display device M: Transmission line measuring device M1 to M4 …… Measurement module (external device) N ... communication path S1 to S4 ... Transmission line to be measured 1 ... Data processing device 2 ... Display processing unit 3 ... Display device 4 ... Communication device 5: Input device 6 ... Storage device 7: Module control unit 8 ... Communication control unit 9: Communication device G1 …… Initial screen G2 …… Secondary screen a1, c1, c2 ... Graph b1 to b4, d1 to d4 ... Operation buttons

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Claims (5)

[Claims] 1. A data display device for displaying each data acquired from a plurality of external devices (M1 to M4) as a graph, wherein an outline of data regarding each external device (M1 to M4) is displayed as an initial screen (G1). Display and specify external equipment (M1)
Is specified, the details of the data regarding the specific external device (M1) are replaced with the initial screen and the secondary screen (G2) is displayed.
A data display device characterized by displaying as a graph. 2. The data display device according to claim 1, wherein the external device (M1 to M4) is a measurement module for measuring a signal transmission state of a measurement target transmission line, and data is the signal transmission state. . 3. The initial screen (G1) displays the time when a signal transmission abnormality occurs on the measurement target transmission line for each external device (M1 to M).
The data display device according to claim 2, wherein a graph is displayed for each 4). 4. The data display device according to claim 2 or 3, wherein the secondary screen (G2) graphically displays the abnormality occurrence time for each constituent unit of the signal transmitted through the measurement target transmission line. 5. The secondary screen (G2), when a structural unit in which an abnormality has occurred is designated, the number of times of occurrence of the abnormality is also displayed in a graph in addition to the graph of the time of the occurrence of the abnormality. Data display device.