JPH06141029A - Communication network fault display system - Google Patents

Abstract

PURPOSE:To automatically specify and display a screen group expressing the whole content and detail of a fault and to quickly recognize faulty status by an operator in a network management display system. CONSTITUTION:The summary screen/part screen of a generated fault and an alarm musical interval are decided by utilizing a CRT 111 on which a screen of fault is displayed, a buzzer ringing device 114 from which an alarm tone is issued, a network map group, and a display information data base 104 on which the correspondence relation of a communication network constituent and display information is registered. The screen group that goes to the focus of the generated fault is automatically displayed and a buzzer is rung by program memory 110 in which program groups 106-109 to perform screen display control are stored. Therefore, it is possible to dispense with work to retrieve a fault corresponding screen when the fault occurs by the operator and to immediately recognize the whole content and detail of the faulty status without missing the occurrence of the fault.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a failure display method in a network management display system, and more specifically, it collects and manages information from a communication network including exchanges, data multiplexers, etc., and displays the status of the communication network. In a network management display system for displaying on a screen, the present invention relates to a fault automatic focus display of a communication network on a hierarchical network map group in which a communication network is pseudo-screen-displayed by a picture, and particularly to a multiple fault auto focus display system.

[0002]

2. Description of the Related Art A network that collects the configuration and operation information of a communication network in order to efficiently operate and maintain the communication network and displays the operation status on a map screen simulating the communication network of a display device based on the information. A management display system is provided. In particular, since the communication network spreads over a wide area and is large-scale, a technique for displaying the status using a network map group hierarchically divided according to geographical division, management division, degree of detail, etc. E-, network magazine, March (1991)
Year) 10th to 15th pages (IEEE, NetworkMagazin
e, March (1991) PP10-15) and Hurlet Packer Journal, April (1990) pp. 60-65 (HEWLETT-PACKARD JOURNAL, APRI
L (1990) PP60-65).

[0003]

However, in the above-mentioned prior art, when a failure occurs in the communication network, the map necessary for grasping the failure status from the hierarchical network map group, that is, the failure error that is occurring. Network map and one-by-one representation of the entire group of groups at the most detailed level
There is a problem that the operator himself / herself needs to search the screen by utilizing the zoom function or the like when extracting the network map expressing the generation site of one alarm.

In addition, when a specific network map is being zoomed when an error occurs and an additional error occurs in another area,
The displayed map screen does not display the corresponding fault, and even if the operator is notified by a fault message, etc., the operator reads the message and operates the corresponding map screen that expresses the fault condition. There is a problem that you must search by yourself.

Furthermore, since the display elements represented by the top-level map are grouped and abstracted from the display elements represented by the lower-level map, the top-level map of the map hierarchy is fixed or operated. -It can be displayed on request,
Even if a failure status is displayed by color, such as the topmost display element as a representative, if there is a failure corresponding to a plurality of display elements that are lower than the common topmost display element, the number of failure occurrences,
Since the failure location cannot be expressed, the operator must search the map at an appropriate level of detail, which makes it difficult to grasp the failure status quickly.

An object of the present invention is to provide a fault display method using a hierarchical network map of a network management display system, in which the operator can instantly obtain the full details and details of the fault that has occurred without the operator searching the map. The purpose is to provide a means for automatically identifying an appropriate network map that can be recognized without omission from the hierarchical map group.

Another object of the present invention is to provide means capable of automatically updating a display map in response to a dynamic change in a failure situation such as additional occurrence of failure or recovery of failure in a communication network. It is in.

Another object of the present invention is to provide a fault autofocus display system capable of automatically displaying a map group which always captures the focus of a communication network fault condition.

[0009]

In order to achieve the above object, in the fault display system according to the present invention, the communication network is geographically /
In the case where layers are created according to the physical relationship, each level of the hierarchy is used as a map screen with different levels of abstraction, and the map screens related to the part where the failure occurs are displayed on a common screen. Storage means having data expressing the position of each map screen based on the hierarchical inclusion relation, and a failure part for specifying a map screen group corresponding to all failure parts occurring at the time of failure of the communication network A screen specifying means and a summary screen for specifying one upper screen, which is the most detailed level and includes all the map screen groups in which the failure has occurred, by using the data.
It is characterized by comprising a Mari screen specifying means.

[0010]

The function of specifying the map part corresponding to the part of the failure is specified by the means for specifying the part of failure, and the means for specifying the summary screen uses the data expressing the position of each map screen based on the hierarchical inclusion relationship between the screens. Since the summary screen is automatically specified, in response to dynamic changes in the failure status such as failure occurrence, additional failure occurrence, or recovery from it, the status of the overall failure overview and the status of individual failure points required by the operator can be immediately displayed. The focus can be displayed automatically. The means for controlling the display of the failure part screen and the summary screen should prioritize the summary screen and the failure part screen or control the display timing according to the number of allowable display screens obtained by dividing the common screen. You can

[0011]

Embodiments of the present invention will now be described with reference to the drawings. [Embodiment 1] First, a first embodiment of the present invention will be described.
FIG. 1 is a block diagram of an embodiment of a network management display system to which the fault autofocus display system of the present invention is applied. This system comprises a managed communication network 101 and a network management display system 102. The network management display system 102 collects alarm information about the constituent elements of the communication network 101, and an error control unit 103. -Data base 104 for storing frame information and display information, and data base 104
There is provided a work memory 105 for storing a calculation area and a result for a process of searching for more necessary information and temporarily storing it, or specifying a fault part screen / summary screen and determining an alarm pitch.

The network management display system 102 further includes, as a program memory 110, a failure information collection / management unit 106 for managing collection of alarm information from a communication network and registration / update in a database, and a failure. Occurrence / dynamic change, the failure display screen for selecting / updating a failure display / summary screen identification update processing unit 107, the alarm pitch determination processing unit for determining the pitch of the buzzer according to the number of failures and the importance 108, and a presenter for controlling generation, deletion, and updating of a display screen including a failure display screen and buzzer sounding timing / pitch change.
The operation control unit 109 is provided. In addition, a CRT 111 for displaying a map screen, a keyboard 112 for an operator to input an open / close / transition of the map screen, a mouse 113, and a buzzer sounding device for generating a buzzer sound. 114 and an I / O control unit 115 for controlling these inputs / outputs, and a CPU 116 for controlling input / output, memory, database access, and execution of each program.

Site map display element / component correspondence table 2 stored in the display information database 104
An example of 00 is shown in FIG. This table is a data structure of the network map screen group 300 that is hierarchized according to the inclusion relation of geographical and physical fields of view as shown in FIG. 201 is a component name in the alarm information, 20
2 is a display element ID corresponding to the component name, 203 is a map name, and 204 is a map hierarchy identifier.

FIG. 4 shows an example of the upper symbol / lower map correspondence table 400 stored in the display information database 104. This table is shown in Figure 5.
Display symbols (P
The correspondence information between the N1 and PN2) and the lower map screen (I, J) is defined. This table includes a corresponding site map screen 401 and a display site symbol ID 402.

Next, an example of the operation of the fault autofocus display method according to the present invention will be described with reference to FIGS.
FIG. 6 is an operation flow chart of the fault autofocus display processing when a fault occurs in the network management display system of FIG. First, when a failure occurs in the communication network 101, alarm information of the communication network (failure component name, failure importance) is notified to the communication control unit 103 of the network management display system 102, and this communication control unit is notified. The step 103 (6) of notifying the fault information collection / management unit 106 of the receipt of the alarm information
01).

The fault information collection / management unit 106 stores the alarm information in the display information database 104 and issues a fault display request to the presentation control unit 109 (602). Upon receiving this failure display request, the presentation control unit 109 issues a display screen selection determination request to the failure site / summary screen specific update processing unit 107 (603).

The faulty part / summary screen specific update processing unit 107 which has received the display screen selection decision request is shown in FIG. 2 which is stored in advance in the display information database 104 as shown in FIG. By referring to the correspondence table 200 (FIG. 2) between the definition display elements in the site map and the constituent elements of the communication network and the constituent element names in the generated alarm information (705), the corresponding information in the alarm information is referred to. Display element I corresponding to component name 201
D202 and the map name 20 that contains the display element
3. All the map hierarchy identifiers 204 (failure part screen) are extracted and stored in the work memory 105 (706).

Here, the value of the map hierarchy identifier 204 is
The hierarchical inclusion relationship between the map screens is represented by a hierarchical numerical expression as shown in FIG. For example, from the communication network, three pieces of alarm information can be obtained at the same time (failure component name = PBXN
o.1, Importance = Critical; Fault occurrence component name = WS
-04, Importance = Warning; Fault occurrence element name = PBXN
o.4, importance = Warning), map hierarchy identifier 1.2.2.1 for map name I, display element ID = SN1, map hierarchy for map name J from the corresponding table in FIG. Identifier 1.2.2.2, display element ID
= SN8, map hierarchy identifier 1.
2.1.1, display element ID = SN9 is obtained and stored in the work memory 105.

Next, the faulty part / summary screen specific update processing unit 107 is stored in the display information database 104 in advance, and the upper symbol / lower map correspondence table 400 as shown in FIG. Of the previous failure site screen
The Mali screen is obtained by extracting a continuous common part from the beginning for all the map hierarchy identifiers 204 of the failed part screen (707). However, in the case of a single failure, the part excluding the last numerical value of the map hierarchy identifier 204 is taken out and the map screen one level higher is obtained as the summary screen. Further, in the summary screen associated with the map name 401 including the display element ID corresponding to the failure component and the failure display element ID in the failure site screen from the upper symbol / lower map correspondence table 400 in FIG. The display symbol ID 402 of the above is specified and stored in the work memory 105.

For example, in the case of the above example, as shown in FIG. 8, three map hierarchy identifiers [1.2.2.1] and [1.
The common part of 2.1.1] and [1.2.2.2] is [1.
2], the screen C with the map hierarchy identifier = 1.2 becomes the failure summary screen 801. Also, the failure site screen 80
Map names I, J and H of 2, 803 and 804, upper map screens F and H corresponding to I and J from the correspondence table 400 of FIG. The display site symbol ID in the upper map screen (summary screen) C is L1 and L2 (708). After the above processing is completed, the failure part / summary screen specific update processing unit 1
Reference numeral 07 is a presentation control unit 10 that notifies the completion of processing.
Issue to 9.

Returning to FIG. 6, the presentation control unit 109 notifies the warning pitch determination processing unit 108 of the warning pitch determination processing request (605), and the warning pitch determination processing unit 108.
Is an alert stored in the display information database 104.
The pitch is determined by referring to the music information and performing a numerical operation based on the number of failures and the degree of importance. For example, the value S corresponding to the failure importance level is Critical = 5, Major = 4, Minor
= 3, Indeterminete = 2, Waring = 1, degree of failure occurrence N is single failure = 1, multiple failures (2-9) = 2, multiple failures (10 or more) = 3, When the maximum importance level S ′ is set, the pitch T is set to T = N × S ′ / 5, and if the value of T is 0 <T <1, the pitch of C (do) is 1
If ≦ T <2, pitch of E (Mi), and if 2 ≦ T ≦ 3, G
Correspond to (so). In the above example, the number of failures is 3, S
_{Since 1} = 5, S ₂ = 1 and S ₃ = 1 S ′ = 5, N = 2
When T = 2, the pitch of G is determined. The alarm pitch determination processing unit 108 stores the determined pitch in the work memory 105 and notifies the presentation control unit 109 of the determination completion (606).

The presentation control unit 109 is operated by the faulty part / summary screen specific update processing unit 107.
Fault site map name and server stored in memory 105
Read the marimap name and display information database 104
A more appropriate map screen is taken out and the I / O control unit 115 is requested to display the CRT. In addition, in the CRT display, the failure-corresponding display element and the site symbol in the map screen are displayed in different colors (red) from the failure-corresponding display element ID in the failure part map, and the buzzer sound of the buzzer sounding device 114 is output at the determined pitch. I / O control unit 115 is notified
(607).

Finally, the I / O control unit 115 uses the CRT1
A summary screen and a group of faulty part screens are displayed on the multi-window 11 and a buzzer sounding device 114 issues a buzzer sound. In the case of the previous example, for example, a multi-window display of four screens as shown in FIG. 9 is displayed, and a buzzer sound having a G pitch is issued (608).

FIG. 10 is an operation flow of the presentation control unit 109 corresponding to the operation flow of FIG. If there is a display request (step 801), a screen selection determination request is issued to the faulty part / summary screen specific update processing unit 107 (802), and an alarm pitch determination request is issued to the alarm pitch determination processing unit 108 (803). Next, both processing units 107,
Based on the determined contents of 108, the display method of the summary screen and the site screen group is determined (804). When a part of the failure is recovered (806), the display method of the relevant summary screen and body screen group is updated (807), and the I / O control unit 115 is requested to make the same change ( 8
08).

Next, an example of the operation of the fault autofocus display update process when the fault is recovered and an additional fault occurs will be described with reference to FIG. This operation is similar to that at the time of occurrence of a failure, but the presentation control unit 109 instructs the failure site / summary screen specific update processing unit 107 to display the summary screen based on the updated latest alarm information. A request is made to update the body part screen (802), and a change to the pitch is requested to the alarm pitch determination processing unit 108 (803). And both processing units 1
After obtaining the outputs of 07 and 108, the presentation control unit 109 replaces the already displayed summary screen with the updated summary screen (step 804), and if there is an additional failure, the corresponding part is displayed. The screen is additionally displayed on the CRT 111. If the failure is recovered, the relevant part screen being displayed is deleted in step 807.

Further, based on the changed pitch, the I / O control section 115 is notified to change and issue the buzzer sound of the buzzer sounding device 114 (808). For example, in the example of FIG. 8 described above, when the failure corresponding to the display element ID = SN9 is recovered, the summary screen is updated from the one showing the Kanto region to the one showing Tokyo as shown in FIG. At the same time, the screen of the failure site 1 is deleted and updated to the screen of only the failure sites 2 and 3 as shown in the figure. However, since the pitch T is 2 as in the case of occurrence of a failure, the pitch of the buzzer sound is not changed.

With the configuration and operation as described above, a summary screen showing the entire fault situation at a level of detail and a fault-corresponding part are displayed in response to a fault occurrence and a dynamic change in the fault situation. Since the system can automatically display and update the screen of the failure site, the operator can immediately recognize the failure status without the need to search the screen by the operator. Further, due to the change in the pitch of the buzzer sound or the like, even if the operator is far from the screen of the network management display system, the amount and importance of the obstacle can be recognized by hearing.

[Embodiment 2] Next, as a second embodiment of the present invention, when there are restrictions on the number of screens that can be displayed on the CRT, the failure screens are displayed in priority by the number that can be displayed, and the rest are operated by the operator. The case of displaying by intervention will be described with reference to FIGS. 12 and 13. FIG. 12 shows a modification of the display method determination process in step 804 of FIG.

The system configuration and basic operation are the same as in the case of the embodiment (1). In step 804 of FIG. 10, when the presentation control unit 109 displays the summary screen and the part screen group, the number of allowable display screens is over because there is an existing display screen (FIG. 12, 120
1), the summary screen is displayed, and then the displayable number of priorities is displayed in order of the failure part screen with the highest failure importance (120
2) Instruct the I / O controller 115 to display a message prompting the operator to erase the unnecessary screen (120)
3).

For example, in the case of the example described in the embodiment (1), the allowable number of display screens = 4, and two screens (screen X and screen Y) which are not failure screens are displayed in advance. As shown in the figure, the summary screen and the PBX No. that is the most important level (Critical) are displayed for the number of displayable screens 2. The part screen of the Ochanomizu site containing 1 is prioritized and displayed, and an unnecessary screen deletion message 1001 to the operator is displayed. When the operator erases unnecessary screens by the keyboard 112 or the mouse 113, the presentation control unit 109 causes the I / O control unit 115 to display the remaining faulty screen groups corresponding to the number of deleted screens. Request and display in priority.

With the configuration and operation as described above, even when the number of displayable screens is limited or a large number of failures occur, the failure screens can be displayed within the limited number of displays in descending order of importance. , Effective notification of failure can be made to the operator. Further, by prompting the operator to erase the unnecessary screen by the message notification, the failure notification can be performed without forcibly interrupting the operator's work before the failure.

[Third Embodiment] Next, as a third embodiment of the present invention, when there are a plurality of faults included in the lower level of the summary screen, the number of faults is displayed on the summary screen. ,
The case where the failure-corresponding symbol in the Mali screen is the one having the highest failure importance of the lower-level inclusive failures and is displayed in different colors will be described with reference to FIGS. 2, 4, and 14.

The system configuration and operation are the same as in the case of the embodiment (1). In operation, the presentation control unit 109, in step 804 of FIG. 10, when the failure-corresponding symbol on the summary screen includes a plurality of failures in the lower order when the summary screen is displayed, as shown in FIG. Figure 4
The number of failures (the number of failure-corresponding display elements) is calculated for each symbol expressed on the summary screen from the corresponding table (200, 400), and the numerical value is displayed next to the corresponding symbol on the summary screen. Request to the O control unit 115. In addition, the display color of the corresponding symbol is requested to the I / O control unit so as to be displayed by color according to the color of the most important lower level obstacle. For example, in the case of the summary screen at the time of failure occurrence described in the embodiment (1), the site symbol L1 is the failure display element SN1.
(Importance = Critical) and SN8 (importance = Warning),
When the site symbol L2 includes SN9 (importance = Warning), it is set in advance that the importance is displayed in different colors with Critical = red, Major = red, Minor = pink, Indeterminete = pink, and Warning = yellow. As shown in FIG. 14, 2 is numerically displayed 1101 beside L1, and L1 is displayed in red and L2 is displayed in yellow by color.

With the configuration and operation as described above, the operation
The user can grasp the full extent of the fault, such as the geographical spread of the fault, the number of faults, and the importance of the fault, only from the summary screen.

[Embodiment 4] As a fourth embodiment of the present invention, in the case where there is a restriction on the number of screens that can be displayed on a CRT and the number of already displayed screens is displayed and the failure screen cannot be displayed. A case where the system automatically erases one screen and displays the summary screen will be described with reference to FIGS. 3, 12 and 15.

The system configuration and operation are shown in the embodiment (1),
This is similar to the case of (2). In the operation shown in FIG. 12, when the presentation control unit 109 cannot display the failure screen because it is the already displayed screen (1201), the map hierarchy identifier of the already displayed screen excluding the screen with the input focus is the shortest ( If there are a plurality of objects of the same length, the top screen of the screen hierarchy corresponding to the smaller number is automatically deleted (1204), and the summary screen is displayed instead. 115 is requested (1205). For example, in the example described in the embodiment (1), the screen A (map hierarchy identifier =
1), the screen B (1.1), the screen D (1.1.1), and the screen G (1.1.1.1) have already been displayed, the input focus is on the screen G, the screen H, When a failure occurs at the part of J, as shown in FIG. 15, the screen A is erased and the summary screens for the screens H and J are displayed instead. The subsequent operation is similar to that of the embodiment (2).

With the configuration and operation as described above, even if the number of screens displayed is limited, unnecessary screens can be automatically deleted and the operator can be made to recognize the outline of the failure.

[0038]

According to the present invention, a network management display for collecting and managing the configuration and status information of a communication network and displaying the status on a geographical and hierarchical network map which is a pseudo representation of the communication network on the screen. In the system failure display, a screen group expressing the failure summary and failure location is automatically displayed and provided for dynamic changes in failure status such as failure occurrence, additional failure occurrence, and recovery. This eliminates the need for screen search work by the operator and allows the operator to immediately recognize the full details and details of the failure without omission. Further, even when the number of display screens is limited, the operator can prioritize and display the screens in the order of importance.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration example of a network management display system of the present invention.

FIG. 2 is a diagram showing an example of a site map display element / component correspondence table.

FIG. 3 is a diagram showing an embodiment of a geographical and hierarchical network map screen group.

FIG. 4 is a diagram showing an embodiment of a table corresponding to upper symbols / lower maps.

FIG. 5 is a diagram showing a correspondence relationship between site symbols and site maps.

FIG. 6 is an operation flowchart of a fault autofocus display processing.
Fig.

FIG. 7 is a diagram showing a processing flow of a failure part / summary screen specific update processing unit.

FIG. 8 is a diagram showing a method of identifying a fault automatic focus display screen.

FIG. 9 is a diagram showing an embodiment of a fault autofocus display screen.

FIG. 10 is a diagram showing a processing flow of a presentation control unit.

FIG. 11 is a diagram showing an example of a fault autofocus update display screen.

FIG. 12 is a diagram showing a processing flow of a presentation control unit according to another embodiment of the present invention.

FIG. 13 is a diagram showing an embodiment of a fault autofocus priority display screen.

FIG. 14 is a diagram showing an embodiment of a fault autofocus fault number display screen.

FIG. 15 is a diagram showing an example of a fault autofocus automatic summary display screen.

[Explanation of symbols]

101 ... Communication network, 102 ... Network management display system, 104
... Display information database, 110 ... Program memory,
111 ... CRT, 112 ... Keyboard, 113 ... Mouse, 114 ... Buzzer sounding device, 115 ... I / O control unit,
116 ... CPU

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yasuhiko Nagai 1099, Ozenji, Aso-ku, Kawasaki-shi, Kanagawa Inside the Hitachi, Ltd. Systems Development Laboratory (72) Inventor, Keitomo Suzuki 3-10, Sakae, Naka-ku, Aichi No. 22 In the Nihon Chubu Software Co., Ltd. (72) Inventor Masato Saito 5030 Totsuka-cho, Totsuka-ku, Yokohama-shi, Kanagawa Prefecture Software Development Division Hitachi, Ltd. (72) Inventor Shuji Fujino Totsuka-cho, Totsuka-ku, Yokohama-shi, Kanagawa 5030 Incorporated company Hitachi, Ltd. Software Development Division (72) Inventor Yoshihiro Takahashi 6-81 Onoue-cho, Naka-ku, Yokohama-shi, Kanagawa Hitachi Software Engineering Co., Ltd. In-house

Claims (12)

[Claims] 1. A communication network is hierarchized according to a geographical / physical relationship, each hierarchy level is used as a map screen having different representation levels, and a map screen relating to a part where a failure occurs is on a common screen. In the network management system displayed in, the network management system comprises data expressing the position of each map screen based on the hierarchical inclusion relation between each map screen, and all of the data generated when a failure occurs in the communication network. Fault site and 1
Specifying a map screen group corresponding to 1-to-1, and using the data, specifying one upper screen that is the most detailed level and includes all the map screen groups in which the failure has occurred, as a summary screen. A communication network fault display method characterized by. 2. The communication network fault display method according to claim 1, wherein each time a fault is added or a fault is recovered,
A new map screen group that corresponds one-to-one with all the faulty parts that have occurred is specified, and the new map screen group is all included using the data that expresses the positioning of each map screen, and the most detailed A communication network failure display method characterized in that one upper screen which is a level is specified as a new summary screen, and the summary screen is updated. 3. A communication network is hierarchized according to a geographical / physical relationship, each hierarchy level is used as a map screen with an expression having a different abstraction level, and a map screen related to a site where a failure has occurred is on a common screen. In the network management system that divides and displays the map screen, the network management system includes a map hierarchy identifier that represents the position of each map screen based on the hierarchical inclusion relationship between the map screens, and is generated when a communication network failure occurs. All the obstacles and 1
A map screen group corresponding to pair 1 is specified, and the map screen group in which the failure has occurred is included using the map hierarchy identifier and is at the most detailed level.
A communication network fault display method characterized in that one upper screen is specified as a summary screen, and the fault site screen group and the fault summary screen are displayed on a common screen. 4. The fault display method according to claim 3, wherein a new map screen group including a display element having a one-to-one correspondence with a faulty part occurring is specified each time an additional fault occurs or a fault is recovered. Then, by using the map hierarchy identifier, one upper screen that includes all of the new map screen group and is at the most detailed level is specified as a new summary screen, and the failure summary screen is updated and a failure occurs. A communication network fault display method characterized by adding / deleting a region screen and displaying the latest fault summary screen and fault region screen. 5. The communication network fault display method according to claim 3, wherein each display element in the summary screen to be displayed is a display element in the case of an expression including a plurality of faults occurring. In addition to numerically displaying the number of lower-order failures near
A fault display method for a communication network, wherein the fault display color of the display element is displayed in different colors by prioritizing the faults having the highest fault importance among the lower faults. 6. The communication network fault display method according to claim 3, wherein when a large number of faults occur, the fault site screen having a high fault importance is prioritized and displayed by the number of displayable split screens. Communication network failure display method. 7. A communication network is hierarchized according to a geographical / physical relationship, each hierarchy level is used as a map screen with different levels of abstraction, and a map screen related to a part where a failure has occurred is on a common screen. The storage means having data expressing the position of each map screen based on the hierarchical inclusion relation between the map screens, and all the failure parts occurring at the time of the failure of the communication network.
A failure site screen specifying means for specifying a map screen group corresponding to one-to-one, and one upper screen, which is the most detailed level and includes all the map screen groups in which the failure has occurred, is supported by using the data. A communication network failure display device, comprising: a summary screen specifying means for specifying a summary screen. 8. A communication network is hierarchized in accordance with a geographical / physical relationship, each hierarchy level is used as a map screen with an expression having a different abstraction level, and a map screen relating to a site where a failure has occurred is on a common screen. In the display divided into, the storage means having data expressing the position of each map screen based on the hierarchical inclusion relation between each map screen, and all the faulty parts occurring at the time of the damage of the communication network. Failure site screen specifying means for specifying a one-to-one map screen group, and one upper screen at the highest level of detail that includes all map screen groups in which the failure has occurred using the data. -Summary screen specifying means for specifying as a summary screen, display control means for simultaneously displaying the failure part screen group and the summary screen on the screen, and when an additional failure occurs or a failure occurs. The time of recovery each time service - network fault display device characterized by comprising a means for automatically updating and automatic addition / deletion of the fault generation site screen Mali screen. 9. The communication network failure display device according to claim 8, wherein a failure occurs while a permissible number of screen groups are already displayed on the screen, and a new summary screen or site screen group is created. A communication network including means for automatically erasing one screen at the highest level of the screen inclusion hierarchy in the display screen group and displaying a summary screen instead when the display screen cannot be displayed. Fault indicator. 10. The communication network failure display device according to claim 8, wherein a failure occurs while a permissible number of screen groups are already displayed on the screen, and a new summary screen or site screen group is displayed. If it is not possible, a means for displaying a message prompting deletion of the body part screen, and after deleting the screen according to the number of deleted screens, the new summary screen, the part screen of high importance in this order. A communication network fault display device comprising means for automatically displaying a screen. 11. A hierarchical network map screen group, which collects and manages the state of a communication network and, when a failure occurs, divides and displays a map screen corresponding to a failure site on a common screen. The correspondence information between the internal display elements and the components of the communication network, the correspondence information between the map screen and the map screen definition display elements, the correspondence information between the display elements and the lower layer map screens, and the hierarchical inclusion relationship between each map screen. A map hierarchy identifier expressing the position of each map screen based on
Using the table, the correspondence information, and a failure part screen specifying section for specifying a map screen group corresponding to the failure part occurring at the time of occurrence of a failure in the communication network, and the map hierarchy identifier A summary screen specifying unit that includes all the map screen groups in which the failure has occurred and specifies one upper-level screen as the most detailed level as a summary screen, the failure site screen group and the summary screen A communication network fault display device, comprising: a fault screen display control unit that controls the display of the Mari screen. 12. A map provided with a hierarchical network map screen group, collecting and managing the state of a communication network, and displaying a map screen corresponding to a failure site in a divided manner on a common screen when a failure occurs, each map screen The correspondence information between the internal display elements and the components of the communication network, the correspondence information between the map screen and the map screen definition display elements, the correspondence information between the display elements and the lower layer map screens, and the hierarchical inclusion relationship between each map screen. A means for registering a map hierarchy identifier expressing the position of each map screen based on the above, and a one-to-one correspondence with the faulty part that has occurred using the correspondence information.
Using the means for identifying the failure part screen group corresponding to the above, and using the map hierarchy identifier, one upper map screen that includes all the failure groups that have occurred and is the most detailed level is included from the inclusion relationship of the screen hierarchy. Means for specifying as a summary screen, means for updating the failure site screen and the summary screen according to a dynamic change in the failure occurrence status using the correspondence information and the map hierarchy identifier, -If a plurality of faults are included in the fault corresponding display element in the Mali screen, the one having the highest fault importance is displayed in different colors by using the corresponding information, and the number of faults occurring in the subordinates is displayed. A communication network fault auto-focus display device comprising means for numerically displaying in the vicinity of an element and means for controlling the display of the summary screen and the fault site screen under the constraint of the number of display allowable screens. Place