JPH05250296A - Network management support system - Google Patents

Abstract

PURPOSE:To obtain the system for supporting the design and construction of a network by reinforcing the performance management of the network. CONSTITUTION:This system is provided with a connecting place display part 6 to offer the suitable connecting place of an EWS or the like based on network information summed up by the SNMP of a network managing software 2, predictive transmission time display part 7 to predict time for next transmitting data, automatic routing information generation part 8 to automatically generate the information of connection between EWS, and data transmission line display part 9 to display the transmission line and amount of data under transmission corresponding to a constitutive drawing.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a network management support system.

[0002]

2. Description of the Related Art FIG. 7 is a functional diagram of a conventional network management system. In the figure, 1 is the whole network management system, 2 is Ethernet which is a coaxial cable for constructing a network, and S is a standard protocol.
Network management software for inputting network information by NMP, 3 is a data transmission amount information display unit, 4 is a network error display unit, and 5 is a network configuration diagram display unit.

Next, the operation will be described. The network management software 2 inputs data transmission amount information, network error information, and network configuration diagram information, which are network information on the Ethernet, from the Ethernet. The input data transmission amount information is aggregated,
It is output to the CRT screen or the like by the data transmission amount information display unit 3. Further, the network error information display unit 4 and the network configuration diagram display unit 5 also output the network error information and the network configuration diagram information, respectively.

[0004]

Since the conventional network management system is configured as described above, it is limited to the operation of outputting network information, and when the transmission speed of data transmitted on the network is increased. The user can connect to the EWS or other network location (segment) based on his or her experience based on the output information.
Had to move around and predict the transmission time.
In addition, there is a problem that it is difficult to grasp the flow of data during transmission. Furthermore, when creating connection information (routing information) required for data transmission between different networks, it is necessary for the user to set it.

The present invention has been made to solve the above problems, and an object of the present invention is to obtain a network management support system for strengthening network performance management and supporting network design and construction.

[0006]

A network management support system according to the present invention includes a transmission source and a transmission destination EWS.
It is provided with a means for proposing an optimum connection location of the EWS based on the result of totaling the amount of data transmitted between them.

Further, a means for judging the transmission path of the data to be transmitted and a means for calculating the transmission rate of each network from the total result of the transmission data amount are provided, and the amount of the data to be transmitted next and the transmission route and the transmission rate are set. It is equipped with a means for predicting the transmission time.

Furthermore, when there is a network connection device such as a router on the transmission path between the transmission source EWS and the transmission destination EWS, a means for automatically generating appropriate connection information (routing information) is provided. ..

Further, there is provided means for displaying the flow and amount of data being transmitted by lines and line thicknesses on the network configuration diagram based on the result of totaling the amount of transmitted data.

[0010]

According to the present invention, the means for proposing the connection location such as EWS is based on the result of totaling the transmission data amount.
EWS on the same network for data transmission between
EWS on the network that is different than the amount of data transmitted between
If there is more data to be transmitted between the two, it is proposed to move one EWS to the network to which the other EWS is connected.

The means for predicting the transmission time is based on the transmission path, transmission data amount, and transmission speed of each network judged from the transmission source and the transmission destination EWS for the next data transmission. Predict and output the required time.

Further, the automatic routing information generation means automatically generates the connection information if there is a network connection device on the transmission path judged from the information of the transmission source and the transmission destination EWS.

Further, the means for displaying the data flow and amount displays the data flow during transmission on the network configuration diagram by a line, and the data amount is expressed by the thickness of the line.

[0014]

【Example】

Example 1. An embodiment of the present invention will be described below with reference to the drawings. In FIG. 1, 1 to 5 are parts which are the same as or correspond to those of the same conventional reference numerals. 6 is a connection location display section for displaying a connection location such as EWS, 7 is a predicted transmission time display section for predicting and displaying a time required for the next transmission, and 8 is a connection during transmission between EWSs on different networks. A routing information automatic generation unit that automatically generates information (routing information), and a data transmission route display unit 9 that displays the flow of data being transmitted.

Next, the operation will be described with reference to the flow charts of FIGS. First, as shown in FIG. 2, the amount of data transmission, the network error information, and the network configuration diagram information are totaled by the SNMP in the network management software 2 (S1). Next, an inquiry display as to whether or not to display an appropriate EWS connection location is performed (S
2) If there is a display request from the user, the process proceeds to processing A by the connection location display unit 6 (described later according to FIG. 3). If there is no request from the user, then an inquiry display is made as to whether or not the predicted transmission time between the specified EWSs is displayed (S
3) If there is a display request from the user, the process proceeds to the process B (described later according to FIG. 4) by the predicted transmission time display unit 7. Similarly, if there is no request from the user, the next is the specified EW.
An inquiry display as to whether or not connection information (routing information) between S is automatically generated is displayed (S4), and if there is a display request from the user, the process proceeds to processing C by the routing information automatic generation unit 8 (described later according to FIG. 5). If there is no request from the user, then an inquiry display as to whether or not to display the data transmission route is performed (S5), and if there is a display request from the user, a process D by the data transmission route display unit 9 (described later according to FIG. 6). ). If there is no request from the user, the process ends.

FIG. 3 shows the process A for displaying the proper connection location of the EWS. First, N = 0 is set as an initial setting (S6). Next, from the result of totaling the amount of transmitted data, all EWS
Numbers are assigned in descending order of the transmission amount as the transmission source EWS, and the highest number is I (S7). N = N +
The value of N is determined by 1 (S8), and for each Nth EWS, it is determined which of the transmission destination EWS is on the same segment and another segment has a larger amount of data. Yes (S9). If the amount of transmission data to another segment is larger, the Nth EWS is moved to the segment having a larger amount of transmission data (S10). The amount of transmission data changed by this movement is corrected (S11). The above process is repeated until N becomes 1 (S is incremented by 1) (S
12) That is, after performing the above processing for all EWSs from the EWS having a small amount of transmission data, the movement information is displayed on the network configuration diagram (S13). Here, in consideration of reducing the influence of the movement of the EWS on the operation of the entire system, the EW having a small amount of transmission data is
Although it has been described that the processing starts from S, the order of EWSs to be processed can be changed.

FIG. 4 shows a process B for displaying the estimated transmission time. First, the transmission source EWS and the transmission destination EWS of the next data transmission are input from an input device such as a mouse or a keyboard (S14). Then, the amount of transmission data is input (S15). Next, the transmission path of the data is judged from the input transmission source EWS and transmission destination EWS (S16),
It is determined whether or not the average value of the transmission efficiency can be extracted based on the presence or absence of the transmission record on this transmission path (S17). When the average value of the transmission efficiency can be extracted, the estimated transmission time is calculated and displayed by the following equation: Transmission prediction time = Transmission data amount (Byte) / Average value of transmission efficiency (Byte / sec) (S18), and the process is executed. finish. If it cannot be extracted, the average value of the network usage rate of the segment is compared with respect to each segment in the transmission path, and the highest average value is extracted. Further, the average value of the transmission efficiency of the entire network is extracted (S1
9), the following formula: Transmission prediction time = (Transmission data volume (Byte) x network utilization average value (%)) / (Transmission efficiency average value of entire network (Byte / sec) x 100) After displaying (S20), the process is terminated.

FIG. 5 shows a process C for automatically generating routing information. First, the transmission source EWS and the transmission destination EWS of the next data transmission are input from an input device such as a mouse or a keyboard (S21). Next, the data transmission path is judged from the input transmission source EWS and transmission destination EWS (S22). When performing data transmission between EWSs on different networks, a router is required on the transmission route, and the number M of routers on the transmission route and the IP address of each router are extracted here (S23). The router has IP addresses on the source side and the destination side,
When the number M of routers is one (NO in S24),
The transmission source EWS is set to the IP address of the transmission destination EWS and the IP address of the transmission source side router, and the transmission destination EWS is set to the IP address of the transmission source EWS and the transmission destination side router I.
And P address are set (S25). Number of routers M is 2
If the number is one or more (YES in S24), the transmission source EW
In addition to S and the transmission destination EWS, the IP address of the connected device is similarly set for each router (S2).
6). The connection information is automatically generated as described above.

FIG. 6 shows a process D for displaying the data transmission path. When the transmission routes on the network are divided into groups, first, the groups are input from an input device such as a mouse or a keyboard (S27), and the groups are color-coded (S28). Next, the data transmission amount of each transmission route being transmitted on the entire network is extracted (S29), and the line thickness is determined according to the transmission amount (S30). Finally, in accordance with the transmission route on the network configuration diagram, the data being transmitted is displayed by a line having a color and a determined thickness according to the input group (S31), and the process ends.

[0020]

As described above, according to the present invention, the EWS
Since it proposes the optimum connection location such as, it is possible to easily review the network design and construction appropriately. Further, since connection information of a router or the like is automatically generated and the flow of data in the data and the transmission time of the next data transmission are predicted and displayed, there is an effect that the performance management of the network is strengthened.

[Brief description of drawings]

FIG. 1 is a block diagram showing functions of a first embodiment of the present invention.

FIG. 2 is a flowchart showing an outline of processing according to the first embodiment.

FIG. 3 is a flowchart showing a process of a connection location display unit in FIG.

FIG. 4 is a flowchart showing processing of a predicted transmission time display unit of FIG.

5 is a flowchart showing a process of a routing information automatic generation unit of FIG.

6 is a flowchart showing a process of a data transmission path display unit of FIG.

FIG. 7 is a block diagram showing functions of a conventional network management system.

[Explanation of symbols]

 1 network management system 2 network management software 3 data transmission amount information display unit 4 network error information display unit 5 network configuration diagram display unit 6 connection location display unit 7 estimated transmission time display unit 8 routing information automatic generation unit 9 data transmission route display Department

Claims (4)

[Claims] 1. A network management support for managing and outputting network information such as a configuration of a plurality of networks to which an EWS (engineering workstation) or the like is connected, network error information, and a transmission data amount transmitted on the network. A network management support system, characterized in that the system is provided with means for proposing an optimum connection location of the EWS based on the aggregated result of the transmission data amount between the transmission source and the transmission destination EWS. 2. A network management support system that manages and outputs network information such as the configuration of a plurality of networks to which EWS and the like are connected, error information of the network, and the amount of transmission data transmitted on the network. A means for determining the data transmission path and a means for calculating the transmission speed of each network from the aggregated result of the transmission data amount are provided, and the transmission time is predicted from the amount of data to be transmitted next, the transmission path and the transmission speed. A network management support system comprising means. 3. A network management support system that manages and outputs network information such as the configuration of a plurality of networks to which EWS and the like are connected, network error information, and the amount of transmission data transmitted on the network. A network management support system comprising means for automatically generating appropriate connection information (routing information) when there is a network connection device such as a router on the transmission path between the EWS and the transmission destination EWS. 4. A network management support system for managing and outputting network information such as a configuration of a plurality of networks to which EWS and the like are connected, network error information, and the amount of transmission data transmitted on the network, wherein the transmission is performed. A network management support system comprising means for displaying the flow and amount of data being transmitted as lines and line thicknesses on the network configuration diagram based on the data volume totalization result.