JP2016220064A - Network device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a network device that allows a network manager to grasp information on the setting and state of a network device easily without difficult operation.SOLUTION: A network device 1 includes: a control unit 500; a storage unit 520 for storing information on the setting and state of the device; and a plurality of ports 10-1 to N connected with communication cable. A display unit 20 includes a plurality of LEDs per port, and the control unit turns on each LED according to a light emission pattern corresponding to the information stored in the storage unit. A display unit 30 displays the display mode of the network device by turning on or off the LEDs.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a technology for supporting operation management of a communication network.

  In recent years, in-house information systems have been generally constructed by laying LANs (Local Area Networks) in corporate offices and factories. Since LAN installation, operation management, and the like require specialized knowledge, they are usually performed by a specialist engineer (hereinafter referred to as a network administrator). For example, when laying a LAN, a network administrator connects a device such as a personal computer (hereinafter referred to as a PC) to each port of a network device such as a switching hub or a router via a LAN cable. Further, at the time of LAN operation management, the network administrator monitors a communication state such as a communication amount and a communication speed between the network device and another device for each port. Various techniques for supporting the installation and operation management of such a LAN have been proposed in the past, and examples thereof include the techniques disclosed in Patent Documents 1 to 3.

  The network monitoring device disclosed in Patent Document 1 has a plurality of ports, and a relay device (network device) to be monitored is connected to each port. This relay device also has a plurality of ports, and a PC is connected to each port. The network monitoring apparatus acquires information (for example, communication amount) indicating a communication state between the relay device and the PC from the relay device, and displays the information on the display unit of the own device. The network administrator can grasp the communication state between the relay device and the PC for each port by confirming the display content of the display unit.

  The network device disclosed in Patent Document 2 includes a plurality of ports for inserting a network cable such as a LAN cable, an indicator corresponding to each port, and a display for displaying a character string. The indicator and the display are controlled by a user operation using a management tool such as Telnet or EMS. For example, when instructing a port that corresponds to a network cable to be inserted / removed to a worker who is performing the operation of inserting / removing a network cable at the work site, the network administrator in the management room or the like operates the management tool to operate the port. Enter information to identify The management tool acquires necessary information with reference to the database storing the setting information of the network device, turns on an indicator corresponding to the port specified based on the information, and displays related information on the display. Thereby, it is possible to give an instruction to a worker who performs work at a remote place.

  The network connection device disclosed in Patent Document 3 includes a plurality of input / output ports arranged in a horizontal row and three LEDs (one for each input / output port in a direction orthogonal to the input / output port arrangement direction). That is, a total of three LED groups arranged in a horizontal row). The identifiers of communication 1 to 3 are assigned to each of the three LED groups. When data is transmitted / received between a certain input / output port, this network connection device turns on the LED of the corresponding input / output port in the communication 1 LED group. Thereafter, when data is transmitted / received between different input / output ports, the LED of the corresponding input / output port in the LED group of communication 2 is turned on. Thereafter, when data is transmitted / received between different input / output ports, the LED of the corresponding input / output port in the LED group of communication 3 is turned on. Therefore, even if data is transmitted / received at the same time between the three sets of input / output ports, the user can confirm that the LED groups of communication 1 to 3 are turned on, so that the transmission / reception is performed between any of the input / output ports. You can see what is going on.

Japanese Patent Laid-Open No. 2002-261871 JP 2010-220161 A Japanese Patent Laid-Open No. 10-145413

  By the way, with the progress of information processing technology in recent years, the range of information to be managed (or monitored) by the network manager is expanding. An example of this type of information is VLANID (Virtual LAN Identifier) in VLAN (Virtual LAN). VLAN refers to a technique for logically dividing a LAN segment within the switching hub, and VLANID is an identifier for identifying each segment. When a network administrator divides an in-house network into a plurality of segments using a VLAN, the segmentation is realized by assigning a VLAN ID to each port of the switching hub. This is because a VLAN-compatible switching hub allows only communication between devices connected to a port to which the same VLAN ID is assigned. In this way, when the internal network is divided into a plurality of segments using VLAN, it is necessary to manage the VLAN ID assigned to each port of the switching hub. In addition, when a LAN is configured using a PoE (Power over Ethernet (registered trademark)) compatible switching hub that supplies power to other devices through a LAN cable, the network administrator must It is necessary to monitor the power supply status from other devices to other devices. As described above, when the network to be managed by the network administrator includes a VLAN-compatible switching hub or a PoE-compatible switching hub, the network administrator assigns information regarding the setting of the switching hub (for example, assigning a VLAN ID to each port). Information) and information indicating the state of the switching hub (for example, information indicating the amount of power supplied from the switching hub to other devices) must be grasped and managed.

  However, the network monitoring device disclosed in Patent Document 1 can acquire information related to the communication status between the relay device and the PC, but cannot acquire information related to the setting and status of the relay device main body. . Similarly, the network connection device disclosed in Patent Literature 3 can acquire information related to the transmission / reception status between the input / output ports of the own device, but cannot acquire information related to the setting and status of the own device. . On the other hand, according to the network device disclosed in Patent Document 2, the network administrator can acquire information related to the settings and status of the network device body using Telnet. However, in order to acquire various types of information using Telnet, it is needless to say that Telnet login authority is required, and it is necessary to fully understand various commands in Telnet. Also, since Telnet is a CUI-based user interface, command execution results are displayed as character strings and the like, and it is necessary to interpret these character strings in order to grasp the command execution results. In addition, when information is acquired using Telnet, there is a concern that accidents such as rewriting or erasing the information due to erroneous input of a command or the like may occur. These problems are the same when the network device is controlled by a method other than Telnet, for example, when an instruction is given to the network device through a serially connected console cable.

  The present invention has been made in view of the circumstances described above, and it is an object of the present invention to provide a technique that allows a network administrator to easily grasp information relating to settings and states of a network device body.

  The present invention acquires the information from one or a plurality of ports to which each communication cable is connected, display means provided for each port, and a storage device that stores information related to the setting or status of the own device. And a control unit that performs display control of each display unit in accordance with the network device.

  According to this invention, information regarding the setting and status of the network device is displayed on each display means. For example, when the display means corresponding to one port is composed of a plurality of light emitting elements, the various information is displayed by the light emission pattern of each light emitting element. In this case, by checking the light emission pattern of the light emitting element, the user can intuitively grasp information regarding the setting and status of the network device without an operation requiring specialized knowledge such as command input.

1 is a front view of a network device 1 according to an embodiment of the present invention. It is a figure which shows the correspondence of the light emission pattern which VLANID and LED200A_n (n = 1-N) and 200B_n (n = 1-N) can take in the embodiment. It is a figure which shows the correspondence of the light emission pattern which LED200A_n (n = 1-4) and 200B_n (n = 1-4) can take, and electric power feeding state in the embodiment. It is a figure which shows the structural example of the network apparatus 1 in the embodiment. 4 is a flowchart showing the contents of display control processing executed by a control unit 500 in the embodiment. It is a figure for demonstrating the network apparatus 1 of a modification (1). It is a figure which shows the example of a display of the communication speed and link state of each port in the modification (1). It is a figure which shows the example of a display of the presence or absence of generation | occurrence | production of the loop in the modification (1). It is a figure for demonstrating the display mode of VLANID in the modification (1). It is a figure for demonstrating the example of a display of VLANID in the modification (1).

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(A: Configuration)
FIG. 1 is a front view of a network device 1 according to an embodiment of the present invention. The network device 1 is a switching hub that supports VLAN and PoE technologies. The network device 1 relays communication between devices connected to a port to which the same VLAN ID is assigned in an in-house LAN composed of a plurality of VLANs. The network device 1 supplies power to a device installed in a place where power supply is difficult. In the present embodiment, the network device 1 supplies power to one device in one power supply process. As shown in FIG. 1, the network device 1 includes a port 10 — n (n = 1 to N: N is a natural number, N = 15 in the present embodiment), a display unit 20, a display unit 30, and a switch 40. ing.

  A network cable such as a LAN cable is connected to each of the ports 10_n (n = 1 to N). A terminal device such as a PC, a network device (another switching hub or router), or the like is connected to the LAN cable connected to the port 10_n (n = 1 to N) (none is shown in FIG. 1).

  The display unit 20 includes LEDs 200A_n and 200B_n corresponding to the port 10_n. Each of the LEDs 200A_n (n = 1 to N) and 200B_n (n = 1 to N) is a two-color LED (Light-Emitting Diode), and emits light, for example, yellow or green. In the present embodiment, various information is displayed to the network administrator by turning on or off the LEDs 200A_n (n = 1 to N) and 200B_n (n = 1 to N). One of the information displayed on the display unit 20 is information on the communication state of each port. For example, when the LEDs 200A_n (n = 1 to N) and 200B_n (n = 1 to N) are turned on or off, the port through which data is transmitted and received is displayed. More specifically, when data is transmitted / received via the port 10_m, the LEDs 200A_m and 200B_m are turned on. At this time, both the LEDs 200A_m and 200B_m may be turned on, or only one of the LEDs 200A_m or 200B_m may be turned on. In this embodiment, the communication speed is displayed by turning on or off the LEDs 200A_n (n = 1 to N) and 200B_n (n = 1 to N). More specifically, when data is transmitted / received via the port 10_m, the LEDs 200A_m and 200B_m are lit with a light emission pattern corresponding to the communication speed.

  As described above, for network devices that support VLAN and PoE technologies, the network administrator must manage not only the communication status of each port but also the settings and status of the network device itself. Specifically, it is necessary to grasp the VLAN ID assigned to the port 10_n (n = 1 to N) and the power supply state from the network device 1 to other devices. Therefore, the network device 1 according to the present embodiment is configured to be able to display the VLAN ID assigned to the port 10_n and the information regarding the power supply state from the network device 1 to other devices using the light emission patterns of the LEDs 200A_n and 200B_n. This is a feature of this embodiment.

  The display mode of VLANID by the light emission pattern of LED200A_n and 200B_n is as follows. As described above, the LEDs 200A_n (n = 1 to N) and 200B_n (n = 1 to N) are two-color LEDs, and each LED has three states: off, on (yellow), and on (green). It can take. Therefore, by turning on or off the LEDs 200A_n and 200B_n, the VLAN IDs assigned to the ports 10_n can be displayed with a total of nine (3 × 3) light emission patterns. FIG. 2 is a diagram illustrating a correspondence relationship between the VLANID and the light emission patterns that the LEDs 200A_n and 200B_n can take. As shown in FIG. 2, each of the values 1 to 9 that can be taken by VLANID is associated with a lighting color (lighting state) that can be taken by each of the LEDs 200A_n and 200B_n. Since each combination of lighting colors associated with each VLAN ID (that is, the light emission pattern) is different, the network administrator knows the VLAN ID assigned to the port 10_n (n = 1 to N) through this light emission pattern. can do. The relationship between the LED lighting color and light emission pattern and VLANID is merely an example, and may be changed as appropriate.

  Next, a display mode of the power supply state from the network device 1 to other devices will be described. In the present embodiment, the maximum power that can be supplied from the network device 1 is 120 W, and the power supply state from the network device 1 to other devices is 0 W <P ≦ 30 W, 30 W <P ≦ 60 W, depending on the power supply amount P. It is classified into four states of 60W <P ≦ 90W and 90W <P ≦ 120W. FIG. 3 is a diagram illustrating a correspondence relationship between light emission patterns that can be taken by the LEDs 200A_n (n = 1 to 4) and 200B_n (n = 1 to 4) and power supply states. In this figure, the lit LEDs 200A_n (n = 1 to 4) and 200B_n (n = 1 to 4) are represented in black. FIGS. 3A to 3D show display modes when the power supply amount P to other devices is 0 W <P ≦ 30 W, 30 W <P ≦ 60 W, 60 W <P ≦ 90 W, and 90 W <P ≦ 120 W, respectively. Is shown. As shown in FIG. 3A, when 0W <P ≦ 30W, the network device 1 turns on the LED 200A_1 and the LED 200B_1. As shown in FIG. 3B, when 30W <P ≦ 60W, the network device 1 lights the LEDs 200A_1 to 200A_2 and the LEDs 200B_1 to 200B_2. As shown in FIG. 3C, when 60W <P ≦ 90W, the network device 1 lights the LEDs 200A_1 to 200A_3 and the LEDs 200B_1 to 200B_3. And as shown in FIG.3 (d), when 90 <P <= 120W, the network apparatus 1 lights LED200A_1-200A_4 and LED200B_1-200B_4. The network administrator can grasp the power supply state from the network device 1 to other devices through the light emission patterns of the LEDs 200A_n (n = 1 to 4) and 200B_n (n = 1 to 4). Note that the relationship between the light emission pattern of the LEDs and the power supply state shown in FIGS. 3A to 3D is an example, and the combination, the number of LEDs to emit light, the light emission color, and the like may be changed as appropriate.

  As described above, in this embodiment, a plurality of types of information can be displayed using the display unit 20. In the following, a state for displaying the communication state of each port (in this embodiment, the communication speed of data communication via each port) is displayed in display mode 1, and a state for displaying the VLAN ID assigned to each port is displayed in display mode 2. A state in which the power supply state from the network device 1 to other devices is displayed is referred to as a display mode 3. Immediately after the network apparatus 1 is turned on, the display mode 1 is initially set. The switch 40 is an operation unit for inputting an operation for switching the display modes 1 to 3. More specifically, when the switch 40 is operated under the condition of the display mode 1, the network device 1 switches the display mode from the display mode 1 to the display mode 2. Thereafter, when the switch 40 is operated, the network device 1 switches the display mode from the display mode 2 to the display mode 3. When the switch 40 is further operated, the network device 1 switches the display mode from the display mode 3 to the display mode 1.

  The display unit 30 includes LEDs 300_1 and 300_2. The display unit 30 displays the display mode of the network device 1 by turning on or off. Each of the LEDs 300_1 and 300_2 is a single color LED. When the display mode is the display mode 1, both the LEDs 300_1 and 300_2 are turned off. When the display mode is the display mode 2, only the LED 300_1 is lit, and when the display mode is the display mode 3, only the LED 300_2 is lit. The network administrator can grasp the display mode of the network device 1 through the light emission patterns of the LEDs 300_1 and 300_2.

  FIG. 4A is a diagram illustrating a configuration example of the network device 1. As shown in FIG. 4A, the network device 1 includes a control unit 500, a communication interface (hereinafter referred to as I / F) unit 510, a storage unit 520, a user I / F unit 530, and data exchange between these components. Including a bus 540 that mediates. The user I / F unit 530 includes a display unit 20, a display unit 30, and a switch 40.

The communication I / F unit 510 is, for example, a NIC (Network
Interface card) and has ports 10_n (n = 1 to N). Communication I / F unit 510 provides control unit 500 with data received via a LAN cable connected to port 10 — n (n = 1 to N). Further, the communication I / F unit 510 transmits the data given from the control unit 500 to the port 10_n (n = 1 to N) corresponding to the transmission destination.

  FIG. 4B is a diagram illustrating a configuration example of the storage unit 520. As illustrated in FIG. 4B, the storage unit 520 includes a volatile storage unit 522 and a nonvolatile storage unit 524. The volatile storage unit 522 is a volatile memory such as a RAM (Random Access Memory). The volatile storage unit 522 is used by the control unit 500 as a work area when executing each program to be described later. The volatile storage unit 522 is used as an area for storing display mode information 522a indicating the display mode of the network device 1.

  The nonvolatile storage unit 524 is a nonvolatile memory such as a flash ROM (Read Only memory). As shown in FIG. 4B, in the nonvolatile storage unit 524 of this embodiment, a relay control program 524a, a power supply control program 524b, a display control program 524c, and an OS program 524d are stored in advance. The nonvolatile storage unit 524 stores a MAC (Media Access Control) address table (not shown in FIG. 4B) and data representing information related to the settings of the network device 1. . An example of this type of data is the VLAN management table 524e.

  Since the MAC address table is not particularly different from that of a general switching hub, description thereof is omitted. The VLAN management table 524e is a table for managing the VLAN ID assigned to each port of the network device 1. The VLAN management table 524e stores the VLAN ID assigned to the port indicated by the identifier in association with the identifier (port number) indicating each of the ports 10_n (n = 1 to N).

  The relay control program 524a, the power supply control program 524b, and the OS program 524d are not particularly different from those in the conventional switching hub, and thus detailed description thereof is omitted, but the outline is as follows. The relay control program 524a is a program that causes the control unit 500 to implement relay control such as data communication performed between devices in the VLAN. The control unit 500 operating according to the relay control program 524a measures the communication speed (for example, data transmission / reception amount per unit time) of data communication through the port for each port 10_n, and represents the measurement result. A process of writing data (hereinafter, communication state data) in a predetermined storage area of the volatile storage unit 522 is also executed. The power supply control program 524b is a program that causes the control unit 500 to realize power supply control from the network device 1 to another device. The control unit 500 operating according to the power supply control program 524b performs, in addition to performing the power supply control, data (hereinafter referred to as power supply state data) representing the power supply amount per unit time in a predetermined amount of the volatile storage unit 522. A process of writing to the storage area is also executed. The OS program 524d is software for causing the control unit 500 to realize an OS (Operating System).

  The display control program 524c is a program that causes the control unit 500 to execute processing that clearly shows the features of the present invention. More specifically, the display control program 524c is a program for controlling display contents of the display units 20 and 30 (that is, light emission patterns of the LEDs 200A_n and 200B_n and the LEDs 300_1 and 300_2). The details of the display control operation executed by the control unit 500 according to the display control program 524c will be clarified in the operation example in order to avoid duplication of explanation.

The controller 500 is, for example, a CPU (Central
Processing Unit). The control unit 500 functions as a control center of the network device 1 by executing each program stored in the storage unit 520 (more precisely, the nonvolatile storage unit 524). In the present embodiment, the control unit 500 reads out the OS program 524d from the nonvolatile storage unit 524 to the volatile storage unit 522 and starts executing it when the power (not shown) of the network device 1 is turned on. The control unit 500 that operates according to the OS program 524d and realizes the OS reads the relay control program 524a, the power supply control program 524b, and the display control program 524c from the nonvolatile storage unit 524 to the volatile storage unit 522. Run the program in parallel.
The above is the configuration of the network device 1.

(B: Operation)
Next, among the operations performed by the network device 1, an operation that significantly shows the characteristics of the present embodiment, that is, a display control operation will be described with reference to FIG. In this operation example, a network administrator A (hereinafter referred to as employee A) belonging to company B (hereinafter referred to as company B) that employs network device 1 as a switching hub in laying the internal LAN is assumed to be After the laying is completed, the in-house LAN is managed using the network device 1. Here, Company B is a company composed of three departments, Department 1 to Department 3, and the internal LAN of Company B is composed of three VLANs with each department as one unit. Five employees belong to each department, and the PCs of the employees belonging to each department are all connected to the network device 1. More specifically, the employee's PC belonging to department 1 is connected to ports 10_1 to 10_5 of network apparatus 1, and the employee's PC belonging to department 2 is connected to ports 10_6 to 10_10 of network apparatus 1. Employee PCs belonging to the department 3 are connected to the ports 10_11 to 10_15 of the network device 1. Among these, the PC connected to the port 10_15 is installed in a place where power supply is difficult, and power is supplied through the LAN cable. The maximum power that can be supplied to the network device 1 is 120 W. In the following description, when the LEDs 200A_n and 200B_n are not distinguished, they are described as LEDs 200_n.

  FIG. 5 is a flowchart showing the contents of display control processing executed by the control unit 500. When the employee A turns on the network device 1 and the network device 1 is activated, the control unit 500 determines whether or not there is a switching instruction (step S10). Here, the switching instruction is generated when a signal generated when the switch 40 is pressed is given to the control unit 500. The control unit 500 determines whether or not there is a switching instruction based on whether or not the signal is received. In a state where the switch 40 is not pressed immediately after the power is turned on, the determination result of step S10 is No, and the control unit 500 executes the process of step S30. In step S30, the controller 500 identifies the current display mode with reference to the display mode information 522a. Since the display mode is initially set to display mode 1 immediately after the power is turned on, the control unit 500 executes a display control process corresponding to display mode 1 (step S40). In step S <b> 40, the control unit 500 turns on the LEDs 200 </ b> _ <b> 1 to 200_ <b> 15 with a light emission pattern corresponding to the communication state indicated by the communication state data stored in the volatile storage unit 522. Thereafter, the control unit 500 repeatedly executes the processes after step S10 until instructed to end the display control process. In this state, the employee A can intuitively grasp the communication speed of the data communication through each of the ports 10_n (n = 1 to 15) through the light emission patterns of the LEDs 200_1 to 200_15.

  When the employee A presses the switch 40 to confirm the VLAN ID assigned to the ports 10_1 to 10_15, the determination result in step S10 is Yes, and the control unit 500 displays the display mode information 522a from the data indicating the display mode 1. The data indicating mode 2 is updated (step S20). Thereafter, the control unit 500 executes step S30 and executes a display control process corresponding to the display mode 2 (step S50). More specifically, the controller 500 reads the VLAN ID assigned to the ports 10_1 to 10_15 from the VLAN management table 524e. Then, the control unit 500 turns on the LED 300_1 and turns on the LED 200_n with a light emission pattern corresponding to the VLANID assigned to the port 10_n.

  As a result of the employee A performing the above operation, the light emission patterns of the LEDs 200A_1 to 200A_5 and 200B_1 to 200B_5 are (off and off), the light emission patterns of the LEDs 200A_5 to 200A_10 and 200B_5 to 200B_10 are respectively (off and yellow), and the LED 200A_10 Suppose that the emission patterns of .about.200A_15 and 200B_10 to 200B_15 are respectively turned off (green). Employee A confirms this light emission pattern, and in Company B's internal LAN, grasps that VLAN ID 1 is assigned to department 1, 2 is assigned to department 2, and 3 is assigned to department 3. (See FIG. 2).

  Next, it is assumed that the employee A presses the switch 40 in order to confirm the power supply state by the network device 1. In this case, the determination result in step S10 is Yes, and the control unit 500 updates the display mode information 522a from the data indicating the display mode 2 to the data indicating the display mode 3 (step S20). Thereafter, the control unit 500 executes step S30 and executes a display control process corresponding to the display mode 3 (step S60). More specifically, the control unit 500 turns on the LEDs 200_1 to 200_4 with a light emission pattern corresponding to the power supply amount represented by the power supply state data.

  As a result of employee A performing the above operation, LEDs 200A_1 to 200A_2 and 200B_1 to 200B_2 are turned on. This indicates that the power supply amount P from the network device 1 to other devices is 30 W <P ≦ 60 W. By confirming this light emission pattern, the employee A can recognize that there is a surplus in the amount of power supplied from the network device 1 to other devices, that is, the power supply state is good.

  According to the present embodiment, the network administrator can grasp the assignment of VLANID and the power supply state from the network device 1 to other devices only by operating the switch 40, and it is not necessary to learn a command or the like. In addition, in this embodiment, the VLAN ID assigned to each port and the power supply state from the network device 1 to other devices are displayed as an LED light emission pattern in an easy-to-understand manner to the network administrator. That is, according to the present embodiment, the network administrator can easily grasp information related to the settings and status of the network device 1 main body.

(C: deformation)
While various embodiments of the present invention have been described above, other embodiments are possible for the present invention.
(1) In the network device 1 of the above embodiment, as shown in FIG. 1, the LED 200A_n and the LED 200B_n are provided separately from the port 10_n. However, as shown in FIG. Also good. FIG. 6A is a front view of the network device 1 according to this modification. As shown in FIG. 6A, the port 10_n in the present modification is a LAN port to which a LAN cable is connected, and has a convex opening. An LED 200B_n is provided on the right shoulder of the opening of the port 10_n, and an LED 200A_n is provided on the left shoulder. The LED 200A_n and the LED 200B_n are two-color light emitting LEDs capable of emitting two colors, green and orange, and can take five states: off, green flashing, green lighting, orange flashing, and orange lighting. Hereinafter, in this modification, these five states are distinguished by hatching shown in FIG.

  The display mode 1 in the network device 1 of this modification is a mode for displaying the communication speed and communication state (whether the link is lost, the link is established, or the data is being transferred) of each port. The display mode 2 is a display mode for displaying whether or not a loop has occurred, and the display mode 3 is a display mode for displaying a VLANID (hereinafter abbreviated as VID) assigned to the port 10_n. Specific examples of the display mode in each of these display modes are as follows.

  In the display mode 1, the communication speed of data communication via the port 10_n is displayed using the LED 200B_n, and the state of data communication via the port 10_n (such as whether a link is established) is displayed using the LED 200A_n. For example, as shown in FIG. 7A, the control unit 500 turns off the LED 200B_n if the physical layer of data communication via the port 10_n is 10BASE-T (that is, communication speed = 10 megabits / second), If it is 100BASE-TX (communication speed = 100 megabit / second), the LED 200B_n is lit in orange, and if it is 1000BASE-T (communication speed = 1 gigabit / second), the LED 200B_n is lit in green. Further, as shown in FIG. 7B, the control unit 500 turns off the LED 200A_n if the data communication via the port 10_n is in a link lost state, and turns on the LED 200A_n in green if the link is in an established state. If transfer is in progress, the LED 200A_n blinks in green. Therefore, when the physical layer of data communication via the port 10_n is 100BASE-TX and data is being transferred, the display state of the LED 200A_n and the LED 200B_n is as shown in FIG.

  In the display mode 2, as shown in FIG. 8, when the control unit 500 detects a loop for the port 10_n and performs blocking, the control unit 500 blinks the LED 200A_n and the LED 200B_n in orange and detects the loop for the other ports. When the loop is not detected for the port 10_n, the LED 200A_n and the LED 200B_n are lit in orange. The control unit 500 turns off the LED 200A_n and the LED 200B_n when a loop is not detected or when a LAN cable is not connected to the port 10_n.

  In the display mode 3, when the VID is not set to the port 10_n, the control unit 500 turns off the LED 200A_n and the LED 200B_n and sets the VID to the port 10_n as shown in FIG. 9A. The VID set for the port 10_n is displayed in the display patterns of FIGS. 9B to 9I. More specifically, FIG. 9B to FIG. 9G show display patterns (FIG. 9B is the youngest) in which six of the VIDs assigned to each port in the network apparatus 1 are displayed from the youngest. 9C, FIG. 9D, FIG. 9E, and FIG. 9D), and FIG. 9H is a display pattern showing other VIDs. (I) is a display pattern indicating that a plurality of VIDs are assigned.

  For example, port 10_1 has VID 100, port 10_2 has VID 101, port 10_3 has VID 102, port 10_4 has VID 103, port 10_5 has VID 104, port 10_6 has port 10_6 When VID 105 is set, the control unit 500 turns on or off the LEDs 200A_n and 200B_n (n = 1 to 6) as shown in FIG. The port 10_1 has VIDs 100 and 101, the port 10_2 has VID 102, the port 10_3 has VID 103, the port 10_4 has VIDs 104 and 105, and the port 10_5 has VID 104. When 106 is set as the VID for the port 10_6, the control unit 500 turns on or off the LEDs 200A_n and the LEDs 200B_n (n = 1 to 6) as shown in FIG.

(2) In the above embodiment, when a change occurs in the setting or state of the network device 1, information related to the setting or state before the change is written and stored in the nonvolatile storage unit 524 as a log, and is changed according to the operation on the switch 40. Then, the control unit 500 may execute a process of lighting the LEDs 200A_n and 200B_n with the light emission pattern corresponding to the log. As a result, the network administrator can compare the VID, communication state, etc. set in the past with the current one, and can evaluate the change over time in the power supply state by the network device 1. In the above embodiment, information related to the settings of the network device 1 and information related to the status of the network device 1 are stored in the storage unit 520 of the network device 1, and the control unit 500 of the network device 1 stores the information in the storage unit 500. In the above description, the display control of the LED 200_n is performed according to the information read (obtained) from the above. However, the above information is stored in a storage device that can communicate with the network device 1, and the control unit 500 stores the information in the storage device. Display control of the LED 200_n may be performed according to the information acquired from the above.

(3) In the above embodiment, each information indicating the setting and state of the network device 1 is displayed by the light emission pattern of the LED 200_n. However, the buzzer and the sound emission means for emitting music are provided, and the number of times the buzzer is Each information indicated by the display modes 1 to 3 may be notified according to the type of music or its tone color. Moreover, each information which shows the setting and state of the network apparatus 1 may be displayed by the light emission pattern of the LED 200_n, and a notification by sound may be performed when a change occurs in the setting or state of the network apparatus 1.

(4) In the above embodiment, a two-color LED is used for the LED 200_n. However, when the range of the VID value is wider, an LED capable of emitting three or more colors may be used, or a light emitting element other than the LED may be used. For the LEDs 300_1 and 300_2, light emitting elements capable of emitting multicolor light may be used, and the display mode may be displayed by a light emission pattern including a combination of light emission colors in addition to a combination of lighting and extinguishing. In the above embodiment, the application example of the present invention to the switching hub has been described. However, the network device to which the present invention is applied is not limited to the switching hub, and may be a router.

(5) In the above embodiment, an example in which the power supply state to the device connected to one port is displayed in the display mode 3 has been described. However, the power supply status to the devices connected to the plurality of ports may be displayed. In this case, the LED 200_1 to 200_4, the LED 200_5 to 200_10,..., The LED 200_n-3 to 200_n are each formed as a unit, and the power supply state to the device connected to each port is set to each LED set. Display it.

(6) In the embodiment described above, the control unit 500 may cause the LED 200_n to display information related to settings and states other than the display modes 1 to 3. For example, when the network device 1 has a QoS (Quality of Service) function, the control unit 500 may display the bandwidth used during data communication on the LED 200_n.

(7) In the above embodiment, the application example of the present invention to the network device corresponding to both the VLAN and PoE technologies has been described. However, even if the present invention is applied to a network device compatible with only one of the technologies. good. For example, when the present invention is applied to a network device that supports VLAN but does not support PoE, it is not necessary to store the power supply control program 524b in the network device. When the present invention is applied to a network device that supports PoE but does not support VLAN, it is not necessary to store the VLAN management table 524e in the network device. That is, the power supply control program 524b and the VLAN management table 524e in FIG. 4B are not essential components of the network device of the present invention, but are optional components that can be omitted as appropriate according to the corresponding technology of the network device. It is of course possible to apply the present invention to a network device corresponding to another network technology different from VLAN. Examples of other network technologies include link aggregation technology and VRRP (Virtual Router Redundancy Protocol) technology.

  Link aggregation is a technology that uses a plurality of physical ports as one logical port between network devices directly connected by a LAN cable or the like, and realizes improvement in communication speed and fault tolerance. Technology. A logical port in link aggregation is composed of a plurality of physical ports and is called LAG (Link Aggregation Group). The same LAG number is assigned to physical ports belonging to the same LAG. By applying the present invention to a network device that supports link aggregation, it becomes possible to display the LAG number assigned to each port by the light emission pattern of the LEDs 200A_n and 200B_n. Specifically, instead of the VALN management table 524e, the LAG number assigned to the port indicated by the identifier is stored in association with the identifier (port number) indicating each of the ports 10_n (n = 1 to N). The LAG management table may be stored in the nonvolatile storage unit 524, and the control of the LED 200A_n and the LED 200B_n according to the stored contents of the LAG management table may be performed.

  VRRP is a protocol for multiplexing routers. The VRRP technique makes it possible to avoid the suspension of communication services when a router failure occurs. More specifically, in the VRRP technique, a plurality of routers are handled as one group, and priority is given to each router in the group. Normally, communication is performed by a router with a higher priority (master router), but when a failure occurs, the process automatically switches to the other router (backup router) in the same group with the higher priority. Communication can be continued. By applying the present invention to a network device that supports VRRP, the priority given to the network device can be displayed by the light emission patterns of the LEDs 200A_n and 200B_n.

(8) In the above embodiment, a plurality of light emitting elements provided for each port are used as display means for displaying each information indicating the setting and status of the network device. However, a liquid crystal display is used. May be. Some network devices include a small liquid crystal display. In such a network device, a display area corresponding to each of the LEDs 200A_n and 200B_n is provided on the display screen of the liquid crystal display, and these display areas are provided. Is used as a display means provided for each port, and display control (for example, display color control of each display area) for displaying various types of information may be performed by the control unit 500. In short, the control unit of the network device having the control unit, one or a plurality of ports to which each communication cable is connected, the display means provided for each port, and the control unit is related to the setting or status of the own device. Any mode may be used as long as the information is acquired from the storage device that stores the information, and display control of each display unit is performed according to the information so that the network administrator can visually grasp the information.

(9) In the above embodiment, the display control program 524c that significantly shows the features of the present invention is stored in the storage unit 520 in advance. However, the display control program 524c is stored in a CD-ROM (Compact
It may be distributed by writing on a computer-readable recording medium such as a disk-read only memory, or by downloading via a telecommunication line such as the Internet. By operating the control unit of the network device (that is, a computer such as a CPU) according to the display control program 524c distributed in this way, the network device can be made to function as the network device of the present invention. It is.

DESCRIPTION OF SYMBOLS 1 ... Network device, 10_n ... Port, 20, 30 ... Display part, 40 ... Switch, 200A_n, 200B_n, 300_1, 300_2 ... LED, 500 ... Control part, 510 ... Communication I / F part, 520 ... Memory | storage part, 530 ... User I / F unit, 522 ... volatile storage unit, 522a ... display mode information, 524 ... non-volatile storage unit, 524a ... relay control program, 524b ... power supply control program, 524c ... display control program, 524d ... OS program, 524e ... VLAN management table.

Claims (7)

One or more ports each connected to a communication cable;
Display means provided for each port;
A network device, comprising: a control unit that acquires the information from a storage device that stores information related to a setting or a state of the own device and performs display control of each display unit according to the information. An operation unit for inputting an instruction to switch information to be displayed on each display unit;
The network device according to claim 1, wherein the control unit performs display control of each display unit according to information instructed by an operation on the operation unit. The controller is
When a change occurs in the setting or state of the own device, a log of information on the setting or state before the change is written in the storage device,
The network device according to claim 2, wherein display control of each display unit is performed in accordance with a setting or a state indicated by the log in response to an operation on the operation unit. It has a sound emission part,
The network device according to claim 3, wherein the control unit notifies that a change has occurred in a setting or a state of the own device by sound emission from the sound emission unit. Each of the display means provided for each port is a plurality of light emitting elements, and the control unit controls a light emission pattern of each light emitting element according to the information. The network device according to any one of the above.   The network apparatus according to claim 5, wherein the information regarding the port is displayed by a light emission pattern of a plurality of light emitting elements corresponding to the port.   The network apparatus according to claim 6, wherein the information related to a port is a VLAN ID.

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