JPWO2021084616A1 - Communications system - Google Patents

Abstract

Provided is a communication system that collects and outputs the communication status of a wireless communication network. The communication system includes a plurality of communication devices connected to the wireless communication network and a host device connected to the wireless communication network. The host device has an information collecting unit and an information output unit. The information collecting unit collects communication information regarding the communication status of each of the plurality of communication devices from each of the plurality of communication devices. The information output unit outputs the communication information collected by the information collection unit.

Description

The present invention relates to a communication system.

Patent Document 1 discloses a system that unifies lighting information of a laminated signal lamp that indicates an operating status of a production facility by lighting an indicator lamp. According to Patent Document 1, a lighting detection device is attached to each laminated signal lamp. The lighting detection device detects the lighting information of the indicator lamp and wirelessly transmits it to the transmitter / receiver.

Japanese Unexamined Patent Publication No. 2018-195109

In the system disclosed in Patent Document 1, a plurality of lighting detection devices and a transceiver perform wireless communication, but depending on the wireless communication environment, the connection between one of the lighting detection devices and the transceiver may be disconnected. There is. In such a case, it is necessary to identify the lighting detection device in which the connection is disconnected and take measures, but the user may not notice that the connection has been disconnected in the first place. However, Patent Document 1 does not disclose a method for taking measures against such a problem.

An object of the present invention is to provide a communication system and a program for outputting the communication status of a wireless communication network.

A communication system according to one aspect of the present invention includes a plurality of communication devices connected to a wireless communication network and a host device connected to the wireless communication network. The host device has an information collecting unit and an information output unit. The information collecting unit collects communication information regarding the communication status of each of the plurality of communication devices from each of the plurality of communication devices. The information output unit outputs the communication information collected by the information collection unit.

According to this configuration, communication information regarding the communication status of the collected and collected communication devices is output.

In the communication system, the wireless communication network may be a mesh network in which the plurality of communication devices are communicably connected to each other, and the communication information is the communication information among the plurality of communication devices and the host device. It may contain information that identifies adjacent devices on the mesh network.

In the communication system, the communication information may include quality information regarding the quality of the communication path between each of the plurality of communication devices and the adjacent device.

In the communication system, the host device has a predetermined rank of the quality of the communication path between each of the plurality of communication devices and the host device based on the quality information collected from the plurality of communication devices. It may further have a communication diagnosis unit classified into.

In the communication system, the information output unit may generate a screen for displaying identification information identifying each of the plurality of communication devices in association with the rank classified by the communication diagnosis unit.

According to this configuration, the quality of the communication path between each of the plurality of communication devices and the host device is classified into ranks and displayed, so that even a user who does not have expertise in the communication field can easily perform network communication. You can grasp the situation.

In the communication system, the host device may further have a storage unit that stores the identification information in association with the classified rank, and the information output unit may store the identification information in the storage unit. You may generate a screen that displays the information and the classified ranks in chronological order.

According to this configuration, the user can easily confirm the time-series transition of the ranks of the plurality of communication devices.

In the communication system, each of the plurality of communication devices responds to an input unit to which a signal from another device assigned to the communication system is input, a display that emits light, and a signal input to the input unit. It may have a display output unit that emits the emitted light to the display.

According to this configuration, each of the plurality of communication devices can visualize the signal from the other device to which each is assigned.

In the communication system, each of the plurality of communication devices may have a display that emits light and a local display output unit that emits light to the display in response to a request from the host device.

According to this configuration, the communication device can be physically identified by the light emitted from the display.

In the communication system, each of the plurality of communication devices has a photodetector for detecting light, and the detection result of the photodetector may be transmitted to the host device.

The program according to one aspect of the present invention causes a computer to perform the following steps.
-A step of collecting communication information regarding the communication status of each of the plurality of communication devices from each of the plurality of communication devices connected to the wireless communication network.
-A step of aggregating and outputting the collected communication information.

According to the present invention, a communication system and a program for outputting the communication status of a wireless communication network are provided.

The whole view of the communication system which concerns on one Embodiment. The block diagram which shows the electric structure of the communication system which concerns on one Embodiment. The figure which shows an example of the display screen of the communication system which concerns on one Embodiment. The figure which shows an example of the network of the communication system which concerns on one Embodiment. The figure which shows an example of the network diagnosis processing which concerns on one Embodiment. A flowchart showing a flow of network diagnostic processing according to an embodiment. The figure which shows an example of the display screen of the communication system which concerns on one Embodiment. A flowchart showing a flow of network diagnostic processing according to an embodiment. The figure which shows an example of the display screen of the communication system which concerns on one Embodiment. The block diagram which shows the electric structure of a communication device and the like which concerns on a modification.

Hereinafter, a communication system and a program according to an embodiment of the present invention will be described with reference to the drawings.

<1. Overall configuration of communication system>
FIG. 1 is an overall configuration diagram of the communication system 1 according to the present embodiment, and FIG. 2 is a block diagram showing an electrical configuration of the communication system 1. The communication system 1 is applicable to, for example, factory equipment. More specifically, the communication system 1 centrally monitors the operating status of equipment and the output information of equipment manually operated by workers when notifying troubles on a production line. Can be applied.

The communication system 1 includes a plurality of communication devices 2 and a host device 3 connected to a wireless communication network 10 (hereinafter, may be simply referred to as a network 10). The plurality of communication devices 2 are assigned to the equipment devices 5 constituting the factory equipment and the like, and the operating status of the equipment device 5 is displayed and output on the spot and transmitted to the host device 3 via the network 10. The network 10 of the present embodiment is a mesh network, and the communication device 2 connected to the network 10 can perform multi-hop communication via another communication device 2 when communicating with the host device 3. be. The host device 3 transmits a signal to the plurality of communication devices 2 via the network 10 and collects information from the plurality of communication devices 2. The host device 3 is connected to the information processing terminal 4 so as to be able to communicate with each other by wire. The user can monitor the operating status of the equipment 5 via the information processing terminal 4 and grasp the quality of the communication path of the network 10 for monitoring the operating status.

As shown in FIG. 1, the equipment 5 is a machine arranged in a building of factory equipment or the like. The type of the equipment 5 is not particularly limited, and each may be the same type of machine or may be a different type of machine. A communication device 2 assigned to each of the equipment 5 is installed in the equipment 5. The equipment device 5 supplies power to the installed communication device 2.

With reference to FIG. 2, each equipment device 5 includes a control unit 50. The control unit 50 is composed of a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), and the like, and is electrically connected to the input unit 25 of the communication device 2 described later. The control unit 50 controls the operation of each part of the equipment device 5. Further, the control unit 50 generates a status signal indicating the operation status according to the operation status of the equipment device 5, and inputs the status signal to the input unit 25 of the communication device 2. The type of the status signal is not particularly limited, and for example, "normal" indicating that the equipment 5 is operating normally, "abnormality" indicating that a trouble has occurred in the operation of the equipment 5, and the equipment 5 It can be a "stop" or the like indicating that an emergency stop is necessary.

The timing at which the control unit 50 inputs the status signal of the equipment device 5 to the input unit 25 is not particularly limited. The timing may be, for example, every predetermined cycle, when the communication device 2 receives the status request signal transmitted from the host device 3, or when the operating status of the equipment device 5 changes. May be. Here, the status request signal is a signal requesting that the operating status of the equipment device 5 be transmitted to the host device 3. The status request signal is generated by the host device 3 and transmitted to each communication device 2, for example, when the user instructs the host device 3 to transmit the status request signal through the web browser of the information processing terminal 4.

As shown in FIG. 1, the communication device 2 has a substantially cylindrical appearance as a whole. The communication device 2 includes a base portion 24 at the lower portion of the cylindrical shape and a display 23 laminated on the base portion 24, respectively. A control unit 20, a communication module 21, and a storage unit 22 are housed in the base portion 24, and these elements are connected to each other via a bus line (see FIG. 2). Further, the control unit 20 and the display 23 are electrically connected to each other. The storage unit 22 is a non-volatile storage device including a hard disk, a flash memory, or the like, and stores a program for operating the communication device 2. Further, the storage unit 22 stores ID information (identification information) for identifying the communication device on the network 10.

The control unit 20 is composed of a CPU, RAM, ROM, and the like. The control unit 20 operates as an input unit 25, a display output unit 26, a local display output unit 27, a lighting information generation unit 28, and a communication information generation unit 29 by reading a program from the storage unit 22 and executing the program. The input unit 25 is telecommunications-enabled with the control unit 50 of the equipment device 5 via an input signal line or the like, and a signal from the control unit 50 is input. The display output unit 26 and the on-site display output unit 27 control the operation of the display unit 23 as described later. The operation of the lighting information generation unit 28 and the communication information generation unit 29 will be described later.

The display 23 is a device that emits light, and the display 23 of the present embodiment is a laminated signal lamp in which cylindrical lamps that emit light of different colors are laminated in the vertical direction. The display 23 of the present embodiment has lamps 230 to 232 of three colors of red, yellow, and green stacked in order from the top, and lamps 233 installed separately from them. The three-color lamps 230 to 232 of the display 23 are each associated with the status signal of the equipment 5, for example, "stop" when the red lamp 230 is lit, "abnormal" when the yellow lamp 231 is lit, and green. When the lamp 232 lights up, it indicates "normal". The display output unit 26 lights a lamp of a color corresponding to the status signal according to the status signal of the equipment device 5 input to the input unit 25. The number and colors of the lamps of the display 23 are not limited to this, and can be changed as appropriate.

The lamp 233 is used by the user to identify the physical position of the communication device 2. The local display output unit 27 turns on the lamp 233 when the local display request signal is received. Here, the local display request signal is a signal transmitted by the user from the host device 3 to the specific communication device 2 through the web browser of the information processing terminal 4. The user can inquire about the physical position of the communication device 2 in the factory equipment or the like by lighting the lamp 233 on the communication device 2 designated on the web browser of the information processing terminal 4.

When the display output unit 26 lights any of the lamps 230 to 232, the lighting information generation unit 28 generates lighting information for specifying the color of the lamp lit by the display output unit 26 in conjunction with the lighting. .. The lighting information generation unit 28 outputs the generated lighting information to the communication module 21 and causes the host device 3 to transmit the generated lighting information. Since the lighting information is information based on the status signal of the equipment device 5, the timing at which the lighting information is generated and transmitted is linked to the timing at which the status signal is input to the input unit 25. Further, there is a one-to-one correspondence between the lighting information and the operating status of the equipment device 5, and the lighting information indicates the operating status of the equipment device 5.

The communication information generation unit 29 generates communication information regarding the communication status, and causes the communication module 21 to transmit the communication information to the host device 3. The communication information may include information for identifying adjacent devices adjacent to each other on the communication device 2 and the network 10, and quality information regarding the quality of the communication path between the adjacent devices. The adjacent device is a device capable of directly communicating with the communication device 2 on the network 10, and may be another communication device 2 and a host device 3. In the present embodiment, the information that identifies the adjacent device is the ID information of the adjacent device. The quality information is an LQI value in the present embodiment, and the LQI value and the ID information of the adjacent device are held by the communication module 21 at the time of communication. The LQI value is represented by a numerical value from 0 to 255, and the larger the numerical value is, the higher the communication quality is, and the smaller the numerical value is, the lower the communication quality is.

The communication information generation unit 29 generates communication information when the network quality diagnosis described later is started, and transmits the generated communication information to the host device 3 via the communication module 21. As will be described later, the network quality diagnosis includes a real-time diagnosis and a long-term diagnosis. In the real-time diagnosis, the communication information generation unit 29 generates communication information when the communication information request signal transmitted from the host device 3 is received. In the long-term diagnosis, when a communication information request signal transmitted from the host device 3 at a predetermined cycle is received, the communication information generation unit 29 generates communication information each time. Here, the communication information request signal is a signal requesting the host device 3 to transmit the communication information of the communication device 2. The communication information generation unit 29 may be configured to spontaneously generate communication information at a predetermined cycle or a predetermined time and transmit it to the host device 3 regardless of the reception of the communication information request signal.

The communication module 21 is made of a communication module board or the like provided with an antenna for wireless communication. As a result, the communication device 2 functions as an element constituting the network 10, and communication with other communication devices 2 and the host device 3 becomes possible. The communication module 21 of this embodiment conforms to the ZigBee (registered trademark) communication standard, and the ID information stored in the storage unit 22 is a unique address conforming to the IEEE standard. The communication module 21 combines the lighting information generated by the lighting information generation unit 28 and the ID information of the communication device 2 and transmits the lighting information to the host device 3. Further, the communication module 21 combines the communication information generated by the communication information generation unit 29 and the ID information of the communication device 2 and transmits the communication information to the host device 3. Further, the communication module 21 receives various request signals transmitted from the host device 3. The communication module 21 may include a part or all of the control unit 20 and the storage unit 22.

The power supply of the communication device 2 is supplied from the equipment device 5. Therefore, the power ON / OFF state of the communication device 2 depends on the power ON / OFF state of the equipment device 5. When the power of the equipment 5 is turned off, the power of the communication device 2 installed therein is also turned off, and the communication device 2 is in an offline state, that is, in a state of not participating in the network 10.

As shown in FIG. 1, the host device 3 has a substantially rectangular parallelepiped appearance shape. The host device 3 is preferably mounted and used at a position where it is not physically obstructed from the plurality of communication devices 2, and is preferably mounted on the ceiling or wall surface of a building, for example. In the example shown in FIG. 1, the host device 3 is attached to the ceiling of the building. The host device 3 of the present embodiment is connected to a power source by a power cable or the like, and is mainly used in a state where the power is always on.

The host device 3 includes a control unit 31 housed inside a substantially rectangular parallelepiped housing, a communication module 32, a communication interface 33, and a storage unit 34, and these elements are connected via a bus line. Connected to each other. The control unit 31 is composed of a CPU, RAM, ROM, and the like. The communication interface 33 is an interface for communicating with the information processing terminal 4. In the present embodiment, the communication between the host device 3 and the information processing terminal 4 is performed in accordance with the Ethernet (registered trademark) standard. The user can communicate with the host device 3 via the web browser included in the information processing terminal 4.

The communication module 32 is made of a communication module board or the like provided with an antenna for wireless communication. As a result, the host device 3 functions as an element constituting the network 10, and communication with the communication device 2 becomes possible. The communication module 32 of this embodiment complies with the ZigBee® communication standard. The communication module 32 holds the ID information of the adjacent device and the LQI value indicating the quality of the communication path with the adjacent device at the time of communication. The adjacency device can be one or more communication devices 2 on the network 10. The communication module 32 may include a part or all of the control unit 31 and the storage unit 34.

The storage unit 34 is a non-volatile storage device including a hard disk, a flash memory, or the like, and has a program 344 for operating the host device 3 and ID information (identification information) for identifying the host device 3 on the network 10. It has been written. The ID information of the host device 3 of the present embodiment is a unique address conforming to the IEEE standard. Further, the threshold data 345 is stored in the storage unit 34. The threshold data 345 is a threshold for classifying the quality of the LQI value in the process of network quality diagnosis described later, and the threshold can be set as appropriate.

An ID information storage area 342 is secured in the storage unit 34. The ID information storage area 342 stores ID information of all communication devices 2 registered by the user as communication devices to be connected to the network 10. The ID information of the communication device 2 can be registered in advance by the user via the information processing terminal 4. In the ID information storage area 342, a user name given by the user to the communication device 2 may be registered in association with the ID information. Further, the user can appropriately rewrite the ID information storage area 342 as the new communication device 2 is added to the network 10 or the existing communication device 2 is deleted from the network 10. The storage unit 34 further secures a communication information storage area 340, a diagnosis result storage area 341, and a lighting information storage area 343. These areas will be described later.

The control unit 31 operates as a signal generation unit 310, a communication diagnosis unit 311, an information output unit 312, and an information collection unit 313 by reading and executing the program 344 from the storage unit 34. The signal generation unit 310 generates various request signals according to instructions from the user. The request signal is a status request signal, a local display request signal, and a communication information request signal. The communication information request signal is a signal requesting the host device 3 to transmit communication information regarding the communication status of each communication device 2. The user can instruct the signal generation unit 310 to generate a request signal via the information processing terminal 4.

When the lighting information is transmitted from the communication device 2, the information collecting unit 313 includes the ID information of the communication device 2 accompanying the information and the ID information of the communication device 2 registered in the ID information storage area 342. The ID information of the communication device 2 and the lighting information are associated with each other and stored in the lighting information storage area 343. The ID information and the lighting information may be stored in the lighting information storage area 343 in association with the time information such as the time when the lighting information is generated.

The information collecting unit 313 determines that, among the communication devices 2 registered in the ID information storage area 342, the communication device 2 for which the lighting information has not been transmitted within the predetermined time limit is in the offline state. In the offline state of the communication device 2, the power of the equipment 5 in which the communication device 2 is installed is turned off, or the power of the equipment 5 is turned on, but the communication device 5 is connected to the network 10 depending on the communication environment. Indicates that it may not be. Further, when the information collecting unit 313 detects the communication device 2 in which the lighting information has been transmitted but the ID information accompanying the lighting information is not registered in the ID information storage area 342, the communication device 2 is not registered. Judge. The information collecting unit 313 may also store the ID information and the lighting information of the unregistered communication device 2 detected during the synchronization in the lighting information storage area 343.

When the lighting information is repeatedly collected in a predetermined cycle, the information collecting unit 313 can separately store the set of the lighting information and the ID information of the communication device 2 in the lighting information storage area 343 for each cycle. The information collecting unit 313 counts the number of times each lamp is lit on each display 23 from the set of the accumulated lighting information and the ID information, and stores it in the lighting information storage area 343.

The information output unit 312 outputs the information collected from each communication device 2 by the information collection unit 313. The information output unit 312 of the present embodiment is configured to output the information collected in the form of a screen, and more specifically, generates a web screen that visualizes the counted lighting information. The user can access the network 10 from the web browser of the information processing terminal 4 and browse the web screen generated by the information output unit 312 on the display device 402. When the information processing terminal 4 makes a request to view the lighting information, the information output unit 312 may access the lighting information data stored in the lighting information storage area 343 and generate a web screen for displaying the list. can.

As shown in FIG. 3, for example, the web screen can be a list page that displays the number of times each lamp of the display 23 is lit for each communication device 2. In the example shown in FIG. 3, the user name and the ID information registered in advance in the ID information storage area 342 are displayed in the text boxes under "User name:" and "IEEE address:", respectively. A graphic representing the display 23 is drawn below it, and a text box on the side of the graphic representing each lamp displays the number of times each lamp has been lit within the previous period. The information output unit 312 may further draw a "local display request signal" button graphic below the graphic showing the display 23. When the user presses the "local display request signal" button graphic via the operation unit 404 of the information processing terminal 4, the signal generation unit 310 generates a local display request signal and transmits it to the designated communication device 2.

The information output unit 312 is registered in the ID information storage area 342, but for the communication device 2 determined to be offline by the information collection unit 313, the column of the communication device 2 is grayed out and displayed. You may do it. Further, although not shown in FIG. 3, for the communication device 2 determined to be unregistered, the ID information and the number of times of lighting may be displayed while the text box of the user name is left blank.

The information processing terminal 4 is, for example, a general-purpose personal computer, which includes a control unit 400, a storage unit 401, a display device 402, a communication interface 403, and an operation unit 404, and these elements are connected to each other via a bus line. ing. The control unit 400 is composed of a CPU, RAM, ROM, and the like. The storage unit 401 is a non-volatile storage device including a hard disk, a flash memory, or the like. The display device 402 may be a general-purpose display, and is composed of a liquid crystal display, an organic EL display, a plasma display, and the like. The communication interface 403 is an interface for communicating with the host device 3. The operation unit 404 is composed of a keyboard, a mouse, a touch panel, and the like, and receives instructions from the user. The user can set the operation of the system 1 via the operation unit 404, rewrite the ID information storage area 342, transmit the request signal, and access the information possessed by the host device 3. ..

The program 410 is stored in the storage unit 401. By reading and executing the program 410, the control unit 400 captures the web screen generated by the information output unit 312 and displays it on the display device 402, or receives a user's instruction via the operation unit 404. Can be done.

<2. Network quality diagnostic process>
Hereinafter, the network quality diagnosis process of the communication system 1 will be described by taking the network 10 shown in FIG. 4 as an example. In the present embodiment, there are a real-time diagnosis for diagnosing the communication quality at the time of inputting an instruction and a long-term diagnosis for diagnosing the communication quality at a predetermined cycle over a period specified by the user. The user selects whether to perform real-time diagnosis or long-term diagnosis from the web screen displayed on the display device 402 of the information processing terminal 4. When the user selects real-time diagnosis via the information processing terminal 4 and inputs an instruction to start diagnosis, the real-time diagnosis starts when the instruction is received by the host device 3. When the user selects a long-term diagnosis, specifies a period for performing the diagnosis, and then inputs an instruction to start the diagnosis, the long-term diagnosis starts when the instruction is received by the host device 3. Hereinafter, the processing of real-time diagnosis will be described as an example.

In the example shown in FIG. 4, one host device 3 and six communication devices 2 (hereinafter, referred to as 2a to 2f to distinguish them from each other) are connected to the network 10. It is assumed that the ID information of the communication devices 2a to 2f is already registered in the ID information storage area 342 of the host device 3.

The line in FIG. 4 shows the route currently available for communication. The devices connected by a line represent devices adjacent to each other on the network 10. For example, in the example of FIG. 4, the communication devices 2a to 2c are adjacent to the host device 3.

FIG. 6 is a flowchart showing the flow of the network quality diagnosis process. In step S1, the information collecting unit 313 of the host device 3 collects the LQI values each of the communication devices 2a to 2f and the ID information of the adjacent device, and the ID information of the communication device 2 that transmits these communication information. It is stored in the communication information storage area 340 in association with the above. Here, if there is a communication device 2 in which reception of communication information is not confirmed within a predetermined time limit even though the information collection unit 313 is registered in the ID information storage area 342, the communication device is the communication device. 2 is judged to be offline.

In step S2, the communication diagnosis unit 311 identifies the LQI value of each route based on the data stored in the communication information storage area 340, the ID information of the adjacent device of the host device 3, and the LQI value. Here, since both of the adjacent devices hold the LQI value for each route, two types of LQI values can be obtained for one route. The communication diagnosis unit 311 of the present embodiment adopts the higher of the two LQI values for one route as the LQI value specified for that route.

In step S3, the communication diagnosis unit 311 identifies a high-quality route from the routes of the network 10. The communication diagnosis unit 311 can refer to the threshold data 345 and specify a route having an LQI value higher than a predetermined threshold as a high quality route. In the example shown in FIG. 5, the route highlighted by the thick line represents the high quality route.

In step S4, the communication diagnosis unit 311 calculates the route distance from the host device 3 to the communication devices 2a to 2f via only the high-quality route. The route distance is the number of routes from the host device 3 to the specific communication device 2, and if the route distance is "1", it means that the communication device 2 is adjacent to the host device 3. ing. Further, if the route distance is "2", it indicates that one other communication device 2 is interposed from the host device 3 to the communication device 2. In the example shown in FIG. 5, the path distance from the host device 3 to the communication device 2a or the communication device 2c is "1", and the path distance from the host device 3 to the communication device 2b or the communication device 2d is "1". 2 ". Among the communication devices 2, in step S6 to be described later, those having a route distance of only the high quality route of "1" are assigned to rank A, those having a route distance of "2" or more are assigned to rank B or rank C, and the high quality route is assigned to the rank A. Those that do not are classified as rank D.

In the following step S5, the communication diagnosis unit 311 identifies the communication device 2 having a path distance of "1" from the host device 3 regardless of the quality of the communication path. That is, the communication diagnosis unit 311 distinguishes between the communication device 2 adjacent to the host device 3 and the communication device 2 not adjacent to the host device 3.

In the following step S6, the communication diagnosis unit 311 classifies each communication device 2 into ranks A to E according to the distance and quality of the communication path from the communication device 2 to the host device 3. With reference to the example of FIG. 5, the communication devices 2a and 2c are classified into rank A. Further, the communication device 2b determined in step S4 that the path distance of only the high-quality route is "2" or more and is adjacent to the host device 3 in step S5 is classified into rank B. On the other hand, the communication device 2d determined in step S4 that the path distance of only the high-quality route is "2" or more and is not adjacent to the host device 3 in step S5 is classified into rank C. .. The communication devices 2e and 2f that cannot reach the host device 3 only through the high quality route are classified into rank D. Further, since the communication devices 2e and 2f are not adjacent to the host device 3, they are classified into rank D. However, even if they are adjacent to the host device 3, if they cannot reach the host device 3 only by a high quality route, the relevant communication device 2e and 2f are classified. The communication device 2 is classified into rank D. If there is a communication device 2 determined to be in the offline state, the communication device 2 is classified into rank E.

Each rank shows the following information.
Rank A: Direct communication with the host device 3 is possible with sufficient quality, and there is no problem in the installation environment. Rank B: The quality of the direct communication with the host device 3 is not sufficient, but the quality of the multi-hopping communication is sufficient. Yes, there is no problem in the installation environment Rank C: Direct communication with the host device 3 is not possible, but the quality of the multi-hopping communication is sufficient, and there is no problem in the installation environment Rank D: The quality of the multi-hopping communication is sufficient. It is recommended to adjust the installation environment instead of Rank E: Communication is not possible

In step S7, the information output unit 312 generates a result display screen that lists and displays the diagnosis results of the communication diagnosis unit 311. FIG. 7 shows an example of a real-time diagnosis result display screen. In the example of FIG. 7, there are items such as "user name", "IEEE address", and "rank" in the first row of the table, and the columns of "user name" and "IEEE address" have the ID information storage area 342 in advance. The user name and ID information saved in are displayed. In the "rank" column, the rank in which each communication device 2 is classified is shown. The user can confirm the diagnosis result on the result display screen displayed on the display device 402 of the information processing terminal 4.

A "local display request" button graphic is drawn in the "confirmation" column of the result display screen. By clicking this via the operation unit 404, the user can transmit the local display request signal to the communication device 2 in the line where the button graphic is located. In addition, a "download" button graphic is drawn at the bottom right of the screen. By clicking this via the operation unit 404, the user can download and save the diagnosis result as tabular data or the like in the storage unit 401 of the information processing terminal 4.

FIG. 8 is a flowchart showing the flow of long-term diagnostic processing. The process from step S1 to step S6 is common to the real-time diagnosis, but the process proceeds to step S8 after step S6. In step S8, the communication diagnosis unit 311 associates the ID information of the communication device 2, the rank and the time information classified in step S6, and stores them in the diagnosis result storage area 341. The processing from step S1 to step S8 is repeated at a predetermined cycle during the period specified by the user. That is, new diagnosis result data is accumulated in the diagnosis result storage area 341 every time one cycle elapses.

When the period specified by the user ends, the process proceeds to step S9, the information output unit 312 reads out the data stored in the diagnosis result storage area 341, and the ID information and rank of each communication device 2 are read in chronological order. Generate a result display screen to display a list. FIG. 9 shows an example of a long-term diagnosis result display screen. In the example shown in FIG. 9, there are items such as "user name", "IEEE address", and "rank" in the first row of the table, and cells separated by time are displayed under "rank". .. In the example shown in FIG. 9, five cells whose ranks are displayed are formed under the cell representing the time unit of one hour, and the processes of steps S1 to S8 are performed every 12 minutes. I understand. The result display screen may be generated so that the diagnosis result from the start to the end of the specified period can be viewed by the side-scrolling operation along the time series.

After the end of the designated period, the user inputs an instruction to display the result display screen on the display device 402 via the web browser of the information processing terminal 4. The user can confirm the transition of the rank of each communication device 2 in the designated period from the result display screen displayed on the display device 402. The information output unit 312 may be configured to draw a "local display request" button graphic and a "download" button graphic even on the long-term diagnosis result display screen.

The user can easily grasp the transition of the communication status of each communication device 2 from the result display screen as illustrated in FIG. Then, the user can identify the time zone in which the communication device 2 is rank D and rank E, and verify the communication environment in that time zone to find the cause of the unstable communication. For example, if the power of the equipment 5 is turned off in a certain time zone, the communication device 2 installed in the equipment 5 is classified into rank E in the same time zone. From this, the user can estimate whether the reason why the communication device 2 is ranked E is due to the power off of the equipment device 5 or the communication environment.

<3. Features>
The communication system 1 according to the above embodiment can diagnose the state of the network 10 for monitoring the operating status of the equipment 5 and visualize the diagnosis result. In the conventional communication system, each device connected to the network may indicate whether or not its own communication status is stable by lighting a lamp or the like of the device. However, in such a configuration, the stability of the communication status cannot be confirmed unless the user moves to the installation location of each device and confirms the display of the lamp. In the communication system 1 according to the above embodiment, the host device 3 collects the communication information of each communication device 2 and visualizes the diagnosis result. As a result, the user can centrally grasp the communication status of each communication device 2 without checking the communication status on site. Further, in the conventional configuration in which each device itself displays its own communication status, the time-series communication status is not saved, but in the communication system 1 according to the above embodiment, the rank of each communication device 2 is time-series. It is saved in order, and you can check the transition of rank.

In the communication system 1 according to the above embodiment, the diagnosis of the communication path is performed in the relationship between each communication device 2 and the host device 3. Therefore, the diagnosis is performed in consideration of not only the quality of the direct communication between the communication device 2 and the host device 3 but also the quality of the multi-hop communication, and the status of the network 10 can be grasped in more detail.

<4. Modification example>
Although some embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the spirit of the present invention. For example, the following changes are possible. In addition, the gist of the following modifications can be combined as appropriate.

(1)
As shown in FIG. 2, the control units of the communication device 2 and the host device 3 are each divided into a plurality of units. However, these divisions are conceptual divisions and do not need to be physically distinguished. Similarly, each storage area 340 to 343 secured in the storage unit 34 of the host device 3 is a conceptual division and does not need to be physically distinguished.

(2)
In the above embodiment, the communication standard between the host device 3 and the information processing terminal 4 is Ethernet (registered trademark), but it may be changed to another communication standard. Further, the communication between the host device 3 and the information processing terminal 4 may be performed wirelessly instead of by wire. Further, the information processing terminal 4 may be a portable device such as a tablet terminal, a smartphone, or a notebook PC instead of a general-purpose personal computer.

(3)
The equipment device 5 may be a switch manually operated by a worker in addition to a machine used for production or the like, and the display 23 may be an Andon device or the like that displays a signal input to the switch. .. In this case, the status signal is the signal input to the switch. The switch may have any form such as a push button type, a switching lever type, and a dial type. Further, the configuration of the display 23 may be omitted.

(4)
As shown by an example in FIG. 10, the display 23, the input unit 25, and the display output unit 26 may be provided in another device 6 configured as a separate body from the communication device 2. Each communication device 2 has a photodetector 200 that detects the light emitted by the lamps 230 to 232 of the assigned display 23, and is installed so that the light detection unit 200 can detect the light emitted by the display 23. You may. The lighting information generation unit 28 may be configured to generate lighting information as to which color of the lamp is lit based on the detection result of the photodetector, and transmit the generated lighting information to the host device 3. ..

(5)
The signal generation unit 310, the communication diagnosis unit 311 and the information output unit 312 may be provided in the information processing terminal 4 instead of the host device 3. That is, the communication information and lighting information collected by the host device 3 are output to the information processing terminal 4, and the information processing terminal 4 generates various request signals, performs network diagnostic processing, and visualizes the lighting information on the screen and diagnosis. It may be configured to generate a result display screen. Similarly, at least a part of the communication information storage area 340, the diagnosis result storage area 341, the ID information storage area 342, the lighting information storage area 343, and the threshold data 345 is not the host device 3 but the storage unit 401 of the information processing terminal 4. May be prepared for.

(6)
The mode in which the information output unit 312 outputs lighting information, communication information, and network quality diagnosis results is not limited to the web screen as in the above embodiment. The information output unit 312 may output lighting information, communication information, and network quality diagnosis results to the information processing terminal 4 or an external device in a data format other than screen data.

(7)
The method of network diagnosis processing is not limited to that of the above embodiment, and can be appropriately changed as long as it is a method that can diagnose the quality of the communication path between each communication device 2 and the host device 3.

(8)
In the above embodiment, the communication between the plurality of communication devices 2 and the host device 3 is based on ZigBee (registered trademark), but the communication method is not limited to this, for example, Wi-Fi (registered trademark) and Bluetooth (registered trademark). It may be a trademark) or the like. Further, the ID information that identifies the communication device 2 and the host device 3 on the network 10 may be an identifier different from that of the above embodiment as long as it is a physical address that uniquely identifies the device. Further, the quality information is not limited to the LQI value, and may be, for example, a value indicating the radio wave intensity.

1 Communication system 2 Communication device 3 Host device 4 Information processing terminal 5 Equipment device 10 Wireless communication network 23 Display 25 Input unit 26 Display output unit 27 Local display output unit 200 Optical detection unit 310 Signal generation unit 311 Communication diagnosis unit 312 Information output Department 313 Information Collection Department

Claims (10)

With multiple communication devices connected to the wireless communication network,
A host device connected to the wireless communication network is provided.
The host device includes an information collecting unit that collects communication information about the communication status of each of the plurality of communication devices from each of the plurality of communication devices, and an information output unit that outputs the communication information collected by the information collecting unit. Have,
Communications system. The wireless communication network is a mesh network in which the plurality of communication devices are connected so as to be able to communicate with each other.
The communication information includes information for identifying an adjacent device adjacent to the mesh network among the plurality of communication devices and the host device.
The communication system according to claim 1. The communication information includes quality information regarding the quality of a communication path between each of the plurality of communication devices and the adjacent device.
The communication system according to claim 2. The host device classifies the quality of the communication path between each of the plurality of communication devices and the host device into predetermined ranks based on the quality information collected from the plurality of communication devices. Has more parts,
The communication system according to claim 3. The information output unit generates a screen for displaying the identification information that identifies each of the plurality of communication devices in association with the rank classified by the communication diagnosis unit.
The communication system according to claim 4. The host device further has a storage unit that stores the identification information in association with the classified rank, and the information output unit has the identification information stored in the storage unit and the classified rank. Generate a screen that displays in chronological order,
The communication system according to claim 5. Each of the plurality of communication devices has an input unit to which a signal from another device to which the device is assigned is input, a display that emits light, and a display that displays light corresponding to the signal input to the input unit. It has a display output unit that emits light from the device.
The communication system according to any one of claims 1 to 6. Each of the plurality of communication devices has a display that emits light and a local display output unit that emits light to the display in response to a request from the host device.
The communication system according to any one of claims 1 to 7. Each of the plurality of communication devices has a photodetector that detects light, and transmits the detection result of the photodetector to the host device.
The communication system according to any one of claims 1 to 8. A step of collecting communication information regarding the communication status of each of the plurality of communication devices from each of the plurality of communication devices connected to the wireless communication network, and
The step of aggregating and outputting the collected communication information and
Let the computer run
program.

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