JP2009239384A - Communication system and communication method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a communication system for quickly and easily performing maintenance of each function and reducing costs required for addition by providing each apparatus with each function. <P>SOLUTION: The communication system comprises: connection means 301 and 401 communicable with a host device; path selection means 201 and 211 connected to the connection means 301 and 401, for selecting a path of a packet during communication; communication means 303, 313 and 403 connected to the path selection means 201 and 211 and a terminal, and communicable with the terminal; control means 302 and 402 for controlling the communication means 303, 313 and 403; controlling and monitoring means 305 and 405 for controlling the operations of the respective means; and a synchronizing means 101 for synchronizing the respective means. Each of the means is provided individually. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a communication system and a communication method for performing communication between a host device and a terminal.

In recent years, for example, with the development of IP communication and the like, various communication systems such as mobile communication using high-rate Ethernet (registered trademark) and the like are used (for example, see Patent Documents 1 to 4).
In such a mobile communication system or the like, traffic may increase at a specific time, and sometimes a situation exceeding the capacity of the system may occur.
Here, today, due to the diversification of services, transmission at a higher rate has been demanded.
Therefore, when traffic increases, it is necessary to add as necessary to maintain and improve performance.
JP 2006-319972 A JP 2007-074097 A JP 2005-333625 A JP 2004-297621 A

However, in the communication system as described above, there is a problem that the base station itself needs to be additionally installed and the cost increases.
In addition, although the communication network itself at the device end is common to each vendor, individual function units inside the device are vendor-specific, so if a problem specific to a specific vendor occurs, the system must be restored. There is a problem that it takes a lot of time.

  The present invention has been made in view of such circumstances, and by providing an individual device for each function, maintenance can be performed quickly and easily for each function, and the cost for expansion can be reduced. It is an object to provide a communication system and a communication method that can be reduced.

In order to solve the above problems, the present invention provides the following means.
The present invention is a communication system that performs communication between a host device and a terminal, and is connected to the host device and performs processing capable of communication with the host device; and A route selection unit that is connected to select a route of a packet at the time of communication; a communication unit that is connected to the route selection unit and the terminal and performs a process capable of communicating with the terminal; and the route Control means connected to the selection means for controlling the communication means, the connection means, the route selection means, a control monitoring means for controlling the operation of the communication means and the control means, the connection means, the route selection Synchronization means for synchronizing the communication means, the communication means, the control means and the control monitoring means, the connection means, the route selection means, the communication means, the control means, the control monitoring means and the front Synchronization means, respectively, characterized in that it is provided as a separate device.

  According to the present invention, it is possible to individually add and repair devices for each function, and to reduce the cost for the addition.

  Further, the present invention is characterized in that the control monitoring unit acquires operation information indicating whether or not the operation is possible from each device, and performs load distribution between the devices based on the operation information. To do.

  According to the present invention, it is possible to maintain and improve the performance of the entire system.

  Further, the present invention comprises a plurality of local communication systems each having each device, the control monitoring means provided in one local communication system obtains the operation information from each device provided in another local communication system, Based on the operation information, load distribution among the devices is performed across the one local communication system and the other local communication system.

  According to the present invention, even when a problem occurs in the local communication system, it is possible to maintain and improve the performance of the entire system.

  In addition, the present invention is characterized by comprising encryption means for encrypting vendor-specific information of each device.

  According to the present invention, vendor-specific information can be protected and security can be improved.

  In addition, the present invention is a communication method in a communication system that performs communication between a host device and a terminal, and a connection unit connected to the host device performs a process capable of communicating with the host device. A connection step; a route selection step in which a route selection unit connected to the connection unit performs packet route selection during communication; and a communication unit connected to the route selection unit and the terminal. A communication step for performing processing that can be communicated between, a control means connected to the route selection means, a control step for controlling the communication means, and a control monitoring means, the connection means, the route selection means, A control monitoring step for controlling the operation of the communication means and the control means; and a synchronization means for the connection means, the route selection means, the communication means, the control means and the control monitoring means. And a the synchronization synchronization step, said connection means, said routing means, said communication means, said control means, said control monitoring means and said synchronizing means, respectively characterized in that it is a separate device.

  According to the present invention, it is possible to individually add and repair devices for each function, and to reduce the cost for the addition.

  According to the present invention, by providing an individual device for each function, maintenance can be performed quickly and easily for each function, and the cost for expansion can be reduced.

(Embodiment 1)
Hereinafter, a communication system according to a first embodiment of the present invention will be described with reference to the drawings.
FIG. 1 shows a communication system as a first embodiment of the present invention.
The communication system 1 is formed by connecting one local communication system A and another local communication system B through a network.
In the present embodiment, it is assumed that the local communication system A and the local communication system B have the same function.
The local communication system A includes an independent device for each function. That is, the local communication system A includes a main router (route selection means) 201, a sub-router 202, a transmission path device (connection means) 301, communication data control devices (control means) 302 and 312 and communication data processing devices ( Communication means) 303, 313, a common control monitoring device (control monitoring means) 305, and wireless devices 304, 314. The local communication system A includes a transmission line network 100, a synchronization device (synchronization means) 101, an optical switch 104, a local network 102, and a synchronization network 103.
The transmission line network 100, the synchronization device 101, and the optical switch 104 are also used for the local communication system B.

Further, the local communication system B includes an independent device for each function. That is, the local communication system B includes a main router (route selection means) 211, a subrouter 212, a transmission path device (connection means) 401, a communication data control device (control means) 402, and a communication data processing device (communication means). 403, a wireless device 404, and a common control monitoring device (control monitoring means) 405. The local communication system B includes a transmission line network 100, a synchronization device 101, an optical switch 104, a local network 112, and a synchronization network 113.
The local communication system A and the local communication system B are connected to each other, and a network is connected among the synchronization device 101, the main router 201, and the main router 211.

The transmission line network 100 is provided by a telecommunications carrier. That is, the transmission line network 100 is an ATM line or IP line transmission line network prepared by a telecommunications carrier. A plurality of communication systems are connected, and communication with a host device is performed via the transmission line network 100. .
The synchronization device 101 is connected to the local communication system A and the local communication system B, and controls the synchronization of the entire system and the network between the communication systems. The synchronization device 101 has a function of supplying a periodic synchronization signal according to IEEE 1588 prepared by a communication carrier to the local communication system A and the local communication system B. In addition, the synchronization device 101 transmits a synchronization signal and time information to each device based on a GPS or the like or a system clock from the outside at the start of the synchronization process, and after receiving a response from each device, the first synchronization It has a function of calculating an offset of a signal and a response and transmitting an offset value to each device. Further, the synchronization device 101 communicates with the common control monitoring device 305 and the common control monitoring device 405 via the local networks 102 and 112, and based on the traffic state, the link between the main router 201 and the main router 211 is communicated. It has a function to perform control.

The local networks 102 and 112 are high-rate Ethernet (registered trademark) networks through which communication data such as user data and control data flows.
The local network 102 is a network connected to the synchronization device 101, the transmission line device 301, the communication data control devices 302 and 312, the communication data processing devices 303 and 313, and the common control monitoring device 305 via the main router 201. That is, all communication data in the local communication system A is exchanged via the local network 102.
Similarly, the local network 112 is a network connected to the synchronization device 101, the transmission path device 401, the communication data control device 402, the communication data processing device 403, and the common control monitoring device 405 via the main router 211. That is, all communication data in the local communication system B is exchanged via the local network 112.

The synchronization networks 103 and 113 are Ethernet (registered trademark) networks for synchronizing the devices.
The synchronization network 103 transmits the synchronization signal from the synchronization device 101 to the transmission path device 301, the communication data control devices 302 and 312, the communication data processing devices 303 and 313, and the common control monitoring device 305 via the subrouter 202. That is, the synchronization signal in the local communication system A is transmitted to each device via the synchronization network 103.
Similarly, the synchronization network 113 transmits the synchronization signal from the synchronization device 101 to the transmission path device 401, the communication data control device 402, the communication data processing device 403, and the common control monitoring device 405 via the subrouter 212. That is, the synchronization signal in the local communication system B is transmitted to each device via the synchronization network 113.

The main routers 201 and 211 are routers that relay a local network between devices.
The main router 201 is a router that performs route selection of the local network 102, and has a function of controlling change of route selection from the common control monitoring device 305.
Similarly, the main router 211 is a router that performs route selection of the local network 112, and has a function of controlling change of route selection from the common control monitoring device 405.
The sub-routers 202 and 212 are routers that relay the synchronous networks 103 and 113 between the devices.
The subrouter 202 has a function of a router that performs route selection of the synchronous network 103.
Similarly, the subrouter 212 has a function of a router that performs route selection of the synchronous network 113.

  The transmission path devices 301 and 401 are connected to the transmission path network 100 and terminate the transmission path. The transmission path devices 301 and 401 are devices that connect the host device and the local communication system A or the local communication system B. These transmission path devices 301 and 401 are configured to send IP packets for the local networks 102 and 112 to the local networks 102 and 112, regardless of whether the transmission path network 100 is an ATM line or an IP line. Data is transmitted and received after being converted into packets for the transmission line network 100. Also, the transmission path devices 301 and 401 provide the transmission path network 100 with an identification field in the packet so that the vendor specific information can be recognized as vendor specific information. Send it out. Further, the transmission path devices 301 and 401 have a function of extracting a clock from the ATM network and supplying it as the system clock of the synchronization apparatus 101 when the transmission path network 100 is an ATM line.

The communication data control devices 302, 312, and 402 manage user data based on control data and set and release a wireless line. These communication data control devices 302, 312, and 402 communicate with the communication data processing devices 303, 313, and 403 based on the control data from the respective transmission path devices 301 and 401, such as setting and releasing of wireless lines. It has a function to perform processing control.
The communication data processing devices 303, 313, and 403 perform processing such as modulation and demodulation of user data of communication data, conversion to radio data and inverse conversion, encoding, spreading, and despreading. The communication data processing devices 303, 313, and 403 control user data from the transmission path devices 301 and 401 or wireless data from the wireless devices 304, 314, and 404, and control the communication data control devices 302, 302, and 402. And a function of performing communication such as modulation / demodulation and encoding.

  The wireless devices 304, 314, and 404 transmit and receive wireless data and perform wireless communication with terminals. The wireless devices 304, 314, and 404 amplify the wireless frequency power of the wireless data from the communication data processing devices 303, 313, and 403, and transmit them to the terminal wirelessly. In addition, it has a function of amplifying the radio frequency from the terminal to a required reception level, converting this to radio data, and transmitting it to the communication data processing devices 303, 313, and 403.

  The common control monitoring devices 305 and 405 control traffic on the local networks 102 and 112, management of failure information, and operation of each device. The common control monitoring devices 305 and 405 manage the traffic state in the local communication system A or the local communication system B, respectively, and control the used bandwidth of the local networks 102 and 112 via the communication data control devices 302, 302, and 402. And load distribution within the local communication systems A and B and load distribution between systems. The failure information of each device in each local communication system A, B is collected in the common control monitoring devices 305, 405. The common control monitoring devices 305, 405 pass the failure information through the local networks 102, 112. Then, the transmission path devices 301 and 401 transmit (report) to the higher level apparatus through the transmission path network 100. Furthermore, the common control monitoring devices 305 and 405 have a function of reading only the operation information indicating the operational status of each device and autonomously distributing the load. Further, the common control monitoring devices 305 and 405 exchange load information between the common control monitoring device 305 and the common control monitoring device 405 via the local networks 102 and 112, and the same device in different communication systems (main Routers 201 and 211, sub-routers 202 and 212, transmission path devices 301 and 401, communication data control devices 302, 312, and 402, and communication data processing devices 303, 313, and 403). Have.

The optical switch 104 performs optical data path selection. That is, the communication data processing devices 303, 313, 403 and the wireless devices 304, 314, 404 are interconnected via the optical switch 104.
Each device includes an encryption unit (not shown) for encrypting vendor-specific information. That is, by using the IP encryption function, vendor-specific information is encrypted and transmitted / received.

Next, the operation of the communication system 1 will be described in detail with reference to the flowcharts of FIGS. Note that the local communication system B is assumed to have links between the devices.
As shown in FIG. 2, the subrouter 202 establishes a link with each connected device (step S1). Then, the main router 201 establishes a link with the connected device (step S2). Further, the synchronization device 101 generates a synchronization signal based on an external system clock and synchronizes with each device in the local communication system A. Note that the links in the local communication system B are also established and synchronized in the same manner as described above.
Further, the synchronization device 101 invalidates only the link between the common control monitoring device 305 and the common control monitoring device 405 with respect to the common control monitoring device 305 established with the main router 201 in step S2, and the main router The main router 201 and the main router 211 are set via the local networks 102 and 112 so that another link is established between the main router 211 and the main router 211 (step S3).

Next, the common control monitoring device 305 transmits a status report request to each device in order to confirm the traffic status in the local network 102 (step S4). At this time, since the link between the common control monitoring device 305 and the common control monitoring device 405 is invalid, the common control monitoring device 305 confirms the traffic state only in the local communication system A.
Then, the common control monitoring device 305 determines the initial load distribution in the local communication system A from the traffic state in the local network 102 returned from each device, and the communication data control devices 302 and 312 The range of the communication data processing device 303 and the communication data processing device 313 to be controlled is notified (step S5).

Further, the common control monitoring device 305 notifies the transmission line device 301 of the initial load distribution information in step S5 (step S6). The transmission path device 301 sets a destination when transmitting communication data of the transmission path network 100 to each device on the local network 102 based on the load distribution information notified from the common control monitoring apparatus 305 (step). S7). Then, the transmission line device 301 receives communication data from the transmission line network 100 (step S8).
Further, when the transmission line network 100 is an ATM line, the transmission line device 301 extracts the system clock from the transmission line network 100 and transmits it to the synchronization device 101 (step S9). Then, based on the system clock output from the transmission path device 301, the synchronization device 101 synchronizes each device with the local communication system A again (step S10).
If the transmission line network 100 is an IP line, the processes in steps S9 and S10 are omitted.

Further, the transmission line device 301 generates an IP packet for the local network 102. At this time, if the communication data is control data, the transmission line device 301 generates an IP packet using the SCTP protocol, and if it is user data, generates the IP packet using the UDP protocol in consideration of the transfer rate. Then, the transmission path device 301 transmits the generated IP packet to the main router 201 (step S11).
Then, when an IP packet for user data is transmitted from the transmission path device 301, the main router 201 selects a route to the corresponding device based on the IP address (step S12).
On the other hand, when an IP packet for control data is transmitted from the transmission path device 301, the main router 201 transmits the control data of the IP packet to the communication data control devices 302 and 312 based on the IP address. The communication data control devices 302 and 312 control the communication data processing devices 303 and 313 based on the control data received via the main router 201 (step S13).

The communication data processing devices 303 and 313 process user data received via the main router 201 based on the control from the communication data control devices 302 and 312 and convert the data into wireless data (step S14). Then, the communication data processing devices 303 and 313 set the wireless data to the wavelengths for the wireless devices 304 and 314, and transmit them to the optical switch 104 through the optical interface (step S15).
The optical switch 104 performs route selection and transmits the received wireless data to the wireless device 304 or the wireless device 314 of the corresponding wavelength (step S16).
The wireless devices 304 and 314 amplify the radio frequency signal from the wireless data transmitted from the optical switch 104, and transmit user data to the terminal (step S17).

Further, the wireless devices 304 and 314 that have received the user data from the terminal amplify the wireless frequency from the terminal to a necessary reception level to obtain wireless data, and transmit the wireless data to the optical switch 104 (step S18).
The optical switch 104 transmits the received wireless data to the communication data processing devices 303 and 313 based on the route selection set in step S16 (step S19).
The communication data processing devices 303 and 313 process the received wireless data, convert the processed user data into IP packets for the local network 102 based on control by the control devices 302 and 312, and the main router 201. Then, the data is transmitted to the transmission line device 301 (step S20).
Furthermore, the transmission line device 301 changes the IP address to an IP packet for an ATM cell if the transmission line network 100 is an ATM line, or an IP packet for the transmission line network if the transmission line network 100 is an IP line, and transmits the user data to the transmission line network 100 ( Step S21).

Next, the operation of the local communication system A when a failure occurs in the local communication system A where the communication data processing device 313 cannot continue operation will be described with reference to FIG.
The communication data processing device 313 transmits the operation information indicating the operable state and the failure information to the common control monitoring device 305 (step S22). At this time, the communication data processing device 313 encrypts and transmits only the failure information.
Then, the common control monitoring device 305 reads only the operation information from the received information, and transmits the failure information from the local network 102 to the transmission line device 301 via the main router 201 (step S23).
The transmission line device 301 transmits the received failure information to the host device via the transmission line network 100 (step S24).

Further, if the operation information is not operable, the common control monitoring device 305 changes the communication data control devices 302 and 312 to change the range of communication data processing devices to be controlled only to the communication data processing device 303. The transmission path device 301 is notified of the change of the load distribution information. In addition, if the operation information is operable, the common control monitoring device 305 does not notify the communication data control devices 302 and 312 of the change of the controlled range unless there is control from the host device. In addition, the change of the load distribution information is not notified to the transmission line device 301 (step S25).
The communication data control devices 302 and 312 control the communication data processing device 303 based on the notification of the change of the control range from the common control monitoring device 305 (step S26).
Then, the transmission line device 301 changes the destination of the communication data based on the load distribution information notified from the common control monitoring device 305 (step S27).

Next, the operation of addition dispersion will be described with reference to FIG.
When the load on the communication data control device 312 and the communication data processing device 313 increases, the common control monitoring device 305 performs load distribution so that the loads on the communication data control devices 302 and 312 and the communication data processing devices 303 and 313 are equalized. Information is updated (step S28).
Further, the common control monitoring apparatus 305 performs communication load control in the local communication system A based on the updated load distribution information, so that the communication data processing apparatuses 303 and 313 that control the communication data control apparatuses 302 and 312 are controlled. Notify change of control range. Further, the load distribution information is also notified to the transmission line device 301 (step S29).
The transmission line device 301 changes the destination of the communication data based on the notified load balancing information (step S30).

Next, an operation when a failure occurs in the communication data processing device 403 in the local communication system B will be described with reference to FIG.
When the communication data processing device 403 in the local communication system B fails, the operation in the local communication system B cannot be performed, so that the common control monitoring device 405 communicates with the common control monitoring device 305 via the main routers 211 and 201. The operation disabled information indicating that the communication system B cannot be operated, the necessary load information, and the MAC address and IP address of each device in the local communication system B are notified (step S31).
Based on the notification received from the common control monitoring device 405, the common control monitoring device 305 determines the load of the communication data control devices 302 and 312 and the communication data processing devices 303 and 313 in the local communication system A and the local communication system B. The load distribution information is updated so that the load does not affect the operation (step S32).

  Further, since the common control monitoring device 305 performs load distribution between the local communication system A and the local communication system B, communication data processing for controlling the communication data control devices 302 and 312 based on the updated load distribution information. A change in the range of the devices 303 and 313 is notified. Further, the load distribution information is also notified to the transmission path device 301, the common control monitoring device 405, and the synchronization device 101, and the MAC address and IP address of each device in the local communication system A are notified to the common control monitoring device 405. Notify the address. Further, the common control monitoring device 305 updates the route selection of the main router 201 based on the MAC address and IP address information of each device in the local communication system B notified from the common control monitoring device 305 (step S33). ).

Then, the synchronization apparatus 101 calculates an offset value from the synchronization signal of the local communication system A and the synchronization signal of the local communication system B, and passes through the subrouter 212 to each apparatus in the local communication system B via the synchronization network 113. The offset value is transmitted, and the synchronization in the local communication system B is updated (step S34).
Based on the load distribution information transmitted from the common control monitoring device 305, the common control monitoring device 405 notifies the communication data control device 402 of the range of the communication data processing devices 303 and 313 to be controlled. The common control monitoring device 405 also notifies the transmission line device 401 of load distribution information. Further, the common control monitoring device 405 updates the route selection of the main router 211 based on the MAC address and IP address information of each device in the local communication system A notified from the common control monitoring device 305 (step S35). ).
The transmission path devices 301 and 401 operate by changing the destination of the communication data based on the load distribution information notified in step S33 and step S35. At this time, the communication data processing devices 303 and 313 generate wireless data of the wireless device 404 and optically communicate with the wavelength for the wireless device 404, and the optical switch 104 selects the wireless data for the wireless device 404. Therefore, there is no influence on the terminals under the radio apparatus 404 (step S36).

Next, an operation when a failure occurs in the communication data control apparatus 402 in the local communication system B will be described with reference to FIG.
When the communication data control device 402 in the local communication system B fails, the operation in the local communication system B cannot be performed, so that the common control monitoring device 405 communicates with the common control monitoring device 305 via the main routers 211 and 201. The operation disabled information indicating that the operation of the communication system B cannot be performed, the necessary load information, and the MAC address and IP address of each device in the local communication system B are notified (step S37).
Based on the notification received from the common control monitoring device 405, the common control monitoring device 305 determines the load on the communication data control devices 302 and 312 and the communication data processing devices 303 and 313 in the local communication system A and the load on the local communication system B. The load balancing information is updated so as not to affect the operation (step S38).

Further, the common control monitoring device 305 performs communication data to control the communication data control devices 302 and 312 in order to perform load distribution between the local communication system A and the local communication system B based on the updated load distribution information. The range of the processing devices 303, 313, and 403 is notified. Further, the load distribution information is also notified to the transmission path device 301, the common control monitoring device 405, and the synchronization device 101, and the MAC address and IP of each device in the local communication system A are notified to the common control monitoring device 405. Notify the address. Further, the common control monitoring device 305 updates the route selection of the main router 201 based on the MAC address and IP address information of each device in the local communication system B notified from the common control monitoring device 405 (step S39). .
The synchronization device 101 calculates an offset value from the synchronization signal of the local communication system A and the synchronization signal of the local communication system B, and sends the offset value to each device in the local communication system B by the synchronization network 113 via the subrouter 212. And the synchronization in the local communication system B is updated (step S40).

The common control monitoring device 405 notifies the communication data control device 402 of the range of the communication data processing devices 303 and 313 to be controlled based on the load distribution information notified from the common control monitoring device 305. The common control monitoring device 405 also notifies the transmission path device 301 of load distribution information. Furthermore, the common control monitoring device 405 updates the route selection of the main router 211 based on the MAC address and IP address information of each device in the local communication system A notified from the common control monitoring device 305 (step S41). ).
The transmission line devices 301 and 401 change and operate the destination of the communication data based on the load distribution information notified in step S39 and step S41 (step S42).

As described above, according to the communication system 1 in the present embodiment, even when a failure that cannot be performed occurs in the devices in the local communication systems A and B, communication with terminals under the system can be performed by using a device of another system. It can be carried out.
Moreover, since what is normally operated by one apparatus is apparatus-ized independently for every function part, the expansion according to the traffic condition and load distribution can be performed easily.
Furthermore, since what is normally operated by one device is deviceized independently for each functional unit, even if the communication system is configured by different vendors, the communication system itself is operated due to the problem of unique vendors. It is possible to avoid a state where it cannot be done.
In addition, development costs for each function can be reduced.

Even when the transmission line device fails, the system can be operated using the transmission line device of another communication system as in the example shown in the present embodiment.
The technical scope of the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.

(Background of the present invention)
In mobile communications, traffic may increase at a specific time, often exceeding the capacity of the device. This increase in traffic sometimes requires a device of the same scale when the number of devices is increased or when the load increases significantly because the current device configuration satisfies many functions. . If an apparatus is provided for each function, the cost of adding is small, and there is a case where the adding itself is not necessary by distributing the load with the adjacent communication system. Furthermore, as services diversify, transmission at a high rate is required, but even if it corresponds to these, if many functions are satisfied with a single device, it may not be sufficient to make a partial change. In such a case, if an apparatus is provided for each function, the scale of change is smaller than when a single apparatus satisfies many functions.

1 is an overall configuration diagram showing an embodiment of a communication system according to the present invention. It is a flowchart which shows operation | movement of a communication system. It is a flowchart which shows operation | movement of a communication system. 6 is a flowchart showing an operation when a failure occurs in a device in the local communication system A. It is a flowchart which shows the operation | movement about addition dispersion | distribution. 6 is a flowchart showing an operation when a failure occurs in a device in the local communication system B. 10 is a flowchart showing an operation when a failure occurs in another device in the local communication system B.

Explanation of symbols

1 Communication System 101 Synchronization Device (Synchronization Means)
201, 211 Main router (route selection means)
301, 401 Transmission path device (connection means)
302, 312, 402 Communication data control device (control means)
303, 313, 403 Communication data processing device (communication means)
305, 405 Common control monitoring device (control monitoring means)
A, B Local communication system

Claims (5)

A communication system for performing communication between a host device and a terminal,
A connection means connected to the host device for performing processing capable of communicating with the host device;
Route selection means connected to the connection means for performing packet route selection during communication;
A communication unit that is connected to the route selection unit and the terminal and performs a process capable of communicating with the terminal;
Control means connected to the route selection means for controlling the communication means;
Control monitoring means for controlling operation of the connection means, the route selection means, the communication means and the control means;
Synchronization means for synchronizing the connection means, the route selection means, the communication means, the control means and the control monitoring means,
The communication system, wherein the connection means, the route selection means, the communication means, the control means, the control monitoring means, and the synchronization means are provided as separate devices.   2. The control monitoring unit according to claim 1, wherein the control monitoring unit acquires operation information indicating whether or not the operation is possible from each device, and performs load distribution among the devices based on the operation information. Communication system. A plurality of local communication systems having each device,
Control monitoring means provided in one local communication system acquires the operation information from each device provided in another local communication system, and based on the operation information, the one local communication system and the other local communication The communication system according to claim 2, wherein load distribution is performed among the devices over the system.   The communication system according to any one of claims 1 to 3, further comprising an encryption unit configured to encrypt vendor-specific information of each device. A communication method in a communication system for performing communication between a host device and a terminal,
A connection step in which connection means connected to the higher-level device performs a process capable of communicating with the higher-level device; and
A route selection step in which the route selection means connected to the connection means performs route selection of a packet during communication;
A communication step in which a communication unit connected to the route selection unit and the terminal performs a process capable of communicating with the terminal;
A control unit connected to the route selection unit controls the communication unit;
A control monitoring step for controlling operation of the connection means, the route selection means, the communication means and the control means;
Synchronization means includes a synchronization step of synchronizing the connection means, the route selection means, the communication means, the control means and the control monitoring means,
The communication method, wherein the connection unit, the route selection unit, the communication unit, the control unit, the control monitoring unit, and the synchronization unit are separate devices.

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