JP6598939B2 - COMMUNICATION SYSTEM, RADIO DEVICE, AND TRANSMISSION METHOD - Google Patents

Description

  The present invention relates to a communication system and the like.

Patent Document 1 discloses a traffic control system that controls a traffic terminal such as a traffic signal controller, an optical beacon, and a traffic information board (hereinafter also simply referred to as “terminal”) with a central device of a traffic control center. ing.
As a transmission method of the traffic control system, for example, a UD type transmission method is used as disclosed in Patent Document 1.

  FIG. 46 shows a network configuration of a traffic control system using the UD type transmission system. As shown in FIG. 46, in a traffic control system of the UD type transmission system, a router (UD type terminal line aggregation device; UD-RTR) 101 is connected to a central apparatus 100 via an aggregation line 102. One or a plurality of traffic terminals 103 are connected to the router 101 via a terminal line (dedicated link) 104.

JP 2006-4403 A

The Japan Radio Industry Association, “700MHz band intelligent transportation system ARIB-STD T109 1.0 edition”, [online], Internet <http://www.arib.or.jp/tyosakenkyu/kikaku_tushin/tsushin_kikaku_number.html> ITS Information Communication System Promotion Conference, “700 MHz Band Intelligent Transport System Extended Function Guidelines ITS FORUM RC-010 1.0 Edition”, [online], Internet <http://www.itsforum.gr.jp/>

Incidentally, it is conceivable to perform communication between the router 101 and the terminal 103 in FIG. 46 wirelessly. In this case, since the terminal line 104 between the router 101 and the terminal 103 can be omitted, cost reduction can be achieved.
For example, there are those shown in Non-Patent Documents 1 and 2 as standards relating to wireless communication of road traffic systems. From the viewpoint of cost reduction, it is desired to use such wireless communication also in a traffic control system. Specifically, it is preferable that communication between the router 101 and the terminal 103 can be performed using a base station (roadside communication device) defined in Non-Patent Documents 1 and 2. That is, in order to effectively use existing terminals in the traffic control system, for example, base stations (roadside communication devices) defined in Non-Patent Documents 1 and 2 are used for communication between the existing router 101 and the existing terminal 103. It is desirable to be able to. However, the present invention may be applied to communication between the existing router 101 and the new terminal 103 and communication between the new router 101 and the new terminal 103.
Therefore, if a router and a terminal are individually connected to a roadside communicator that forms part of an existing traffic control system and wireless communication between the router and the terminal is performed, existing resources can be utilized. This is advantageous from the viewpoint of cost reduction as compared with the case where wired wiring is performed.

  However, in Non-Patent Document 1, data (wireless packet) transmitted from a roadside communication device is premised on broadcasting to an unspecified mobile station (on-vehicle device). Therefore, the wireless packet transmitted from the roadside communication device is transmitted to all the wireless devices (base station, mobile station) within the communication range of the roadside communication device, and can be received by all the wireless devices.

Then, in the traffic control system described in Patent Document 1, it is assumed that wireless communication as defined in Non-Patent Documents 1 and 2 is simply introduced. In this case, a wireless packet including information (upper layer packet) for a specific terminal is also transmitted to a wireless device connected to another terminal. As a result, an upper layer packet intended for a specific terminal is intercepted by another terminal.
Here, for example, an individual IP address is assigned to each roadside communication device, and for each wireless packet transmitted from the roadside communication device, the IP of the roadside communication device connected to the terminal that is the destination of the information included in the wireless packet It is possible to include an address. In this case, if the routing using the IP address is performed for the wireless packet between the roadside communication devices, it becomes possible to transmit the upper layer packet for the specific terminal only to the specific terminal.

However, as shown in FIG. 2, the number of other roadside communication devices 5B, 5C, 5D, and 5E that can receive a signal transmitted from one roadside communication device 5A is not limited to one. Therefore, when a wireless packet destined for the terminal 6 connected to the roadside communication device 5B is transmitted from the roadside communication device 5A, other roadside communication devices 5C, 5D, 5E other than the roadside communication device 5B also receive the wireless packet. Can be received. However, since the destination IP address of the wireless packet is not the terminal 6 connected to the roadside communication devices 5C, 5D, and 5E that received the wireless packet, the roadside communication devices 5C, 5D, and 5E are used for IP routing. The radio packet is further transmitted to be received by the roadside communication device B.
As a result, many wireless packets having the same contents are transmitted to the roadside communication device 5B, and unnecessary congestion occurs.
Moreover, it is not always possible to transmit a wireless packet directly from the source roadside communication device 5A to the destination roadside communication device 5B, and another roadside communication device 5C may have to transfer (relay) it halfway. In this case, there is a possibility that the roadside communication devices 5A, 5D, 5E, etc. receive the wireless packets transmitted for relaying by the other roadside communication device 5C and transfer them unnecessarily.
When performing IP routing in a roadside communication device, the roadside communication device needs to refer to a destination IP address (terminal IP address) that is not required to be referenced in the systems of Non-Patent Documents 1 and 2 among wireless packets. There is a risk that processing will be delayed. In order to perform the routing process simply, it is preferable that the routing process can be performed simply by referring to the identification information of the roadside communication device which is a wireless device.
Furthermore, since the information transmitted from the central device is not limited to the terminal but may be intended for the roadside communication device, it is desirable to cope with such a case.
For this reason, when using wireless communication as shown in Non-Patent Documents 1 and 2 in a traffic control system, a device that takes the above-described circumstances into consideration is required.

  The present invention has been made in view of the above-described reasons, and an object thereof is to appropriately perform wireless communication in a communication system including a wireless communication section.

  From one aspect, a communication system according to the present invention includes a first communication device that transmits a communication frame of a first protocol in which an upper layer packet is encapsulated, an IP address, and the communication frame of the first protocol. A second communication device for receiving, and a plurality of wireless devices for transmitting and receiving wireless packets of the second protocol for wireless communication, wherein the upper layer packet includes a destination IP address as destination information of the upper layer packet, The wireless packet includes wireless device identification information of a wireless device as a destination as destination information of the wireless packet, and the wireless device identification information is identification information different from an IP address, and is assigned to each of a plurality of wireless devices. The plurality of radios, the first radio that receives the communication frame transmitted from the first communication device; A second wireless device that transmits the communication frame to two communication devices, and a third wireless device that transfers the received wireless packet by wireless communication, the first wireless device received from the first communication device An upper layer packet extracted from the communication frame is encapsulated to generate the wireless packet, and the generated wireless packet is wirelessly transmitted. The first wireless device includes the destination IP address and the wireless device identification information The first wireless device refers to the table data based on the destination IP address included in the communication frame received from the first communication device, and stores the destination data. The wireless device identification information corresponding to the IP address is acquired, and the acquired wireless device identification information is set as destination information of the wireless packet. When configured to generate the wireless packet, the second wireless device, upon receiving the wireless packet, determines whether or not its wireless device identification information is set as the destination information of the wireless packet; When the wireless device identification information of its own device is set as the destination information, the higher layer packet is extracted from the received wireless packet, and the second wireless device is assigned an IP address, If the destination IP address included in the higher layer packet extracted from the received wireless packet is an IP address assigned to the second wireless device, the second wireless device transmits the upper layer packet to the second wireless device. Destination address included in the upper layer packet that is processed by the second radio device itself as a packet addressed to two radio devices and extracted from the received radio packet When the IP address is an IP address assigned to the second communication device, the communication device generates the communication frame by encapsulating the upper layer packet, and transmits the generated communication frame to the second communication device. The third wireless device includes a storage unit that stores setting information indicating the wireless device identification information included in the wireless packet to be transferred, and the third wireless device is included in the received wireless packet. The setting information is referred to based on the wireless device identification information, and a transfer determination process for determining whether or not to transfer the received wireless packet is performed.

  Another aspect of the present invention is a transmission method in a communication system, in which the communication system includes a first communication device that transmits a communication frame of a first protocol encapsulating higher layer packets and an IP address. A second communication device that receives the communication frame of the first protocol and a plurality of wireless devices that transmit and receive a wireless packet of the second protocol for wireless communication, and the upper layer packet is the upper layer packet A destination IP address as the destination information of the wireless packet, and the wireless packet includes, as destination information of the wireless packet, wireless device identification information of the wireless device that is the destination, and the wireless device identification information is identification information different from the IP address. And each of the plurality of wireless devices is transmitted from the first communication device. A first wireless device that receives a communication frame; a second wireless device that transmits the communication frame to the second communication device; and a third wireless device that transfers the received wireless packet by wireless communication. One wireless device has table data indicating the correspondence between the destination IP address and the wireless device identification information, the second wireless device is assigned an IP address, and the third wireless device A storage unit storing setting information indicating the wireless device identification information included in the wireless packet to be transmitted, and the transmission method is included in the communication frame received by the first wireless device from the first communication device The wireless device identification information corresponding to the destination IP address is acquired by referring to the table data based on the destination IP address, and the acquired wireless device identification information is the wireless packet. The wireless packet that is set as destination information and includes the upper layer packet extracted from the communication frame is generated, the generated wireless packet is wirelessly transmitted, and the third wireless device is included in the received wireless packet A transfer determination process for determining whether to transfer the received wireless packet, referring to the setting information based on the wireless device identification information, and transferring the received wireless packet based on a transfer determination process result When the second wireless device receives the wireless packet, the second wireless device determines whether the wireless device identification information of the own device is set as the destination information of the wireless packet, and the wireless device of the own device is used as the destination information. When the machine identification information is set, the upper layer packet is extracted from the received radio packet, and is extracted from the received radio packet. When the destination IP address included in the upper layer packet is an IP address assigned to the second radio, the second radio itself processes the upper layer packet as a packet addressed to the second radio. If the destination IP address included in the upper layer packet extracted from the received wireless packet is an IP address assigned to the second communication device, the communication packet is encapsulated in the communication frame. And transmitting the generated communication frame to the second communication device.

  From another viewpoint, the present invention provides a first communication device that transmits a communication frame of a first protocol, a second communication device that receives a communication frame of the first protocol, and a wireless packet of a second protocol for wireless communication. And the communication frame includes an upper layer packet including a destination IP address, and the wireless packet includes an inter-radio communication control header and the upper layer packet, The inter-radio communication control header includes identification information, and the identification information indicates whether the upper layer packet included in the received radio packet is related to the radio that has received the radio packet. Information used for determination processing by a wireless device that has received a wireless packet, and the plurality of wireless devices are transmitted from the first communication device. A first wireless device that receives the communication frame, a second wireless device that transmits the communication frame to the second communication device, and a third wireless device that transfers the received wireless packet by wireless communication, When one wireless device receives the communication frame of the first protocol from the communication device, the wireless device generates a wireless packet including a communication control header between wireless devices and an upper layer packet included in the communication frame, and the generated wireless packet When the wireless packet is wirelessly transmitted and the second wireless device receives the wireless packet, the second wireless device performs the determination process with reference to the identification information of the inter-radio communication control header included in the wireless packet. Based on the result, it is determined whether to transmit the communication frame including the upper layer packet included in the wireless packet to the second communication device, 3 When the wireless device receives the wireless packet, the wireless device refers to the identification information of the communication control header between wireless devices included in the wireless packet, performs the determination process, and receives the received wireless packet based on the result of the determination process. Is a communication system that determines whether or not to transfer the data by wireless communication.

  The present invention relates to each wireless device used in the communication system, a transmission method implemented in the communication system, a processing method in a wireless device that transmits a wireless packet, and processing in a wireless device that receives the wireless packet. It can also be understood as a method, a processing method in a wireless device for transferring wireless packets, or a computer program for executing these methods by a computer. Also, some or all of the functions realized by the computer program can be realized as a semiconductor integrated circuit. Furthermore, the program can be stored in a recording medium such as a CD-ROM.

  According to the present invention, wireless communication can be appropriately performed in a communication system including a wireless communication section.

1 is an overall configuration diagram of a communication system according to an embodiment. It is a figure which shows the example of installation on the road of the communication system which concerns on embodiment. (A) is a block diagram of a wireless device according to the embodiment, and (b) is a block diagram of a router according to the embodiment. It is a figure which shows the protocol stack of the radio | wireless apparatus which concerns on embodiment. It is a figure which shows the data structure of the radio | wireless packet transmitted by the radio | wireless machine which concerns on embodiment. It is a figure which shows an example of the header which concerns on embodiment. It is explanatory drawing which shows case 1 which concerns on embodiment. It is a figure explaining the protocol conversion which concerns on embodiment. It is a conceptual diagram which shows the connection setting information and table data of the radio | wireless machine in the case of case 1 which concerns on embodiment. It is a conceptual diagram which shows the connection setting information and table data of the radio | wireless machine in the case of case 1 which concerns on embodiment. It is a conceptual diagram which shows the connection setting information and routing table of a router in the case of case 1 which concerns on embodiment. The communication processing procedure of each radio when transmitting an upper layer packet from a router to a terminal in the embodiment is shown. It is a flowchart which shows the content of the reception determination process performed with the radio | wireless machine which concerns on embodiment. It is explanatory drawing which shows case 1 which concerns on embodiment. In case 1 according to the embodiment, (a) is a conceptual diagram showing table data of a radio, and (b) is a routing table held by a router. It is explanatory drawing which shows case 2 which concerns on embodiment. It is a conceptual diagram which shows the connection setting information and table data of the radio | wireless machine in the case of case 2 which concerns on embodiment. It is explanatory drawing which shows case 3 which concerns on embodiment. It is a conceptual diagram which shows the table data of the radio | wireless machine in the case of case 3 which concerns on embodiment. It is a conceptual diagram which shows the connection setting information and table data of the radio | wireless machine in the case of case 3 which concerns on embodiment. It is a conceptual diagram which shows the connection setting information of the radio | wireless machine in the case of case 3 which concerns on embodiment. It is explanatory drawing of a 1st modification. It is a conceptual diagram which shows the connection setting information and table data of the radio | wireless machine in the case of a 1st modification. It is a conceptual diagram which shows the connection setting information of the radio | wireless machine in the case of a 2nd modification. It is a flowchart which shows the content of the reception determination process performed with the radio | wireless machine which concerns on a 3rd modification. It is a flowchart which shows the content of the reception determination process performed with the radio | wireless machine which concerns on a 4th modification. It is a block diagram of a radio. It is a figure which shows the protocol stack of a radio | wireless machine. It is a data structure figure of a wireless packet and a PPP frame. It is a figure which shows an example of an IRC header. It is a figure which shows an example of an IRC header. It is a figure which shows an example of an IRC header. It is a figure which shows an example of an IRC header. FIG. 6 is an explanatory diagram showing Case 1; It is a figure which shows the connection setting information of a 1st radio | wireless machine. It is a figure which shows the connection setting information of a 2nd radio | wireless machine. It is a figure which shows the connection setting information of a 3rd radio | wireless machine. This is a PPP frame transmission sequence. It is a figure which shows the connection setting information of a 1st radio | wireless machine. It is a figure which shows the connection setting information of a 2nd radio | wireless machine. It is a figure which shows the connection setting information of a 3rd radio | wireless machine. FIG. 6 is an explanatory diagram showing Case 2. It is a figure which shows the connection setting information of a 1st radio | wireless machine. It is a figure which shows the connection setting information of a 2nd radio | wireless machine. It is a figure which shows the connection setting information of a 3rd radio | wireless machine. FIG. 6 is an explanatory diagram showing Case 3. It is a figure which shows the connection setting information of a 1st radio | wireless machine. It is a figure which shows the connection setting information of a 2nd radio | wireless machine. It is a figure which shows the connection setting information of a 3rd radio | wireless machine. It is a figure which shows the connection setting information of a 4th radio | wireless machine. It is a figure which shows the connection setting information of a 5th radio | wireless machine. It is a figure which shows the connection setting information of a 3rd radio | wireless machine. It is a figure which shows the connection setting information of a 4th radio | wireless machine. It is a figure which shows the frame structure at the time of protocol conversion. It is explanatory drawing of a 1st modification. It is another explanatory view of the 1st modification. It is a figure which shows the connection setting information of a 1st radio | wireless machine. It is a figure which shows the connection setting information of a 2nd radio | wireless machine. It is a figure which shows the connection setting information of a 3rd radio | wireless machine. It is the data structure of the radio | wireless packet and Ethernet frame in a 2nd modification. It is a figure which shows an example of an IRC header. It is a figure which shows an example of an IRC header. It is a figure which shows an example of an IRC header. It is a figure which shows an example of an IRC header. It is explanatory drawing of the communication system in a 2nd modification. It is other explanatory drawing of the communication system in a 2nd modification. It is other explanatory drawing of the communication system in a 2nd modification. It is a figure which shows the connection setting information of a 1st radio | wireless machine. It is a figure which shows the connection setting information of a 2nd radio | wireless machine. It is a figure which shows the connection setting information of a 3rd radio | wireless machine. It is a figure which shows the connection setting information of a 1st radio | wireless machine. It is a figure which shows the connection setting information of a 2nd radio | wireless machine. It is a figure which shows the connection setting information of a 3rd radio | wireless machine. It is a figure which shows the connection setting information of a 1st radio | wireless machine. It is a figure which shows the connection setting information of a 2nd radio | wireless machine. It is a figure which shows the connection setting information of a 3rd radio | wireless machine. It is a transmission sequence of an Ethernet frame. It is another transmission sequence of an Ethernet frame. It is explanatory drawing of transmission of an Ethernet frame. It is explanatory drawing of an ARP request | requirement and an ARP response. It is the conventional communication network block diagram.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.
[1. Description of Embodiment]
(1) In a traffic control system, PPP (Point-to-Point Protocol) is used as a communication protocol for connecting a terminal to a device such as a router.
For example, in the UD type transmission system, an S9 type interface standard (New Traffic Management System Association) is defined as a transmission interface standard between the router (UD-RTR) 101 and the terminal 103 shown in FIG. In this S9 interface standard, PPP is adopted as a connection method.
Therefore, when the terminal 103 communicates with the central apparatus 100, a PPP link (dedicated link) is established between the router 101 and the terminal 103 in FIG.

  PPP adopted in the traffic control system is a protocol for point-to-point communication, and it is assumed that there is a physical one-to-one connection by wire. For example, there is LCP (Link Control Protocol) as one of the protocols constituting PPP. The LCP is used to control the PPP link, and is specifically used for establishing, maintaining, and releasing the PPP link. Since PPP presupposes the existence of a physical one-to-one connection by wire, destination information is not included in the LCP control packet. Devices that attempt to establish a PPP link first recognize each other at startup (when the power is turned on).

Here, it is considered that communication between the router 101 and the terminal 103 in FIG. 46 is performed wirelessly. In this case, since the terminal line 104 between the router 101 and the terminal 103 can be wireless, it is possible to reduce costs such as a communication line laying cost and a line maintenance cost.
On the other hand, conventionally, a traffic control system using a base station (roadside communication device) that performs wireless communication with a mobile station (on-vehicle device) has been provided. In this type of traffic control system, those shown in Non-Patent Documents 1 and 2 are adopted as standards relating to wireless communication performed by a base station.
And, if the router and the terminal are individually connected to the roadside communicator that constitutes a part of the existing traffic control system and communication is performed between the router and the terminal, the existing resources are utilized. This is advantageous from the viewpoint of cost reduction.

  However, in Non-Patent Document 1, transmission from a roadside communication device to a mobile station (on-vehicle device) is premised on broadcast. That is, all the destinations in the MAC layer of the wireless data transmitted from the roadside communication device are fixed at a value of “1” and do not have a specific destination. Note that even in a layer higher than the MAC layer defined in Non-Patent Document 1, there is no transmission method for designating a specific traffic control system terminal as a destination in transmission of a roadside communication device.

  Therefore, the wireless packet transmitted from the roadside communication device is transmitted to all the wireless devices (base station, mobile station) within the communication range of the roadside communication device, and can be received by all the wireless devices. Then, in the traffic control system described in Patent Document 1, it is assumed that wireless communication as defined in Non-Patent Documents 1 and 2 is simply introduced. In this case, a wireless packet including information for a specific terminal is also transmitted to a wireless device connected to another terminal. And information for a specific terminal may be intercepted by another terminal.

  Here, for example, an individual IP address may be assigned to each roadside communication device, and each wireless packet transmitted from the roadside communication device may include the IP address of the terminal that is the destination of the information included in the wireless packet. It is done. In this case, if the routing using the IP address is performed for the wireless packet between the roadside communication devices, the information for the specific terminal can be transmitted only to the specific terminal.

However, as shown in FIG. 2, the number of other roadside communication devices 5B, 5C, 5D, and 5E that can receive a signal transmitted from one roadside communication device 5A is not limited to one. Therefore, when a wireless packet destined for the terminal 6 connected to the roadside communication device 5B is transmitted from the roadside communication device 5A, other roadside communication devices 5C, 5D, 5E other than the roadside communication device 5B also receive the wireless packet. Can be received. However, since the destination IP address of the wireless packet is not the terminal 6 connected to the roadside communication devices 5C, 5D, and 5E that received the wireless packet, the roadside communication devices 5C, 5D, and 5E are used for IP routing. The radio packet is further transmitted to be received by the roadside communication device B.
As a result, many wireless packets having the same contents are transmitted to the roadside communication device 5B, and unnecessary congestion occurs.
Moreover, it is not always possible to transmit a wireless packet directly from the source roadside communication device 5A to the destination roadside communication device 5B, and another roadside communication device 5C may have to transfer (relay) it halfway. In this case, there is a possibility that the roadside communication devices 5A, 5D, 5E, etc. receive the wireless packets transmitted for relaying by the other roadside communication device 5C and transfer them unnecessarily.
When performing IP routing in a roadside communication device, the roadside communication device needs to refer to a destination IP address (terminal IP address) that is not required to be referenced in the systems of Non-Patent Documents 1 and 2 among wireless packets. There is a risk that processing will be delayed. In order to perform the routing process simply, it is preferable that the routing process can be performed simply by referring to the identification information of the roadside communication device which is a wireless device.
Furthermore, since the information transmitted from the central device is not limited to the terminal but may be intended for the roadside communication device, it is desirable to cope with such a case.

  Therefore, the communication system according to the present embodiment receives a first communication device that transmits a communication frame of the first protocol in which the upper layer packet is encapsulated, an IP address, and receives the communication frame of the first protocol. A second communication device, and a plurality of wireless devices that transmit and receive wireless packets of a second protocol for wireless communication, wherein the upper layer packet includes a destination IP address as destination information of the upper layer packet, and the wireless The packet includes, as destination information of the wireless packet, wireless device identification information of a wireless device serving as a destination. The wireless device identification information is identification information different from an IP address, and is assigned to each of a plurality of wireless devices. The plurality of wireless devices include a first wireless device that receives the communication frame transmitted from the first communication device, and the second wireless device. A second wireless device that transmits the communication frame to a communication device; and a third wireless device that transfers the received wireless packet by wireless communication, wherein the first wireless device receives the first wireless device from the first communication device. An upper layer packet extracted from a communication frame is encapsulated to generate the wireless packet, and the generated wireless packet is wirelessly transmitted. The first wireless device includes the destination IP address, the wireless device identification information, The first wireless device refers to the table data based on the destination IP address included in the communication frame received from the first communication device, and stores the destination IP. The wireless device identification information corresponding to an address is acquired, and the acquired wireless device identification information is set as destination information of the wireless packet. The wireless device is configured to generate a wireless packet, and upon receiving the wireless packet, the second wireless device determines whether or not wireless device identification information of its own device is set as the destination information of the wireless packet, and When the wireless device identification information of its own device is set as the destination information, the higher layer packet is extracted from the received wireless packet, the second wireless device is assigned an IP address, When the destination IP address included in the upper layer packet extracted from the received wireless packet is an IP address assigned to the second wireless device, the second wireless device transmits the upper layer packet to the second wireless device. Destination IP included in the upper layer packet processed by the second radio itself as a packet addressed to the radio and extracted from the received radio packet When the address is an IP address assigned to the second communication device, the communication device generates the communication frame by encapsulating the higher layer packet, and transmits the generated communication frame to the second communication device. The third wireless device includes a storage unit that stores setting information indicating the wireless device identification information included in a wireless packet to be transferred, and the third wireless device is included in the received wireless packet. It is configured to refer to the setting information based on the wireless device identification information and to perform a transfer determination process for determining whether or not to transfer the received wireless packet.

  According to the above configuration, when the second wireless device receives the wireless packet, the second wireless device determines whether or not its wireless device identification information is set as the destination information of the wireless packet. Necessary wireless packets can be identified without referring to the destination IP address of.

  In addition, when the destination IP address included in the upper layer packet extracted from the received wireless packet is the IP address assigned to the second wireless device, the second wireless device sends the upper layer packet to the own device. If the destination IP address included in the higher layer packet extracted from the received wireless packet is the IP address assigned to the second communication device, the second wireless device itself processes the packet as To generate a communication frame, and transmit the generated communication frame to the second communication device. For this reason, even if the upper layer packet included in the received wireless packet is addressed to the own device or the second communication device, it can be appropriately processed.

  In addition, the third wireless device refers to the setting information based on the wireless device identification information included in the received wireless packet, and performs a transfer determination process for determining whether to transfer the received wireless packet. . For this reason, even if the wireless packet transmitted from the first wireless device does not reach the second wireless device directly, the third wireless device can transfer the wireless packet and deliver it to the second wireless device.

(2) The wireless packet includes both wireless device identification information as destination information of the wireless packet and wireless device identification information as transmission source information, and the second wireless device includes destination information and transmission of the wireless packet. It is preferable that the transfer determination process is performed based on the original information.
In this case, the second wireless device can appropriately perform the transfer determination process based on the destination information and the transmission source information of the wireless packet.

(3) The first communication device has one or more communication ports connected to the first wireless device, and the first communication device includes an IP address as destination information of the upper layer packet and the communication frame. The communication port for transmitting the communication frame is selected by referring to the correspondence information based on the IP address as the destination information of the upper layer packet. Preferably, in the correspondence information, a plurality of IP addresses as destination information of the upper layer packet are associated with a smaller number of the communication ports than the number of the plurality of IP addresses.
According to the above configuration, the number of communication ports can be made smaller than the number of destination IP addresses as destination information of higher layer packets. Therefore, the configuration of the first communication device and the first radio can be simplified by reducing the number of necessary ports.

(4) A wireless device according to the embodiment is connected to a first communication device that transmits a communication frame of a first protocol in which an upper layer packet is encapsulated, and wireless that transmits a wireless packet of a second protocol for wireless communication. The higher layer packet includes a destination IP address as destination information of the upper layer packet, and the wireless packet includes wireless device identification information of a destination wireless device as destination information of the wireless packet. When the communication frame transmitted from the first communication device is received, the wireless packet is generated by encapsulating the upper layer packet extracted from the received communication frame, and the generated wireless packet is wirelessly transmitted. And holding table data indicating a correspondence relationship between the destination IP address and the wireless device identification information, The radio equipment identification information corresponding to the destination IP address is obtained by referring to the table data based on the destination IP address included in the communication frame received from the first communication device, and the obtained radio equipment The wireless device generates the wireless packet in which identification information is set as destination information of the wireless packet.

(5) The wireless device according to the embodiment receives the wireless packet transmitted by the wireless device according to (4) or the wireless packet transferred by another wireless device, and transfers the received wireless packet by wireless communication. A storage unit configured to store setting information indicating the wireless device identification information included in the wireless packet to be transferred, and refer to the setting information based on the wireless device identification information included in the received wireless packet The wireless device is configured to perform a transfer determination process for determining whether to transfer the received wireless packet.

(6) A wireless device according to the embodiment is connected to a second communication device that receives a communication frame of a first protocol in which an upper layer packet is encapsulated, and wireless that receives a wireless packet of a second protocol for wireless communication. When the wireless packet transmitted by the wireless device described in (4) or the wireless packet transferred by the wireless device described in (5) is received, the wireless device transmits the wireless packet as the destination information of the wireless packet. It is configured to determine whether or not device identification information is set, and when the wireless device identification information of the own device is set as the destination information, the higher layer packet is extracted from the received wireless packet and received. When the destination IP address included in the upper layer packet extracted from the wireless packet is an IP address assigned to the own device, the upper layer packet If the destination IP address included in the upper layer packet extracted from the received wireless packet is the IP address assigned to the second communication device Is a radio configured to generate the communication frame by encapsulating the upper layer packet and to transmit the generated communication frame to the second communication device.

(7) A transmission method in the present embodiment is a transmission method in a communication system, and the communication system includes a first communication device that transmits a communication frame of a first protocol in which an upper layer packet is encapsulated, and an IP address. And a second communication device that receives the communication frame of the first protocol and a plurality of wireless devices that transmit and receive a wireless packet of the second protocol for wireless communication, and the upper layer packet is the upper layer packet A destination IP address is included as destination information of the layer packet, and the wireless packet includes wireless device identification information of a wireless device as a destination as destination information of the wireless packet, and the wireless device identification information is different from the IP address. Identification information, which is assigned to each of a plurality of wireless devices, and the plurality of wireless devices are transmitted from the first communication device. A first wireless device that receives the communication frame, a second wireless device that transmits the communication frame to the second communication device, and a third wireless device that transfers the received wireless packet by wireless communication. The first wireless device has table data indicating a correspondence relationship between the destination IP address and the wireless device identification information, and the second wireless device is assigned an IP address, and the third wireless device Includes a storage unit that stores setting information indicating the wireless device identification information included in the wireless packet to be transferred, and the transmission method includes the communication frame received from the first communication device by the first wireless device. The wireless device identification information corresponding to the destination IP address is obtained by referring to the table data based on the destination IP address included in the wireless communication device. The wireless packet that is set as packet destination information and includes the upper layer packet extracted from the communication frame is generated, the generated wireless packet is wirelessly transmitted, and the third wireless device receives the received wireless packet The transfer information is referred to based on the wireless device identification information included in the wireless device, and a transfer determination process is performed to determine whether to transfer the received wireless packet. Based on the transfer determination process result, the received wireless packet is transmitted. When the second wireless device receives the wireless packet, the wireless device determines whether or not the wireless device identification information of the own device is set as the destination information of the wireless packet. When the wireless device identification information is set, the upper layer packet is extracted from the received wireless packet and extracted from the received wireless packet. When the destination IP address included in the higher layer packet is an IP address assigned to the second radio device, the second radio device is regarded as a packet addressed to the second radio device. When the destination IP address included in the upper layer packet processed by itself and extracted from the received wireless packet is an IP address assigned to the second communication device, the upper layer packet is encapsulated. The transmission method includes generating the communication frame and transmitting the generated communication frame to the second communication device.

(8) A communication system according to the embodiment includes a first communication device that transmits a communication frame of a first protocol, a second communication device that receives a communication frame of the first protocol, and a second protocol for wireless communication. A plurality of radios for transmitting and receiving radio packets, wherein the communication frame includes an upper layer packet including a destination IP address, and the radio packet includes an inter-radio communication control header and the upper layer packet. The inter-radio communication control header includes identification information, and the identification information indicates whether the upper layer packet included in the received radio packet is related to the radio that has received the radio packet. , Information used for determination processing by the wireless device that has received the wireless packet, and the plurality of wireless devices are the first communication device. A first wireless device that receives the communication frame transmitted from the second wireless device, a second wireless device that transmits the communication frame to the second communication device, and a third wireless device that transfers the received wireless packet by wireless communication. When the first wireless device receives the communication frame of the first protocol from the communication device, the first wireless device generates a wireless packet including a wireless communication control header and an upper layer packet included in the communication frame, When the generated wireless packet is wirelessly transmitted and the second wireless device receives the wireless packet, the second wireless device performs the determination process with reference to identification information of a communication control header between wireless devices included in the wireless packet, and Based on the result of the determination process, it is determined whether to transmit the communication frame including the upper layer packet included in the wireless packet to the second communication device. Then, when the third wireless device receives the wireless packet, the third wireless device performs the determination process with reference to the identification information of the communication control header between wireless devices included in the wireless packet, and based on the result of the determination processing, The communication system determines whether or not to transfer a received wireless packet by wireless communication.

  According to the communication system, the wireless packet includes the inter-radio communication control header in addition to the upper layer packet including the destination IP address, and the second radio apparatus or the third radio apparatus that has received the radio packet. Can determine whether or not the upper layer packet is related to the wireless device that has received the wireless packet, based on the identification information in the communication control header between the wireless devices. Therefore, the wireless device that has received the wireless packet can determine whether or not the received wireless packet is related to the own device without referring to the destination IP address included in the wireless packet.

(9) When the second wireless device determines by the determination process that the upper layer packet included in the received wireless packet is related to the wireless device that has received the wireless packet, the second wireless device Reference is made to a destination IP address included in a layer packet, and when the destination IP address is an IP address assigned to the second radio, the upper layer packet is regarded as a packet addressed to the second radio. When the second wireless device itself processes and the destination IP address is an IP address assigned to the second communication device, the communication frame including the upper layer packet is transmitted to the second communication device. Is preferred.

[2. Details of Embodiment]
[2.1 System configuration]
FIG. 1 shows a traffic control system (communication system) 1 as an example of a communication system of the present invention. The traffic control system 1 includes a central device 2 and a plurality of traffic terminals 6 managed (controlled) by the central device 2. The traffic control system 1 of this embodiment performs communication using a UD type transmission system.

  One or a plurality of routers (UD type routers; UD-RTR) 4 are connected to the central unit (UD type central unit) 2 via a network 3. A plurality of traffic terminals 6 such as signal controllers are connected to each router 4 via a wired communication path 8 or a communication path including a wireless communication path.

  The UD type transmission system uses the S9 type interface standard for communication between routers and terminals (including inter-router communication when routers are connected), and PPP (2) as a data link layer protocol. The first protocol for point-to-point communication) is used. The transmission method (line type; layer 2 type) is not limited to the UD type and S9 type.

  The traffic control system 1 includes a plurality of wireless devices 5 for forming a wireless communication path between a router (first communication device) 4 and a terminal (second communication device) 6.

  The plurality of wireless devices 5 include a wireless device 5 connected to the router 4 and a wireless device 5 connected to the terminal 6. A router 4 may further be interposed between the wireless device 5 and the terminal 6.

  These wireless devices (roadside communication devices) 5 have functions required as base stations of Non-Patent Documents 1 and 2.

That is, the wireless device 5 as a base station has a communication function between a base station and a mobile station (a road-to-vehicle communication function or the like, and broadcasts a wireless packet to a mobile station such as an in-vehicle device. Can be sent.
In Non-Patent Document 1, road-to-vehicle communication does not use PPP.

Here, since the wireless packet transmitted from the base station is broadcast, the wireless packet can be received not only by the mobile station, but other base stations other than the base station that transmitted the wireless packet, Wireless packets can be received. That is, although not defined in the standards of Non-Patent Documents 1 and 2, communication between the wireless devices 5 that are base stations (inter-road communication; inter-base station communication) is possible.
Therefore, in the present embodiment, communication between the wireless devices 5 serving as base stations (inter-road communication) is used for communication between the router 4 and the terminal 6.

  However, in Non-Patent Documents 1 and 2, communication (road-to-road communication) between the wireless devices 5 as base stations is performed as a type of transmission (road-to-vehicle communication) by the base station in the standards of Non-Patent Documents 1 and 2. Need to be Therefore, the communication between the wireless devices 5 (communication between roads) is also premised on broadcast transmission, and the standards of Non-Patent Documents 1 and 2 do not include PPP.

[2.2 System installation example]
FIG. 2 shows an example in which the radio device 5 and the terminal 6 in the traffic control system 1 are arranged on the road.
A terminal 6 such as a signal controller is installed near an intersection or near a road other than the intersection. Each terminal 6 is connected to a wireless device 5 via a communication line. The wireless device 5 is installed in the vicinity of the terminal 6. The router 4 is connected to a specific terminal 6 (a terminal installed near a relatively large intersection) among the plurality of terminals 6 via a communication line.

The router 4 connected to the central device 2 via the network 3 can distribute the information transmitted from the central device 2 to the terminal 6 connected to the router 4. In addition, the router 4 can give the information transmitted from the central apparatus 2 to the radio device 5 connected to the router 4. The wireless device 5 connected to the router 4 includes the information transmitted from the central device 2 in a wireless packet, transmits (broadcasts) it to the other wireless device 5, and is connected to the other wireless device 5. 6 can acquire the wirelessly transmitted information.
Conversely, the router 4 can acquire information transmitted from the terminal 6 connected to the other wireless device 5 via wireless communication and transmit it to the central device 2.
Note that the wireless device 5 as a base station also transmits information to the wireless device 7 as a mobile station (on-vehicle device).

As described above, even the terminal 6 that is not connected to the router 4 by the wired communication line communicates with the router 4 and the central device 2 using the wireless communication (inter-road communication) between the wireless devices 5. be able to.
In the present embodiment, it is not necessary to lay a long communication line between the terminal 6 and the router 4 installed at a location relatively distant from the installation location of the router 4 (a distance of several tens to several hundred meters). Therefore, cost reduction is possible.

[2.3 Configuration of radio equipment (base station) and router]
FIG. 3A is a block diagram of the wireless device 5 according to the present embodiment, and FIG. 3B is a block diagram of the router 4 according to the present embodiment.
As illustrated in FIG. 3A, the wireless device 5 includes a wireless communication unit 51 that transmits and receives wireless signals, a first processing unit 52 that performs information processing in the wireless device 5, and a first storage unit 53. I have. The first processing unit 52 performs processing for generating a wireless packet of a wireless communication protocol (second protocol) transmitted from the wireless communication unit 51 and giving the wireless packet to the wireless communication unit 51. Further, the wireless device 5 performs gateway processing on the wireless packet received by the wireless communication unit 51.
By the way, the wireless device 5 is given identification information (wireless device identification information) unique to the wireless device. This wireless device identification information is different from the IP address.
The first storage unit 53 stores information (first setting information, second setting information, table data, and other information described later) used for processing in the first processing unit 52.

  The first processing unit 52 of the wireless device 5 may have a part or all of the functions realized by the first processing unit 52 configured by a hardware circuit, or a part or all of the functions may be a computer program. It may be realized by. When part or all of the functions of the first processing unit 52 are realized by a computer program, the first processing unit 52 includes a computer, and the computer program executed by the computer is stored in the first storage unit 53. The

The wireless device 5 includes a first wired communication unit 54 and a second wired communication unit 55. The first wired communication unit 54 is for communicating with the router 4 by PPP (first protocol for point-to-point communication). The first wired communication unit 54 conforms to the S9 interface standard. The first wired communication unit 54, the port (communication port: S9 port) and a _{P 1.} The first wired communication unit 54 may have a plurality of ports. This port is connected to a port (communication port) of a router 4 described later in a one-to-one correspondence.
In the following description, one port (S9 port) is described as a port for performing transmission / reception. In other words, port (S9 port) P ₁ shown in FIG. 3 (a) are those containing a sending port and the receiving port in S9 form interface standard.

The second wired communication unit 55 is a communication unit for Ethernet (registered trademark) connection, and includes one or a plurality of e-supports P _M1 , P _M2 , P _M3 , and P _M4 . An S11 interface standard (general UTMS association) has been formulated for a safe driving support system (DSSS: Driving Safety Support Systems). The e-supports _PM1 , _PM2 , _PM3 , and _PM4 included in the wireless device 5 are ports that can also support the S11 interface standard (Ethernet). Radio 5, via E. support P _M, can also be connected to the router 4 and terminals 6.

As shown in FIG. 3B, the router 4 includes a third wired communication unit 41, a fourth wired communication unit 44, a second processing unit 42 that handles information processing in the router 4, and a second storage unit 43. It is equipped with. The second processing unit 42 performs a process of giving the communication frame received by the fourth wired communication unit 44 from the network 3 to the third wired communication unit 41, and the communication frame received by the third wired communication unit 41 is the fourth. Processing to be given to the wired communication unit 44 is performed.
The second storage unit 43 stores information (first setting information, second setting information, routing table, and other information described later) used for processing in the second processing unit 42.

  In the second processing unit 42 of the router 4, part or all of the functions realized by the second processing unit 42 may be configured by a hardware circuit, or part or all of the functions may be performed by a computer program. It may be realized. When some or all of the functions of the second processing unit 42 are realized by a computer program, the second processing unit 42 includes a computer, and the computer program executed by the computer is stored in the second storage unit 43. The

The third wired communication unit 41 is for communicating with the wireless device 5 by PPP. The third wired communication unit 41 complies with the S9 interface standard. The third wired communication unit 41 includes at least two ports (S9 ports) _PR1 , _PR2 . The port _{PR 1} is connected to the wireless device 5, and the port PR ₂ is connected to the terminal 6. Specifically, the port P _R2 are connected by the port P ₁ and the communication line of the wireless device 5.

The fifth wired communication unit 45 is a communication unit for Ethernet (registered trademark) connection, and includes one or a plurality of e-supports _PMR1 , _PMR2 , _PMR3 , and _PMR4 . These e-supports _PMR1 , _PMR2 , _PMR3 , _PMR4 are, for example, ports for the S11 interface standard. Router 4 via the E-support P _M, can also be connected to a radio 5 and terminals 6.

FIG. 4 shows a protocol stack in the wireless device 5. The protocol stack shown in FIG. 4 includes a physical layer (PHY layer: Physical Layer), a MAC sublayer (Medium Access Control sublayer), an LLC sublayer (Logical Link Control sublayer), an inter-vehicle / road-vehicle shared communication control information layer (C). -RVC layer: Inter-Vehicle Communication-Load to Vehicle Communication Layer), Layer 7 (L7), and Extended Layer (EL).
The layer 1, the MAC sublayer, the LLC sublayer, the IVC-RVC layer, and the layer 7 are layers defined in Non-Patent Document 1. The extension layer is a layer defined in Non-Patent Document 2.

  The EL or L7 can access security management. The security management can generate secure data by performing security processing (encryption processing, signature processing, etc.) on unsecured data received from the EL. In addition, the security management can return secure data subjected to security processing to data unsecurely.

  In the present embodiment, an IRC layer for controlling communication between roads is provided as an upper layer of EL. The IRC layer is not defined in Non-Patent Documents 1 and 2, but is provided as an extension layer or a layer immediately above the layer 7 in the present embodiment. The IRC layer is connected to the PPP layer and the Ethernet layer, which are wired interfaces. Note that the Ethernet layer corresponds to a data link layer in the Ethernet standard. The PPP layer processes the PPP header of the PPP frame (adding a header, reading the header, etc.), and the Ethernet layer processes the Ethernet header of the Ethernet frame (adding a header, reading the header, etc.).

[2.4 Data structure]
FIG. 5 is a diagram illustrating a data structure of a wireless packet transmitted by the wireless device 5 according to the embodiment.
[2.4.1 Wireless packet structure]
The wireless packet in the present embodiment has, from the beginning, wireless communication control information, IRC (inter-road communication control information) header, data, and FCS areas.
The wireless communication control information conforms to Non-Patent Documents 1 and 2, and from the top, a PHY header (physical header), a MAC control field (MAC header), an LLC control field (LLC header), an IR control field (IR Header), L7 header, EL header, and Security header.

  The PHY header is a header corresponding to the physical layer of layer 1 in the standard of Non-Patent Document 1. The MAC control field is a control field corresponding to the MAC sublayer (Medium Access Control Sublayer) of layer 2 in the same standard. The LLC control field is a control field corresponding to the LLC sublayer (Logical Link Control Sublayer) of layer 2 in the same standard. The IR control field is a control field corresponding to the vehicle-to-vehicle / road-vehicle shared communication control information (IVC-RVC) layer in the same standard. The L7 header is a header corresponding to layer 7 in the standard. The EL header is a header corresponding to the extended layer shown in Non-Patent Document 2. Note that the EL header may be omitted. The Security header is a header generated by security management.

  As shown in FIG. 5, in the standard of Non-Patent Document 1, an L7 header is provided with an “Application Associated Information” field. In the same standard, the contents of the application-related information field are not defined, but in the present embodiment, the application-related information field is provided with a “communication classification” field.

  In the communication classification field, the type of wireless packet (communication type), that is, the wireless packet is “1. Communication from mobile station to mobile station / base station (vehicle-to-vehicle / inter-road shared communication)”, “2. “Communication from base station to mobile station / base station (road-to-vehicle / road-to-road communication)”, “3. Communication from mobile station to mobile station (inter-vehicle communication)”, “4. From base station to mobile station” Communication (road-to-vehicle communication) "," 5. communication from mobile station to base station (inter-road communication) "," 6. communication from base station to base station (road-to-road communication) " This is for classifying whether the packet is for communication. The communication classification field may not be this.

  Since the communication classification field is provided in the wireless packet, the wireless devices 5 and 7 that have received the wireless packet refer to the communication classification field included in the received wireless packet, and are packets necessary for the wireless device. If it is unnecessary without referring to a higher layer (a layer higher than layer 7) (for example, when a mobile station receives a packet for a base station and determines that it is unnecessary), The packet can be discarded.

  Further, as shown in FIG. 5, in the standard of Non-Patent Document 1, the EL header (EL base station header) includes base station ID information (BaseStation ID: wireless transmission source ID). Therefore, when an EL header is included in the wireless packet, the receiving-side wireless device 5 (the EL layer thereof) refers to the base station ID information in the EL header to determine the ID of the wireless device 5 that transmitted the wireless packet. Can be acquired.

  In the wireless packet, an area between the Security header and the FCS (an IRC header and data area in the wireless packet in FIG. 4) is an area in which application data as a wireless packet is stored. Application data as a wireless packet may be secure data that has been subjected to security processing (encryption processing, signature processing, etc.) by security management (see FIG. 4). The ELs and L7 of the wireless devices 5 that have received the secure data pass the secure data to the security management and have the security management return the unsecured data to the upper layer. hand over.

  When unsecured data is passed from the EL to the security management, areas subsequent to the EL header (Security header, IRC header and data area in the wireless packet in FIG. 5) become secure data. Further, when unsecured data is passed from L7 to the security management, areas subsequent to the L7 header (EL header, IRC header and data areas in the wireless packet in FIG. 5) are secure data. Furthermore, unsecured data may be passed from the IRC layer to the security management.

When the wireless device 5 transmits data (road vehicle data) for the wireless device 7 as a mobile station (on-vehicle device), the application data for the wireless device 7 is stored in the area where the application data is stored. Is done.
On the other hand, the wireless device 5 of the present embodiment is a case where communication between the wireless devices 5 (communication between roads) is performed, and when information related to management of the terminal 6 is transmitted, application data as a wireless packet is stored. The IRC frame consisting of the IRC header and the upper layer packet is stored in the area to be processed.

The IRC (inter-road communication control information) header is a header corresponding to the IRC layer for controlling the inter-road communication. The IRC header will be described later.
In the wireless packet shown in FIG. 5, the security header is on the front side of the IRC header, but may be on the rear side of the IRC header. If the security header is in front of the IRC header, the IRC header can be made secure data. However, since the IRC header is a target of security processing, in order to read the IRC header, processing for unsecure is required. On the other hand, when the security header is behind the IRC header, since the IRC header is unsecured data, the process of making it unsecured is not necessary for reading the IRC header. Further, the security header may be omitted from the wireless packet.

  The security header may be on the front side of the EL header or on the rear side of the EL header. When the security header is on the front side of the EL header, both the EL header (base station ID information (wireless transmission source ID)) and the IRC header can be made secure data. In addition, when the security header is behind the EL header, the EL header is unsecured. Therefore, when the information such as the base station ID information (wireless transmission source ID) included in the EL header is read, the process of making it unsecure Is unnecessary.

[2.4.2 Upper layer packet structure]
The radio device 5 that has acquired the upper layer packet generated by the router 4 or the terminal 6 adds radio communication control information or the like to the upper layer packet and encapsulates it to generate a radio packet.
As shown in FIG. 5, the upper layer packet generated by the router 4 or the terminal 6 includes an IP header, a UDP header, a Datex-Ash header, and a data part. Here, the IP header includes destination information (such as a destination IP address) of the upper layer packet.

[2.4.3 IRC (Route Communication Control Information; Radio Communication Control) Header]
The IRC header is generated by processing (information addition processing; IRC header addition processing) by the IRC layer of the wireless device 5 that generates a wireless packet (wireless transmission data), and the wireless device 5 that has received the wireless packet (wireless transmission data). It is used for processing by the IRC layer.
As shown in FIG. 6, the IRC header includes communication type information 71, data type information 72, source radio ID 73, destination radio ID 74, source radio ID 75, and generation count information 76. It is out.

The communication type information 71 is identification information indicating whether the wireless packet corresponds to “road-to-vehicle communication”, “vehicle-to-vehicle communication”, or “road-to-road communication”. For example, in the case of a wireless packet exchanged between the wireless device 5 connected to the router 4 and the wireless device 5 connected to the terminal 6, the communication type information 71 is set to indicate “inter-road communication”. .
The generation source wireless device ID 73 indicates unique identification information given to the wireless device 5 that generated the wireless packet of the second protocol. The destination wireless device ID 74 indicates unique identification information given to the wireless device 5 that is the destination of sending the wireless packet. For example, when a wireless packet is transferred across a plurality of wireless devices 5, the transmission source wireless device ID 75 indicates unique identification information given to the transferred wireless device 5.
By the way, each of the generation source radio ID 73, the destination radio ID 74, and the transmission source radio ID 75 is configured by identification information unique to the radio. These pieces of identification information are determined so that the wireless device that has received the wireless packet determines whether or not the upper layer packet included in the received wireless packet is related to the wireless device that has received the wireless packet. Used for processing (reception determination processing, transfer determination processing, etc.). The identification information unique to the wireless device is different from the IP address.

  Thereby, the number of IP addresses required in the entire communication system can be reduced as compared with a communication system in which the wireless device identification information is composed of IP addresses. Further, since the IP address for the wireless device is not necessary, the number of IP addresses for the communication device can be ensured accordingly.

  The generation count information 76 is information relating to the number of times a radio packet is generated. Note that the generation count information may be omitted.

[2.5 Road-to-road communication involving wireless communication sections]
Next, the road-to-road communication in which the wireless communication section according to the present embodiment is interposed will be described in detail. Here, four cases will be described.
[2.5.1 Case 1]
FIG. 7 is an explanatory diagram showing the case 1 according to the present embodiment.
In Case 1, a communication device (router (first communication device) 4, terminal (second communication device) 61) is connected to each of a pair of wireless devices (first wireless device 5A and second wireless device 5B). It shall be. The router 4 and the first wireless device 5A transmit and receive a PPP frame, and are located at both ends of a PPP link L0 that is a point-to-point communication link. Here, the PPP frame is encapsulated by adding a PPP header to an upper layer packet received by the router 4 from the central apparatus 2. The terminal 61 and the second radio device 5B both transmit and receive a PPP frame and are located at both ends of the PPP link L1 that is a point-to-point communication link.

  In addition to the second radio device 5B, there is also a third radio device 5C in the vicinity of the first radio device 5A, and the radio waves transmitted from the first radio device 5A can be received by the third radio device 5C. To do. A terminal 62 is connected to the third wireless device 5C. The terminal 62 and the third wireless device 5C perform transmission and reception of PPP frames, and are located at both ends of the PPP link L2, which is a point-to-point communication link. In addition, a terminal 65 is wired to the router 4. The router 4 and the terminal 65 perform transmission / reception of a PPP frame.

  In the router 4, an IP address “IP-R1” is assigned to a port connected to the first radio device 5 </ b> A, and is connected to the central device 2 (IP address: IP-Y) side (network network 3 side). An IP address “IP-X” is assigned to the port. An IP address “IP-1A” is assigned to a port connected to the router 4 of the wireless device 5A. The IP addresses “IP-1B” and “IP-1C” are also assigned to the ports connected to the terminals 61 and 62 of the wireless devices 5B and 5C, respectively. IP addresses “IP-T1” and “IP-T2” are assigned to ports connected to the wireless devices 5B and 5C of the terminals 61 and 62, respectively.

By the way, in the communication system according to the present embodiment, protocol conversion is performed in the wireless communication section.
FIG. 8 is a diagram illustrating protocol conversion according to the present embodiment.
Each of the radio devices 5A and 5B extracts an upper layer packet from the PPP frame.

  The PPP frame has a PPP header and a data portion. The PPP header has a preamble and a protocol area. The preamble of the PPP header has Flag, Address, and Control fields, each of which stores a fixed value.

  The protocol of the PPP header indicates the type of the data part that follows this protocol. When the value stored in the protocol area is any one of LCP (Link Control Protocol), authentication, and NCP (Network Control Protocol), the content of the data portion of the PPP frame is a PPP control packet. When the value stored in the protocol area is a value indicating an upper layer (for example, IP), the content of the data portion of the PPP frame is an upper layer packet. When the data part is a PPP control packet, the wireless devices 5A and 5B do not generate a wireless packet from the PPP frame.

The PPP control packet has fields of Code, ID, Length, data, or parameter list.
Code is information indicating the type of the PPP control packet. ID is an identifier of a PPP control packet. Length is a PPP control packet length. The data or parameter list field stores data related to each PPP control packet.

  The LCP or authentication PPP control packet does not have information indicating the destination of the PPP control packet. Therefore, the LCP or authentication PPP frame does not have destination information. That is, PPP is a protocol that may not have destination information in its communication frame (PPP frame). When the content of the data portion of the PPP frame is an upper layer packet, the PPP frame includes destination information (such as an IP address) of the upper layer packet.

  For example, the first wireless device 5A that has received the PPP frame from the router 4 extracts an upper layer packet from the PPP frame. Then, the first radio device 5A adds an IRC header including communication type information and a generation source radio device ID to the extracted upper layer packet, and further adds radio communication control information (from the Security header to the PHY header). , Generate a wireless packet.

When the wireless packet is received by the second wireless device 5B, the second wireless device 5B extracts an upper layer packet from the received wireless packet. Then, the second radio device 5B adds a protocol and a preamble from the upper layer packet (generates a PPP frame).
The same protocol conversion is performed in cases 2 to 4 described later.

  In case 1, the first storage unit 53 of the first wireless device 5A has connection setting information (first setting information, second setting information) as shown in FIG. 9A and FIG. 9B. Table data as shown in the table below is set. In each first storage unit 53 of the second wireless device 5B and the third wireless device 5C, connection setting information (first setting information and second setting information) as shown in FIG. Table data as shown in (b) is set.

The first setting information is information that is referred to when each wireless device 5A, 5B, 5C receives a PPP frame from a connected communication device (router 4 or terminals 61, 62).
The first setting information includes an own port IP address (own device port IP) indicating an IP address of a port (own device port) connected to the router 4 or the terminal 6 among the ports of the own devices 5A, 5B, and 5C. The port IP address (source port IP) of the source (router 4 or terminal 6) is associated with each other.

The second setting information is information that is referred to when each wireless device 5A, 5B, 5C receives a wireless packet from another wireless device 5. The second setting information is used when generating a PPP frame from the received wireless packet.
The second setting information includes an own port IP address (own device port IP) indicating an IP address of a port (own device port) connected to the router 4 or the terminal 6 among the ports of the own devices 5A, 5B, and 5C. The IP address (destination port IP) of the port on the router 4 or terminal 6 side directly connected to the port, or the own port IP and the IP address (destination IP) of the central device 2 or terminal 6 that is the destination correspond It is attached and configured.

  The table data held by each of the wireless devices 5A, 5B, and 5C includes an IP address of a destination included in an upper layer packet that constitutes a part of the wireless packet, and unique wireless device identification information assigned to the other wireless device 5. (Destination wireless device ID) are associated with each other. This table data is used when a radio packet is generated from a PPP frame received from the router 4 or the terminal 6.

  The wireless device 5A extracts an upper layer packet from the PPP frame received from the router 4. Then, when the destination IP address (destination IP) included in the upper layer packet is “IP-T1” or “IP-T2”, the wireless device 5A refers to the table data, and the destination of the IRC header in the wireless packet The wireless device ID 74 is set to “ID-5B” and “ID-5C”. At this time, the wireless device 5A sets both the generation source wireless device ID 73 and the transmission source wireless device ID 75 of the IRC header in the wireless packet to “ID-5A”.

  On the other hand, in the wireless device 5B (5C), when the destination IP address (destination IP) included in the PPP frame received from the terminal 61 (62) is “IP-Y”, the table 5 is referred to and the wireless packet The destination wireless device ID 74 of the IRC header is set to “ID-5A”. At this time, the wireless device 5B (5C) sets both the generation source wireless device ID 73 and the transmission source wireless device ID 75 of the IRC header in the wireless packet to “ID-5B (5C)”.

  Further, in case 1, the second storage unit 43 of the router 4 stores connection setting information (first setting information, second setting information) as shown in FIG. 11A and as shown in FIG. A routing table is set up.

The first setting information is information that is referred to when the router 4 receives a PPP frame from the wireless device 5A.
The first setting information includes an own port IP address (own device port IP) indicating an IP address of a port (own device port) connected to the wireless device 5A, and a transmission source (central device 2, terminal 6, wireless device 5A). ) Port IP address (source port IP) indicating the IP address of the source port (source port).

The second setting information (corresponding information) is information that is referred to when the router 4 receives an upper layer packet from the central device 2, the terminal 6, and the wireless device 5A. The second setting information is used when generating a PPP frame from the received upper layer packet.
The second setting information is connected to the own device port IP address (own device port IP) indicating the IP address of the port (own device port) connected to the central device 2, the terminal 6, and the wireless device 5A and the transmission destination. In addition, a destination port IP address (destination port IP) indicating an IP address of a port (destination port) of the central device 2, the terminal 6, and the wireless device 5A is associated with each other.

  The routing table (corresponding information) held by the router 4 associates the destination IP address included in the upper layer packet with the IP address assigned to the wireless device 5A, the central device 2, the terminal 65, and the like. This routing table is used, for example, when routing an upper layer packet received from the central apparatus 2 or an upper layer packet extracted from a PPP frame received from the first radio device 5A.

  In the router 4, when the destination IP address (destination IP) included in the upper layer packet received from the central device 2 is “IP-T1” or “IP-T2”, the upper layer packet is assigned to the IP corresponding to the wireless device 5 </ b> A. Send to address “IP-1A”. At this time, the router 4 generates a PPP frame from the upper layer packet and sends the PPP frame to the wireless device 5A via its own port “IP-R1”. Further, in the router 4, when the destination IP address (destination IP) included in the PPP frame received from the wireless device 5A is “IP-Y”, the upper layer packet is extracted from the PPP frame, and “IP-X1” is extracted. To the IP address “IP-Y” corresponding to the central device 2 via the own port.

FIG. 12 shows a communication processing procedure of the first radio device 5A and the second radio device 5B when transmitting an upper layer packet from the router 4 to the terminal 61 in the present embodiment.
First, the router 4, the PPP frame including information for the terminal 61, and transmits from the port (S9 _{port) P R1.}
The first wireless device 5A receives the PPP frame transmitted from the port assigned the IP address “IP-R1” of the router 4 at the port assigned the IP address “IP-1A” (step S1). .

  The first processing unit 52 of the first radio device 5A performs an upper layer packet extraction process for extracting an upper layer packet from the received PPP frame (step S2).

  Subsequently, the first processing unit 52 (its function as the IRC layer) refers to the table data based on the destination IP address (IP-T1) included in the higher layer packet, and the destination wireless device ID (ID- 5B), an IRC header including this destination wireless device ID is generated and added to the top of the upper layer packet (IRC header addition processing; step S3). Here, the IRC header stores the radio identification information (“ID-5A”) given to the first radio 5A in the fields of the base station ID of the generation source and the base station ID of the transmission source, and the destination In the base station ID field, the radio identification information (“ID-5B”) assigned to the second radio 5B is stored. In the IRC header, the communication type information is set to information indicating “inter-road communication”, and the generation count information is set to “0”, for example. In this way, an IRC frame encapsulating the received upper layer packet is generated.

Then, the IRC layer makes a wireless transmission request for the generated IRC frame to the enhancement layer (EL) (layer 7 when no enhancement layer exists) (step S4).
Each layer from the enhancement layer to the PHY layer generates the wireless packet by adding the wireless communication control information (from the Security header to the PHY header) shown in FIG. 5 to the IRC frame (wireless packet generation processing; step) S5). That is, the generation of the wireless packet is performed by a layer (an extension layer to a PHY layer) different from the IRC layer.
In the wireless packet generation process, the extension layer of the first wireless device 5A sets the ID of the first wireless device 5A in the base station ID information field of the EL header. In the wireless packet generation process, the layer 7 of the first wireless device 5A sets information indicating “6. Communication from base station to base station (inter-road communication)” in the communication classification field. To do.

The generated wireless packet is broadcast from the first wireless device 5A (step S6).
When security processing is performed by security management, it may be for IRC data (data excluding the IRC header to PHY header) or IRC frame (data excluding the Security header to PHY header). It may be. Further, when accessing security management from the layer 7, it may be for L7 data (data excluding the L7 header to the PHY header).

  The broadcast-transmitted wireless packet is received by the second wireless device 5B. The first processing unit 52 (the layers from the PHY layer to the extension layer; the wireless processing function unit) of the second wireless device 5B that has received the wireless packet performs reception processing of the wireless packet (step S7).

  Of the wireless packet reception processing, in the processing at layer 7, the determination based on the communication classification included in the L7 header is performed. When the communication classification indicated by the communication classification field is not a classification addressed to the base station, the second radio device 5B as the base station can discard the received radio packet. However, because the communication classification field is set to “6. Communication from base station to base station (inter-route communication)”, which is one of the categories addressed to the base station, the received radio packet is discarded. Can be processed without.

  On the other hand, since the classification indicated by the communication classification field is not the classification addressed to the base station, the in-vehicle device (mobile station) 7 that receives the wireless packet transmitted from the first wireless device 5A discards the received wireless packet. May be.

  The first processing unit 52 of the second wireless device 5B removes the IRC frame (IRC header and higher layer packet) from which the wireless communication control information (from the PHY header to the Security header) has been removed from the received wireless packet from the enhancement layer. The process given to the layer is performed (step S8). Further, the extension layer of the second radio device 5B transfers the ID of the first radio device 5A stored in the base station ID field of the EL header of the received radio packet to the IRC layer according to the service primitive of Non-Patent Document 2. give. Therefore, the process of obtaining the IRC frame from the received radio packet is performed by a layer different from the IRC layer.

  The IRC layer of the second wireless device 5B performs reception determination processing (determination processing) using the communication type information 71, the source wireless device ID 73, the destination wireless device ID 74, and the transmission source wireless device ID 75 included in the IRC header ( Step S9). In this reception determination process, the necessity of the IRC frame obtained from the wireless packet is determined. This reception determination process is a type of determination process for determining whether or not an upper layer packet included in a received wireless packet is related to a wireless device that has received the wireless packet. The wireless device that has received the wireless packet determines whether or not to transmit a communication frame including the upper layer packet included in the wireless packet to the terminal (second communication device) based on the result of the reception determination process.

FIG. 13 is a flowchart showing the contents of the reception determination process performed by the wireless device (second wireless device) 5B according to this embodiment.
First, the second wireless device 5B updates the holding list (step S91). Here, the “holding list” is management information stored together with the received IRC frame held in the first storage unit 53 by the second radio device 5B, and manages the IRC frame received by the second radio device 5B. It is a list to do. For example, the time when the IRC frame is received, information included in the IRC header, and the like are registered in the holding list. This holding list is updated when the held IRC frame is processed (transferred or discarded). Although not shown in the drawing, the update processing of the holding list in step S91 assumes that the information is discarded when the holding period of the already held IRC frame is longer than a predetermined time.
Next, based on the communication type information 71 included in the IRC header, the second radio device 5B determines whether or not the communication type is “road-to-road communication” data (step S92).

When the communication type information 71 included in the IRC header does not indicate “inter-road communication” (step S92: No), the second radio device 5B determines that the IRC frame is “unnecessary”.
On the other hand, when the communication type information 71 included in the IRC header indicates “inter-road communication” (step S92: Yes), the second wireless device 5B includes the source wireless device ID 73 and the destination wireless device included in the IRC header. The machine ID 74 and the transmission source radio machine ID 75 are read (step S93).

  Subsequently, the second wireless device 5B collates the read source wireless device ID 75 with the base station ID registered in advance in the own device 5B (source base station ID of the packet to be received) and reads the read destination. The wireless device ID 74 is compared with the wireless device ID (wireless device identification information) assigned to the own device 5B (step S94).

If the collation result is NG (step S95: No), the second radio device 5B determines that the IRC frame is “unnecessary”.
On the other hand, when the collation result is OK (step S95: Yes), the second wireless device 5B acquires the destination IP address of the upper layer packet included in the IRC frame from the IRC frame, and the acquired destination IP address and the own device. A destination IP address registered in advance in 5B (for example, IP address “IP-T1” assigned to port P1 of terminal 61 connected to own device 5B) is collated (step S96).
When the collation result is NG (step S97: No), the second radio device 5B determines that the IRC frame is “unnecessary”.
On the other hand, when the collation result is OK (step S97: Yes), the holding list is updated (step S98), and the IRC frame is determined as “necessary”. Here, for example, the second radio device 5B holds the reception time and generation count information of the received IRC frame according to the conditions from the communication type of the IRC header to the transmission source radio device ID. The reception time and generation number information for the condition are updated from the IRC frame determined (that is, retained).
As will be described later, when the upper layer packet can be addressed to the second radio device 5B, the destination IP address registered in advance in the second radio device 5B for destination IP address verification (step S96) is The IP address assigned to the two-radio device 5B may be included.

Returning to FIG. 12, if the IRC layer of the second radio device 5B determines that the IRC frame is “necessary” by the reception determination process, the IRC frame recognizes that the obtained IRC frame is addressed to its own device 5B, and An upper layer packet is extracted from the frame. When the destination IP address included in the upper layer packet is confirmed and it is confirmed that the destination IP address is addressed to the terminal 61 connected to the own device, the upper layer packet is transmitted from the IRC layer to the second radio device. Passed to the 5B PPP layer, the PPP layer generates a PPP frame from the upper layer packet. Then, the PPP layer refers to the second setting information based on the destination IP address included in the upper layer packet, and transmits the PPP frame from the port “IP-1B” to the port “IP-T1” of the terminal 61. (Step S10).
The PPP frame transmitted from the second radio device 5B is received by the terminal 61.

  Note that the IRC layer of the second radio device 5B recognizes that the obtained IRC frame is not addressed to the terminal 61 connected to the own device 5B when the IRC frame is determined to be “unnecessary” by the reception determination process. In this case, a transfer determination process (described later in case 3) (step S11) is performed, and if no transfer is necessary, the IRC frame is discarded (step S12).

The wireless packet broadcast from the first wireless device 5A is received not only by the second wireless device 5B but also by the third wireless device 5C. The first processing unit 52 (each layer from the PHY layer to the extension layer; the wireless processing function unit) of the third wireless device 5C that has received the wireless packet performs wireless packet reception processing in the same manner as the second wireless device 5B. To obtain an IRC frame.
The IRC layer of the third wireless device 5C performs reception determination processing using the communication type information 71, the destination wireless device ID 74, and the transmission source wireless device ID 75 included in the IRC header.

  As described above, the upper layer packet (data) transmitted from the router 4 may be broadcast by the first radio device 5A and received by the plurality of radio devices 5B and 5C. However, since the reception side wireless devices 5B and 5C perform reception determination using the destination wireless device ID 74 included in the IRC header, it is possible to reliably deliver the upper layer packet to the second wireless device 5B that is the original destination. it can.

Moreover, the third wireless device 5C, which is not related to the original destination, discards the wireless packet in the third wireless device 5C without sending the upper layer packet to the terminal 62 connected to the third wireless device 5C. For this reason, since it is not necessary to perform the process of discarding the upper layer packet in the terminal 62, the processing load on the terminal 62 can be reduced.
The wireless packet transmitted from the first wireless device 5A is also received by the third wireless device 5C. However, since the wireless packet is not addressed to the third wireless device 5C, the reception determination process of the third wireless device 5C is performed. As a result, it is discarded. Therefore, the upper layer packet transmitted to the terminal 61 can be prevented from being intercepted by the terminal 62.

Transmission from the terminal 61 to the central apparatus 2 via the router 4 is also performed in the same procedure as described above.
That is, the terminal 61 transmits a PPP frame including information to be transmitted to the central apparatus 2 from the port to which the IP address “IP-T1” is assigned. Then, the second wireless device 5B receives the PPP frame transmitted from the terminal 61 at the port to which the IP address “IP-1B” is assigned.

The second radio device 5B performs a process of extracting an upper layer packet from the received PPP frame (upper layer packet extraction process).
Then, the second radio device 5B encapsulates the upper layer packet with the IRC header generated by referring to the table data, and generates an IRC frame. Further, the second wireless device 5B adds wireless communication control information (from the Security header to the PHY header) to the IRC frame to generate a wireless packet. The generated wireless packet is broadcast from the second wireless device 5B.

  When security processing is performed by security management, the IRC data (data excluding the IRC header to the PHY header) or the IRC frame (data excluding the Security header to the PHY header) may be used. It may be against. Further, when accessing security management from the layer 7, it may be for L7 data (data excluding the L7 header and PHY header).

The IRC layer of the first wireless device 5A that has received the wireless packet performs reception determination processing using the communication type information 71, the destination wireless device ID 74, and the transmission source wireless device ID 75 included in the IRC header.
The first wireless device 5A can recognize that the destination of the acquired IRC frame is the own device 5A by the reception determination process. Then, the first wireless device 5A generates a PPP frame from the upper layer packet included in the IRC frame, refers to the second setting information based on the destination IP address (IP-Y) included in the upper layer packet, and The frame is transmitted from the port assigned the IP address “IP-1A” to the port assigned the IP address “IP-R1” of the router 4. Then, the PPP frame transmitted from the first radio device 5A is received by the router 4.

  Thus, the radio packet including the upper layer packet transmitted from the terminal 61 may be broadcast by the second radio device 5B and received by the plurality of radio devices 5A and 5C. However, since the reception side wireless devices 5A and 5C perform reception determination using the destination wireless device ID 74 included in the IRC header, it is possible to reliably deliver the upper layer packet to the first wireless device 5A that is the original destination. it can.

  The wireless packet transmitted from the second wireless device 5B is also received by the third wireless device 5C, but is discarded as a result of the reception determination process of the third wireless device 5C. Therefore, the upper layer packet included in the wireless packet transmitted from the terminal 61 is prevented from being intercepted by the terminal 62.

Regarding the case 1, in the above description, the example of using the communication type information 71, the destination wireless device ID 74, and the transmission source wireless device ID 75 included in the IRC header has been described in the reception determination process. However, the present invention is not limited to this. For example, the source wireless device ID 73 and the destination wireless device ID 74 may be used.
When the generation source radio ID 73 and the destination radio ID 74 are used, the transmission method of the communication frame may be read as “generation source” as “transmission source” in the above description regarding FIG.

By the way, in case 1, the upper layer packet transmitted from the router 4 may be sent to the radio devices 5A, 5B, 5C instead of the terminals 61, 62, 63.
FIG. 14 is an explanatory diagram showing a case where the destination of the upper layer packet is wireless devices 5A, 5B, and 5C in Case 1. Here, FIG. 7 is different from FIG. 7 in that IP addresses “IP-T5A”, “IP-T5B”, and “IP-T5C” are assigned to the wireless devices 5A, 5B, and 5C, respectively.

  When the router 4 receives, for example, information (application data) for the IP address (IP-T5A) assigned to the first wireless device 5A, the IP address “IP-R1” of the router 4 is assigned. The information is transmitted to the first radio device 5A via a connection between the port and the port to which the IP address “IP-1A” of the first radio device 5A is assigned. The information is, for example, information for in-vehicle devices (information for mobile stations) for the first wireless device 5A to wirelessly transmit to the wireless device (in-vehicle device) 7 by road-to-vehicle communication, and more specifically, For example, traffic information, road alignment information, or signal information. Further, when the router 4 receives information for IP addresses (IP-T5B, IP-T5C) assigned to the wireless devices 5B and 5C, for example, the information passes through the first wireless device 5A. It is transmitted to 5B and 5C.

Connection setting information (first setting information, second setting information) and table data are set as setting information corresponding to the network configuration shown in FIG. 7 or 14 in the first storage unit 53 of the first wireless device 5A. Yes. Here, the table data is, for example, as shown in FIG. Note that the connection setting information of the first wireless device 5A is the same as that of the above-described embodiment.
Also, connection setting information and table data corresponding to the network configuration shown in FIG. 7 or FIG. 14 are set in the first storage units 53 of the second wireless device 5B and the third wireless device 5C. The connection setting information and table data of the second radio device 5B and the third radio device 5C are the same as those in the embodiment.

Also, a routing table as shown in FIG. 15B is set in the second storage unit 43 of the router 4. The connection setting information of the router 4 is the same as that described in case 1 above.
In the routing table shown in FIG. 15B, the destination IP address included in the upper layer packet is associated with the IP address assigned to the wireless device 5A, the central device 2, the terminal 65, and the like. In particular, in this routing table, the IP address “IP-1A” of the port connected to the router 4 in the first wireless device 5A is associated with the IP addresses of the wireless devices 5A, 5B, and 5C. .
For example, the destination IP address (destination IP) included in the upper layer packet received from the central apparatus 2 is changed to the IP addresses “IP-T5A”, “IP-T5B”, and “IP-T5C” of the wireless devices 5A, 5B, and 5C. Suppose that it is set. In this case, the router 4 sends the upper layer packet to the port to which the IP address “IP-1A” of the first radio device 5A is assigned.

When the PPP frame addressed to the second wireless device 5B is transmitted from the port to which the IP address “IP-R1” of the router 4 is assigned, the first wireless device 5A transmits the PPP frame to the IP address “IP -1A "is received at the port.
Then, the 1st process part 52 of 5 A of 1st radio | wirelesses extracts an upper layer packet from a PPP frame in an upper layer packet extraction process (step S2).
The first processing unit 52 of the first wireless device 5A acquires the IP address (IP-T5B) of the second wireless device 5B that is the destination from the upper layer packet. Then, the first wireless device 5A refers to the table data shown in FIG. 15A, and the wireless device ID of the second wireless device 5B corresponding to the acquired IP address (IP-T5B) of the second wireless device 5B. (ID-5B) is recognized as wireless device identification information.
Then, based on the obtained wireless device identification information, an IRC header addition process (step S3) and a wireless packet generation process (step S5) are performed, and then the wireless packet is transmitted from the first wireless device 5A.

The first processing unit 52 (IRC layer) of the second wireless device 5B that has received the wireless packet uses the identification information included in the IRC header of the IRC frame obtained from the received wireless packet to perform reception determination processing (step S9). I do.
As a result of the reception determination process, the second radio device 5B recognizes that the destination of the upper layer packet included in the radio packet is the own device 5B. As a result, an upper layer packet is extracted from the radio packet. After that, when the destination IP address included in the upper layer packet is the second wireless device 5B, it does not transmit a PPP frame including the upper layer packet to the terminal 61 connected to the own device 5B. The upper layer packet is processed at 5B.
Similarly, a wireless packet having the transmission source of the second wireless device 5B can also be transmitted to the port to which the IP address “IP-R1” of the router 4 is assigned via the first wireless device 5A.

Further, when the router 4 transmits a PPP frame addressed to the third wireless device 5C from the port to which the IP address “IP-R1” of the router 4 is assigned, the first wireless device 5A transmits the PPP frame to the IP address “IP -1A "is received at the port.
Then, the first processing unit 52 of the first radio device 5A performs the upper layer packet extraction process (step S2) and the IRC header addition process (step S3), and the radio packet is transmitted from the first radio device 5A. At this time, the first wireless device 5A refers to the table data shown in FIG. 15A based on the destination IP address (IP-T5C) included in the upper layer packet extracted in the upper layer packet extraction process. The destination wireless device ID (ID-5C) is recognized. At this time, if the destination IP address included in the upper layer packet is the own device (IP-T5A), the first radio device 5A determines that the information is addressed to the own device, and processes the upper layer packet.

  Then, the wireless devices 5B and 5C that have received the wireless packet perform reception determination processing using the transmission source wireless device ID 75 and the destination wireless device ID 74 included in the IRC header of the received wireless packet. The radio devices 5B and 5C can recognize that the destination of the received upper layer packet is the own device 5B and 5C by the reception determination process. As a result, the upper layer packet included in the wireless packet is processed by the wireless devices 5B and 5C.

  As described above, even when the router 4 and the wireless devices 5A, 5B, and 5C are not compatible with the wireless communication protocol, the router 4 can receive the upper layer packet addressed to the wireless devices 5A, 5B, and 5C. Can be reliably sent to the wireless devices 5A, 5B, 5C.

[2.5.2 Case 2]
FIG. 16 is an explanatory diagram showing Case 2 according to the present embodiment.
In the case 2, there are the router 4 and three (a plurality of) terminals 61, 62, and 63 that respectively transmit and receive to / from the router 4.
Of the three terminals 61, 62, 63, two terminals 61, 62 are connected to the second wireless device 5B. That is, the second radio device 5B is connected to the terminals 61 and 62 at the two ports P _1B and P _2B . The remaining terminal 63 is connected to the third wireless device 5C.
Further, the three wireless devices 5A, 5B, and 5C can wirelessly communicate with each other.

  In Case 2, the PPP link L0 is formed between the router 4 and the first radio device 5A, and the PPP links L1 and L2 are formed between the terminal 61, the terminal 62, and the second radio device 5B, and the terminal 63 It is assumed that a PPP link L3 is formed between the first wireless device 5C and the third wireless device 5C.

  In the wireless device 5B, IP addresses “IP-1B” and “IP-2B” are assigned to ports connected to the terminals 61 and 62. Since the router 4, the wireless device 5C, and the terminals 61, 62, and 63 are the same as in the case 1, detailed description thereof is omitted.

  In Case 2, first setting information, second setting information, and table data shown in FIG. 17 are set as setting information corresponding to the network configuration in FIG. 16 in the first storage unit 53 of the second wireless device 5B. . Also, the first setting information, the second setting information, and the table data are set as the connection setting information corresponding to the network configuration of FIG. 16 in each first storage unit 53 of the first wireless device 5A and the third wireless device 5C. Has been. Note that the connection setting information and table data of the first wireless device 5A and the third wireless device 5C are the same as in the case 1, and detailed description thereof is omitted here.

When the central apparatus 2 transmits an upper layer packet to the terminal 61 via the router 4, the router 4 transmits a PPP frame in which the upper layer packet to be transmitted to the terminal 61 is encapsulated by the IP address “IP-R1”. Send from the given port. The first wireless device 5A receives the PPP frame transmitted from the port assigned the IP address “IP-R1” of the router 4 at the port assigned the IP address “IP-1A”.
The first processing unit 52 of the first wireless device 5A refers to the table data shown in FIG. 9B, performs destination recognition processing, and performs the destination IP address “IP− of the terminal 61 that is the destination of the higher layer packet. From the “T1”, the radio ID “ID5B” of the second radio 5B is obtained as identification information.
The first wireless device 5A that has confirmed that the destination is the terminal 61 of the corresponding IP address extracts the upper layer packet from the PPP frame. Then, the first radio device 5A encapsulates the extracted upper layer packet with the IRC header to generate an IRC frame. Further, the first wireless device 5A adds wireless communication control information (from the Security header to the PHY header) to the IRC frame to generate a wireless packet. The generated wireless packet is broadcast from the first wireless device 5A.

  The second wireless device 5B that has received the wireless packet performs reception determination processing using the destination wireless device ID 74 and the transmission source wireless device ID 75 included in the IRC header of the received wireless packet. At this time, the second wireless device 5B determines that the destination of the upper layer packet included in the received wireless packet is the terminal 61, 62 connected to the own device 5B (as shown in FIG. When the IP address is given, it can be recognized that the IP address is any one of the own device 5B.

  When the second wireless device 5B determines that the destination of the upper layer packet included in the wireless packet is not one of the terminals 61 and 62 (and its own device 5B) as a result of the reception determination processing, the second wireless device 5B performs transfer determination processing (FIG. 11 step S11).

  If the second wireless device 5B determines that the destination of the upper layer packet included in the wireless packet is one of the terminals 61 and 62 as a result of the reception determination process, the second wireless device 5B generates a PPP frame from the upper layer packet. Then, the second wireless device 5B refers to the second setting information, and the own wireless device port (own device port) corresponding to the port to which the destination IP address (destination port IP: IP-T1, IP-T2) is assigned. The generated PPP frame is transmitted from (IP: IP-1B, IP-2B). The transmitted PPP frame is received by the terminal 61 or the terminal 62.

  As described above, the second wireless device 5B refers to the second setting information, so that the plurality of terminals connected to the own device 5B can generate the PPP frame generated from the upper layer packet of the wireless packet received by the own device 5B. It can be recognized which of 61 and 62 should be transmitted. Thereby, even if a plurality of terminals 61 and 62 are connected to the own device 5B, it is possible to prevent the PPP frame from being transmitted to the terminal 62 that is not the destination.

Even when the upper layer packet is transmitted from the terminal 61 to the central apparatus 2 via the router 4, the processing is performed in the same procedure as described above.
That is, the terminal 61 transmits a PPP frame that encapsulates an upper layer packet to be transmitted to the central apparatus 2 from the port to which the IP address “IP-T1” is assigned. The second radio device 5B receives the PPP frame transmitted from the terminal 61 at the port to which the IP address “IP-1B” is assigned.
The first processing unit 52 of the second wireless device 5B performs destination recognition processing with reference to the table data shown in FIG. Recognize machine ID “ID-5A”.

  The second radio device 5B that has confirmed that the destination is the central device 2 of the corresponding IP address extracts the upper layer packet from the received PPP frame. Then, the second radio device 5B encapsulates the upper layer packet with the IRC header and generates an IRC frame. Furthermore, the second radio device 5B adds radio communication control information (from the Security header to the PHY header) to the IRC frame to generate a radio packet. The generated wireless packet is broadcast from the second wireless device 5B.

The first wireless device 5A that has received the wireless packet performs reception determination processing using the destination wireless device ID 74 and the transmission source wireless device ID 75 included in the IRC header of the received wireless packet. At this time, the first wireless device 5A confirms that the destination of the received upper layer packet is addressed to the destination IP address (destination IP, central device 2) registered in the table of its own device 5A by the reception determination process. Can be recognized.
The first radio device 5A extracts an upper layer packet from the radio packet, encapsulates the extracted upper layer packet, and generates a PPP frame. Then, the first wireless device 5A refers to the second setting information in FIG. 9A and transmits the generated PPP frame from the port to which the IP address “IP-1A” is assigned. The transmitted PPP frame is received by the router 4.

  As described above, the second wireless device 5B refers to the connection setting information (first setting information, second setting information) even when a plurality of terminals 61 and 62 are connected, so that the destination and transmission of the PPP frame are transmitted. The original terminal 61 can be correctly recognized.

  The wireless packets transmitted from the first wireless device 5A and the second wireless device 5B are also received by the third wireless device 5C, but the destination wireless device ID 74 included in the IRC header is the wireless signal of the third wireless device 5C. The wireless packet that is not the machine ID is discarded or transferred by the reception determination process.

  Also in case 2, as in case 1, the source wireless device ID 73 and the destination wireless device ID 74 may be used in the reception determination process. In this case, as a method for transmitting a communication frame, “transmission source” in the above description regarding FIG. 12 may be read as “generation source”.

[2.5.3 Case 3]
FIG. 18 is an explanatory diagram showing Case 3 according to the present embodiment.
In case 3, there are the router 4 and four (plural) terminals 61, 62, 63, and 64 that respectively transmit and receive upper layer packets to and from the router 4.
The terminal 61 is connected to the second radio 5B, the terminal 62 is connected to the third radio 5C, the terminal 63 is connected to the fourth radio 5D, and the terminal 64 is connected to the fifth radio 5E.

  In Case 3, a PPP link L0 is formed between the router 4 and the first radio device 5A, a PPP link L1 is formed between the terminal 61 and the second radio device 5B, and the terminal 62 and the third radio device 5C. It is assumed that a PPP link L2 is formed between Further, it is assumed that the PPP link L3 is formed between the terminal 63 and the fourth wireless device 5D, and the PPP link L4 is formed between the terminal 64 and the fifth wireless device 5E.

  In the case 3, as in the case 1, the wireless devices 5A to 5E, the router 4, and the terminals 61 to 64 are assigned IP addresses corresponding to the ports. Detailed description is omitted here.

  Further, in case 3, only the second radio device 5B and the third radio device 5C can communicate with the first radio device 5A, and the fourth radio device 5D and the fifth radio device 5E communicate with the first radio device 5A. Shall not be able to communicate wirelessly (no radio waves reach). However, it is assumed that the third wireless device 5C can wirelessly communicate with the fourth wireless device 5D, and the fourth wireless device 5D can wirelessly communicate with the fifth wireless device 5E. For this reason, the wireless packet addressed to the fourth wireless device 5D passes through the first wireless device 5A and the third wireless device 5C. The wireless packet addressed to the fifth wireless device 5E passes through the first wireless device 5A, the third wireless device 5C, and the fourth wireless device 5D.

In Case 3, connection setting information (first setting information and second setting information) corresponding to the network configuration in FIG. 18 and table data as shown in FIG. 19 are stored in the first storage unit 53 of the first wireless device 5A. Has been. Note that the connection setting information of the first wireless device 5A is the same as in the case 1.
Also, the first storage units 53 of the wireless devices 5B to 5E also have connection setting information (first setting information and second setting information) as shown in FIG. 20A corresponding to the network configuration of FIG. And table data as shown in FIG. 20B is stored.

Further, in each first storage unit 53 of the wireless devices 5B to 5E, as connection setting information as shown in FIG. 21, a destination wireless device ID, a transmission source wireless device ID, a generation wireless device ID, and a wireless transmission packet are generated. Third setting information in which the number of times is associated may be stored. Here, the destination wireless device ID of the third setting information is transfer determination information. The transfer determination information is information indicating a wireless packet that needs to be transferred.
If the destination wireless device ID included in the IRC header of the received wireless packet matches a wireless device ID other than the wireless device ID registered in the third setting information, the wireless packet is transferred. Candidate (target) If the destination wireless device ID included in the IRC header is the wireless device ID of the own device registered in the third setting information, the same processing as in case 1 is performed.

  In addition, the transmission source radio ID of the third setting information is transfer permission information. The transfer permission information is for limiting wireless packets to be transferred. Even if the destination wireless device ID included in the IRC header of the received wireless packet matches the transfer determination information, the transmission source wireless device ID of the received wireless packet is set as the transfer permission information. If it does not match the wireless device ID, it is not transferred.

  For example, it is assumed that the first wireless device 5A transmits a wireless packet (IP address: IP-T3) including an upper layer protocol addressed to the terminal 63. The wireless packet transmitted from the first wireless device 5A does not reach the fourth wireless device 5D connected to the terminal 63. The third wireless device 5C receives the wireless packet, and since the destination wireless device ID included in the IRC header does not match the wireless device ID of the own device, the received wireless packet is a terminal connected to the own device 5C. It is determined that it is not addressed to 62 (reception determination processing; step S9 in FIG. 12).

As a result of the reception determination process in the third wireless device 5C, if it is determined that the upper layer packet included in the received wireless packet is unnecessary for the terminal 62, the IRC layer of the third wireless device 5C further determines the transfer determination. Processing (step S11 in FIG. 12) is performed.
This transfer determination process is a kind of determination process for determining whether or not an upper layer packet included in a received wireless packet is related to a wireless device that has received the wireless packet. The wireless device that has received the wireless packet determines whether to transfer the wireless packet by wireless communication based on the result of the transfer determination process.
In the transfer determination process, the destination wireless device ID registered in the table data is searched, and it is determined whether or not the destination wireless device ID that matches the destination wireless device ID 74 included in the IRC header of the received wireless packet is registered. To do. If the destination wireless device ID is registered in the third setting information, the transmission source wireless device ID included in the IRC header is registered as the transmission source wireless device ID corresponding to the destination wireless device ID in the table data. It is determined whether or not.

That is, the third wireless device 5C should transfer the received wireless packet when the destination wireless device ID 74 and the transmission source wireless device ID included in the IRC header are registered in association with the third setting information. Is determined. As a result, the third wireless device 5C performs a wireless packet transfer process (step S13 in FIG. 12), and the wireless packet is transferred (broadcast transmission) (step S14 in FIG. 12). The transferred wireless packet is received by the fourth wireless device 5D. The fourth wireless device 5D confirms that the destination wireless device ID 74 included in the IRC header matches the wireless device ID assigned to the own device 5D, and then confirms the destination IP address included in the upper layer packet. As a result, it is recognized that the received wireless packet is addressed to the terminal 63 connected to the own device 5D.
Similarly, when the first wireless device 5A transmits a wireless packet including an upper layer packet addressed to the terminal 64, the fifth wireless device 5E passes through the transfer processing by the third wireless device 5C and the transfer processing by the fourth wireless device 5D. Received by.

As described above, the third wireless device 5C determines whether or not to transfer the wireless packet based on the destination wireless device ID (destination information) and the transmission source wireless device ID (transmission source information) of the received wireless packet. Then, the wireless packets to be transferred are sorted. Therefore, useless transfer of wireless packets by the second wireless device can be reduced.
In addition, the first wireless device 5A and the fourth wireless device 5D and the fifth wireless device 5E cannot directly perform wireless communication, and the first wireless device 5A and the third wireless device 5C can wirelessly communicate. Even in this case, the wireless packet including the upper layer packet addressed to the terminal 63 transmitted from the first wireless device 5A is transferred to the fourth wireless device 5D in the third wireless device 5C.

  By the way, when the wireless packet addressed to the terminal 64 transmitted from the first wireless device 5A is transferred in the order of the third wireless device 5C and the fourth wireless device 5D, the wireless packet transferred from the fourth wireless device 5D is Also received (bounced back) by the third wireless device 5C.

  At this time, the third wireless device 5C confirms that the fourth wireless device 5D has transferred to the fifth wireless device 5E by using the wireless packet information received from the fourth wireless device 5D. it can. This is because if the communication environment in the communication section is deteriorated due to shadowing due to trees or fading due to surrounding mobile bodies (cars), it is possible to estimate whether or not the adjacent wireless device 5 can transfer, so retransmission or continuous transmission is possible. There are merits such as being able to decide the necessity of sending. However, as described above, it may be difficult to determine only the destination wireless device ID and the transmission source wireless device ID because the generation source is unknown and the transferred radio packet is unknown. . Accordingly, in the first storage unit 53 of each wireless device 5, in addition to the destination wireless device ID and the transmission source wireless device ID, the generation wireless device ID and the number of generated wireless transmission packets are associated as connection setting information. The set third setting information may be stored. In this case, the third wireless device 5C determines whether or not retransmission of the wireless packet or continuous transmission is necessary based on the destination wireless device ID, the transmission source wireless device ID, the generation wireless device ID, and the number of wireless transmission packet generations. It becomes possible. FIG. 21 shows an example of the third setting information stored in the first storage unit 53 of each wireless device. Here, the wireless device 5 that transmits the wireless packet first transmits the wireless packet with the generation count information 76 included in the IRC header of the wireless packet set to 0, and transfers the received wireless packet. The wireless packet is transferred. In this case, the generation number information 76 included in the IRC header indicates the number of times generated by the wireless device 5 that is the generation source.

  For example, it is assumed that the third wireless device 5C receives a wireless packet including an upper layer packet addressed to the terminal 63 from the first wireless device 5A. The transmission source wireless device ID 75 included in the IRC header of this wireless packet is set to “ID-5A”, the destination wireless device ID 74 is set to “ID-5D”, and the generation wireless device ID 73 is set to “ID-5A”. In this case, since the third wireless device 5C is registered in the connection setting information (third setting information) in association with the destination wireless device ID, the transmission source wireless device ID, and the generation wireless device ID, the received wireless device Identify packets as transfer candidates. Then, the third wireless device 5C refers to the third setting information, and determines whether or not the generation number information 76 of the IRC header is different from (for example, a large value) the generation number registered in the third setting information. judge.

  Here, the IRC header generation count information 76 of the wireless packet received from the first wireless device 5A is set to “1”, and the first wireless device 5A registered in the third setting information of the third wireless device 5C. When the number of generations of the wireless packet addressed to the terminal 63 from the condition for each wireless device ID is set to “0”, the third wireless device 5C determines that a new wireless packet has been received from the first wireless device 5A. It is determined that the data is to be transferred. On the other hand, if the number of generations is set to “1”, the third wireless device 5C determines that the same wireless packet is received again from the first wireless device 5A, and processes the wireless packet with the same condition in the past. Therefore, it is determined that the received wireless packet is not transferred.

  In this case, from the standpoint of the third wireless device 5C on the receiving side, it is possible to determine whether or not the same wireless packet has been received again, and to determine whether or not transfer is necessary, thereby preventing unnecessary transfer.

On the other hand, when the fourth wireless device 5D that has received the transferred wireless packet receives the wireless packet transferred to the fifth wireless device 5E, the third wireless device 5C receives the destination wireless device ID and the transmission source of the wireless packet. A wireless packet that can be determined not to be a transfer candidate from the wireless device ID, and is transferred by the third wireless device 5C based on the generation wireless device ID and the number of generations in addition to the destination wireless device ID and the transmission source wireless device ID. Can be determined by the fourth wireless device 5D.
In this case, from the standpoint of the third wireless device 5C on the transmission side, it can be determined whether or not the wireless packet transferred by the own device 5C has been successfully transferred by the predetermined fourth wireless device 5D. If the data is not transferred from the fourth wireless device 5D even after the elapse of time, it is possible to determine that information has not been transmitted from the third wireless device 5C to the fourth wireless device 5D due to the communication environment or the like. Therefore, it is possible to prevent unnecessary retransmissions compared to simple retransmission (continuous transmission).

  As described above, in the communication system of the present embodiment, wireless communication between the first wireless device 5A and the second wireless device 5B is performed using a wireless device ID (wireless device identification information) different from the IP address. Therefore, no IP address is required for the wireless communication. The second radio device 5B needs to be given an IP address when the second radio device 5B is a destination of an upper layer packet. However, if it is not a destination of an upper layer packet, the second radio device 5B is given an IP address. Is unnecessary. That is, the IP address may be assigned to at least the terminal (second communication device) 61 that is the destination of the upper layer packet. Thereby, the number of necessary IP addresses can be reduced as compared with a configuration in which wireless communication between the first wireless device 5A and the second wireless device 5B is performed using the IP address. Therefore, it is possible to increase the number of IP addresses that can be assigned to a terminal that is a destination of the upper layer packet. That is, there is an advantage that it is possible to cope with an increase in the number of terminals that are destinations of upper layer packets while using wireless communication.

  In the communication system of the present embodiment, the router 4 transmits upper layer packets of a plurality of destinations (for example, the terminals 61 and 62) from one common port to one common port included in the wireless device 5. . For example, the router 4 transmits a plurality of destination higher layer packets from the port assigned the IP address “IP-R1” to the port assigned the IP address “IP-1A”.

  As a result, the number of ports of the router 4 and the number of ports of the wireless device 5 (first wireless device 5A) can be made smaller than the number of destinations of the upper layer packet. Therefore, the configuration of the router 4 and the wireless device 5 can be simplified by the amount of necessary ports that can be reduced.

  In the communication system of the present embodiment, it is assumed that the terminal (second communication device) 61 (62) does not support the wireless communication protocol (second protocol). Even in this case, the router 4 can reliably send the upper layer packet addressed to the terminal 61 (62) to the terminal 61 (62).

  By the way, in the communication system of this embodiment, the router 4 and the terminal (for example, the terminals 61 and 62 in case 1) transmit and receive a PPP frame that may not include the destination information. It is necessary to send information to the two terminals 61 and 62 individually.

  On the other hand, according to the configuration of the present embodiment, not the terminal 61 (62) but the first wireless device 5A may not contain the router 4 (first communication device) and destination information (PPP control). Packet) and the IP address of the terminal 61 (62) included in the PPP frame received from the router 4 (first communication device) transmitted after the processing, and the table data stored in the storage unit 53 The second radio device 5B corresponding to the terminal 61 (62) that is the destination of the data (information) included in the PPP frame is specified. Thus, while the router 4 and the terminal 61 (62) are configured to transmit and receive a PPP frame that may not include the destination information, the router 4 reliably transmits the data addressed to the terminal 61 (62). ).

Further, a configuration is conceivable in which the router 4 and the terminals 61 and 62 are individually connected so as to enable communication via a PPP frame. In this case, the router 4 and each of the terminals 61 and 62 can be configured to transmit and receive a PPP frame that may not include destination information.
However, in this case, it is necessary to provide a communication port (S9 port) compatible with the PPP protocol in a state in which the router 4 and the first wireless device 5A correspond to the terminals 61 and 62 on a one-to-one basis.

  On the other hand, according to the configuration of the present embodiment, communication via the PPP frame that may not include the destination information is performed between the router 4 and the first wireless device 5A and the wireless device (for example, the first wireless device). This is performed between the wireless device 5A) and a terminal (for example, the terminal 61). Communication between the first wireless device 5A and the second wireless device 5B is performed via a wireless packet including a wireless device ID (ID-5B) as destination information. Thereby, while the router 4 and the terminals 61 and 62 are configured to transmit and receive the PPP frame, the router 4 and the first wireless device 5A have a communication port (S9 port) compatible with the PPP protocol for intercommunication use. Only one thing needs to be provided. Therefore, the number of communication ports corresponding to the PPP protocol necessary for the router 4 and the first radio device 5A can be reduced, and the configuration of the router 4 and the first radio device 5A can be simplified.

[2.6 First Modification]
In the first modification, the router 4 and the terminals 61 and 62 are connected by the PPP links L1 and L2, and apart from these, the router 4 and the first radio device 5A are connected by the PPP link L0. Has been.

FIG. 22 is an explanatory diagram of this modification.
In this modification, the router 4 is connected to the first radio device 5A, and the terminals 61 and 62 are connected to the second radio device 5B and the third radio device 5C, respectively. The first wireless device 5A and the router 4 transmit and receive a PPP frame, and are located at both ends of a PPP link L0 that is a point-to-point communication link. The router 4 and the terminal 61 transmit and receive a PPP frame, and are located at both ends of the PPP link L1, which is a point-to-point communication link. Furthermore, the router 4 and the terminal 62 transmit and receive a PPP frame, and are located at both ends of a PPP link L2 that is a point-to-point communication link.
Here, in addition to the second radio device 5B and the third radio device 5C, there are also a fourth radio device 5D and a fifth radio device 5E in the vicinity of the first radio device 5A, which are transmitted from the first radio device 5A. It is assumed that the received radio waves can be received by the fourth radio device 5D and the fifth radio device 5E.

In this modification, connection setting information (first setting information, second setting information) and table data are stored in the first storage unit 53 of the first wireless device 5A. Here, the connection setting information (first setting information, second setting information) is, for example, as shown in FIG. The table data is, for example, as shown in FIG.
Connection setting information (first setting information, second setting information) is also stored in each first storage unit 53 of the second wireless device 5B and the third wireless device 5C.

The first setting information stored in the first storage unit 53 of the second wireless device 5B (third wireless device 5C) is the port (own device port) connected to the terminal 61 (terminal 62) of the wireless devices 5B and 5C. This is for associating the own device port IP indicating the IP address of the device with the destination port where the PPP link is formed between the own device port.
Specifically, the first setting information is configured by associating its own port IP, source port IP, and destination port IP. For example, the first setting information of the second wireless device 5B (third wireless device 5C) is the IP address “IP-R1” (“IP--” of the port of the router 4 with respect to the first setting information shown in FIG. R2 ”) is added as“ destination port IP ”.

  The second setting information associates the IP address of the destination port with the own port IP that is the IP address of the port (own device port) connected to the terminal 61 (terminal 62) in the wireless devices 5B and 5C. belongs to. Specifically, the second setting information is configured by associating the source port IP, the destination port IP, and the own port IP. For example, the second setting information of the second wireless device 5B (third wireless device 5C) is the IP address “IP-T1” of the port of the terminal 61 (62) with respect to the second setting information shown in FIG. This corresponds to a case where “IP-T2”) is added as “source port IP”.

  The first setting information described above is information that is referred to when the wireless devices 5B and 5C receive a PPP frame from the connected terminals 61 and 62.

  The second setting information is information that is referred to when each of the wireless devices 5A, 5B, and 5C receives a wireless packet from another wireless device. The second setting information is used for processing (reception determination processing, transfer determination processing) for determining how to handle a received wireless packet. Here, in the IRC header of the wireless packet received by the wireless devices 5B and 5C, information that can identify the PPP link, that is, when the router 4 establishes the PPP link with the terminal 61 via the wireless devices 5A and 5B, Information that can identify the link is included as “PPP link identification information”.

Here, a case where a PPP frame is transmitted from the central apparatus 2 to the terminal 61 via the router 4 will be described. Here, a case where the PPP link identification information is stored in the destination wireless device ID of the IRC header is illustrated.
The router 4 transmits a PPP frame including information to be transmitted to the terminal 61 from the port to which the IP address “IP-R1” is assigned. The first wireless device 5A receives the PPP frame transmitted from the port assigned the IP address “IP-R1” of the router 4 at the port assigned the IP address “IP-1A”.
The first processing unit 52 of the first wireless device 5A refers to the table data shown in FIG. 23B, performs destination recognition processing, and from the port assigned the IP address “IP-1A” of the own device 5A. Since it has been received, it is recognized that it is necessary to transfer to the destination wireless device ID “ID-5B-LinkT1”.

  The first radio device 5A encapsulates the upper layer packet and the protocol portion in FIG. 8 using an IRC header to generate an IRC frame. At this time, “ID-5B-LinkT1” is assigned to the destination wireless device ID as the PPP link identification information between the router 4 and the terminal 61. Further, the first wireless device 5A adds wireless communication control information (from the Security header to the PHY header) to the IRC frame to generate a wireless packet. The generated wireless packet is broadcast from the first wireless device 5A.

  The second wireless device 5B that has received the wireless packet performs reception determination processing that refers to the table data and the second setting information based on the destination wireless device ID (PPP link identification information) included in the IRC header of the received wireless packet. Do. First, since the second wireless device 5B is the destination wireless device ID registered in the table data, the upper layer packet and the protocol part are extracted from the received wireless packet by the reception determination process.

  Next, the second wireless device 5B refers to the second setting information and recognizes that its own port needs to be transferred to the port to which the IP address “IP-1B” is assigned. Then, a PPP frame is generated from the data and transmitted from its own port. The transmitted PPP frame is received by the port to which the IP address “IP-1B” of the terminal 61 is assigned.

Even when a PPP frame is transmitted from the terminal 61 to the router 4, processing is performed in the same procedure as described above.
That is, the terminal 61 transmits a PPP frame including information to be transmitted to the central apparatus 2 from the port to which the IP address “IP-T1” is assigned. The second wireless device 5B receives the PPP frame transmitted from the port of the terminal 61 at the port to which the IP address “IP-1B” is assigned.
The first processing unit 52 of the second wireless device 5B refers to the table data, performs destination recognition processing, and recognizes whether it is necessary to transfer to the destination wireless device ID “ID-5A-LinkR1”.
The second radio device 5B encapsulates the upper layer packet and the protocol portion in FIG. 8 with an IRC header including identification information, and generates an IRC frame. Furthermore, the second radio device 5B adds radio communication control information (from the Security header to the PHY header) to the IRC frame to generate a radio packet. The generated wireless packet is broadcast from the second wireless device 5B.

The first wireless device 5A that has received the wireless packet performs reception determination processing that refers to the table data and the second setting information based on the destination wireless device ID (PPP link identification information) included in the IRC header of the received wireless packet. Do. First, the first wireless device 5A extracts the upper layer packet and the protocol portion from the received wireless packet by the reception determination process. Next, the first wireless device 5A generates a PPP frame from the extracted data based on the second setting information, and transfers it to the IP address “IP-1A” of the port connected to the router 4 (own device port). Recognize that there is a need.
When the first wireless device 5A recognizes the IP address “IP-1A” of the own device port, the first wireless device 5A generates a PPP frame from the data and transmits it from the own device port assigned the IP address “IP-1A”. The transmitted PPP frame is received by the port to which the IP address “IP-R1” of the router 4 is assigned.

Next, a case where an upper layer packet is transmitted from the router 4 to the fourth radio device 5D will be described.
The router 4 establishes a PPP link with the fourth radio device 5D connected to the port to which the IP address “IP-R3” is assigned in advance. Thereafter, the router 4 transmits a PPP frame including information to be transmitted to the fourth wireless device 5D from the port to which the IP address “IP-R3” is assigned. The first wireless device 5A receives the PPP frame transmitted from the port of the router 4 at the port to which the IP address “IP-3A” is assigned.
The first processing unit 52 of the first wireless device 5A extracts the upper layer packet included in the PPP frame by receiving the PPP frame at the port (own device port) to which the IP address “IP-3A” is assigned. Decide to perform the process. That is, the first radio device 5A determines to perform processing for extracting a higher layer packet from the PPP frame and encapsulating the extracted higher layer packet to generate a radio packet.

  Then, the first radio device 5A extracts an upper layer packet from the PPP frame, encapsulates the upper layer packet extracted by the IRC header, and generates an IRC frame. Here, when the destination IP address included in the upper layer packet is the IP address (IP-T5D) of the fourth wireless device 5D, the destination wireless device ID included in the IRC header is given to the fourth wireless device 5D. Set to radio ID (ID-5D). Further, the first wireless device 5A adds wireless communication control information (from the Security header to the PHY header) to the IRC frame to generate a wireless packet. The generated wireless packet is broadcast from the first wireless device 5A.

  The fourth wireless device 5D that has received the wireless packet performs reception determination processing using the transmission source wireless device ID 75 and the destination wireless device ID 74 included in the IRC header of the received wireless packet. The fourth wireless device 5D can recognize that the destination of the received upper layer packet is the own device 5D by the reception determination process. As a result, the upper layer packet included in the wireless packet is processed in the upper layer of the fourth wireless device 5D.

Even when an upper layer packet is transmitted from the fourth wireless device 5D to the central device 2 or the like via the router 4, processing is performed in the same procedure as described above.
That is, the fourth radio device 5D encapsulates the upper layer packet to be transmitted to the central apparatus 2 via the router 4 with the IRC header to generate an IRC frame. Further, the fourth wireless device 5D adds wireless communication control information (from the security header to the PHY header) to the IRC frame to generate a wireless packet. The generated wireless packet is broadcast from the fourth wireless device 5D.

The first wireless device 5A that has received the wireless packet performs reception determination processing using the destination wireless device ID 74 included in the IRC header of the received wireless packet. The first wireless device 5A can recognize that the destination of the upper layer packet included in the received wireless packet is the central device 2 (IP-Y) connected to the own device 5A by the reception determination process. .
The first wireless device 5A refers to the second setting information shown in FIG. 23A and recognizes the port to which the IP address “IP-3A” is assigned as its own port. Then, the first wireless device 5A transmits the PPP frame from its own port assigned the IP address “IP-3A”. The transmitted PPP frame is received by the port to which the IP address “IP-R3” of the router 4 is assigned.

[2.7 Second Modification]
In this modification, communication between the router 4 and the wireless device 5 is performed by Ethernet communication. That is, the router 4 and the wireless device 5 communicate with each other via the S11 interface standard port. Specifically, when receiving the wireless packet, the wireless device 5 extracts an upper layer packet from the wireless packet, and adds an Ethernet header to the extracted upper layer packet to generate an Ethernet frame. Then, the wireless device 5 transmits the generated Ethernet frame from e-support (S11 port: e-support P _M1 ). Then, the router 4 receives the Ethernet frame transmitted from the wireless device 5 by the e-support _{PM 1} . Similarly, Ethernet communication may be performed between the wireless device 5 and the terminal 6.

  Here, the Ethernet header of the Ethernet frame includes a destination MAC address and a source MAC address. For example, when data is transmitted to the router 4 or the wireless device 5, the destination MAC address is the MAC address of the wireless device 5, and the transmission source MAC address is the MAC address of the router 4.

  In the present modification, connection setting information (first setting information, second setting information) as shown in FIG. 24A is stored in the first storage unit 53 of the first wireless device 5A. Then, connection setting information (first setting information, second setting information) as shown in FIG. 24B is stored in each first storage unit 53 of the second wireless device 5B and the third wireless device 5C. Yes.

The first setting information is information that is referred to when each of the wireless devices 5A, 5B, and 5C receives an Ethernet frame from the connected communication device (router 4 or terminals 61 and 62).
The first setting information is transmitted with the MAC address (MAC-1A (1B, 1C)) of the port connected to the router 4 or the terminal 6 of the own device 5A, 5B, 5C (own device port: port P _M1, for example). the MAC address of the source port (e.g., port _{P MT1, P MT2} port _{P MR1} and terminal 6 of router 4) (MAC-R1 (T1 , T2)), are configured in association with each other.

The second setting information is information that is referred to when each wireless device 5A, 5B, 5C receives a wireless packet from another wireless device 5. The second setting information is used when generating an Ethernet frame from the received wireless packet.
The second setting information includes the MAC address (MAC-1A (1B, 1C)) of the port (own port: for example, port P _M1 ) connected to the router 4 or the terminal 6 of the own device 5A, 5B, 5C, and the destination port (e.g. port _P MT1 port _{P MR1} and terminal 6 of the router _{4, P MT2)} MAC address (MAC-R1 (T1, T2 )) , but is configured in association with each other.

  As described above, in the communication system according to this modification, the router (first communication device) 4 and the first wireless device 5A are respectively connected between the second wireless device 5B and the terminal (second communication device) 61. It can be connected via Ethernet.

[2.8 Third Modification]
This modification is different from the embodiment in that the reception determination process performed by the wireless device 5 is performed using the transmission source wireless device ID and the destination IP address. Other processes are the same as those of the embodiment described with reference to FIG.
Here, the reception determination process performed by the second radio device 5B when the upper layer packet is transmitted from the router 4 to the terminal 61 will be described.

FIG. 25 is a flowchart showing the contents of the reception determination process performed by the wireless device (second wireless device) 5B according to this modification.
First, the second wireless device 5B performs the processing from steps S91 to S93 described with reference to FIG.
Next, the second radio device 5B collates the read source radio device ID 75 with the source radio device ID registered in advance in the own device 5B (step S291).

If the collation result is NG (step S292: No), the second radio device 5B determines that the IRC frame is “unnecessary”.
On the other hand, when the collation result is OK (step S292: Yes), the second wireless device 5B acquires the destination IP address of the upper layer packet included in the IRC frame from the IRC frame, and the acquired destination IP address and the own device. The destination IP address registered in advance in 5B (for example, the IP address “IP-T1” assigned to the port P1 of the terminal 61) is collated (step S293).

If the collation result is NG (step S294: No), the second radio device 5B determines that the IRC frame is “unnecessary”.
On the other hand, if the collation result is OK (step S294: Yes), the holding list is updated (step S96), and the IRC frame is determined as “necessary”.

Thus, in this modification, the process of collating the destination wireless device ID is not performed in the reception determination process. Therefore, when transmitting an upper layer packet from the router 4 to the terminal 61, the first wireless device 5A does not need to set the destination wireless device ID 74 of the IRC header. Therefore, the first wireless device 5A does not need to have table data indicating the correspondence between the destination IP address and the destination wireless device ID. As a result, the storage capacity required for the first storage unit 53 of the first wireless device 5A can be reduced.
Further, the second radio device 5B is also required to store the IP address assigned to the port of the terminal 61 connected to the own device 5B, so that it is required for the first storage unit 53 of the second radio device 5B. There is also an advantage that the storage capacity is small.

[2.9 Fourth Modification]
This modification is different from the embodiment in that the reception determination process performed by the wireless device 5 is performed using the transmission source wireless device ID and the destination IP address. Other processes are the same as those of the embodiment described with reference to FIG.
Here, the reception determination process performed by the second radio device 5B when the upper layer packet is transmitted from the router 4 to the terminal 61 will be described.

FIG. 26 is a flowchart illustrating the contents of the reception determination process performed by the wireless device (second wireless device) 5B according to this modification.
First, the second wireless device 5B performs the processing from steps S91 to S95 described with reference to FIG.

  Next, the second radio device 5B determines whether or not the upper layer packet included in the IRC frame is the same as the upper layer packet transmitted before (immediately before), or whether or not it has been transmitted a predetermined number of times or more. (Step S391).

  Then, if it is determined that the upper layer packet included in the IRC frame is the same as the upper layer packet transmitted before (immediately before) or has been transmitted a predetermined number of times or more (step S391: Yes), the second radio The device 5B determines that the IRC frame is “unnecessary”.

  On the other hand, when it is determined that the upper layer packet included in the IRC frame is different from the upper layer packet transmitted before (immediately before) or the number of transmissions is less than the predetermined number (step S391: No), the second radio The device 5B updates the holding list (step S96) and determines that the IRC frame is “necessary”.

  As described above, in this modification, in the reception determination process, the upper layer packet included in the IRC frame is the same as the upper layer packet transmitted before (immediately before) or is transmitted a predetermined number of times or more. , It is determined that the IRC frame is unnecessary. Thereby, it can suppress that an upper layer packet is sent to the terminal 61 from the 2nd radio | wireless machine 5B redundantly. Therefore, the terminal 61 can reduce the processing load of the upper layer packet.

[3. Details of Embodiment (Part 2)]
[3.1 System configuration]
It is the same as that of FIG. 1, and uses the description of [2.1 System configuration].

[3.2 System installation example]
It is the same as FIG. 2, and the description of [2.2 System Installation Example] is cited.

[3.3 Configuration of radio equipment (base station)]
As illustrated in FIG. 27A, the wireless device 5 includes a wireless communication unit 51 that transmits and receives wireless signals, a processing unit 52 that performs information processing in the wireless device 5, and a storage unit 53. The processing unit 52 generates a wireless packet (wireless transmission data) transmitted from the wireless communication unit 51, performs processing given to the wireless communication unit 51, and processes the wireless packet received by the wireless communication unit 51.
The storage unit 53 stores information (first setting information, second setting information, third setting information, and other information described later) used for processing in the processing unit 52.

  In the processing unit 52 of the wireless device 5, part or all of the functions realized by the processing unit 52 may be configured by a hardware circuit, or part or all of the functions are realized by a computer program. May be. When part or all of the functions of the processing unit 52 are realized by a computer program, the processing unit 52 includes a computer, and the computer program executed by the computer is stored in the storage unit 53.

The wireless device 5 includes a first wired communication unit 54 and a second wired communication unit 55. The first wired communication unit 54 is for communicating with the router 4 by PPP. The first wired communication unit 54 conforms to the S9 interface standard. The first wired communication unit 54 includes a plurality of ports (S9 ports) P ₁ , P ₂ , P ₃ , P ₄ . In the following description, one port (S9 port) is described as a port for performing transmission / reception. That is, each of the plurality of ports (S9 ports) P ₁ , P ₂ , P ₃ , P ₄ shown in FIG. 27 includes a transmission port and a reception port in the S9 interface standard. The router 4 is also provided with a plurality of S9 ports, and each port (S9 port) P ₁ , P ₂ , P ₃ , P _{4 of} the wireless device 5 is an S9 port on the router 4 or terminal 6 side. And connected by a communication line.
The second wired communication unit 55 is a communication unit for Ethernet (registered trademark) connection, and includes one or a plurality of e-supports P _M1 , P _M2 , P _M3 , and P _M4 . An S11 interface standard (New Traffic Management System Association) has been formulated for a road safety support system (DSSS: Driving Safety Support Systems). The e-supports _PM1 , _PM2 , _PM3 , and _PM4 included in the wireless device 5 are ports for the S11 interface standard (Ethernet). Radio 5, via E. support P _M, may be connected with other devices such as routers 4 or terminal 6.

FIG. 27B shows a protocol stack in the wireless device 5 (although it is also described in FIG. 4, it will be described again for the sake of safety). The protocol stack shown in FIG. 27B includes a physical layer (PHY layer: Physical Layer), a MAC sublayer (Medium Access Control subscriber), an LLC sublayer (Logical Link Control sublayer), an inter-vehicle / road-to-vehicle shared communication control information layer (IV). -RVC layer:-Inter-Vehicle Communication-Load to Vehicle Communication Layer), Layer 7 (L7), and Extended Layer (EL).
Layer 1, MAC sublayer, LLC sublayer, IVC-RVC layer, and L7 are layers defined in Non-Patent Document 1. EL is a layer defined in Non-Patent Document 2.

  The EL or L7 can access security management. The security management can generate secure data by performing security processing (encryption processing, signature processing, etc.) on unsecured data received from the EL. In addition, the security management can return secure data subjected to security processing to data unsecurely.

  In the present embodiment, an IRC layer for controlling communication between roads is provided as an upper layer of EL. The IRC layer is not defined in Non-Patent Documents 1 and 2, but is provided as an extension layer or a layer immediately above the layer 7 in this embodiment. In addition, as an upper layer of the IRC layer, a PPP layer and an Ethernet layer are provided. Note that the Ethernet layer corresponds to a data link layer in the Ethernet standard. The PPP layer processes the PPP header of the PPP frame (adding a header, reading the header, etc.), and the Ethernet layer processes the Ethernet header of the Ethernet frame (adding a header, reading the header, etc.).

[3.4 Data structure]
FIG. 28 shows a data structure of a wireless packet (wireless transmission data) transmitted by the wireless device 5 and a data structure of a PPP frame transmitted by the router 4 or the terminal 6.
[3.4.1 Wireless packet structure]
The wireless packet in the present embodiment has, from the beginning, wireless communication control information, IRC (inter-road communication control information) header, data, and FCS areas.
The wireless communication control information is based on Non-Patent Documents 1 and 2, and from the top, a PHY header (physical header), a MAC control field (MAC header), an LLC control field (LLC header), an IR control field (IR Header), L7 header, and EL header.

  The PHY header is a header corresponding to layer 1 (physical layer) in the standard of Non-Patent Document 1. The MAC control field is a control field corresponding to the MAC sublayer (Medium Access Control Sublayer) of layer 2 in the same standard. The LLC control field is a control field corresponding to the LLC sublayer (Logical Link Control Sublayer) of layer 2 in the same standard. The IR control field is a control field corresponding to the vehicle-to-vehicle / road-vehicle shared communication control information (IVC-RVC) layer in the same standard. The L7 header is a header corresponding to layer 7 in the standard. The EL header is a header corresponding to the extended layer shown in Non-Patent Document 2. Note that the EL header may be omitted.

  As shown in FIG. 28, in the standard of Non-Patent Document 1, the L7 header is provided with an “Application Associated Information” field. In the same standard, the contents of the application-related information field are not defined, but in the present embodiment, the application-related information field is provided with a “communication classification” field.

  In the communication classification field, the type of wireless packet (communication type), that is, the wireless packet is “1. Communication from mobile station to mobile station / base station (vehicle-to-vehicle / inter-road shared communication)”, “2. “Communication from base station to mobile station / base station (road-to-vehicle / road-to-road communication)”, “3. Communication from mobile station to mobile station (inter-vehicle communication)”, “4. From base station to mobile station” Communication (road-to-vehicle communication) "," 5. communication from mobile station to base station (inter-road communication) "," 6. communication from base station to base station (road-to-road communication) " This is for classifying whether the packet is for communication. The communication classification field may not be this.

  Since the communication classification field is provided in the wireless packet, the wireless devices 5 and 7 that have received the wireless packet refer to the communication classification field included in the received wireless packet, and are packets necessary for the wireless device. If it is unnecessary without referring to a higher layer (a layer higher than layer 7) (for example, when a mobile station receives a packet for a base station and determines that it is unnecessary), The packet can be discarded.

  As shown in FIG. 28, in the standard of Non-Patent Document 1, the EL header (EL base station header) includes base station ID information (BaseStation ID: wireless transmission source ID). Therefore, when an EL header is included in the wireless packet, the receiving-side wireless device 5 (the EL layer thereof) refers to the base station ID information in the EL header to determine the ID of the wireless device 5 that transmitted the wireless packet. Can be acquired. As will be described later, in this embodiment, the base station ID information is used for wireless packet transfer suppression processing.

In the wireless packet, an area between the EL header and FCS (between the L7 header and FCS when EL is omitted) (an IRC header and data area in the wireless packet in FIG. 28) is an application as a wireless packet. An area where data is stored. Application data as a wireless packet may be secure data that has been subjected to security processing (encryption processing, signature processing, etc.) by security management (see FIG. 3B). The EL or L7 of the wireless device 5 that has received the secure data passes the secure data to the security management and is returned to the unsecured data by the security management, and the unsecured data received from the security management is sent to the upper layer. hand over.
For security management, when unsecured data is passed from L7 instead of EL, the subsequent areas (EL header, IRC header and data areas in the wireless packet in FIG. 28) are more secure than the L7 header. It becomes data. Furthermore, unsecured data may be passed from the IRC layer to the security management.

  When the wireless device 5 transmits data for the in-vehicle device 7 (road vehicle data), the application data for the in-vehicle device 7 is stored in the area where the application data is stored. On the other hand, the wireless device 5 according to the present embodiment is a case where communication between the wireless devices 5 (communication between roads) is performed and information related to management of the terminal 6 is transmitted (when transmission is performed using a PPP link). Then, an IRC frame including an IRC header and a PPP frame is stored in an area where application data as a wireless packet is stored.

The IRC (inter-road communication control information) header is a header corresponding to the IRC layer for controlling the inter-road communication. The IRC header will be described later.
In the wireless packet shown in FIG. 28, a security header generated by security management is omitted. The security header may be on the front side of the IRC header or on the back side of the IRC header. If the security header is in front of the IRC header, the IRC header can be made secure data. However, since the IRC header is a target of security processing, in order to read the IRC header, processing for unsecure is required. On the other hand, when the security header is behind the IRC header, since the IRC header is unsecured data, the process of making it unsecured is not necessary for reading the IRC header.
Further, the security header may be on the front side of the EL header or on the rear side of the EL header. When the security header is on the front side of the EL header, both the EL header (base station ID information (wireless transmission source ID)) and the IRC header can be made secure data. In addition, when the security header is behind the EL header, the EL header is unsecured. Therefore, when the information such as the base station ID information (wireless transmission source ID) included in the EL header is read, the process of making it unsecured Is unnecessary.

[3.4.2 PPP frame structure]
The wireless device 5 that has acquired the PPP frame generated by the router 4 or the terminal 6 adds wireless communication control information to the PPP frame and encapsulates it to generate a wireless packet.
As shown in FIG. 28, the PPP frame generated by the router 4 or the terminal 6 has a PPP header and a data part. The PPP header has a preamble and a protocol area. The preamble of the PPP header includes Flag, Address, and Control fields, each of which stores a fixed value.

  The protocol of the PPP header indicates the type of the data part that follows this protocol. When the value stored in the protocol area is any one of LCP (Link Control Protocol), authentication, and NCP (Network Control Protocol), the contents of the data part of the PPP frame are the PPP control packet shown in FIG. Become. When the value stored in the protocol area is a value indicating an upper layer (for example, IP), the content of the data portion of the PPP frame is an upper layer packet (IP packet) shown in FIG.

The PPP control packet has fields of Code, ID, Length, data, or parameter list.
Code is information indicating the type of the PPP control packet. ID is an identifier of a PPP control packet. Length is a PPP control packet length. The data or parameter list field stores data related to each PPP control packet.

  The LCP or authentication PPP control packet does not have information indicating the destination of the PPP control packet. Therefore, the LCP or authentication PPP frame does not have destination information. That is, PPP is a protocol that may not have destination information in its communication frame (PPP frame). When the content of the data portion of the PPP frame is an upper layer packet, the PPP frame includes destination information (destination IP address, etc.) of the upper layer packet.

[3.4.3 IRC (Route Communication Control Information; Radio Communication Control) Header]
The IRC header is generated by processing (information addition processing; IRC header addition processing) by the IRC layer of the wireless device 5 that generates a wireless packet (wireless transmission data), and the wireless device 5 that has received the wireless packet (wireless transmission data). It is used for processing by the IRC layer. As shown in FIGS. 29A to 29D, the IRC header includes identification information 171, 173, 174 and transfer count information 172.

The identification information 171, 173, and 174 indicates that the wireless device 5 (the IRC layer) that received the wireless packet is a device (router 4 or terminal 6) in which the destination of the PPP frame included in the wireless packet is connected to the own device 5. It is used for reception determination processing for determining whether or not.
The identification information 171, 173, and 174 is information for the wireless device 5 that has received a wireless packet including a PPP frame to determine whether or not the PPP frame is related to the own device 5. In other words, the identification information determines whether or not the wireless device 5 that has received the wireless packet including the PPP frame should transmit the PPP frame to a device (router 4 or terminal 6) connected to the own device 5. It is information for. The identification information is also used in a transfer determination process, which will be described later, which is one of the determination processes regarding whether or not the information is related to the own device 5.

  The number-of-transfers information 172 is information regarding the number of times a wireless packet including a PPP frame has been transferred. Note that the transfer count information may be omitted.

29A to 29D show various examples of IRC headers.
The IRC header in FIG. 29A includes a transmission source port ID (transmission source ID) 171 as identification information in addition to the transfer count information 172. The transmission source port ID 171 is an identifier indicating the port of the apparatus 4 or 6 that is the transmission source of the PPP frame. That is, it is an identifier indicating the S9 port provided in the router 4 or the terminal 6.
FIG. 29B shows another example of the IRC header. The IRC header in FIG. 29B has a destination port ID (destination ID) 173 as identification information in addition to the transfer count information 172. The destination port ID 173 is an identifier indicating the port of the destination device 4 or 6 of the PPP frame.

When the wireless device 5 and the device (router 4 or terminal 6) connected to the wireless device are connected by only a pair of ports, the transmission source port ID 171 is the device 4 of the PPP frame transmission source. Information corresponding to the device ID (transmission source ID) indicating one-to-one, and substantially equivalent information. In the above case, the destination port ID 173 is information substantially corresponding to the device ID (destination ID) indicating the destination devices 4 and 6 of the PPP frame in a one-to-one manner.
Therefore, the identification information stored in the IRC header may be the destination device ID instead of or in addition to the destination port ID 173. Further, the identification information stored in the IRC header may be a transmission source device ID instead of or in addition to the transmission source port ID.

FIG. 29C shows another example of the IRC header. The IRC header of FIG. 29C includes, as identification information, a destination port ID (destination ID) 173, a source port ID (source ID) 61, and a PPP link ID 174 as shown in FIGS. 29A and 29B and FIG. 29D described later. Only one of them may be used, but as shown in FIG. 29C, both the destination port ID (destination ID) 173 and the source port ID (source ID) 61 may be provided. That is, a plurality of pieces of information among the information of the destination port ID (destination ID) 173, the source port ID (source ID) 61, and the PPP link ID 174 may be stored in the ICR header.
FIG. 29D shows another example of the IRC header. The IRC header in FIG. 29D has a PPP link ID 174 as identification information. The PPP link ID 174 is an identifier indicating a PPP link to be formed between the router 4 and the terminal 6. Since the PPP link is a link formed between two ports, the PPP link can be uniquely specified by only one of the source port ID 171 and the destination port ID 173 shown in FIGS. That is, not only the PPP link ID but also the source port ID 171 and the destination port ID 173 are identification information (hereinafter referred to as PPP link identification information) that can identify the PPP link to which the PPP frame is transmitted.

[3.5 PPP link with wireless communication section]
[3.5.1 Case 1]
In case 1, as shown in FIG. 30, one device (router (first device) 4 and one terminal (second device) 61 are provided for each of a pair of wireless devices (first wireless device 5A and second wireless device 5B). ) Is connected. The devices 4 and 61 transmit and receive a PPP frame, and are located at both ends of a PPP link L1 that is a point-to-point communication link.
In addition to the second radio device 5B, there is also a third radio device 5C in the vicinity of the first radio device 5A, and the radio waves transmitted from the first radio device 5A can be received by the third radio device 5C. To do. A terminal 62 is connected to the third wireless device 5C. The terminal 62 can also transmit and receive a PPP frame.

  In Case 1, it is assumed that the PPP link L1 needs to be formed between the router 4 and the terminal 61, and the PPP link is not formed between the router 4 and the terminal 62. For example, it is conceivable that the terminal 62 forms a PPP link with another router installed in a distant place not shown in FIG.

In case 1, the first setting information and the second setting information shown in FIGS. 31A to 31C are set in the storage units 53 of the first wireless device 5A, the second wireless device 5B, and the third wireless device 5C. Has been.
The first setting information is information that is referred to when each of the wireless devices 5A, 5B, and 5C receives a PPP frame from the connected devices 4, 61, and 62. The first setting information is added to the PPP frame and used to generate identification information that constitutes a wireless packet.
First setting information indicates own apparatus 5A, 5B, port _P 1A _{to P} 4A of _5C, P _1B to P _4B, port connected to the router 4 or terminal 6 of the P 1C _{to P 4C} (reception port) This is for associating the reception port ID with identification information (PPP link identification information). Specifically, the first setting information is configured by associating a reception port ID (first port ID), a transmission source port ID (transmission source ID), and a destination port ID (destination ID). Yes. The source port ID (source ID) and the destination port ID (destination ID) in the first setting information are both PPP link identification information. The source port ID (source ID) and destination port ID (destination ID) as identification information are both PPP link identification information, and it is sufficient if any one of the information exists, and other information is omitted. Also good. By omitting the information, the amount of information can be suppressed.

The second setting information is information that is referred to when each of the wireless devices 5A, 5B, 5C receives a wireless packet from another wireless device. The second setting information is used for processing (reception determination processing, transfer determination processing) for determining how to handle a received wireless packet.
The second setting information includes the identification information (PPP link identification information) and the router 4 or the terminal 6 among the ports P _{1A to} P _4A , P _{1B to} P _4B , and P _{1C to} P _4C of the own devices 5A, 5B, 5C. This is for associating the transmission port ID indicating the connected port (transmission port). Specifically, the second setting information is configured by associating a transmission source port ID (transmission source ID), a destination port ID (destination ID), and a transmission port ID (second port ID). Yes. The transmission source port ID (transmission source ID) and the destination port ID (destination ID) in the second setting information are both PPP link identification information. As with the first setting information, the source port ID (source ID) and the destination port ID (destination ID) as identification information are both PPP link identification information, and it is sufficient that one of the information exists. Other information may be omitted.

FIG. 32 shows a communication processing procedure of the first radio device 5A and the second radio device 5B when a PPP frame is transmitted from the router 4 to the terminal 61. In FIG. 32, the same reference numerals (S1 to S14) as in FIG. 12 are used, but this is for facilitating the comparison between FIG. 32 and FIG. However, the processing content may differ between FIG. 32 and FIG.
First, the router 4, the PPP frame including information for the terminal 61, and transmits from the port (S9 _{port) P R1} of terminals 61 addressed information. However, the PPP frame does not include information indicating the destination terminal 61 as described above. Also, the PPP frame does not include information indicating the router 4 that is the transmission source.
The first radio 5A is a PPP frame transmitted from the port _{P R1} router 4 is received at the port (S9 _{port) P 1A} (step S1).

The processing unit 52 of the first wireless device 5A performs transmission source recognition processing for recognizing the transmission source of the received PPP frame without discarding the received PPP frame (step S2). Information indicating the transmission source recognized by the transmission source recognition process is used as identification information of the IRC header.
In the transmission source recognition processing, in order to obtain the transmission source of the PPP frame, the reception port ID of the first setting information is searched using the port information indicating the port P _1A that has received the PPP frame as a search key. The first setting information of the first radio telephone 5A shown in FIG. 31A, the reception port ID _{(P 1A)} is present which matches the port ID _{(P 1A)} is a search key. Here, the transmission source port ID is used as the identification information among the two pieces of identification information (transmission source port ID, destination port ID). Therefore, in the transmission source recognition process, the transmission source port ID (P _R1 ) that is identification information corresponding to the reception port ID (P _1A ) that matches the search key is obtained.
That is, information (identification information) indicating the port _PR1 of the router 4 that is the transmission source of the received PPP frame is obtained by the transmission source recognition process.

Subsequently, the processing unit 52 (function as IRC layer) is, IRC identification information indicating the _{P R1} is a port ID of the router 4 which is the source of the PPP frame received is stored in the field source port ID171 A header (see FIG. 29A) is generated and added to the beginning of the PPP frame (identification information adding process; step S3). That is, an IRC frame that encapsulates the received PPP frame is generated. Note that the transfer count information is set to 0, for example.
As described above, the identification information is added by the IRC layer which is a layer different from the PPP layer (a layer lower than the PPP layer).

Then, the IRC layer makes a wireless transmission request for the generated IRC frame to the enhancement layer (EL) (layer 7 when no enhancement layer exists) (step S4).
Each layer from the enhancement layer (EL) to the PHY layer generates radio packets by adding the radio communication control information (from EL header to PHY header) shown in FIG. 28 to the IRC frame (radio packet generation). Process: Step S5). That is, the generation of the wireless packet is performed by a layer (an extension layer to a PHY layer) different from the PPP layer and the IRC layer.
In the wireless packet generation process, the extension layer of the first wireless device 5A sets the ID of the first wireless device 5A in the base station ID information field of the EL header. In the wireless packet generation process, the layer 7 of the first wireless device 5A sets information indicating “6. Communication from base station to base station (inter-road communication)” in the communication classification field. To do.
The generated wireless packet is broadcast from the first wireless device 5A (step S6).
When security processing is performed by security management, it may be for IRC data (data excluding IRC header to PHY header) or IRC frame (data excluding EL header to PHY header). It may be. Also, when accessing security management from layer 7, it may be for L7 data (data excluding the L7 header PHY header).

The broadcast-transmitted wireless packet is received by the second wireless device 5B. The processing unit 52 (each layer from the PHY layer to the enhancement layer (EL); the wireless processing function unit) of the second wireless device 5B that has received the wireless packet performs a wireless packet reception process (step S7).
Of the wireless packet reception processing, in processing at layer 7, determination based on the communication classification included in the L7 header is performed. When the communication classification indicated by the communication classification field is not a classification addressed to the base station, the second radio device 5B as the base station can discard the received radio packet. However, since the communication category field is set to “6. Communication from base station to base station (inter-road communication)”, which is one of the categories addressed to the base station, the received radio packet is discarded. Can be processed without.
On the other hand, since the classification indicated by the communication classification field is not a classification addressed to the base station, the in-vehicle device (mobile station) 7 that has received the wireless packet transmitted from the first wireless device 5A discards the received wireless packet. May be.

  The processing unit 52 of the second wireless device 5B gives the IRC frame (IRC header and PPP frame) from which the wireless communication control information (from the PHY header to the EL header) is removed from the received wireless packet from the enhancement layer to the IRC layer. Processing is performed (step S8). The enhancement layer of the second radio device 5B gives the ID of the first radio device 5A stored in the base station ID information field of the EL header of the received radio packet to the IRC layer. The process of obtaining the IRC frame from the received radio packet is performed by a layer different from the PPP layer and the IRC layer.

The IRC layer of the second radio device 5B performs reception determination processing using the identification information included in the IRC header (step S9). The IRC layer that performs the reception determination process is a layer different from the PPP layer (a layer lower than the PPP layer).
The reception determination process is a process for determining the destination of the PPP frame included in the received wireless packet and determining the handling of the obtained PPP frame. Specifically, in the reception determination process, the IRC layer determines whether the destination of the PPP frame is the terminal 61 connected to the own device 5B.

For reception determination processing, the IRC layer of the second radio device 5B sets the identification information (source port ID = P _R1 ) included in the received IRC header as a search key in the storage unit 53 of the second radio device 5B. The source port ID of the second setting information (reception determination information) is searched. In the second setting information of the second radio device 5B shown in FIG. 31B, there is a transmission source port ID (P _R1 ) that matches the transmission source port ID = P _R1 that is a search key. Therefore, in the reception determination process (step S9), the transmission port ID (P _1B ) corresponding to the transmission source port ID (P _R1 ) that matches the search key is obtained.
That is, the second wireless device 5B can identify the port (transmission port; second port) _P1B connected to the device 61 that is the destination of the received PPP frame by the reception determination process.

When the identification information of the transmission port is obtained, the IRC layer of the second radio device 5B recognizes that the obtained PPP frame is addressed to the terminal 61 connected to the own device 5B. PPP layer of the second radio 5B is the resulting PPP frame, and transmits the identified transmission port _{P 1B} (step S10).
The PPP frame transmitted from the second radio device 5B is received by the terminal 61.

  If the second setting information (reception determination information) is searched using the received identification information as a search key and there is no hitting identification information, the destination of the received PPP frame is the terminal connected to the own device 5B. It is determined that it is not 61. In this case, a transfer determination described later (step S11) is performed, and if there is no need for transfer, the PPP frame is discarded (step S12).

The wireless packet broadcast from the first wireless device 5A is received not only by the second wireless device 5B but also by the third wireless device 5C. The processing unit 52 (the layers from the PHY layer to the enhancement layer (EL); the wireless processing function unit) of the third wireless device 5C that has received the wireless packet performs the reception processing of the wireless packet in the same manner as the second wireless device 5B. To obtain an IRC frame (IRC header and PPP frame).
The IRC layer of the third radio device 5C performs reception determination processing using the identification information (source port ID = P _R1 ) included in the IRC header.
However, in the second setting information of the third wireless device 5C illustrated in FIG. 31C, there is no source port ID that matches the received source port ID = _PR1 . Accordingly, the third wireless device 5C determines that the destination of the received PPP frame is not the terminal 62 connected to the own device 5C. In this case, the third wireless device 5C performs transfer determination described later, and discards the PPP frame if transfer is not necessary.

As described above, the PPP frame transmitted from the router 4 may be broadcast by the first radio device 5A and received by the plurality of radio devices 5B and 5C. However, since the reception side radio devices 5B and 5C perform reception determination using the identification information included in the IRC header, even if the PPP frame does not include the destination information, it is surely the original destination. Only two wireless devices 5B can receive.
In addition, the third wireless device 5C, which has nothing to do with the original destination, discards the PPP frame in the third wireless device 5C without giving the PPP frame to the terminal 62 connected to the third wireless device 5C. 62 can prevent the PPP link establishment process from being erroneously performed with the router 4.

Even when a PPP frame is transmitted from the terminal 61 to the router 4, processing is performed in the same procedure as described above.
That is, the terminal 61, the PPP frame containing information to be transmitted to the router 4, and transmitted from the port (S9 _{port) P T1} for the router 4 addressed information. The second radio device 5B receives the PPP frame transmitted from the port P _{T1 of the} terminal 61 at the port P _1B .
The processing unit 52 of the second wireless device 5B refers to the first setting information shown in FIG. 31B, performs transmission source recognition processing, and uses the transmission source port ID (P _T1 ) of the terminal 61 that is the transmission source as identification information. Get.
The second radio device 5B encapsulates the PPP frame with an IRC header including identification information to generate an IRC frame. Further, the second wireless device 5B adds wireless communication control information (from EL header to PHY header) to the IRC frame to generate a wireless packet. The generated wireless packet is broadcast from the second wireless device 5B.
When security processing is performed by security management, the IRC data (data excluding the IRC header to the PHY header) or the IRC frame (data excluding the EL header to the PHY header) may be used. It may be against. Also, when accessing security management from layer 7, it may be for L7 data (data excluding the L7 header PHY header).

The first wireless device 5A that has received the wireless packet, based on the identification information (source port ID = P _T1 ) included in the IRC header of the received wireless packet, receives reception determination that refers to the second setting information shown in FIG. 31A. Process. The first wireless device 5A can recognize that the destination of the received PPP frame is the device (router 4) connected to the own device 5A by the reception determination process. Further, the first wireless device 5A can identify the port (transmission port; second port) _P1A connected to the router 4 that is the destination of the received PPP frame by the reception determination process.
When the first wireless device 5A identifies the transmission port _P1A , the first wireless device 5A transmits a PPP frame from the transmission port _P1A . The transmitted PPP frame is received by the router 4.

  The wireless packet transmitted from the second wireless device 5B is also received by the third wireless device 5C, but is discarded as a result of the reception determination process of the third wireless device 5C. Therefore, the PPP frame transmitted from the terminal 61 is also prevented from being received by the terminal 62.

Regarding case 1, in the above description, the identification information is the source port ID, but it may be the destination port ID. When the identification information is the destination port ID, the header structure of the IRC header is as shown in FIG. 29B.
When the identification information is the destination port ID, the transmission method of the communication frame may be read as “destination” in the description above with reference to FIG. 32, but will be specifically described below. The point which is not demonstrated below uses the description about the case where identification information is transmission origin port ID.

First, the first wireless telephone 5A is a PPP frame transmitted from the port _{P R1} router 4 is received at the port (S9 _{port) P 1A} (step S1).

The processing unit 52 of the first wireless device 5A performs destination recognition processing for recognizing the destination of the received PPP frame (step S2). Information indicating the destination recognized by the destination recognition processing is used as identification information of the IRC header.
In the destination recognition processing, in order to obtain the destination of the PPP frame, the reception port ID of the first setting information is searched using the port information indicating the port P _1A that has received the PPP frame as a search key. The first setting information of the first radio telephone 5A shown in FIG. 31A, the reception port ID _{(P 1A)} is present which matches the port ID _{(P 1A)} is a search key. Therefore, in the destination recognition process, a destination port ID (P _T1 ) that is identification information corresponding to the reception port ID (P _1A ) that matches the search key is obtained.
That is, information (identification information) indicating the port P _T1 of the terminal 61 that is the destination of the received PPP frame is obtained by the destination recognition process.

Subsequently, (a function as IRC layer) processing unit 52, the received IRC header identification information indicating _{P T1} the port ID of the terminal 61 which is the destination of the PPP frame is stored in the field of the destination port ID 173 ( 29B) is generated and added to the beginning of the PPP frame (identification information adding process; step S3). That is, an IRC frame that encapsulates the received PPP frame is generated. Note that the transfer count information is set to 0, for example.

Then, the IRC layer makes a wireless transmission request for the generated IRC frame to the enhancement layer (EL) (layer 7 when no enhancement layer exists) (step S4).
Each layer from the enhancement layer (EL) to the PHY layer generates radio packets by adding the radio communication control information (from EL header to PHY header) shown in FIG. 28 to the IRC frame (radio packet generation). Process: Step S5).
The generated wireless packet is broadcast from the first wireless device 5A (step S6).

  The broadcast-transmitted wireless packet is received by the second wireless device 5B. The processing unit 52 (each layer from the PHY layer to the enhancement layer (EL); the wireless processing function unit) of the second wireless device 5B that has received the wireless packet performs a wireless packet reception process (step S7).

  The processing unit 52 of the second radio device 5B gives the IRC frame (IRC header and PPP frame) from which the radio communication control information (from the PHY header to the EL header) is removed from the received radio packet from the enhancement layer to the IRC layer. Processing is performed (step S8). The enhancement layer of the second radio device 5B gives the ID of the first radio device 5A stored in the base station ID information field of the EL header of the received radio packet to the IRC layer.

  The IRC layer of the second radio device 5B performs reception determination processing using the identification information included in the IRC header (step S9).

For reception determination processing, the IRC layer of the second radio device 5B sets the identification information (destination source port ID = P _T1 ) included in the received IRC header as a search key in the storage unit 53 of the second radio device 5B. The destination port ID of the set second setting information (reception determination information) is searched. In the second setting information of the second radio device 5B shown in FIG. 31B, there is a destination port ID (P _T1 ) that matches the search port destination port ID = P _T1 . Therefore, in the reception determination process (step S9), the transmission port ID (P _1B ) corresponding to the destination port ID (P _T1 ) that matches the search key is obtained.
That is, the second wireless device 5B can identify the port (transmission port; second port) _P1B connected to the device 61 that is the destination of the received PPP frame by the reception determination process.

When the identification information of the transmission port is obtained, the IRC layer of the second radio device 5B recognizes that the obtained PPP frame is addressed to the terminal 61 connected to the own device 5B, and transmits the PPP frame to the identified transmission. Transmission is performed from the port P _1B (step S10).
The PPP frame transmitted from the second radio device 5B is received by the terminal 61.

The wireless packet broadcast from the first wireless device 5A is received not only by the second wireless device 5B but also by the third wireless device 5C. The processing unit 52 (the layers from the PHY layer to the enhancement layer (EL); the wireless processing function unit) of the third wireless device 5C that has received the wireless packet performs the reception processing of the wireless packet in the same manner as the second wireless device 5B. To obtain an IRC frame (IRC header and PPP frame).
The IRC layer of the third wireless device 5C performs reception determination processing using identification information (destination port ID = P _T1 ) included in the IRC header.
However, in the second setting information of the third wireless device 5C illustrated in FIG. 31C, there is no destination port ID that matches the received destination port ID = P _T1 . Accordingly, the third wireless device 5C determines that the destination of the received PPP frame is not the terminal 62 connected to the own device 5C. In this case, the third wireless device 5C performs transfer determination described later, and discards the PPP frame if transfer is not necessary.

Even when a PPP frame is transmitted from the terminal 61 to the router 4, processing is performed in the same procedure as described above.
That is, the terminal 61, the PPP frame containing information to be transmitted to the router 4, and transmitted from the port (S9 _{port) P T1} for the router 4 addressed information. The second radio device 5B receives the PPP frame transmitted from the port P _{T1 of the} terminal 61 at the port P _1B .
The processing unit 52 of the second wireless device 5B refers to the first setting information shown in FIG. 31B, performs destination recognition processing, and obtains the destination port ID (P _R1 ) of the router 4 as the destination as identification information.
The second radio device 5B encapsulates the PPP frame with an IRC header including identification information to generate an IRC frame. Further, the second wireless device 5B adds wireless communication control information (from EL header to PHY header) to the IRC frame to generate a wireless packet. The generated wireless packet is broadcast from the second wireless device 5B.

The first wireless device 5A that has received the wireless packet, based on the identification information (destination port ID = _PR1 ) included in the IRC header of the received wireless packet, receives determination processing that refers to the second setting information shown in FIG. 31A. I do. The first wireless device 5A can recognize that the destination of the received PPP frame is the device (router 4) connected to the own device 5A by the reception determination process. Further, the first wireless device 5A can identify the port (transmission port; second port) _P1A connected to the router 4 that is the destination of the received PPP frame by the reception determination process.
When the first wireless device 5A identifies the transmission port _P1A , the first wireless device 5A transmits a PPP frame from the transmission port _P1A . The transmitted PPP frame is received by the router 4.

  The wireless packet transmitted from the second wireless device 5B is also received by the third wireless device 5C, but is discarded as a result of the reception determination process of the third wireless device 5C. Therefore, the PPP frame transmitted from the terminal 61 is also prevented from being received by the terminal 62.

  Further, both the destination port ID and the source port ID may be used as the identification information. When both the destination port ID and the transmission source port ID are used as identification information, the header structure of the IRC header is as shown in FIG. 29C. When both the destination port ID and the transmission source port ID are used as the identification information, the transmission source recognition process (step S2) refers to the first setting information, and determines the transmission source port ID and the destination from the reception port ID. The port ID is obtained, and the reception determination process (step S9) refers to the second setting information and obtains the transmission port ID from the transmission source port ID and the destination port ID.

Further, the identification information may be a PPP link ID that is identification information of a PPP link. When a PPP link ID is used as identification information, the header structure of the IRC header is as shown in FIG. 29D. FIG. 33A to FIG. 33C show setting information of each of the wireless devices 5A, 5B, and 5C when the PPP link ID is used as identification information.
When the PPP link ID is used as the identification information, the transmission source recognition process (step S2) refers to the first setting information and obtains the PPP link ID from the reception port ID. The reception determination process (step S9) The transmission port ID is obtained from the PPP link ID with reference to the second setting information.

[3.5.2 Case 2]
As shown in FIG. 34, in case 2, there are the router 4 and three (plural) terminals 61, 62, and 63 that each transmit / receive a PPP frame to / from the router 4. Accordingly, the first wireless device 5A connected to the router 4 is connected to the router 4 at the three ports P _1A , P _2A , and P _3A corresponding to the three terminals 61, 62, and 63.
Of the three terminals 61, 62, 63, two terminals 61, 62 are connected to the second wireless device 5B. That is, the second radio device 5B is connected to the terminals 61 and 62 at the two ports P _1B and P _2B . The remaining terminal 63 is connected to the third wireless device 5C.
The three wireless devices 5A, 5B, and 5C can perform wireless communication with each other.

  In Case 2, the first PPP link L1 is formed between the router 4 and the terminal 61, the second PPP link L2 is formed between the router 4 and the terminal 62, and the third PPP link is connected between the router 4 and the terminal 63. Assume that L3 is formed.

  In Case 2, the storage units 53 of the first wireless device 5A, the second wireless device 5B, and the third wireless device 5C have setting information corresponding to the network configuration in FIG. 34 as the setting information shown in FIGS. 35A to 35C. One setting information and second setting information are set.

When sending PPP frames from the router 4 to the terminal 61, router 4, the PPP frame containing information to be transmitted to the terminal 61, and transmits from the port _{P R1} of terminals 61 addressed information. The first radio 5A is a PPP frame transmitted from the port _{P R1} router 4 receives at port _{P 1A.}
Processing unit 52 of the first wireless telephone 5A refers to the first setting information shown in FIG. 35A, it performs the source recognition processing, among a plurality of ports P _R1 to P _R4, the transmission of the router 4 which is the sender The original port ID (P _R1 ) is obtained as identification information.
The first radio device 5A encapsulates the PPP frame with an IRC header including identification information to generate an IRC frame. Furthermore, the first wireless device 5A adds wireless communication control information (from EL header to PHY header) to the IRC frame to generate a wireless packet. The generated wireless packet is broadcast from the first wireless device 5A.

The second wireless device 5B that has received the wireless packet, based on the identification information (source port ID = P _R1 ) included in the IRC header of the received wireless packet, receives determination that refers to the second setting information shown in FIG. 35B. Process. Through the reception determination process, the second wireless device 5B can recognize that the destination of the received PPP frame is the terminal 61 among the terminals 61 and 62 connected to the own device 5B. In addition, the second wireless device 5B, through the reception determination process, among the plurality of ports P _{1B to} P _2B , the port (transmission port; second port) P _1B connected to the terminal 61 that is the destination of the received PPP frame. Can be identified.
The second radio 5B, when identifying a transmission port _{P 1B,} and transmits the PPP frame from the transmission port _{P 1B.} The transmitted PPP frame is received by the terminal 61.

  As described above, the second wireless device 5B refers to the second setting information based on the identification information, and thereby the PPP frame received by the own device 5B is converted into a plurality of terminals 61 and 62 connected to the own device 5B. It is possible to recognize to which one of the terminals 61 and 62 should be transmitted, and even if a plurality of terminals 61 and 62 are connected to the own device 5B, it is possible to prevent the PPP frame from being transmitted to the terminal 62 that is not the destination.

Even when a PPP frame is transmitted from the terminal 61 to the router 4, processing is performed in the same procedure as described above.
That is, the terminal 61, the PPP frame containing information to be transmitted to the router 4, and transmitted from the port (S9 _{port) P T1} for the router 4 addressed information. The second radio device 5B receives the PPP frame transmitted from the port P _{T1 of the} terminal 61 at the port P _1B .
Processing unit 52 of the second radio 5B refers to the first setting information shown in FIG. 35B, it performs a source recognition, among the respective ports _P T1 _{to P T2} of the plurality of terminals 61 and 62, the source The source port ID (P _T1 ) of the terminal 61 is obtained as identification information.
The second radio device 5B encapsulates the PPP frame with an IRC header including identification information to generate an IRC frame. Further, the second wireless device 5B adds wireless communication control information (from EL header to PHY header) to the IRC frame to generate a wireless packet. The generated wireless packet is broadcast from the second wireless device 5B.

The first wireless device 5A that has received the wireless packet, based on the identification information (source port ID = P _T1 ) included in the IRC header of the received wireless packet, receives reception determination that refers to the second setting information shown in FIG. 35A. Process. The first wireless device 5A can recognize that the destination of the received PPP frame is the device (router 4) connected to the own device 5A by the reception determination process. In addition, the first wireless device 5A, through the reception determination process, among the plurality of ports P _{1A to} P _3A , the port (transmission port; second port) P _1A connected to the router 4 that is the destination of the received PPP frame Can be identified.
When the first wireless device 5A identifies the transmission port _P1A , the first wireless device 5A transmits a PPP frame from the transmission port _P1A . The transmitted PPP frame is received by the router 4.

As described above, the second wireless device 5B can correctly recognize the terminal 61 that is the transmission source of the PPP frame by referring to the first setting information even when the plurality of terminals 61 and 62 are connected.
The first radio 5A also be connected to a plurality of ports _P R1 _{to P R3} router 4, it is possible to correctly recognize the appropriate transmit ports _{P R1.}

  Note that the wireless packets transmitted from the first wireless device 5A and the second wireless device 5B are also received by the third wireless device 5C, but the wireless packet having a PPP frame not addressed to the terminal 63 is shown in FIG. As a result of the reception determination process of the third wireless device 5C based on the two setting information, it is discarded.

  In case 2, as in case 1, the identification information may be a destination port ID, a destination port ID and a source ID, or a PPP link ID instead of the source port ID.

[3.5.3 Case 3]
As shown in FIG. 36, in case 3, there are the router 4 and four (plural) terminals 61, 62, 63, 64 that each transmit / receive a PPP frame to / from the router 4. Accordingly, the first wireless device 5A connected to the router 4 is connected to the router 4 at the four ports P _1A , P _2A , P _3A , P _4A corresponding to the four terminals 61, 62, 63, 64. Has been.
The terminal 61 is connected to the second radio 5B, the terminal 62 is connected to the third radio 5C, the terminal 63 is connected to the fourth radio 5D, and the terminal 64 is connected to the fifth radio 5E.

  In Case 3, the first PPP link L1 is formed between the router and the terminal 61, the second PPP link L2 is formed between the router 4 and the second terminal 62, and between the router 4 and the third terminal 63. It is assumed that the third PPP link L3 is formed and the fourth PPP link L4 is formed between the router 4 and the fourth terminal 64.

In Case 3, only the second wireless device 5B and the third wireless device 5C can communicate with the first wireless device 5A. The fourth wireless device 5D and the fifth wireless device 5E are wireless with the first wireless device 5A. It is assumed that communication is not possible (the radio wave does not reach). However, the third wireless device 5C can wirelessly communicate with the fourth wireless device 5D, and the fourth wireless device 5D can wirelessly communicate with the fifth wireless device 5E.
For this reason, the third PPP link L3 goes through the third wireless device 5C in addition to the first wireless device 5A and the fourth wireless device 5D.
Further, the fourth PPP link L4 goes through the third wireless device 5C and the fourth wireless device 5D in addition to the first wireless device 5A and the fifth wireless device 5E.

In Case 3, the storage units 53 of the first wireless device 5A, the second wireless device 5B, the third wireless device 5C, the fourth wireless device 5D, and the fifth wireless device 5E correspond to the network configuration of FIG. As the setting information, the first setting information and the second setting information shown in FIGS. 37A to 37E are set.
Further, in case 3, as shown in FIGS. 37C and 37D, the third setting information for wireless packet transfer is stored in the storage unit 53 of the third wireless device 5C and the storage unit 53 of the fourth wireless device 5D. Is set.
The third setting information includes information (transfer determination information) used for transfer determination processing for determining whether or not the own devices 5C and 5D need to transfer the transferred wireless packet (PPP frame). The third setting information includes information (transfer permission information) used for the transfer suppression process.

In FIG. 37C and FIG. 37D, the transmission source port ID and the destination port ID (at least one of them) are transfer determination information. The transfer determination information is information indicating a PPP frame (wireless packet) that needs to be transferred. Since the third wireless device 5C transfers the PPP frames of the third PPP link L3 and the fourth PPP link L4, the transmission determination information of the third wireless device 5C includes the source port IDs of the third PPP link L3 and the fourth PPP link L4. And a combination of destination port IDs (a combination that distinguishes transmission and reception).
Since the fourth wireless device 5D transfers the PPP frame of the fourth PPP link L4, the transfer determination information of the fourth wireless device 5D includes a combination of the transmission source port ID and the destination port ID of the fourth PPP link L4 (distinguish transmission / reception). Combination) is set.
When the identification information included in the received IRC header matches the transmission source port ID or destination port ID of the third setting information, the PPP frame (wireless packet) received together with the identification information is a transfer candidate (target). It becomes.

  In FIG. 37C and FIG. 38, the wireless packet transmission source is transfer permission information. The transfer permission information is for limiting wireless packets to be transferred. Even if the received identification information and the transfer determination information match, if the transmission source of the received wireless packet does not match the wireless packet transmission source set as the transfer permission information, it is not transferred.

For example, it is assumed that the first radio device 5A in FIG. 36 transmits a radio packet including a PPP frame addressed to the terminal 63 (identification information = P _R3 ). The wireless packet transmitted from the first wireless device 5A does not reach the fourth wireless device 5D connected to the terminal 63. Even if the third wireless device 5C receives the wireless packet and refers to the second setting information (FIG. 37C), there is no transmission port ID that matches the identification information. It is determined that it is not addressed to the terminal 62 connected to (reception determination process; step S9 in FIG. 32).

If it is determined that the received PPP frame is unnecessary for the terminal 62 as a result of the reception determination process in the third wireless device 5C, the IRC layer of the third wireless device 5C further performs a transfer determination process (step of FIG. 32). S11) is performed. In the transfer determination process, using the received identification information (P _R3 ) as a search key, the source port ID or destination port ID (transfer determination information) of the third setting information of the third wireless device 5C is searched, and the received identification information It is determined whether or not a transmission source port ID or a destination port ID that matches (P _R3 ) is set.
Further, in the transfer determination process, a transfer suppression process for determining whether or not the transmission source of the received wireless packet (the wireless transmission source ID indicated by the base station ID information in the EL header) is set as the transfer permission information is also performed. .
The IRC layer that performs the transfer determination process is a layer (a layer lower than the PPP layer) different from the PPP layer.

Here, in the third wireless device 5C, the transmission source port ID that matches the received identification information (P _R3 ) is set as the third setting information, and the third wireless device 5C corresponds to the transmission source port (P _R3 ). Since the set wireless packet transmission source (5A) also matches the transmission source (5A) of the received wireless packet, it is determined that the received PPP frame (wireless packet) should be transferred. As a result, the third wireless device 5C performs a wireless packet transfer process (step S13 in FIG. 32), and the wireless packet is transferred (broadcast transmission) (step S14 in FIG. 32). The transferred wireless packet is received by the fourth wireless device 5D. The fourth wireless device 5D can recognize that the received PPP frame is addressed to the terminal 63 connected to the own device 5D with reference to the second setting information shown in FIG. 37D.

Similarly, the first wireless telephone 5A of FIG. 36, the case of transmitting a radio packet (identification information _{= P R4)} including PPP frame addressed to the terminal 64, the transfer processing by the third radio 5C (see FIG. 37C), and The data is received by the fifth wireless device 5E through the transfer process (see FIG. 37D) by the fourth wireless device 5D.

Here, when the wireless packet addressed to the terminal 64 transmitted from the first wireless device 5A is transferred in the order of the third wireless device 5C and the fourth wireless device 5D, the wireless packet transferred from the fourth wireless device 5D Is also received (bounced back) by the third wireless device 5C. The third wireless device 5C that bounces and receives the wireless packet has the source port ID that matches the identification information (P _R4 ) included in the bounced and received wireless packet is set as the third setting information. Although the packet is determined as a transfer candidate, the transmission source (5D) of the received wireless packet does not match the wireless packet transmission source (5A) set corresponding to the transmission source port (P _R4 ). It is determined that it is unnecessary. As a result, it is possible to prevent the wireless packet transfer from being repeated unnecessarily due to the rebound of the wireless packet.

In addition, in the second setting information of each of the wireless devices 5A, 5B, 5C, and 5D, information on the wireless packet transmission source associated with the identification information may be set. In this case, even if a plurality of wireless packets having the same PPP frame are transmitted from a plurality of wireless packet transmission sources, it is possible to prevent a terminal connected to the receiving-side radio device from receiving a plurality of identical content PPP frames. . For example, if a wireless packet transferred from the third wireless device 5C (a wireless packet including a PPP frame addressed to the terminal 64) reaches the fifth wireless device 5E, the fifth wireless device 5E includes the wireless packet. since the source port ID that matches the identification information (P _R4) (P _R4) is set as the second setting information, the result of the reception determination processing, PPP frames received, which is connected to the fifth radio 5E It is determined that the terminal 64 is necessary. That is, the fifth wireless device 5E determines the received wireless packet as a transmission candidate to the terminal 64. However, since the transmission source (5C) of the received wireless packet does not match the wireless packet transmission source (5D) set corresponding to the transmission source port (P _R4 ), transmission to the terminal 64 is unnecessary. It is determined. Therefore, the fifth wireless device 5E discards the packet. On the other hand, when the wireless packet transferred from the third wireless device 5C is further transferred to the fourth wireless device 5D and received by the fifth wireless device 5E, the transmission source (5D) of the received wireless packet is It is determined that transmission to the terminal 64 that matches the wireless packet transmission source (5D) set corresponding to the transmission source port (P _R4 ) is necessary. As a result, it is possible to suppress the same wireless packet received by the fifth wireless device 5 from being increased to a plurality. Furthermore, it is possible to prevent the terminal 64 from receiving a plurality of PPP frames having the same contents and preventing proper management of the PPP link.

As shown in FIGS. 38C and 38D, the transfer permission information set as the third setting information may be information (transfer count information) that can identify the transfer count of the wireless transmission packet.
For example, the wireless device 5 that first transmits a wireless packet transmits the wireless packet with the transfer number information 172 shown in FIGS. 29A to 29D set to 0, and transmits the received wireless packet. Assume that the wireless packet is transferred with the number-of-times information 172 incremented. In this case, the transfer number information 172 indicates the number of times transferred so far.
Then, for example, the third wireless device 5C that has received the wireless packet including the PPP frame addressed to the terminal 63 from the first wireless device 5A (identification information = _PR3 , transfer count information = 0) receives the received identification information ( _PR3). ) Is set as the third setting information and matches the transfer count information (0) set corresponding to the transmission source port (P _R3 ). It is determined that the frame (wireless packet) should be transferred.
Note that the transfer count information 172 set in the radio packet by the radio device 5 that transmits the radio packet first is not limited to 0, but may be a transfer count upper limit value indicating the upper limit of the transfer count. In this case, the wireless device 5 that transfers the received wireless packet decrements the transfer count of the transfer count information 172 and transmits the radio packet. As a result, the transfer count information 172 indicates the number of transfers that can be performed from now on.
Further, the transfer count information 172 does not have to be a value indicating the number of times transferred so far or the number of times that transfer can be performed, but can be any information that can identify the number of times transferred so far or the number of times transferable from now on. It ’s enough. For example, the transfer number information 172 may be a value obtained by adding or subtracting a predetermined value N to the number of times transferred so far or the number of times transferable from now.

  In case 3, as in case 1, the identification information may be a destination port ID, a destination port ID and a source ID, or a PPP link ID instead of the source port ID.

  In order to suppress transfer, a packet valid period may be set in an ICR header or the like. The wireless device that has received the wireless packet performs transfer if it is within the valid period, and does not perform transfer if the valid period has expired.

[3.6 Protocol conversion in wireless communication section]
FIG. 39 shows a modification in which PPP is converted into another protocol in the wireless communication section.
In the storage unit 53 of each of the wireless devices 5A and 5B, a conversion table for converting (converting protocol) the PPP frame into data (conversion data) of another format (different protocol) and returning the converted data to the PPP frame is set. Has been.
For example, the first wireless device 5A that has received the PPP frame from the router 4 refers to the conversion table, converts the protocol of the PPP frame and the portion of the PPP control packet into converted data, and adds identification information to the converted data. An IRC header is added, and wireless communication control information (EL header to PHY header) is added to generate a wireless packet and wirelessly transmit it. Since the PPP preamble portion is a fixed value, it can be restored on the receiving side without using a conversion table.

  When the wireless packet is received by the second wireless device 5B, the second wireless device 5B refers to the conversion table and restores the protocol and the PPP control packet from the received converted data. Also, the second radio device 5B restores the PPP frame by adding a preamble that is a fixed value before the restored protocol.

By converting the PPP frame into converted data, the converted data can be made smaller than the PPP frame, and wireless communication can be performed efficiently.
As described above, the wireless packet does not need to encapsulate the PPP frame itself, and may encapsulate converted data obtained by converting the PPP frame.

By the protocol conversion, the wireless communication section between the first wireless device 5A and the second wireless device 5B is not a PPP link, and the first partial PPP link L _pa between the router 5 and the first wireless device 5A. And only the second partial PPP link L _pb between the second radio 5B and the terminal 61 exists. However, as shown in FIG. 39, even if there is no PPP link in the wireless communication section, there is one PPP link between the router 4 and the terminal 61 when viewed from the router 4 and the terminal 61. Since the first partial PPP link L _pa and the second partial PPP link L _pb are combined, it can be considered that there is one PPP link.
Therefore, even if information about PPP is not exchanged in the wireless communication section as shown in FIG. 39, the first partial PPP link L _pa and the second partial PPP link L _pb are converted by converting the PPP frame into converted data. In addition, it can be managed as one PPP link.

[3.7 First Modification]
FIG. 40A shows a configuration for the central apparatus 2 to transmit information (application data) to the first wireless device 5A. In Figure 40A, during the port of the router 4 (S9 form _{port) P R5} and the port (S9 form _{port) P 5A} of the first radio telephone 5A is connected by wire. A port _{P R5} router 4 To the port _{P 5A} of the first radio telephone 5A, and IP addresses respectively is assigned, the information of the router 4's IP address assigned to the port _{P 5A} of the first radio telephone 5A when receiving the (application data), via a connection between the ports P _R5 router 4 port P _5A of the first radio 5A, the information is transmitted to the first radio 5A. The information is, for example, information for in-vehicle devices (information for mobile stations) for the first wireless device 5 to wirelessly transmit to the in-vehicle device 7 by road-to-vehicle communication, and more specifically, traffic information, road information Linear information or signal information.
Incidentally, the port P _R5 router 4 are applied to the port P _5A of the first radio telephone 5A need not be IP address, it may be any identifiable identifier, respectively.

FIG. 40B also shows a configuration for the central apparatus 2 to transmit information (application data) to the radio devices 5B and 5C. In Figure 40B, the port (S9 form _{port) P R1, P R2, P} R3, P R4 each router 4, a first radio port (S9 form _{port) P 1A, P 2A, P} 3A, P 4A respectively Is wired.
In FIG. 40B, not only information (application data) addressed to the first terminal 61 or the second terminal 62 is transmitted from the router 4, but also information (application data) addressed to the second radio device 5B or the third radio device 5C. ) Is also sent.
Further, not only the first terminal 61 or the second terminal 62 in FIG. 40B transmits information for the central device 2 to the router 4, but the second radio device 5B or the third radio device 5C also receives information for the central device 2. Can be transmitted to the router 4.

In order that the second radio device 5B and the third radio device 5C in FIG. 40B can be the destination device or the transmission source device of the PPP link, each of the second radio device 5B and the third radio device 5C has a terminal 61. P _T5B and P _T5C are set as IDs for performing the same functions as the port IDs P _T1 and P _T2 (functions as link destination IDs or transmission source IDs).
In each storage unit 53 of the first wireless device 5A, the second wireless device 5B, and the third wireless device 5C of FIG. 40B, the first information shown in FIGS. 40C to 40E is set as setting information corresponding to the network configuration of FIG. 40B. Setting information, second setting information, and third setting information are set.

For example, PPP frame addressed second radio 5B is, when transmitted from the port _{P R2} router 4, the first radio 5A is the PPP frame is received at the port _{P 2A.}
Then, the processing unit 52 of the first wireless telephone 5A, in source recognition processing or destination recognition process (step S2), and as a search key the port information indicating the reception port P _2A of PPP frame, the first wireless telephone 5A first 1 Retrieval of the reception port ID of the setting information (see FIG. 40C) is performed.
Processing unit 52 of the first wireless telephone 5A as a result of the source recognition processing or destination recognition process, P _R2 as a source port ID as the identification _information, or to obtain a P _T5B as the destination ID to be identification information.
Then, based on the obtained identification information, an identification information addition process (step S3) is performed, and a wireless packet is transmitted from the first wireless device 5A.

The processing unit 52 (IRC layer) of the second wireless device 5B that has received the wireless packet performs reception determination processing (step S9) using the identification information included in the IRC header of the IRC frame obtained from the received wireless packet. .
In the reception determination process, the destination ID of the second setting information (see FIG. 40D) set in the storage unit 53 of the second wireless device 5B is searched using the identification information (for example, destination ID = P _T5B ) as a search key. Is called. As a result of the reception determination process, the second wireless device 5B recognizes that the destination of the PPP frame is the own device 5B. As a result, the information included in the PPP frame is processed in a layer higher than the PPP layer and the PPP layer of the second radio device 5B.
Similarly, PPP frames whose transmission source is the second radio 5B also, via the first radio 5A, can be transmitted to the port _{P R2} router 4 (second setting information and FIG. 40D of Figure 40C 1st setting information reference).

When the router 4 transmits a PPP frame addressed to the third wireless device 5C from the port _{PR4 of the} router 4, the first wireless device 5A receives the PPP frame at the port _P4A .
Then, the processing unit 52 of the first wireless telephone 5A, in source recognition processing or destination recognition process (step S2), and as a search key the port information indicating the reception port P _4A of PPP frame, the first wireless telephone 5A first 1 Retrieval of the reception port ID of the setting information (see FIG. 40C) is performed.
Processing unit 52 of the first wireless telephone 5A as a result of the source recognition processing or destination recognition process, P _R4 as a source port ID as the identification _information, or to obtain a P _T5C as the destination ID to be identification information.
Then, based on the obtained identification information, an identification information addition process (step S3) is performed, and a wireless packet is transmitted from the first wireless device 5A.

The processing unit 52 (IRC layer) of the second wireless device 5B that has received the wireless packet performs reception determination processing (step S9) using the identification information included in the IRC header of the IRC frame obtained from the received wireless packet. .
In the reception determination process, the destination ID of the second setting information (see FIG. 40D) set in the storage unit 53 of the second wireless device 5B is searched _using the identification information (for example, destination ID = P _T5C ) as a search key. However, there is no destination ID that hits the search key.
Therefore, the processing unit 52 of the second wireless device 5B performs a transfer determination process (step S11). In the transfer determination process, the third setting information (FIG. 40D) of the second wireless device 5B is referred to. Here, as a result of the transfer determination process, it is determined that the data should be transferred. Therefore, the second wireless device 5B performs a transfer process (step S13) of the received PPP frame (wireless packet).
Then, the third wireless device 5C performs reception determination processing using the identification information included in the transferred wireless packet. In the reception determination process of the third wireless device 5C, the second setting information illustrated in FIG. 40E is referred to. As a result of the reception determination process, the third wireless device 5C recognizes that the destination of the PPP frame is the own device 5C. As a result, the information included in the PPP frame is processed in a layer higher than the PPP layer and the PPP layer of the third wireless device 5C.

Similarly, a PPP frame originating from the third wireless device 5C can also be transmitted to the port _{PR4 of the} router 4 via the second wireless device 5B and the first wireless device 5A (the first frame in FIG. 40C). 2 setting information, 3rd setting information of Drawing 40D, and the 1st setting information of Drawing 40E).

As described above, the terminal (first device or second device) connected to the wireless device is not limited to the terminals 61 and 62 provided separately from the wireless devices 5B and 5C, but the PPP of the wireless devices 5B and 5C. It may be a higher layer than the layer and the PPP layer. This also applies to a second modification described later. In the second modification, the terminal (the first device or the second device) connected to the wireless device may be a layer higher than the Ethernet layer and the Ethernet layer of the wireless devices 5B and 5C. .
As described above, the function corresponding to the terminal (first device or second device) may be incorporated in the wireless devices 5B and 5C. In FIG. 40B, the terminal 61 and the terminal 62 may not be provided.
Similarly, the router 4 does not need to be provided separately from the radio device 5A, and the router may be incorporated in the radio device 5A.

  In FIG. 40B as well as in FIG. 40A, information may be transmitted from the central apparatus 2 to the first radio device 5A.

[3.8 Second Modification]
41 to 45 show a second modification of the communication system. In the second modified example, communication between the router 4 and the terminal 6 is performed by Ethernet communication. That is, the wireless device 5 receives the Ethernet frame generated by the router 4 or the terminal 6 at the e-support P _M1 , P _M2 , P _M3 , and P _M4 , and encapsulates the Ethernet frame by adding wireless communication control information and the like. , Generate wireless packets and broadcast.
As shown in FIG. 41, the Ethernet header of the Ethernet frame includes a destination MAC address and a source MAC address. For example, when data is transmitted to the router 4 or the terminal 6, the destination MAC address is the MAC address of the terminal 6 and the transmission source MAC address is the MAC address of the router 4.

  However, when wireless communication by the wireless devices 5 and 5 is interposed between the router 4 (first device) for performing Ethernet communication and the terminal 6 (second device), the router 4 (first device) can be obtained only with the MAC address. ) And the terminal 6 (second device) may not be properly performed. Therefore, it is necessary to provide the wireless devices 5 and 5 with an IP routing function so that the wireless devices 5 and 5 perform routing using the IP address. In this case, since the wireless devices 5 and 5 need to have an IP routing function, the wireless devices 5 and 5 are expensive.

That is, in general, when data is transmitted from a certain transmission source (for example, the router 4) to a certain destination (for example, the terminal 6), another device (radio device 5) is on the path between the transmission source and the destination. ) Intervenes, the destination IP address set by the source (router 4) is the IP address of the data destination (terminal 6), but the destination MAC address set by the source (router 4) is the source The MAC address of another device (wireless device 5) connected to the.
Therefore, since the final destination (terminal 6) is not known even if the destination MAC address in the Ethernet header is referred to, the route between the transmission source and the destination is used to deliver the data to the final destination (terminal 6). It is necessary that another device (radio device 5) existing above has a routing function using an IP address.

Therefore, in the second modification, the wireless device 5 adds wireless communication control information (first wireless communication control information) and an IRC header (second wireless communication control information) to the acquired Ethernet frame and encapsulates the wireless packet. Is generated and transmitted wirelessly.
42A to 42D show various examples of the IRC header in the second modified example. The IRC header shown in FIGS. 42A to 42D includes the transfer count information 172, but may be omitted.
The IRC header shown in FIG. 42A has a source MAC address (source ID) 175 as identification information. The transmission source MAC address is the transmission source MAC address of the Ethernet frame acquired by the wireless device 5.
The IRC header shown in FIG. 42B has a destination MAC address (destination ID) 176 as identification information. The destination MAC address is the destination MAC address of the Ethernet frame acquired by the wireless device 5.
The IRC header shown in FIG. 42C has a destination MAC address 176 and a source MAC address 175 as identification information.
The IRC header shown in FIG. 42D has, as identification information, an ID (wireless packet destination ID) 177 of the wireless device 5 that is the destination of the wireless packet including the Ethernet frame.
Also in the second modified example, the identification information may be an ID of a link (Ethernet link).

FIG. 43A shows an example of a communication system in the second modification. Regarding the communication system shown in FIG. 43A, reference is made to FIGS. 44A to 44C and 45A in addition to FIG. 43A. In FIG. 43A, as in FIG. 30, one device (router (first device) 4 and terminal (second device) 61), one for each pair of wireless devices (first wireless device 5A and second wireless device 5B) Is connected. The devices 4 and 61 transmit and receive Ethernet frames.
Similar to FIG. 30, there is also a third wireless device 5C in the vicinity of the first wireless device 5A, and the radio waves transmitted from the first wireless device 5A can also be received by the third wireless device 5C. A terminal 62 is connected to the third wireless device 5C. The terminal 62 can also transmit and receive the Ethernet frame.
In FIG. 43A, the Ethernet link ML1 is formed between the router 4 and the terminal 61, and the Ethernet link is not formed between the router 4 and the terminal 62.

The first setting information and the second setting information shown in FIGS. 44A to 44C are set in the storage units 53 of the first wireless device 5A, the second wireless device 5B, and the third wireless device 5C shown in FIG. 43A. Yes.
The first setting information is information that is referred to when each wireless device 5A, 5B, 5C receives an Ethernet frame from the connected devices 4, 61, 62. The first setting information is added to the Ethernet frame and used to generate identification information constituting a wireless packet.
The first setting information is given to e-support (receiving port) P _M5A , P _M5B , P _M5C connected to the router 4 or the terminal 6 among one or a plurality of e-supports of the own devices 5A, 5B, 5C. This is for associating the reception port MAC address indicating the MAC address with identification information (Ethernet link identification information). Specifically, the first setting information is configured by associating a reception port MAC address, a transmission source MAC address (transmission source ID), a destination MAC address (destination ID), and a wireless packet destination ID. ing. The transmission source MAC address (transmission source ID), the destination MAC address (destination ID), and the wireless packet destination ID in the first setting information are all Ethernet link identification information. The source MAC address (source ID), destination MAC address (destination ID), and wireless packet destination ID as identification information are all Ethernet link identification information, and any one piece of information is sufficient. The information may be omitted. By omitting the information, the amount of information can be suppressed.

The second setting information is information that is referred to when each of the wireless devices 5A, 5B, 5C receives a wireless packet from another wireless device. The second setting information is used for processing (reception determination processing, transfer determination processing) for determining how to handle a received wireless packet.
The second setting information is transmission indicating identification information (Ethernet link identification information) and a port (transmission port) connected to the router 4 or the terminal 6 among one or a plurality of e-supports of the own devices 5A, 5B, and 5C. This is for associating the port MAC address. Specifically, the second setting information is configured by associating a transmission source MAC address (transmission source ID), a destination MAC address (destination ID), and a transmission port MAC address (second port ID). ing. Both the transmission source MAC address (transmission source ID) and the destination MAC address (destination ID) in the second setting information are Ethernet link identification information. Similarly to the first setting information, the source MAC address (source ID) and the MAC address (destination ID) as identification information are both Ethernet link identification information, and it is sufficient that any one information exists. Other information may be omitted.

FIG. 45A shows a communication processing procedure of the first radio device 5A and the second radio device 5B when an Ethernet frame is transmitted from the router 4 to the terminal 61.
First, the router 4 transmits an Ethernet frame including information for the terminal 61 from the e-support (S11 port) _PMR1 for information addressed to the terminal 61. In the Ethernet header of this Ethernet frame, the MAC address (M _R1 ) of the router 4 is set as the source MAC address, and the MAC address (M _T1 ) of the terminal 61 is set as the destination MAC address.
The first wireless device 5A receives the Ethernet frame transmitted from the e-support _PMR1 of the router 4 at the e-support (S11 port) _PM5A (step S101).
Even if the destination MAC address of the received Ethernet header is not the MAC address (M _5A ) of the own wireless device 5A, the first wireless device 5A does not discard the received Ethernet frame, and in a layer lower than the Ethernet layer Then, processing for transmitting a wireless packet (processing after step S102 in FIG. 45) is performed. Note that if the destination MAC address of the received Ethernet header is the MAC address (M _5A ) of the own device 5A, the first wireless device 5A is the frame addressed to the own device 5A. The data in the frame is processed in a layer higher than the Ethernet layer.

The processing unit 52 of the first wireless device 5A performs transmission source recognition processing for recognizing the transmission source MAC address of the received Ethernet frame (step S102). Information indicating the transmission source MAC address recognized by the transmission source recognition processing is used as identification information of the IRC header.
In source recognition process, to obtain the source MAC address of the Ethernet frame as a search key the MAC address _{M 5A} port _{P M5A} receiving the Ethernet frame, search the receive port MAC of the first setting information. In the first setting information of the first wireless device 5A shown in FIG. 44A, there is a reception port MAC address (M _5A ) that matches the MAC address (M _5A ) that is a search key. Here, of the two pieces of identification information (source MAC address, destination MAC address), the source MAC address is used as identification information. Therefore, in the transmission source recognition process, the transmission source MAC address (M _R1 ) that is identification information corresponding to the reception port MAC address (M _5A ) that matches the search key is obtained.
That is, information (identification information) indicating the MAC address of the router 4 that is the transmission source of the received Ethernet frame is obtained by the transmission source recognition process. Note that the MAC address as identification information may be read from the Ethernet header of the Ethernet frame received by the first wireless device 5A. In this case, the MAC address need not be set in the first setting information. Accordingly, the first setting information can be omitted.

Subsequently, the processing unit 52 (its function as an IRC layer) stores the identification information indicating _MR1 which is the MAC address of the router 4 which is the transmission source of the received Ethernet frame in the field of the transmission source MAC address 175. An IRC header (see FIG. 42A) is generated and added to the beginning of the data from the Ethernet frame (identification information adding process; step S103). That is, an IRC frame that encapsulates the received Ethernet frame is generated. Note that the transfer count information is set to 0, for example.
As described above, the identification information is added by the IRC layer which is a layer (a layer lower than the Ethernet layer) different from the Ethernet layer.

Then, the IRC layer makes a radio transmission request for the generated IRC frame to the enhancement layer (EL) (layer 7 if no enhancement layer exists) (step S104).
Each layer from the enhancement layer (EL) to the PHY layer generates radio packets by adding the radio communication control information (from EL header to PHY header) shown in FIG. 41 to the IRC frame (radio packet generation). Process; Step S105). That is, the generation of the wireless packet is performed by a layer (an extension layer to a PHY layer) different from the Ethernet layer and the IRC layer.
In the wireless packet generation process, the extension layer of the first wireless device 5A sets the ID of the first wireless device 5A in the base station ID information field of the EL header. In the wireless packet generation process, the layer 7 of the first wireless device 5A sets information indicating “6. Communication from base station to base station (inter-road communication)” in the communication classification field. To do.
The generated wireless packet is broadcast from the first wireless device 5A (step S106).
When security processing is performed by security management, the IRC data (data excluding the IRC header to the PHY header) or the IRC frame (data excluding the EL header to the PHY header) may be used. It may be against.

The broadcast-transmitted wireless packet is received by the second wireless device 5B. The processing unit 52 (each layer from the PHY layer to the enhancement layer (EL); the wireless processing function unit) of the second wireless device 5B that has received the wireless packet performs a wireless packet reception process (step S107).
Of the wireless packet reception processing, in processing at layer 7, determination based on the communication classification included in the L7 header is performed. If the communication classification indicated by the communication classification field is not a classification addressed to the base station, the second radio device 5B as the base station discards the received radio packet. However, since “6. Communication from base station to base station (inter-road communication)”, which is one of the categories addressed to the base station, is set in the communication classification field, the received radio packet is discarded. Not.
On the other hand, the in-vehicle device (mobile station) 7 that has received the wireless packet transmitted from the first wireless device 5A discards the received wireless packet because the classification indicated by the communication classification field is not the classification addressed to the base station. .

  The processing unit 52 of the second radio device 5B gives the IRC frame (IRC header and Ethernet frame) obtained by removing the radio communication control information (from the PHY header to the EL header) from the received radio packet from the enhancement layer to the IRC layer. Processing is performed (step S108). The enhancement layer of the second radio device 5B gives the ID of the first radio device 5A stored in the base station ID information field of the EL header of the received radio packet to the IRC layer. The process of obtaining the IRC frame from the received wireless packet is performed by a layer different from the Ethernet layer and the IRC layer.

The IRC layer of the second radio device 5B performs reception determination processing using the identification information included in the IRC header (step S109). The IRC layer that performs the reception determination process is a layer (a layer lower than the Ethernet layer) different from the Ethernet layer.
The reception determination process is a process for determining how to handle the obtained Ethernet frame. Specifically, in the reception determination process, the IRC layer determines whether the Ethernet frame is for the terminal 61 connected to the own device 5B.

For reception determination processing, the IRC layer of the second radio device 5B sets the identification information (source MAC address = M _R1 ) included in the received IRC header in the storage unit 53 of the second radio device 5B using the search key. The source MAC address of the second setting information (reception determination information) is searched. In the second setting information of the second radio device 5B shown in FIG. 44B, there is a source MAC address (M _R1 ) that matches the source MAC address = M _R1 that is a search key. Therefore, in the reception determination process (step S109), the transmission port MAC address (M _5B ) corresponding to the transmission source MAC address (M _R1 ) that matches the search key is obtained.
That is, the second wireless device 5B can identify the e-support (transmission port; second port) _PM5B connected to the device 61 that is the destination of the received Ethernet frame by the reception determination process.
Note that the reception determination process may be performed using the destination MAC address stored in the Ethernet header in the Ethernet layer (L2 switch-like process). In this case, the IRC header can be omitted in the wireless packet, and the identification information adding process (step S103) can be omitted in the transmitting wireless device.

When the transmission port identification information is obtained, the IRC layer of the second wireless device 5B recognizes that the obtained Ethernet frame is addressed to the terminal 61 connected to the own device 5B. The Ethernet layer of the second radio device 5B transmits the obtained Ethernet frame from the identified transmission port _PM5B (step S110).
The Ethernet frame transmitted from the second wireless device 5B is received by the terminal 61.

  If the second setting information (reception determination information) is searched using the received identification information as a search key and there is no identification information to be hit, the destination of the received Ethernet frame is the terminal connected to the own device 5B. It is determined that it is not 61. In this case, transfer determination (step S111) is performed, and if there is no need for transfer, the Ethernet frame is discarded (step S112).

The wireless packet broadcast from the first wireless device 5A is received not only by the second wireless device 5B but also by the third wireless device 5C. The processing unit 52 (the layers from the PHY layer to the enhancement layer (EL); the wireless processing function unit) of the third wireless device 5C that has received the wireless packet performs the reception processing of the wireless packet in the same manner as the second wireless device 5B. To obtain IRC frames (IRC header and Ethernet frame).
The IRC layer of the third wireless device 5C performs reception determination processing using identification information (source MAC address = M _R1 ) included in the IRC header.
However, in the second setting information of the third wireless device 5C illustrated in FIG. 44C, there is no source MAC address that matches the received source MAC address = _MR1 . Accordingly, the third wireless device 5C determines that the destination of the received Ethernet frame is not the terminal 62 connected to the own device 5C. In this case, the third wireless device 5C performs transfer determination described later, and discards the Ethernet frame if transfer is not necessary.

As described above, the Ethernet frame transmitted from the router 4 may be broadcast by the first radio device 5A and received by the plurality of radio devices 5B and 5C. However, since the reception side wireless devices 5B and 5C perform reception determination using the identification information included in the IRC header, the second wireless device 5B, which is the original destination, can be surely made without referring to the IP address. Only can be received.
In addition, the third wireless device 5C that is not related to the original destination discards the Ethernet frame in the third wireless device 5C without giving the Ethernet frame to the terminal 62 connected to the third wireless device 5C.

Even when an Ethernet frame is transmitted from the terminal 61 to the router 4, processing is performed in the same procedure as described above.
That is, the terminal 61 transmits an Ethernet frame including information to be transmitted to the router 4 from the e-support (S11 port) _PMT1 . The second radio device 5B receives the Ethernet frame transmitted from the port P _{MT1 of the} terminal 61 at the port P _M5B .
Even if the destination MAC address of the received Ethernet header is not the MAC address (M _5B ) of the own device 5B, the second wireless device 5B does not discard the received Ethernet frame, and in a lower layer than the Ethernet layer Then, processing for transmitting the wireless packet (processing after step S102 in FIG. 45) is performed.
The processing unit 52 of the second radio device 5B refers to the first setting information shown in FIG. 44B, performs transmission source recognition processing (step S102), and uses the transmission source MAC address of the terminal 61 that is the transmission source as identification information. Obtain (M _T1 ).
The second radio device 5B encapsulates the Ethernet frame with an IRC header including identification information to generate an IRC frame. Further, the second wireless device 5B adds wireless communication control information (from EL header to PHY header) to the IRC frame to generate a wireless packet. The generated wireless packet is broadcast from the second wireless device 5B. When security processing is performed by security management, the IRC data (data excluding the IRC header to the PHY header) or the IRC frame (data excluding the EL header to the PHY header) may be used. It may be against.

The first wireless device 5A that has received the wireless packet, based on the identification information (source MAC address = M _T1 ) included in the IRC header of the received wireless packet, receives reception determination that refers to the second setting information shown in FIG. 44A. Processing (step S109) is performed. The first wireless device 5A can recognize that the received Ethernet frame is addressed to the device (router 4) connected to the own device 5A by the reception determination process. Further, the first wireless device 5A can identify the port (transmission port; second port) _PM5A connected to the router 4 that is the destination of the received Ethernet frame by the reception determination process.
The first radio 5A, when identifying a transmission port _{M 5A,} and transmits the Ethernet frame from the transmission port _{P M5A.} The transmitted Ethernet frame is received by the router 4.

  The wireless packet transmitted from the second wireless device 5B is also received by the third wireless device 5C, but is discarded as a result of the reception determination process of the third wireless device 5C. Therefore, the Ethernet frame transmitted from the terminal 61 is also prevented from being received by the terminal 62.

  In the above description, the identification information is the source MAC address, but may be a destination MAC address. When the identification information is the destination MAC address, the header structure of the IRC header is as shown in FIG. 42B. When the identification information is a destination MAC address, “source” in the above description regarding FIG. 45A may be read as “destination”.

Further, the identification information may be an ID (wireless packet destination ID) of a wireless device that is a destination of the wireless packet. When the identification information is a wireless packet destination ID, the header structure of the IRC header is as shown in FIG. 42D.
When the identification information is the wireless packet destination ID, the first wireless device 5A receives the Ethernet frame transmitted from the port _{PMR1 of the} router 4 at the e-support (S11 port) _PM5A (step S101).

The processing unit 52 of the first wireless device 5A performs destination recognition processing for recognizing the wireless device 5B that is the destination of the wireless packet that encapsulates the received Ethernet frame (step S102). Information indicating the wireless packet destination ID recognized by the destination recognition process is used as identification information of the IRC header.
In the destination recognition process, in order to obtain the destination of the wireless packet, the receiving port MAC address of the first setting information is searched using the MAC address (M _5A ) of the port P _M5A that received the Ethernet frame as a search key. In the first setting information of the first wireless device 5A shown in FIG. 44A, there is a reception port MAC address (M _5A ) that matches the MAC address (M _5A ) that is a search key. Therefore, in the destination recognition process, the wireless packet destination ID (5B) that is identification information corresponding to the reception port MAC address (M _5A ) that matches the search key is obtained.
That is, information (identification information) indicating the second wireless device 5B that is the destination of the transmitted wireless packet is obtained by the destination recognition process.

  Subsequently, the processing unit 52 (its function as the IRC layer) generates an IRC header (see FIG. 42D) in which the wireless packet destination ID (5B) that is identification information is stored in the field of the wireless packet destination ID 177, and Ethernet. It is added to the head of the frame (identification information addition processing; step S103). That is, an IRC frame that encapsulates the received Ethernet frame is generated. The transfer count information is set to 0, for example.

Then, the IRC layer makes a radio transmission request for the generated IRC frame to the enhancement layer (EL) (layer 7 if no enhancement layer exists) (step S104).
Each layer from the enhancement layer (EL) to the PHY layer generates radio packets by adding the radio communication control information (from EL header to PHY header) shown in FIG. 41 to the IRC frame (radio packet generation). Process; Step S105).
The generated wireless packet is broadcast from the first wireless device 5A (step S106).

  The broadcast-transmitted wireless packet is received by the second wireless device 5B. The processing unit 52 (each layer from the PHY layer to the enhancement layer (EL); the wireless processing function unit) of the second wireless device 5B that has received the wireless packet performs a wireless packet reception process (step S107).

  The processing unit 52 of the second radio device 5B gives the IRC frame (IRC header and Ethernet frame) obtained by removing the radio communication control information (from the PHY header to the EL header) from the received radio packet from the enhancement layer to the IRC layer. Processing is performed (step S108). The enhancement layer of the second radio device 5B gives the ID of the first radio device 5A stored in the base station ID information field of the EL header of the received radio packet to the IRC layer.

  The IRC layer of the second radio device 5B performs reception determination processing using the identification information included in the IRC header (step S109).

For reception determination processing, the IRC layer of the second radio device 5B determines whether or not the identification information (radio packet destination ID = 5B) included in the received IRC header matches the ID of the own device 5B. For the second wireless device 5B, the identification information (wireless packet destination ID = 5B) included in the received IRC header matches the ID of the own device 5B. Therefore, the Ethernet layer of the second wireless device 5B is set in the storage unit 53 of the second wireless device 5B using the source MAC address (M _R1 ) or the destination MAC address (M _T1 ) included in the Ethernet header as a search key. The source MAC address or destination MAC address of the second setting information (reception determination information) is searched. The second setting information of the second radio 5B shown in FIG. 44B, the search key is a source MAC address _{(M R1)} or source MAC address that matches the destination MAC address _{(M T1) (M R1)} or destination There is a MAC address (M _T1 ). Therefore, in the reception determination process (step S9), the transmission port MAC address (M _5B ) corresponding to the transmission source MAC address (M _R1 ) or the destination MAC address (M _T1 ) that matches the search key is obtained.
That is, the second wireless device 5B can identify the port (transmission port; second port) _PM5B connected to the device 61 that is the destination of the received Ethernet frame by the reception determination process.

When the Ethernet layer of the second wireless device 5B obtains the identification information of the transmission port, it transmits from the identified transmission port _PM5B (step S110).
The Ethernet frame transmitted from the second wireless device 5B is received by the terminal 61.
If the IRC header shown in FIG. 42D includes not only the wireless packet destination ID 177 but also the destination MAC address 176 or the source MAC address 175, the reception determination process is performed by the IRC layer of the second wireless device 5B. Can be done.

The wireless packet broadcast from the first wireless device 5A is received not only by the second wireless device 5B but also by the third wireless device 5C. The processing unit 52 (the layers from the PHY layer to the enhancement layer (EL); the wireless processing function unit) of the third wireless device 5C that has received the wireless packet performs the reception processing of the wireless packet in the same manner as the second wireless device 5B. To obtain IRC frames (IRC header and Ethernet frame).
The IRC layer of the third wireless device 5C performs reception determination processing using identification information (wireless packet destination ID = 5B) included in the IRC header. For the third wireless device 5C, since the identification information (wireless packet destination ID = 5B) included in the received IRC header does not match the ID of the own device 5C, the destination of the received Ethernet frame is connected to the own device 5C. It is determined that the terminal 62 is not. In this case, the third wireless device 5C performs transfer determination (step S111), and discards the Ethernet frame if transfer is not necessary.

  Even when an Ethernet frame is transmitted from the terminal 61 to the router 4, processing is performed in the same procedure as described above.

  Note that when the wireless devices 5A and 5B of the second modification perform transfer determination, third setting information for identifying wireless packets that need to be transferred is set in the storage unit of the wireless devices 5A and 5B. Just do it. That is, in the second modified example, the third setting information includes the Ethernet frame included in the wireless packet that needs to be transferred instead of the source port ID and the destination port ID shown in FIGS. 37C, 37D, 14C, and 14D. It is sufficient that the source MAC address and the destination MAC address are set. Further, in the third setting information, in addition to or instead of the transmission source MAC address and the destination MAC address, the ID of the wireless device (wireless packet destination ID) that is the destination of the wireless packet that needs to be transferred is set. It may be.

FIG. 43B shows a network configuration in which an Ethernet frame is transmitted from the router 4 to a plurality of terminals 61, 62, 63, 64 in the second modification shown in FIG. 43A. Regarding the communication system shown in FIG. 43B, FIG. 44D to FIG. 44F are referred to in addition to FIG. 43B.
A plurality of Yee support _P MR1 router 4 has in FIG. _{43B, P MR2, P MR3,} P MR4 respectively, corresponding E. support _P M1A of the first radio _5A, P _M2A, P _M3A, is connected to the _{P M4A} Yes.
The e-support P _MT1 of the first terminal 61 and the e-support P _MT2 of the second terminal 62 are connected to corresponding e-supports P _M1B and P _M2B of the second radio device 5B.
Further, the e-support P _MT3 of the third terminal 63 and the e-support P _MT4 of the fourth terminal 64 are connected to the corresponding e-supports P _M1C and P _M2C of the third radio device 5C.

A plurality of Yee support _P MR1 router _{4, P MR2, P MR3,} P MR4 respectively, as also shown in FIG. 43B, the MAC address of MAC-R1, MAC-R2, MAC-R3, MAC-R4 Assigned.
As shown in FIG. 43B, each of the plurality of e-supports P _M1A , P _M2A , P _M3A , and P _{M4A of} the first wireless device 5A includes MAC-1A, MAC-2A, MAC-3A, and MAC-4A. A MAC address is assigned.
The MAC addresses of MAC-1B and MAC-2B are assigned to the plurality of e-supports P _M1B and P _{M2B of} the second radio device 5B, respectively.
MAC addresses of MAC-1C and MAC-2C are assigned to each of the plurality of e-supports P _M1C and P _{M2C of} the third wireless device 5C.
The first terminal 61 (its e-support P _MT1 ), the second terminal 62 (its e-support P _MT2 ), the third terminal 63 (its e-support P _MT3 ), and the fourth terminal 64 (its e-support P _MT4 ) 43B, MAC addresses of MAC-T1, MAC-T2, MAC-T3, MAC-T4 are assigned.
The router 4, the first radio 5A, the second radio 5B, the third radio 5C, the first terminal 61, the second terminal 62, the third terminal 63, and the fourth terminal 64 are also shown in FIG. 43B. As shown, IP addresses of IP-R1, IP-5A, IP-5B, IP-5C, IP-T1, IP-T2, IP-T3, and IP-T4 are assigned.

The first setting information and the second setting information shown in FIGS. 44D to 44F are set in the storage units 53 of the first wireless device 5A, the second wireless device 5B, and the third wireless device 5C shown in FIG. 43B. Yes. 43A, the first wireless device 5A, the second wireless device 5B, and the third wireless device 5C shown in FIG. 43B received the Ethernet frame from the router 4 or the terminals 61, 62, 63, and 64. In this case, identification information is generated with reference to the first setting information shown in FIGS. 44D to 44F.
In addition, when the first wireless device 5A, the second wireless device 5B, and the third wireless device 5C illustrated in FIG. 43B receive wireless packets from other wireless devices, the second settings illustrated in FIGS. 44D to 44F are performed. With reference to the information, reception determination processing and transfer determination processing are performed.

FIG. 43C shows a simplified connection between the router 4 and the first wireless device 5A in the communication system shown in FIG. 43B. Regarding the communication system shown in FIG. 43C, reference is made to FIGS. 44G to 44I and FIG. 45B in addition to FIG. 43C.
The router 4 and the first radio device 5A shown in FIG. 43C are connected to each other by a single e-support _PMR1 and _PM1A .
In FIG. 43C, the third wireless device 5C cannot communicate directly with the first wireless device 5A, but communicates with the first wireless device 5A via wireless packet transfer by the second wireless device 5B.

As shown in FIG. 43B, the MAC address of MAC-R1 is assigned to the e-support _PMR1 of the router 4.
The MAC address of MAC-1A is assigned to the e-support _PM 1A of the first wireless device 5A.
The MAC addresses of MAC-1B and MAC-2B are assigned to the plurality of e-supports P _M1B and P _{M2B of} the second radio device 5B, respectively.
MAC addresses of MAC-1C and MAC-2C are assigned to each of the plurality of e-supports P _M1C and P _{M2C of} the third wireless device 5C.
The first terminal 61 (its e-support P _MT1 ), the second terminal 62 (its e-support P _MT2 ), the third terminal 63 (its e-support P _MT3 ), and the fourth terminal 64 (its e-support P _MT4 ) MAC-T1, MAC-T2, MAC-T3 and MAC-T4 are assigned.
The router 4, the first wireless device 5A, the second wireless device 5B, the third wireless device 5C, the first terminal 61, the second terminal 62, the third terminal 63, and the fourth terminal 64 have IP-R1, IP IP addresses of −5A, IP-5B, IP-5C, IP-T1, IP-T2, IP-T3, and IP-T4 are allocated.

The second setting information and the third setting information shown in FIGS. 44G to 44I are set in the storage units 53 of the first wireless device 5A, the second wireless device 5B, and the third wireless device 5C shown in FIG. 43C. ing.
The wireless devices 5A, 5B, and 5C illustrated in FIG. 43C do not recognize the source MAC address or the destination MAC address of the Ethernet frame by the reception port, but the destination MAC address (and the source MAC address included in the received Ethernet header). Address) and the read destination MAC address (and source MAC address) is stored as identification information in the IRC header.
For this reason, since the first setting information for generating the identification information is unnecessary, the first setting information is not provided in the connection setting information shown in FIGS. 44G to 44I.

In the case of the communication system shown in FIG. 43C, the radio devices 5A, 5B, and 5C do not need to distinguish the port that has received the Ethernet frame in order to generate identification information. As in the case of one radio device 5A, both can be connected by a single port _PMR1 , _PM1A .
The system configuration in FIG. 43C is particularly advantageous when the number of terminals 61, 62, 63, 64 to which information is to be transmitted from the router 4 is large. That is, in the case of the system configuration of FIG. 43B, the number of connection lines between the router 4 and the first wireless device 5 is required to be equal to or more than the number of terminals 61, 62, 63, 64 to which information should be transmitted from the router 4. As a result, if the number of terminals is large, the number of ports of the router 4 and the first wireless device 5A may be insufficient. On the other hand, in the system configuration of FIG. 43C, it is possible to suppress an increase in the number of connection lines between the router 4 and the first radio device 5A even if the number of terminals increases. That is, an increase in the number of e-supports provided in the router 4 and the wireless device 5A can be suppressed.

As shown in FIG. 45B, when the first wireless device 5A (Ethernet layer) receives the Ethernet frame from the router 4 (step S101), it reads the destination MAC address of the Ethernet header (MAC address reading process; step S102).
The (IRC layer) of the first wireless device 5A stores the read destination MAC address as identification information in the IRC header (step S103).
Thus, the first wireless device 5A does not need to refer to the first setting information when generating a wireless packet.
The subsequent processing of the first wireless device 5A and the processing of the second wireless device 5B and the third wireless device 5C that receive wireless packets are the same as the procedure shown in FIG. 45A.

Specifically, when the destination MAC address as identification information included in the IRC header is MAC-T1 (the MAC address of the first terminal 61), the second wireless device 5B performs a reception determination process (step S107). The second setting information (see FIG. 44H) of the second radio 5B is searched using MAC-T1 as a search key. As a result, MAC-1B (the MAC address of the e-support _PM1B of the second wireless device 5B) is obtained as the transmission port MAC address.
Therefore, the second radio device 5B can output the Ethernet frame obtained from the received radio packet from the e-support P _M1B to the first terminal 61.

Further, when the destination MAC address as identification information included in the IRC header is MAC-T3 (the MAC address of the third terminal 63), the second wireless device 5B performs the MAC-- for reception determination processing (step S107). The second setting information (see FIG. 44H) of the second wireless device 5B is searched using T3 as a search key. However, since there is no hit in the search for the second setting information, a transfer determination process (step S111) is performed.
For the transfer determination processing, the second wireless device 5B uses the MAC-T3 as the destination MAC address as identification information and the wireless packet transmission source (first wireless device 5A) as a search key to set the third setting information (see FIG. 44H). As a result of searching, it is determined that the received wireless packet should be transferred because it hits.
The wireless packet transferred by the second wireless device 5B is received by the third wireless device 5C. As a result of the reception determination process (step S107) by the third wireless device 5C, the third wireless device 5C obtains MAC-1C as the transmission port MAC address.
Therefore, the third wireless device 5C can output the Ethernet frame obtained from the received wireless packet from the e-support _PM1C to the third terminal 63.

45C shows a destination MAC address, a source MAC address, a destination IP address, and a source IP address set in the Ethernet frame transmitted in the second modification shown in FIGS. 43A to 43C.
As shown in FIG. 45C, the router 4 sets the destination MAC address of the Ethernet header of the Ethernet frame to be transmitted to the first terminal 61 to, for example, the MAC address (MAC-T1) of the first terminal 61, Transmit to the first radio 5A.
In general, since the router 4 transmits in the hope that the Ethernet frame is received by the first wireless device 5A, the destination MAC address of the Ethernet header of the Ethernet frame is set to the first wireless device 5A. The MAC address (MAC-5A) should be set and transmitted.
However, here, the router 4 transmits the Ethernet frame in which the destination MAC address is set to the MAC address (MAC-T1) of the first terminal 61 to the first radio device 5A.
The first wireless device 5A generates identification information without discarding the received Ethernet frame even if the destination MAC address of the received Ethernet frame does not match the MAC address (MAC-5A) of the own device 5A. Thus, a radio packet encapsulating the Ethernet frame is generated. At this time, the Ethernet header of the received Ethernet frame is not rewritten. That is, the destination MAC address remains MAC-T1, and the source MAC address remains MAC-R1, which is the MAC address of the router 4.
Accordingly, the second wireless device 5B that has received the wireless packet transmitted from the first wireless device 5A transmits the same Ethernet frame transmitted by the router 4 (the content of the Ethernet header is the same) to the first terminal 61. can do.
Thus, the router 4 can appropriately transmit information to the terminal 61 without being aware of the presence of the wireless devices 5A and 5B.

Similarly, when the first terminal 61 transmits an Ethernet frame to the router 4 side, the destination MAC address of the Ethernet header of the Ethernet frame to be transmitted to the router 4 is set to the MAC address of the router 4 (MAC-R1). To transmit to the second radio 5B.
Also in this case, the second wireless device 5B does not discard the received Ethernet frame, even if the destination MAC address of the received Ethernet frame does not match the MAC address (MAC-5B) of the own device 5B. To generate a wireless packet encapsulating the Ethernet frame. At this time, the Ethernet header of the received Ethernet frame is not rewritten. That is, the destination MAC address remains MAC-R1, and the transmission source MAC address also remains MAC-T1, which is the MAC address of the first terminal 61.
Therefore, the first wireless device 5A that has received the wireless packet transmitted from the second wireless device 5B transmits to the router 4 the same Ethernet frame transmitted from the first terminal 61 (the content of the Ethernet header is the same). can do.
Thus, the first terminal 61 can appropriately transmit information to the router 4 without being aware of the presence of the wireless devices 5A and 5B.

FIG. 45D shows an ARP (Address Resolution Protocol) request transmitted by the router 4 and an ARP response received by the router 4. ARP is a protocol for obtaining a MAC address of a terminal on a network.
When the router 4 does not know the MAC addresses of the terminals 61, 62, 63, and 64 (when the MAC addresses of the terminals 61, 62, 63, and 64 are not registered in the ARP table of the router 4), the ARP The MAC addresses of the terminals 61, 62, 63, and 64 can be acquired by request.
Each message of the ARP request and the ARP response corresponds to the above-described Ethernet frame.

When the router 4 does not know the MAC address (MAC-T2) of the second terminal 62 (IP address: IP-T2), the router 4 sets the destination IP address as the IP address of the second terminal 62, IP-T2. Broadcast the ARP request set in (1). That is, the broadcast address is set as the destination MAC address of the ARP request. In the ARP request, the MAC address (MAC-R1) and IP address (IP-R1) of the router 4 are set as the source MAC address and source IP address.
The destination MAC address and the source MAC address included in the ARP request correspond to the destination MAC address and the source MAC address included in the above-described Ethernet header.
The Ethernet frame of the ARP request broadcasted by the router 4 is received by the first radio device 5A. The first wireless device 5A encapsulates the ARP request (Ethernet frame) and generates a wireless packet without discarding the ARP request regardless of the destination MAC address of the ARP request.
When the first wireless device 5A receives the Ethernet frame, the first wireless device 5A generates and transmits a wireless packet encapsulating the Ethernet frame, except when the destination (destination MAC address) of the Ethernet frame is only the own device 5A. .

As shown in FIG. 43B, when the router 4 and the first wireless device 5A are connected by a plurality of lines, the broadcast-transmitted ARP request must reach the first wireless device 5A from each of the plurality of lines. Thus, the first wireless device 5A receives a plurality of ARP requests having the same content. In this case, the first radio device 5A generates and transmits a plurality of radio packets, and communication traffic increases unnecessarily.
On the other hand, as shown in FIG. 43C, when the router 4 and the first wireless device 5A are connected by a single line, it is possible to prevent an unnecessary increase in communication traffic.

In the communication system of FIG. 43C, the identification information included in the wireless packet generated based on the ARP request (Ethernet frame whose destination MAC address is the broadcast address) is the broadcast address.
When the identification information is a broadcast address, the wireless device that has received the wireless packet always transmits an Ethernet frame (ARP request) obtained based on the wireless packet to the terminal connected to the wireless device.
Therefore, the wireless packet generated based on the ARP request is received by both the second wireless device 5B and the third wireless device 5C, and the ARP request obtained based on the wireless packet is received by each wireless device 5B, It is transmitted from 5C to each terminal 61, 62, 63, 64.

Of the terminals 61, 62, 63, and 64 that have received the ARP request, the second terminal (IP address = IP-T2) that matches the destination IP address (IP-T2; see FIG. 45D) of the ARP request is shown in FIG. 45D. An ARP response is sent.
In the ARP response, the MAC address (MAC-R1) of the router 4 that transmitted the ARP request is set as the destination MAC address, and the MAC address (MAC-T2) of the second terminal 62 is set as the source MAC address.
The ARP response transmitted by the second terminal 62 is encapsulated by the second wireless device 5B and is wirelessly transmitted as a wireless packet. The second wireless device 5B that has received the wireless packet obtains an ARP response from the received wireless packet and transmits the ARP response to the router 4.
The router 4 stores the source MAC address (MAC-T2) included in the ARP response in the ARP table of the router 4. Through the above processing, the router 4 can grasp the MAC address of the second terminal 62.

[4. Appendix 1 (especially “Details of Embodiment (Part 2)”)
In the above-described embodiment, the IRC header is provided between the PPP header or the Ethernet header and the wireless communication control information. However, information to be stored in the IRC header is wireless communication control information (for example, EL header or L7 header). May be provided in the reserved area). That is, identification information or the like may be provided before the PPP header or the Ethernet header (at the top of the wireless packet; ahead in time).
When the information to be stored in the IRC header is included in the wireless communication control information, the identification information addition process, the reception determination process, and the transfer determination process are performed in a protocol layer (such as an extension layer or layer 7) for wireless transmission. Is called. That is, the identification information addition process, the reception determination process, and the transfer determination process may be performed in a layer different from the PPP layer or the Ethernet layer (a layer lower than the PPP layer or the Ethernet layer).
In addition, when the IRC header is secure data, in order to perform processing using the information stored in the IRC header, processing (such as decryption processing) that unsecures the received IRC header by security management. Necessary. However, when the information to be stored in the IRC header is included in the wireless communication control information, the wireless communication control information can be prevented from being subjected to security processing, so there is no need to perform processing to unsecure the IRC header.

  The identification information transmitted in the wireless packet (wireless transmission data) includes a transmission source port ID (transmission source ID; transmission source MAC address), a destination port ID (destination ID; destination MAC address), and a PPP link ID. It is not limited to (link ID) or the like. For example, the transmitted identification information may include, for example, a transmission port ID from which the receiving-side radio device 5 outputs a PPP frame. In this case, the first setting information referred to by the wireless device 5 that transmits a wireless packet may be provided with a transmission port ID associated with the reception port ID. When the transmission port ID is included in the wireless packet, the wireless device 5 that has received the wireless packet refers to the transmission port ID included in the received wireless packet without referring to the second setting information. The transmission port to which the PPP frame should be output can be grasped.

The transmission port ID may be transmitted together with at least one of other information that is identification information (source port ID (source ID), destination port ID (destination ID), PPP link ID, etc.)). However, only the transmission port ID may exist as the identification information.
When the transmission port ID is present as identification information to be transmitted, if the reception-side wireless device wants to recognize the transmission source port ID or the destination port ID based on the received transmission port ID, the reception-side wireless The second setting information of the machine may be provided with the source port ID or the destination port ID associated with the transmission port ID.
Further, the identification information may be a reception port ID at which the wireless device that transmits the identification information receives a PPP frame from a router or a terminal. In this case, the receiving side wireless device only needs to be provided with the second setting information in which the reception port ID and the transmission port ID are associated with each other.
Furthermore, the communication protocol between the router (first device) and the terminal (second device) is not limited to PPP.

  In the embodiment, the router 4 is provided as a separate body from the wireless device, but the wireless device may have a function as a router. In addition, the wireless device may have a function as a terminal.

[5. Appendix 2]
The above-described embodiments and modifications should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

[Details of Embodiment (No. 1)]
1 Traffic control system (communication system)
L0, L1, L2, L3, L4 PPP link PR1, PR2, P1A, P1B, PT1 Port 2 Central device 3 Network network 4 Router (communication device)
5, 5A, 5B, 5C, 5D, 5E, 7 Radio 6, 61, 62, 63, 64 Traffic terminal (terminal)
8 wired communication path 41 3rd wired communication unit 42 2nd processing unit 43 2nd storage unit 44 4th wired communication unit 45 5th wired communication unit 51 wireless communication unit 52 1st processing unit 53 1st storage unit 54 1st wired Communication unit 55 Second wired communication unit 71 Communication type information 72 Data type information 73 Source wireless device ID
74 Destination radio ID
75 Sender radio ID
76 Number of generations information

[Reference numerals of details of the embodiment (2)]
1: communication system 2: central device, 3: wide area network, 4, 4A, 4B, 4C, 4D, 4F: router (first device), 5, 5A, 5B, 5C, 5D, 5E: radio, 6, 61, 62, 63, 64, 6B, 6C, 6E, 6F: terminal, 8: communication line 51: wireless communication unit, 52: processing unit, 53: storage unit, 54: first wired communication unit, 55: second Wired communication unit 171: Transmission ID port (identification information), 172: Transfer count information (transfer permission information), 173: Destination port ID (identification information), 174: PPP link ID (identification information), 175: Source MAC address (Identification information), destination MAC address (identification information), wireless packet destination ID (identification information)
L1: First PPP link, L2: Second PPP link, L3: Third PPP link, Fourth PPP link P _R1 , P _R2 , P _R3 , P _R4 : Router ports P ₁ , P ₂ , P ₃ , P ₄ : Radio Ports P _1A , P _2A , P _3A , P _4A : Port of the first radio device 5A (first port)
P _1B , P _2B : Port of the second radio device 5B (second port)
P _1C : Port of the third radio 5C (second port)
P _1D : Port of the fourth radio 5D (second port)
P _1E : Port of the fifth radio 5E (second port)
PT1, PT2, PT3, PT4: Terminal port

Claims (10)

A first communication device that transmits a communication frame of a first protocol in which an upper layer packet is encapsulated;
A second communication device which is assigned an IP address and receives a communication frame of the first protocol;
A plurality of wireless devices as base stations for transmitting and receiving wireless packets of the second protocol for wireless communication;
With
The upper layer packet includes a destination IP address as destination information of the upper layer packet,
The wireless packet is classified as the wireless packet destination information, the wireless device identification information of the wireless device serving as the destination, and whether the wireless packet is addressed to a base station or a mobile station different from the base station Information and
The wireless device identification information is identification information different from an IP address, and is assigned to each of a plurality of wireless devices,
The plurality of wireless devices are:
A first radio that receives the communication frame transmitted from the first communication device;
A second radio that transmits the communication frame to the second communication device ;
It includes,
The first radio is configured to encapsulate an upper layer packet extracted from the communication frame received from the first communication device, generate the radio packet, and wirelessly transmit the generated radio packet;
The first wireless device has table data indicating a correspondence relationship between the destination IP address and the wireless device identification information,
The first wireless device refers to the table data based on the destination IP address included in the communication frame received from the first communication device, and acquires the wireless device identification information corresponding to the destination IP address. The acquired wireless device identification information is set as the destination information of the wireless packet, and is configured to generate the wireless packet in which the classification information indicating the classification addressed to the base station is set ,
When the second wireless device receives the wireless packet, if the classification information set in the wireless packet indicates a classification addressed to a mobile station , the second wireless device determines that the wireless packet is unnecessary, and the classification information is addressed to a base station. If the wireless device identification information of its own device is set as the destination information of the wireless packet, and if the wireless device identification information of the own device is set as the destination information, Configured to extract the upper layer packet from the received wireless packet;
The second radio has an IP address,
The second radio is
If the destination IP address included in the upper layer packet extracted from the received wireless packet is an IP address assigned to the second radio device, the upper layer packet is designated as a packet addressed to the second radio device. As the second radio itself processes,
If the destination IP address included in the upper layer packet extracted from the received wireless packet is an IP address assigned to the second communication device, the communication frame is generated by encapsulating the upper layer packet and the generated said communication frame Ru is configured to transmit to the second communication device,
Communications system. The plurality of wireless devices further include a third wireless device that transfers received wireless packets by wireless communication,
The third wireless device includes a storage unit that stores setting information indicating the wireless device identification information included in a wireless packet to be transferred,
The third wireless device is configured to perform transfer determination processing for referring to the setting information based on the wireless device identification information included in the received wireless packet and determining whether to transfer the received wireless packet. Has been
The communication system according to claim 1. The wireless packet includes both wireless device identification information as destination information of the wireless packet and wireless device identification information as transmission source information,
The communication system according to claim 2, wherein the third wireless device is configured to perform a transfer determination process based on destination information and transmission source information of the wireless packet. The first communication device has one or more communication ports connected to the first radio,
The first communication device has correspondence information between an IP address as destination information of the upper layer packet and the communication port that transmits the communication frame, and is based on an IP address as destination information of the upper layer packet. By referring to the correspondence information, the communication port for transmitting the communication frame is selected,
The correspondence information includes a plurality of IP addresses as the destination information of the upper layer packet, one of claims 1 associated with the smaller number the communication ports than the number of the plurality of IP addresses of claim 3 The communication system according to claim 1 . A radio as a base station connected to a first communication device for transmitting a communication frame of a first protocol in which a higher layer packet is encapsulated, and transmitting a radio packet of a second protocol for wireless communication;
The upper layer packet includes a destination IP address as destination information of the upper layer packet,
The wireless packet is classified as the wireless packet destination information, the wireless device identification information of the wireless device serving as the destination, and whether the wireless packet is addressed to a base station or a mobile station different from the base station Information and
When the communication frame transmitted from the first communication device is received, the wireless packet is generated by encapsulating the upper layer packet extracted from the received communication frame, and the generated wireless packet is wirelessly transmitted. ,
Holding table data indicating the correspondence between the destination IP address and the wireless device identification information;
The wireless device identification information corresponding to the destination IP address is obtained by referring to the table data based on the destination IP address included in the communication frame received from the first communication device, and the acquired wireless device A radio for which the identification information is set as destination information of the radio packet and the radio packet in which the classification information indicating the classification addressed to the base station is set is generated. A radio as a base station,
It is configured to receive the wireless packet transmitted by the wireless device according to claim 5 or the wireless packet transferred by another wireless device, and transfer the received wireless packet by wireless communication,
A storage unit that stores setting information indicating the wireless device identification information included in the wireless packet to be transferred;
A wireless device configured to perform transfer determination processing for referring to the setting information based on the wireless device identification information included in the received wireless packet and determining whether to transfer the received wireless packet. A radio as a base station connected to a second communication device that receives a communication frame of a first protocol encapsulated with an upper layer packet and that receives a radio packet of a second protocol for wireless communication,
When the wireless packet transmitted by the wireless device according to claim 5 or the wireless packet transferred by the wireless device according to claim 6 is received,
When the classification information set in the wireless packet indicates a classification addressed to a mobile station, the wireless packet is determined to be unnecessary, and when the classification information indicates a classification addressed to a base station, the destination information of the wireless packet is determined as the destination information. It is determined whether or not the wireless device identification information of its own device is set, and when the wireless device identification information of its own device is set as the destination information, the upper layer packet is extracted from the received wireless packet And
When the destination IP address included in the upper layer packet extracted from the received wireless packet is an IP address assigned to the own device, the upper layer packet is processed by the own device as a packet addressed to the own device. And
If the destination IP address included in the upper layer packet extracted from the received wireless packet is an IP address assigned to the second communication device, the communication frame is generated by encapsulating the upper layer packet And a wireless device configured to transmit the generated communication frame to the second communication device. A transmission method in a communication system, comprising:
The communication system is:
A first communication device that transmits a communication frame of a first protocol in which an upper layer packet is encapsulated;
A second communication device which is assigned an IP address and receives a communication frame of the first protocol;
A plurality of wireless devices as base stations for transmitting and receiving wireless packets of the second protocol for wireless communication;
With
The upper layer packet includes a destination IP address as destination information of the upper layer packet,
The wireless packet is classified as the wireless packet destination information, the wireless device identification information of the wireless device serving as the destination, and whether the wireless packet is addressed to a base station or a mobile station different from the base station Information and
The wireless device identification information is identification information different from an IP address, and is assigned to each of a plurality of wireless devices,
The plurality of wireless devices are:
A first radio that receives the communication frame transmitted from the first communication device;
A second radio that transmits the communication frame to the second communication device ;
It includes,
The first wireless device has table data indicating a correspondence relationship between the destination IP address and the wireless device identification information,
The second radio has an IP address ,
Before Symbol transmission method,
The first wireless device refers to the table data based on the destination IP address included in the communication frame received from the first communication device, and acquires the wireless device identification information corresponding to the destination IP address The acquired wireless device identification information is set as destination information of the wireless packet, the classification information indicating the classification addressed to the base station is set, and the wireless packet including the upper layer packet extracted from the communication frame And wirelessly transmitting the generated wireless packet ,
Before Stories second radios, the receives the wireless packet, the case where the classification information set in the wireless packet indicating the classification of the mobile station, the radio packet was determined to be unnecessary, the classification information is the base station When indicating the destination classification, it is determined whether or not the wireless device identification information of the own device is set as the destination information of the wireless packet, and the wireless device identification information of the own device is set as the destination information The upper layer packet is extracted from the received radio packet, and the destination IP address included in the upper layer packet extracted from the received radio packet is the IP address assigned to the second radio device The upper layer packet processed by the second radio itself as a packet addressed to the second radio and extracted from the received radio packet. If the destination IP address included in the network is the IP address assigned to the second communication device, the communication frame is generated by encapsulating the upper layer packet, and the generated communication frame is 2 A transmission method including transmitting to a communication device. A first communication device for transmitting a communication frame of a first protocol;
A second communication device for receiving a communication frame of the first protocol;
A plurality of wireless devices as base stations for transmitting and receiving wireless packets of the second protocol for wireless communication;
With
The communication frame includes an upper layer packet including a destination IP address,
The wireless packet includes an inter-radio communication control header, and the upper layer packet,
The inter-radio communication control header includes identification information and classification information for classifying whether the radio packet is addressed to a base station or a mobile station different from the base station ,
The identification information is a determination process for determining whether or not the upper layer packet included in the received wireless packet is related to the wireless device that has received the wireless packet, by the wireless device that has received the wireless packet. Information used for
The plurality of wireless devices are:
A first radio for receiving a communication frame transmitted from the first communication device;
A second radio that transmits a communication frame to the second communication device ;
It includes,
When the first radio receives a communication frame of the first protocol from the communication device, the first radio is included in the inter-radio communication control header in which the classification information indicating the classification addressed to the base station is set, and the communication frame An upper layer packet, and wirelessly transmitting the generated wireless packet,
When the second radio receives the radio packet, when the classification information of the radio communication control header included in the radio packet indicates a classification addressed to a mobile station, the second radio determines that the radio packet is unnecessary, and When the classification information indicates the classification addressed to the base station, the determination processing is performed with reference to the identification information of the inter-radio communication control header included in the wireless packet, and the wireless packet is determined based on the determination processing result. Determining whether to transmit the communication frame including the higher layer packet included to the second communication device ;
Communications system. When the second radio device determines that the upper layer packet included in the received radio packet is related to the radio device that has received the radio packet by the determination process, Refer to the destination IP address included,
When the destination IP address is an IP address assigned to the second radio, the second radio itself processes the upper layer packet as a packet addressed to the second radio,
The communication system according to claim 9 , wherein when the destination IP address is an IP address assigned to the second communication device, the communication frame including the upper layer packet is transmitted to the second communication device.

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