KR20110095045A - Packet processing method of wireless mesh router supporting multi-mode - Google Patents

Abstract

PURPOSE: A packet processing method of a wireless mesh router which supports a multi-mode is provided to support an AP service function supporting a communication with a client terminal which does not have a backbone network function and a wireless router function. CONSTITUTION: If the next destination of a frame which will be delivered to the final destination address is a client terminal address which is managed by a wireless mesh router, the frame is transmitted after converting into a frame which is transmitted between the wireless mesh router and a client terminal(S10,S11). If the next destination address is the wireless mesh router address, the corresponding frame is transmitted to the final destination address of the other wireless mesh router.

Description

Packet processing method of wireless mesh router supporting multi-mode {PACKET PROCESSING METHOD OF WIRELESS MESH ROUTER SUPPORTING MULTI-MODE}

The present invention relates to a wireless mesh network technology, and more particularly, to a packet processing technology of a wireless mesh router supporting multiple modes.

Wireless Mesh Networks (Wireless Mesh Networks) is a network technology that provides services such as Internet access to a plurality of client terminals through multi-hop communication between wirelessly connected wireless mesh routers. Unlike a base station-based mobile network or a hotspot-based WLAN, a wireless mesh network transmits data through wireless multi-hop communication between wireless mesh routers, so network expansion is easy and maintenance and repair is easy. Has an advantage. Recently, various standardization organizations have been working to introduce such a wireless mesh network function, and IEEE 802.11s, which is a wireless LAN standard, belongs to this.

The IEEE 802.11s standard proposed the Hybrid Wireless Mesh Protocol (HWMP) for multi-hop routing. The HWMP protocol uses both on-demand ad-hoc on-demand distance vector (AODV) routing schemes and tree-based routing schemes (proactive). In order to manage the tree-type routing path, one root terminal must exist in the network, and an announcement packet must be transmitted to the network periodically. In addition, an access point (AP) service function for supporting a client terminal is still required in a wireless mesh network. Therefore, a wireless mesh router is a component of a backbone network consisting of connections between wireless mesh routers, and should be able to simultaneously perform a function of connecting a wireless mesh network and an AP service function for user service.

The backbone network function and the AP function for client service have different data frame formats. Existing implementation using device driver implements one function in each interface and limits its role for convenience of implementation. Accordingly, network resources of interfaces defined for other purposes cannot be used even if the resources are available.

The current standard only defines the function of the terminal but does not mention a concrete implementation method. In addition, by using the existing single mode support interface, the mesh backbone network and client services are separated by interface, which wastes available network resources. Therefore, there is a need for a technology that increases flexibility of network resource utilization through a multi-mode support interface.

Packet processing method of wireless mesh router supporting backbone network function supporting communication between wireless mesh routers constituting wireless mesh network at one interface and AP service function supporting communication with client terminal without wireless mesh router function This is proposed.

In a packet processing method of a wireless mesh router for multi-mode support according to an aspect of the present invention, an interface that receives a data frame from an external one of a plurality of interfaces in a wireless mesh router, the source address of the received data frame is the wireless Checking whether the mesh router is included in the list of client terminals managed by the mesh router; The interface that receives the frame may include the format of the frame for multi-hop transmission in a wireless mesh network when the source address of the received data frame is included in a list of client terminals managed by the wireless mesh router. Transmitting to a mesh receiving module by changing to a format and transmitting to a mesh receiving module without changing a format of a received frame when a source address of the received data frame is not included in the client terminal list; When the final destination address in the frame received from the interface receiving the frame is the address of the wireless mesh router, the mesh receiving module removes the header of the received data frame and transmits the header to the network layer, and receives the received data. If the final destination address in the frame is not the address of the wireless mesh router, transmitting the received frame to a multi interface forwarding module; The multi-interface forwarding module checks whether there is route information corresponding to the final destination address in a routing table, and transmits one of the plurality of interfaces generated by the wireless mesh router to the final destination using the identified route information. Selecting as an interface and transmitting a corresponding frame to the selected interface; The interface selected for transmission of the frame to the final destination address is transmitted and received between the wireless mesh router and the client terminal when the next destination address in the frame to be transmitted to the final destination address is the address of the client terminal managed by the wireless mesh router. When the format of the frame is changed and transmitted in the format of the frame, and the address of the other wireless mesh router is not the address of the client terminal managed by the wireless mesh router, and transmits the frame to the final destination address to another wireless mesh router. Steps.

The mesh module managing the plurality of interfaces may be located in the MAC layer of the wireless mesh router.

When included in the client terminal list managed by the wireless mesh router, the received frame and the frame transmitted and received between the wireless mesh router and the client terminal are used for access point (AP) service communication between the wireless mesh router and the client terminal. It may include at least one of an address of a transmitting terminal, an address of a receiving terminal, an address for a BSSID and a bridge function.

The frame for multi-hop transmission in the wireless mesh network includes at least one of an address of a transmitting terminal, an address of a receiving terminal, an address for a BSSID and a bridge function, a multi-hop source, an address of a destination, and a control frame for supporting multi-hop routing. It may include one.

In the packet processing method of the wireless mesh router for the multi-mode support, the multi-interface forwarding module, when there is no route information corresponding to the final destination address in a routing table, uses a HWMP (Hybird Wireless Mesh Protocol) to reach a destination. Determining a path of; And selecting, by the multi-interface transfer module, one of the plurality of interfaces as an interface to transmit a frame generated by a wireless mesh router to a final destination using the determined route information, and transmitting the frame to the selected interface. It may further include.

In a packet processing method of a wireless mesh router supporting multiple modes according to another aspect of the present invention, the multi-interface forwarding module checks whether route information corresponding to a final destination address in a frame generated by the wireless mesh router is in a routing table. Making; The multi-interface transfer module selects one of a plurality of interfaces in the wireless mesh router as an interface to transmit a frame generated by the wireless mesh router to the final destination using the identified path information, and transmits the frame to the selected interface. Making; And the interface selected for transmission of the frame to the final destination address is between the wireless mesh router and the client terminal when the next destination address in the frame transmitted to the final destination address is an address of a client terminal managed by the wireless mesh router. If the format of the frame is transmitted and received, the format of the frame is changed and transmitted.If the address is not the address of the client terminal managed by the wireless mesh router but the address of another wireless mesh router, the frame is transmitted to the other destination of the wireless mesh router as the final destination address. Transmitting.

By implementing the backbone network function to support communication between the wireless mesh routers constituting the wireless mesh network in the wireless mesh router and the AP function that allows the client terminal without the wireless mesh router function to communicate through the wireless mesh network, It is possible to effectively use the frequency available resources of the wireless mesh network without changing the hardware and software of the client terminal.

In addition, the wireless mesh router increases the maximum wireless mesh network capacity by dynamically allocating network resources regardless of communication targets in communication between other wireless mesh routers or user terminals using a backbone network, and increases the frame size according to each target. The format can be changed flexibly.

1 is a diagram illustrating a wireless mesh network according to an embodiment of the present invention.
2 is a flowchart illustrating a beacon transmission of a wireless mesh router and a client terminal connected to a wireless mesh router according to an embodiment of the present invention.
3 is a flowchart illustrating a process of transmitting a packet generated at a client terminal to an outside of a wireless mesh network according to an embodiment of the present invention.
4 is a flowchart illustrating a process of delivering a packet generated or delivered in a wireless mesh router according to an embodiment of the present invention to a client terminal.
5 is a flowchart illustrating a packet processing method received from an outside of a wireless mesh router for multi-mode support.
6 is a flowchart illustrating a packet processing method generated in a wireless mesh router for multimode support.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to intention or custom of a user or an operator. Therefore, the definition should be made based on the contents throughout the specification.

1 is a diagram illustrating a wireless mesh network according to an embodiment of the present invention.

As shown, the wireless mesh network includes a wireless mesh portal 10 serving as a gateway and a wireless mesh router 20 that provides a backbone network connection and an access network service to the client terminal 30. In this case, the wireless mesh router 20 includes at least one interface, and each interface simultaneously supports backbone network communication support and communication with client terminals that support communication between wireless mesh routers. That is, at least one interface in the wireless mesh router 20 changes a format of a frame used for communication between the wireless mesh router and the client terminal.

2 is a flowchart illustrating a beacon transmission of a wireless mesh router and a client terminal connected to a wireless mesh router according to an embodiment of the present invention.

As shown, the wireless mesh router 22 may transmit a mesh beacon and an AP beacon to the wireless mesh network, respectively, to simultaneously support communication with the backbone network and communication with the client terminal 30. Send. The same applies to the wireless mesh router 21. In this case, the mesh beacon is information sent for management of the wireless mesh network and used for sharing information between wireless mesh routers. The AP beacon serves to inform the client 22) of the existence of the wireless mesh router performing the AP function, and may be a beacon used in the 802.11 infrastructure mode.

In a state where the wireless mesh routers 21 and 22 are peered and peered with each other to transmit and receive mesh beacons to each other for connection of a backbone network, the wireless mesh router 22 periodically performs a client service to provide an AP service to the client terminal. Create and broadcast an AP beacon for the terminal.

Accordingly, the client terminal 23 transmits a probe request message to the wireless mesh network to request information of accessible APs around the client terminal 23, and the wireless mesh router 22 receiving the probe request message transmits a probe reply message. The message is sent to the client terminal 23. After receiving the Probe Reply message, the client terminal 23 transmits an Authentication Request message to the wireless mesh router 22 to request an authentication request from the client terminal to the wireless mesh router to be connected. The wireless mesh router 22 transmits an Authentication Reply message to the client terminal 23 after completing authentication according to the client terminal authentication request. When the client terminal 23 receives the Authentication Reply message from the wireless mesh router 22, the client terminal 23 generates an association request message for the association request with the wireless mesh router 22 and transmits the association request message to the wireless mesh router 22. The wireless mesh router 22 performs association authentication according to the association request of the client terminal 23 and transmits an association reply message to the client terminal 23 when it is completed. Through this process, the client terminal 23 is connected to the wireless mesh network through the wireless mesh router 22.

Thereafter, the wireless mesh router 22 adds information of the client terminal 23 connected to the client terminal list. In this case, the client information included in the client terminal list may include an association ID and a hardware address, a connected interface, and power saving mode information. The wireless mesh network may transmit the client terminal 23 information added to the client terminal list to other wireless mesh routers in the wireless mesh network or to a network outside the wireless mesh network through the wireless mesh portal.

3 is a flowchart illustrating a process of transmitting a packet generated in a client terminal through a wireless mesh network according to an exemplary embodiment of the present invention.

The client terminal 23 generates a packet to be transmitted through the wireless mesh network, and broadcasts an ARP request message to the wireless mesh network to obtain information for transmitting the generated packet through the wireless mesh network. At this time, the ARP request message is a packet used to know the hardware address of the receiver.

The wireless mesh router 22 generates an ARP response message in response to the ARP request message of the client terminal 23 and broadcasts it to the wireless mesh network. In this case, the hardware address of the wireless mesh router 22 may be recorded in the receiver information in the ARP response message.

The client terminal (not shown) or the wireless mesh router 21 corresponding to the final destination generates a PREQ (Path Request) message and broadcasts it to the wireless mesh network to find a path to the source client terminal 23. At this time, the PREQ message indicates a message for searching for a wireless multi-hop path, a destination address for generating a route, an address of a source terminal, a PREQ ID, a survival time of a route, a metric for selecting a route, a time to live (TTL) value, and the like. It may include. Metric is a value used to measure the cost of a path, and can use a value that reflects data transmission speed and transmission error.

Upon receiving the PREQ message, the wireless mesh router 22 searches for a list of client terminals managed by the wireless mesh router 22 and transmits a PREP (Path Reply) message to the wireless mesh router 21 when there is corresponding information. In this case, the PREP message is used to determine the wireless multi-hop path, and may include a destination address, an address of the source terminal, a survival time of the path, a metric, a TTL value, and the like.

The wireless mesh router 21 transmits an ARP response message to the wireless mesh router 22 using the determined path. Accordingly, the wireless mesh router 22 converts the format of the received ARP response message into a message format applied to the communication with the client terminal 23 and transmits it to the client terminal 23. At this time, the reason for converting the format of the message is that the message format between the wireless mesh router 22 and the client terminal 23 having an AP service function supporting only a single hop cannot be used for multi-hop wireless transmission used in the wireless mesh network. Because. Meanwhile, the header of the message used for AP service communication includes four address fields such as an address of a transmitting terminal, an address of a receiving terminal, an address for a BSSID, and a bridge function, but is used for a wireless mesh network supporting wireless multi-hop. The header of the message includes the address of the transmitting terminal, the address of the receiving terminal, the address for the BSSID and the bridge function, the address of the multi-hop source and the destination. In addition, a control frame for supporting multi-hop routing may be additionally specified. After that, the header of the message generated in the client terminal 23 is converted into the header of the message applied in the wireless mesh network in the wireless mesh router 22 and then transmitted to the wireless mesh network.

4 is a flowchart illustrating a process of delivering a packet generated or transmitted in a wireless mesh router according to an embodiment of the present invention to a client terminal.

As shown, when a packet is generated outside the wireless mesh network and delivered to the wireless mesh router 21 of the wireless mesh network, or when the packet is generated at the wireless mesh router 21, the wireless mesh router 21 sends an ARP request message. Broadcasts to a wireless mesh network. The wireless mesh router 22 broadcasts the broadcasted ARP request message to its client terminal 23. At this time, the wireless mesh router 22 converts the format of the ARP request message received by the wireless mesh router 21 into a format that can be read by the client terminal 23 and transmits it.

Accordingly, the client terminal 23 corresponding to the final destination sends an ARP response message to its wireless mesh router 22. The wireless mesh router 22 broadcasts the PREQ message to the wireless mesh network for path generation, and the wireless mesh router 21 transmits the PREP message to the wireless mesh router 22. This confirms the route. The wireless mesh router 22 transmits an ARP response message to the wireless mesh router 21 through the determined path, and receives a data packet from the wireless mesh router 21. The wireless mesh router 22 checks whether the client terminal corresponding to the hardware address of the receiver included in the data packet received by the wireless mesh router 21 exists in the client terminal list, and if so, the data received by the wireless mesh router 21. The packet is transmitted to the client terminal 23.

5 is a flowchart illustrating a packet processing method received from the outside of a wireless mesh router for multi-mode support.

As shown, there are two cases in which a data frame is started in a wireless mesh router when a data frame occurs in the wireless mesh router itself or when a data frame is received outside the wireless mesh router. In this case, the wireless mesh router includes a plurality of interfaces for supporting communication between other wireless mesh routers or client terminals in the wireless mesh network.

When any one of a plurality of interfaces in the wireless mesh router receives a data frame received from the outside (S1), the interface includes the source address of the received data frame in the client terminal list managed by the wireless mesh router. Check whether the frame is received from the client terminal managed by the wireless mesh router or whether it is received from another wireless mesh router in the wireless mesh network (S2). At this time, the plurality of interfaces are managed by the wireless mesh module, the wireless mesh module may be located in the MAC layer of the wireless mesh router.

As a result, when the received data frame is received from the client terminal managed by the wireless mesh router, the interface that receives the data frame from the outside has received only the information for the single hop transmission. The header is extended to a frame header for recording information for multi-hop transmission in the wireless mesh network and transmitted to the network layer (S3). That is, the interface receiving the data frame from the outside is changed from the frame header format used between the wireless mesh router and the client to the frame header format used between the wireless mesh router.

On the other hand, when a frame is received from another wireless mesh router that receives a data frame from the outside, the frame is transmitted to the mesh receiving module without modification.

The mesh receiving module hooks the frame transmitted from the interface receiving the data frame from the outside before it is transmitted to the network layer (S4), and the final destination address included in the hooked data frame is assigned to the wireless mesh router to which it belongs. Check whether the address (S5).

If the final destination address in the hooked data frame is the address of the wireless mesh router to which it belongs, the header of the hooked data frame is removed and transmitted to the network layer (S6).

On the other hand, if the final destination address in the hooked data frame is not the address of the wireless mesh router to which it belongs, that is, if the frame needs to be delivered to another wireless mesh router or client terminal, the mesh receiving module multi-interfaces the frame. Send to the transfer module (S7).

Accordingly, the multi-interface delivery module checks whether there is route information corresponding to the final destination address in the lighting table. If there is no information on the route to the final destination, the frame is queued and the route to the destination is searched. At this time, the process of finding the route to the destination may be performed by using the HWMP (Hybird Wireless Mesh Protocol).

The multi-interface forwarding module selects one of a plurality of interfaces in the wireless mesh router as an interface to transmit the generated frame to the final destination by using the confirmed route information or the route information determined by using HWMP. It is transmitted to the selected interface (S8).

The interface selected for the transmission of the frame to the final destination address checks whether the next destination address in the frame transmitted to the final destination address is the address of the client terminal managed by the wireless mesh router to which it belongs (S9).

As a result, if the next destination address in the frame to be transmitted to the final destination address is the address of the client terminal managed by the wireless mesh router to which it belongs, the interface selected for the transmission of the frame to the final destination address is between the wireless mesh router and the client terminal. In this case, the format of the corresponding frame is changed and transmitted (S10, S11).

On the other hand, if the next destination address in the frame to be transmitted to the final destination address is not the address of the client terminal managed by the wireless mesh router to which it belongs, but the address of another wireless mesh router, the frame to be transmitted to the final destination address to the other wireless mesh router. Transmit (S11).

6 is a flowchart illustrating a packet processing method generated inside a wireless mesh router for multimode support.

 For the frame generated at the application layer and down to the network layer, that is, the frame generated at the wireless mesh router is transmitted to the multi interface transfer module.

The multi-interface delivery module checks whether route information corresponding to the final destination address in the frame generated by the wireless mesh router is in the routing table. If there is no information on the route to the final destination, the frame is queued and the route to the destination is searched. At this time, the process of finding the route to the destination may be performed by using the HWMP (Hybird Wireless Mesh Protocol).

Thereafter, the multi-interface transfer module selects one of a plurality of interfaces in the wireless mesh router as an interface to transmit a frame generated by the wireless mesh router to the final destination using the identified route information or the route information determined using the HWMP. The frame is transmitted to the selected interface (S13).

The interface selected for the transmission of the frame to the final destination address checks whether the next destination address in the frame transmitted to the final destination address is the address of the client terminal managed by the wireless mesh router to which it belongs (S14).

As a result, if the next destination address in the frame to be transmitted to the final destination address is the address of the client terminal managed by the wireless mesh router to which it belongs, the interface selected for the transmission of the frame to the final destination address is between the wireless mesh router and the client terminal. In this case, the format of the corresponding frame is changed and transmitted (S15, S16).

On the other hand, if the next destination address in the frame to be transmitted to the final destination address is not the address of the client terminal managed by the wireless mesh router to which it belongs, but the address of another wireless mesh router, the frame to be transmitted to the final destination address to the other wireless mesh router. It transmits (S17).

So far, the present invention has been described with reference to the embodiments. Those skilled in the art will understand that the present invention may be implemented in a modified form without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. Therefore, the scope of the present invention should not be limited to the above-described examples, but should be construed to include various embodiments within the scope and equivalents of the claims.

Claims (8)

Receiving a data frame from the outside of a plurality of interfaces in the wireless mesh router, the interface comprising: checking whether the source address of the received data frame is included in the client terminal list managed by the wireless mesh router;
The interface that receives the frame may include the format of the frame for multi-hop transmission in a wireless mesh network when the source address of the received data frame is included in a list of client terminals managed by the wireless mesh router. Transmitting to a mesh receiving module by changing to a format and transmitting to a mesh receiving module without changing a format of a received frame when a source address of the received data frame is not included in the client terminal list;
When the final destination address in the frame received from the interface receiving the frame is the address of the wireless mesh router, the mesh receiving module removes the header of the received data frame and transmits the header to the network layer, and receives the received data. If the final destination address in the frame is not the address of the wireless mesh router, transmitting the received frame to a multi interface forwarding module;
The multi-interface forwarding module checks whether there is route information corresponding to the final destination address in a routing table, and transmits one of the plurality of interfaces generated by the wireless mesh router to the final destination using the identified route information. Selecting as an interface and transmitting a corresponding frame to the selected interface;
The interface selected for transmission of the frame to the final destination address is transmitted and received between the wireless mesh router and the client terminal when the next destination address in the frame to be transmitted to the final destination address is the address of the client terminal managed by the wireless mesh router. When the format of the frame is changed and transmitted in the format of the frame, and the address of the other wireless mesh router is not the address of the client terminal managed by the wireless mesh router, and transmits the frame to the final destination address to another wireless mesh router. Packet processing method of a wireless mesh router for multi-mode support, comprising the step. The method of claim 1,
The mesh module managing the plurality of interfaces is located in the MAC layer of the wireless mesh router, the packet processing method of the wireless mesh router for multi-mode support. The method of claim 1,
When included in the client terminal list managed by the wireless mesh router, the received frame and the frame transmitted and received between the wireless mesh router and the client terminal are:
It is used for AP (Access Point) service communication between the wireless mesh router and the client terminal, and includes at least one of an address of a transmitting terminal, an address of a receiving terminal, an address for a BSSID, and a bridge function. Packet processing method of mesh router. The method of claim 1,
The frame for multi-hop transmission in the wireless mesh network,
A wireless mesh router for multimode support, comprising at least one of an address of a transmitting terminal, an address of a receiving terminal, an address for a BSSID and a bridge function, a multi-hop source, an address of a destination, and a control frame for supporting multi-hop routing. Packet processing method. The method of claim 1,
Packet processing method of the wireless mesh router for the multi-mode support,
Determining, by the multi-interface forwarding module, a route to a destination using a Hydrobird Wireless Mesh Protocol (HWMP) when there is no route information corresponding to the final destination address in a routing table; Wow
The multi-interface forwarding module selects any one of the plurality of interfaces as an interface to be transmitted to a final destination using the determined route information, and transmits the frame to the selected interface. Packet processing method of a wireless mesh router for multi-mode support, including. The multi-interface forwarding module may include: checking whether route information corresponding to a final destination address in a frame generated by the wireless mesh router is in a routing table;
The multi-interface transfer module selects one of a plurality of interfaces in the wireless mesh router as an interface to transmit a frame generated by the wireless mesh router to the final destination using the identified path information, and transmits the frame to the selected interface. Doing; And
The interface selected for transmission of the frame to the final destination address is transmitted and received between the wireless mesh router and the client terminal when the next destination address in the frame transmitted to the final destination address is the address of the client terminal managed by the wireless mesh router. When the format of the frame is changed, the format of the frame is changed and transmitted, and when the address of the other wireless mesh router is not the address of the client terminal managed by the wireless mesh router, the frame is transmitted to the final destination address to another wireless mesh router. Packet processing method of a wireless mesh router for multi-mode support, comprising the step of. The method according to claim 6,
The mesh module managing the plurality of interfaces is located in the MAC layer of the wireless mesh router, the packet processing method of the wireless mesh router for multi-mode support. The method according to claim 6,
Packet processing method of the wireless mesh router for the multi-mode support,
Determining, by the multi-interface forwarding module, a route to a destination using a Hydrobird Wireless Mesh Protocol (HWMP) when there is no route information corresponding to the final destination address in a routing table; Wow
The multi-interface forwarding module selects any one of the plurality of interfaces as an interface to be transmitted to a final destination using the determined route information, and transmits the frame to the selected interface. Packet processing method of a wireless mesh router for multi-mode support, including.

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