KR200417722Y1 - Mesh network configured to autonomously commission a network and manage the network topology - Google Patents

Abstract

A mesh point (MP) includes a receiver, a transmitter, and a processor in communication with both the receiver and the transmitter. The processor sends a signal to discover an additional MP through the transmitter, receives a response signal from the additional MP through the receiver, and compares the authentication and qualification data for the additional MP with the authentication and qualification data for the MP master. And to determine.

Description

A mesh point used for a mesh network that is configured to autonomously delegate authority to the network and to manage the network topology {MESH NETWORK CONFIGURED TO AUTONOMOUSLY COMMISSION A NETWORK AND MANAGE THE NETWORK TOPOLOGY}

1 illustrates a prior art wireless communication system.

2 illustrates a wireless communication system constructed in accordance with the present invention.

3 is a block diagram illustrating a mesh point (MP) pair configured to manage network topology by autonomously delegating authority to the network of the wireless communication system of FIG. 1 in accordance with the present invention;

4 is a diagram illustrating an MP for managing network topology by autonomously delegating authority to a network according to the present invention;

5A is a flowchart illustrating a method of delegating authority to a mesh network in accordance with the present invention.

5B is a flowchart illustrating a method of determining master authority for an area of a mesh network according to the present invention.

6 illustrates a wireless communication system including a cluster and an area in accordance with the present invention.

<Explanation of symbols for the main parts of the drawings>

100: wireless communication system 110, 110 ', 110 ": mesh point (AP)

115, 125: Processor 116, 126: Receiver

117, 127: transmitter 118, 128: antenna

119, 129: memory

The present invention relates to a wireless communication system. More specifically, the present invention relates to a mesh network configured to autonomously delegate authority to a network to manage its topology.

A mesh of a wireless local area network (WLAN) is typically a distribution system (DS) that has a set of two or more mesh points that are typically connected via an IEEE 802.11 link and communicates over a WLAN. It is part of the IEEE 802.11 based wireless distribution system (WDS). The WLAN mesh may support entry points, also called mesh portals, namely automatic topology learning and dynamic path selection.

One type of WLAN is typically an ad hoc network with a unique station (STA) in range of intercommunication over wireless medium (WM). Ad hoc networks are typically created naturally. A prominent key feature of the ad hoc network is its limited space-time range. This limitation allows the creation and teardown of ad hoc networks to be sufficiently direct and convenient for users of network facilities without having specialized technical capabilities.

In addition, since the Independent Basic Service Set (IBSS) includes a STA set capable of directly communicating with each other, the ad hoc network often includes the IBSS. Even in this case, this type of IEEE 802.11 LAN is typically configured without pre-planning and only when a LAN is needed. However, an important disadvantage of the ad hoc network is that STAs belonging to the network can communicate with each other, but the STAs cannot forward (redirect) or reroute (redirect) packets to other STAs within the same network. Therefore, if the calling STA is not connected to the receiving STA, a new direct connection that can send packets to different STAs must be established. 1 shows such a prior art wireless communication system 10. This prior art wireless communication system 10 includes a plurality of STAs 1, 2 and 3. The STA 1 communicates wirelessly with the STA 2 and the STA 3. Although the STA 2 (or STA 3) can communicate with the STA 1, it is communicated to the STA 3 (or STA 2) through the STA 1 as indicated by an X in a dotted line in the figure. It does not forward packets.

Mesh networks formed from both members and mesh points attempt to cure the problems of ad hoc networks by including routing and forwarding capabilities between members or mesh points of the network. This can effectively communicate with other members of the network using other members. However, the capabilities must meet other functional and security requirements without compromising the network's performance.

Currently, solutions for implementing mesh functionality are limited. These solutions address a number of issues, including enhancements in capacity and communication, privacy and security, self-stable and multipath multi-hop routing, self configuration, and bandwidth process distribution, among other limitations. Faced.

Today's mesh networks rely on network management systems operating at centralized facilities that monitor and manage network operation to mitigate some of the problems. Thus, the deployment of current mesh networks requires sophisticated management procedures for the construction of the network topology, including discovery and visualization of wireless access points, mesh portals, and error management. The dynamic nature of these networks is difficult and impractical to pursue this effort because network management based solutions are slow and require complex manual intervention by the operator.

Real-time demanded applications such as dynamic routing or dynamic frequency selection are unable to rely on topology information that can be out- dated. As with the battlefield, highly mobile applications require fast, responsive topology management as mesh members leave and join rather quickly. As the network expands, the network is exposed to new requirements that require faster mesh point relocation based on the characteristics of the changing environment. An example of this may be the case where the mesh point needs to be repositioned to support an increase in traffic demand for a particular route.

Thus, it would be beneficial if there exist methods and systems that are not limited by the constraints of the prior art.

In a wireless communication system, a method of delegating a plurality of mesh points (MPs) and managing communication between them includes: transmitting, by the first MP, a signal to the second MP to establish communication with the second MP; It includes. The second MP sends a response signal to the first MP. The first MP authenticates the second MP to determine if it is a master MP, and the first MP establishes communication with the second MP.

Hereinafter, the term "STA" includes, but is not limited to, a user device, a wireless transmit / receive unit (WTRU), a fixed or mobile subscriber unit, a pager, or other type of device operable in a wireless environment. As mentioned below, "AP" (or alternatively "mesh point" or "MP") may include, but is not limited to, a Node B, site controller, base station, or other type of interfacing device operable in a wireless environment. It doesn't work.

The function of the present invention may be integrated in an integrated circuit (IC), or may be configured in a circuit having a plurality of connection components.

2 shows a wireless communication system 100 constructed in accordance with the present invention. The wireless communication system 100 includes a plurality of MPs 110 capable of wireless communication with each other. In addition, a predetermined number of STAs (not shown) may be connected to the MP 110, and may communicate with each other via the wireless communication system 100 through the MP 110.

FIG. 3 shows a block diagram illustrating two MPs (denoted by MP 110 'and MP 110 ") configured to manage network topology by autonomously delegating authority to a network in a wireless communication system in accordance with the present invention. For purposes of illustrative description, MP 110 ′ and MP 110 ″ are substantially similar units.

In addition to the nominal components included in a typical MP, the MP 110 ′ includes a processor 115 configured to autonomously delegate authority to the network to manage the network topology, and a receiver in communication with the processor 115 ( 116, a transmitter 117 in communication with the processor 115, a memory 119 in communication with the processor 115, and an MP 110 ′ in communication with the receiver 116 and the transmitter 117. And an antenna 118 that facilitates the transmission and reception of wireless data.

In addition to the nominal components included in a typical MP, the MP 110 "includes a processor 125 configured to manage network topology by autonomously delegating authority to the network, and a receiver communicating with the processor 125 ( 126, a transmitter 127 in communication with the processor 125, a memory 129 in communication with the processor 125, and an MP 110 ″ in communication with the receiver 126 and the transmitter 127. And an antenna 128 for facilitating the transmission and reception of wireless data.

Figure 4 shows the signal flow between the MP (110 ') and the MP (110 ") performed in the formation and management of the mesh network according to the present invention. In a preferred embodiment of the present invention, Processor 115 sends a signal request to MP 110 ″ through transmitter 117 and antenna 118 to attempt to establish a wireless link between MP 110 ′ and MP 110 ″. The receiver 126 of the MP 110 ″ receives a signal from the MP 110 ′ via the antenna 128 and passes it to the processor 125. Processor 125 extracts data containing entitlement information about MP 110 ″ from memory 129.

Processor 125 of MP 110 "then transmits a response 420 containing entitlement data to MP 110" via transmitter 127 and antenna 128. The receiver 116 of the MP 110 "receives the response through the antenna 118 and passes it to the processor 115. The processor 115 receives the credentials of the MP 110 'from the memory 119. And compare it with the credential information obtained in the response from the MP 110 ". Processor 115 then determines whether MP 110 'is a master or MP 110 "is a master, and sends authentication signal 430 through transmitter 117 and antenna 118 to MP 110". Send back to). The authentication signal contains information about which MP 110 (110 'or 110 ") is the master in the network. At this point, the MP 110' and the MP 110" constitute a mesh network. Specifically, the two MPs 110 'and 110 "are at this point in the developing mesh network, where a plurality of MPs 110 are designated as masters of the other MPs 110. The mesh network may include a plurality of regions.

In another method of determining which MP 110 is the master of the region, the processor 115 of the MP 110 'extracts the credential information about the MP 110' and then sends a signal request 410. To establish a wireless link. Thus, when the processor 125 of the MP 110 ″ receives a signal request from the MP 110 ′, the processor 125 sends the entitlement information received from the MP 110 ′ to the MP 110 ″. It may be compared with the qualification information stored in the memory 129. In response, the MP 110 ", in response, informs the MP 110 of which MP 110 (MP 110 'or MP 110 &quot;) is the master of the area and information including authentication information. Send back to '). Determination of which MP is the master of the region may be performed by processor 115 of MP 110 ′ and sent to MP 110 ″, or by processor 125 of MP 110 ″. And may be sent to the MP 110 '.

Referring again to FIG. 4, for purposes of illustrative description, MP 110 ′ is designated as the master by having a high qualification. An additional MP 110 '' '(which is substantially similar in structure to MP 110' and MP 110 ") is a request related to the mesh network generated between MP 110 'and MP 110". 440 is sent to the MP 110 '. The master MP 110 ′ receives this request and sends a response 450 with entitlement information about the MP 110 ′ to the MP 110 ′ ″. MP 110 '' 'receives a response from MP 110' and compares the qualification of MP 110 'with the qualification of MP 110' '', so that MP 110 ' It is determined whether the master is held or whether the master authority is in the MP 110 '' '. MP 110 '' 'transmits an authentication signal 460 containing information on which MP 110 (110' or 110 '' ') is the master of the network. At this point, MP 110 ′, MP 110 ″ and MP 110 ′ ″ constitute a mesh network.

5A illustrates a method 500 of delegating authority to a mesh network in accordance with the present invention. In step 510, the first MP 110 ′ sends a signal to the second MP 110 ″ to connect to the second MP 110 ″. The second MP 110 ″ receives a signal from the first MP 110 ′ and transmits a response containing the authentication and entitlement data of the second MP 110 ″ to the first MP 110 ′. (Step 520). The first MP 110 ′ receives the received signal along with authentication and entitlement data and performs a method of determining master authority (step 530).

5B shows a method 505 for determining master authority in accordance with the present invention. In step 515, the first MP 110 ′ authenticates the second MP 110 ″. The first MP 110 ′ authenticates the authenticity of the second MP 110 ″ to a device of a particular operator or a common manufacturer. The second MP 110 ″ can be authenticated by determining the basic configuration of authentication parameters such as keys and security related matters defined as.

When the first MP 110 ′ authenticates the second MP 110 ″, the first MP 110 ′ compares the qualification of the second MP 110 ″, which MP 110 ′ or 110 ″. It is determined whether is to be designated as the master of the mesh network 100 (step 525.) Table 1 below shows a representative qualification level and related information regarding this qualification level, such as "level specification", "capability" and "mesh". Element ".

level Specify level ability Mesh element One Beginner level   ● packet forwarding ● authentication Mesh point 2 Intermediate level   ● Packet forwarding ● Routing capability ● Authentication (client) Mesh point 3 Advanced level   ● Packet forwarding ● Routing capability ● Authentication (client / server) ● Portal capability Mesh point portal

Referring now to Table 1, examples of qualification levels and associated assignments and functions are shown. For example, MP 110 with entitlement level 1 may be designated as a "beginner level" and may perform only packet forwarding (delivery) and authentication. MP 110 with entitlement level 2 may be designated as an “intermediate level” and may perform packet forwarding, routing capability, and client authentication. MP 110 with entitlement level 3 may be designated as an "advanced level" and may perform packet forwarding, routing capability, client / server authentication, and portal capability, becoming a mesh point portal element.

Thus, in step 535, if the entitlement level of the first MP 110 ′ is higher than the entitlement level of the second MP 110 ″, the first MP 110 ′ is designated as the master of the first area of the mesh network. The second MP 110 ″ is designated as a first member of the first region where the first MP 110 ′ and the second MP 110 ″ form a first region of the mesh network. (Step 540).

If the entitlement level of the first MP 110 ′ is not higher than the second MP 110 ″ (step 535), then the second MP 110 ″ is designated as the first member of the mesh network (step 565). The first MP 110 ′ is designated as a first member of the first region where the first MP 110 ′ and the second MP 110 ″ form a first region of the mesh network (step 540).

The qualification level of the first MP 110 'is not higher than the second MP 110 "(step 535), and the qualification level of the second MP 110" is not higher than the first MP 110'. If (step 555), the processor 115 of the first MP 110 'performs a random process to determine which MP 110 is the master of the first region (step 575). This process ensures that the master authority of the zone is reliably determined.

Referring again to FIG. 5A, an additional MP 110 sends a signal to the master of the mesh network to join the area (step 550). The master MP 110 of the mesh network receives this signal and determination and authentication of the mastery process between the mesh network and the additional MP is performed (step 560). Thus, an additional MP 110 accessing this area with a higher qualification level than the current master MP in this area is designated as the new master MP in this area. This process is repeated for every additional MP 110 attempting to access the area.

Alternatively, if two or more MPs 110 hold the same qualifications, these MPs may form a master cluster of regions in which the master MP is responsible for its own region. In this way, the burden of network expansion can be shared as MPs dynamically connect and disconnect to the mesh network.

FIG. 6 shows a wireless communication system 600 including a master cluster 610 formed between a master MP 110 ′ in a first region R1 and a master MP 210 ′ in a second region R2. Giving. The first region R1 includes a master MP 110 ′ that controls all the MPs 110 in this first region R1. Similarly, master MP 210 ′ controls all MPs 210 in its second region R2. Thus, each of the master MPs 110 'and 210' possesses the highest level of security and integrity capabilities within the mesh network 600, so that the master MPs in this area are the same clusters as the authentication MPs. A master MP that is a member of may grant authorization to an MP that may not be a master of the realm.

For example, referring back to FIG. 6, all the member MPs 210 of the second region R2 are the master MP 210 ′ of the second region R2 and the master MP 110 ′ of the first region R1. Since each is a member of the same cluster 610, it can communicate with any member MP 110 in the first region R1.

Cluster members may share wireless communication system 600 related information, such as security, routing, and topology information. Furthermore, since the cluster member is superior to the area member, the cluster member can provide the expanded communication and load distribution to the wireless communication system 600. In addition, cluster members may share information about neighbor maps, routing maps, and neighbor measurements, among other information. Table 2 illustrates the additional functionality that cluster members MP 110 'and 210' can provide.

function input sauce Print Adjacency discovery neighboringMap AP CandidateNeighboringList neighboringMeasurements Client SMP Function neighboringSystemPreference Configurable to the client neighboringAccessTechnology Neighboring map (AP) neighboringMeshCapabilities Neighboring map (AP) routingMap SMP neighboringMap AP neighboringMeasurements

The functions shown in Table 2 differ from other processes; Neighboring information required; Adding / removing MPs to the network can provide impact and interaction of topology discovery by network impact estimates. As with the information obtained from the neighbor discovery, by the network configuration based on the characteristics of the mesh path from the new MP to the potential receiving side MP, the cluster member MP can provide the optimal mesh path establishment. With this data, the cluster member MP can allocate the member MP of one region in the cluster to reallocate to another region within the cluster according to various parameters. In particular, the cluster member MP may want to change the current topology to distribute the load of the mesh network in order to more efficiently manage existing resources in the mesh network, or in accordance with routing requirements in the area MPs.

For example, in response to an increase in traffic within the first region R1 of the mesh network 600, the cluster member MP 110 ′ may replace the feature MP 110 with the cluster member MP 210 ′ of the second region R2. Can be re-assigned to optimize routing. Such reassignment may be initiated by the MP 110 itself or may be initiated by the cluster member MP 110 ′. For purposes of illustration, two regions R1 and R2 constituting regions within the cluster 610 are shown. However, the number of regions constituting the cluster may be any number, in which case the additional cluster member controls the additional region. Next, cluster members MP 110 ′ and MP 210 ′ may update their respective area member MP with a new topology.

The present invention can be implemented in any type of wireless communication system as desired. As an example, the present invention may be implemented in an 802 type of system, or may be implemented in other types of wireless communication systems. In addition, the present invention provides an integrated circuit such as an Application Specific Integrated Circuit (ASIC), a plurality of integrated circuits, a Logical Programmable Gate Array (LPGA), a plurality of LPGAs, individual components, Or a combination of integrated circuit, LPGA and individual components.

Although the functions and elements of the present invention have been described in particular combinations of embodiments, each function and element may have no other functions and elements of the preferred embodiments and may be used alone or in various combinations with or without other functions and elements of the present invention. Can be used alone.

The present invention can manage the topology of the network autonomously by delegating authority to the network.

Claims (4)

In mesh point (MP), With receiver, With transmitter, A processor in communication with the receiver and the transmitter Including, The processor sends a signal for discovering an additional MP through the transmitter, receives a response signal from the additional MP through the receiver, and authenticates and entitles data for the MP with the authentication and entitlement data for the MP. Mesh point to determine the MP master against the data. The mesh point of claim 1, further comprising a memory in communication with the processor. 3. The mesh point of claim 2 wherein said memory comprises entitlement data relating to said MP. The mesh point of claim 1, further comprising an antenna in communication with the transmitter and the receiver.

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