DE202006007235U1 - Management information transmitting method for use in wireless communication system, involves transmitting management frame by mesh point to another mesh point, where management frame identifies destination mesh point - Google Patents

Abstract

The method involves transmitting a management frame by a mesh point (MP) to another MP, where the frame includes a medium access control (MAC) address of a destination MP. The management frame is received from the former MP, and a determination is made if it is the destination MP, by the latter MP. The management frame is updated if the latter MP determines it is not the destination MP. The management frame is transmitted to a third MP, where the management frame identifies the destination MP. Independent claims are also included for the following: (1) a mesh point (MP) in a wireless communication system, comprising a receiver (2) an integrated circuit (IC) of a mesh point.

Description

The The present invention relates to wireless communication systems. In particular, the present invention relates to a device for sending management information in a wireless communication system.

wireless Local area networks (WLANs) are becoming more widespread because of wireless technology continues to evolve. Moreover, in a given geographical Many variants of wireless networks exist. For example, could a conventional one WLAN based on a structured system, which is a base station comprises which communicates with wireless devices and traffic between them leitweglenkt. Another type of wireless network is an ad hoc network, in which a wireless device with one or more others communicates wireless devices in a point-to-point wireless devices dynamically connect to the network and separate from him.

When a combination of the conventional WLAN and an ad hoc network can be a mesh network user devices, terminals, access points (APs) and base stations, all as mesh points (MPs) work. Mesh nets collect due to essential properties, such as an inexpensive coverage extension for WLANs, low-cost and self-configuring WLANs with low complexity and because of their high fault tolerance and redundancy increasing support in the Standardization community.

Of the 802.11 standard currently defines three types of framework: a data frame, a management framework and a control frame. Data frames are typically associated with two (2), three (3) or four (4) media access control addresses (MAC addresses) configured. Administrative and control messages however, only configured with two (2) MAC addresses because of the Entrance architecture of existing wireless networks, such as BSS star, IBSS ad hoc and AP-AP bridge networks, only two MAC addresses needed were.

In however, a mesh WLAN is common the exchange of administrative information on the management framework via a single jump out from one MP to the next MP required. In addition, individual can Dependent on MPs the number of interfaces with which they communicate with other MPs can, be identified by more than one MAC address.

It There is therefore a need to send management information and the MAC addresses of MPs in a wireless communication system, not the limitations of the prior art is clearly too mark.

The The present invention relates to an apparatus for sending management information in a wireless communication system that has multiple mesh points (MPs). In one embodiment comprises an MP: a transmitter configured to receive a Send management frame to another MP, which is a destination MP and specifying a source MP, a receiver configured to that he Management frame receives from another MP, and one with the sender and the receiver connected processor that works with both the sender and the receiver in Communication is. The processor is configured to receive the Sender controls to send management frames. The administrative framework comprises at least one media access control (MAC) address of a Destination MP.

The previous summary as well as the following detailed Description of the preferred embodiments of the present invention The invention will be better understood with reference to the attached Drawings are read, whereby:

1 a wireless communication system constructed in accordance with the present invention;

2 a management framework according to the present invention;

3 Fig. 10 is a block diagram of a mesh point (MP) configured to perform a method of transmitting management information;

4 Fig. 10 is a flowchart of a preferred method for sending management information;

5 Fig. 16 is a signal diagram depicting multiple MPs transmitting a management frame according to the present invention;

6 Figure 12 is a signal diagram depicting multiple MPs transmitting a management frame according to an alternative embodiment of the present invention;

7 is a modified management frame with a mesh connection identifier; and

8th is a modified information element with a mesh connection identifier.

Of the The term "mesh point" (MP) refers to here further on a wireless transmitting / receiving unit (WTRU), a user device (UE), a mobile station, a fixed or mobile subscriber unit, a pager or any other type of device that is capable of being in a wireless However, working environment is not limited to this. In addition, can an MP on a base station, a Node B, a location control, an access point or any other type of interface device in a wireless communication environment.

The Features of the present invention may be incorporated into an integrated circuit (IC) be installed or built in a circuit, having a plurality of interconnected components.

1 is a wireless communication system 100 which is constructed according to the present invention. The wireless communication system 100 includes several MPs 110 who are able to communicate with each other. For the purposes of the description of the present invention, the MPs 110 referred to as MP1, MP2, MP3, MP4 and MP5. Although five MPs 110 as in the wireless communication system 100 should be noted that any number of MPs 110 in the wireless communication system 100 may be included. For the purposes of the description of the present invention, the MP1, MP2, MP3, MP4 and MP5 are essentially similar units.

The MPs 110 communicate management information with each other by sending management control frames. In 2 is a management tax framework 200 shown in accordance with the present invention. The administrative tax framework 200 includes a frame control field 210 , a permanent field 220 , a field for an address 1 (Adr1) 230 , a field for an address 2 (Adr2) 240 , a field for an address 3 (Adr3) 250 , a sequence control field 260 , a field for an address 4 (ADR4) 270 , a payload field 280 and a frame checksum field (FCS field) 290 , The fields 210 to 270 make up the 802.11 MAC header. In the prior art, the frame control field comprises 210 an in-distribution system field (An-DS field) and a Von-Verteilungssystem field (From-DS field). In the present invention, the An-DS and Von-DS fields are replaced by a destination MP field and a source MP field. In addition, the address fields 230 . 240 . 250 and 270 used in the present invention as described in detail below.

3 is a block diagram of an MP 110 configured to perform a method for mesh management. In addition to the nominal components contained in a typical MP, the MP 110 a processor 115 configured to receive, send and process management frames of the present invention, a receiver 116 in communication with the processor 115 , a transmitter 117 in communication with the processor 115 and an antenna 118 both in communication with the recipient 116 as well as the transmitter 117 to the transmission and reception of wireless data to and from the MP 110 to facilitate.

To send a management frame beyond a single jump, the MPs use 110 In accordance with the present invention, the destination MP, source MP and address fields in an existing frame are used to indicate to a receiving MP its state relative to the management frame. The MP is then able to determine how the received management frame should be processed, such as whether it is intended for the receiving MP or not, or whether the receiving MP should forward the management frame to the next MP.

Referring to Table 1 (shown below), when a sending MP sends a management frame to a receiving MP, the sending MP occupies the destination MP field, the source MP field, and address fields according to Table 1. For example, the destination becomes MP field is given a "1" if the MP to receive the frame is the destination MP, and a "0" if it is not. The source MP field is assigned a "1" if the MP sending the management frame is the source MP, and a "0" if he is not. The address fields are determined by the value of the destination MP field and the source MP field as defined in Table 1 with the destination address (ZA), the source address (QA), the receiver address (EA) or the sender address (SA ). In the case where the target MP field is a "1", the EA and the ZA are equal, and similarly, in the case where the source MP field is a "1", the SA and the Therefore, in Table 1, where either the destination MP or source MP fields are a "1", it is possible to use only three address fields (see row 2 and 3 of Table 1). If both the destination MP and source MP fields are "1", it is also possible to use only two address fields (see row 4 of Table 1) Address fields is shown, it is noted that the address fields can be assigned as desired in any way.

Table 1

4 is a flowchart, which is generally a method 300 for transmitting management information in a wireless communication system. In step 310 a first MP sends a management frame a a second MP. The second MP receives the management frame (step 320 ) and determines if it is the target MP or not (step 330 ) by recognizing the value of the destination MP field.

If the target MP field is a "1", then the second MP is in step 330 the destination MP, and the procedure ends. If the second MP in step 330 is not the destination MP (ie the destination MP field is a "0"), then the second MP updates the fields accordingly and sends the management frame to a third MP (step 340 ). The third MP receives the management frame (step 350 ) and determines if it is the target MP or not (step 360 ).

If the third MP in step 360 the target MP is, then the process ends 300 , If the third MP in step 360 is not the destination MP, then the third MP updates the fields in the management frame accordingly and sends the management frame to another MP (step 370 ). Further MPs continue to forward the management frame until the management frame is received by the destination MP (step 380 ). It will be noted that the other MPs may also update the fields before forwarding the management frame as shown in Table 1.

5 is an exemplary signal diagram 400 that has several MPs 110 (referred to as MP1, MP2, MP3, MP4 and MP5), which represents a management frame according to the method 300 send. In particular, for purposes of providing an example, a management frame is shown as being sent from the MP1 via the MP2, the MP3, and the MP4 to the MP5. In this example, the MP1 is the source MP, and the MP5 is the destination MP.

First, the processor sends 115 of the MP1 the management frame to the MP2 ( 410 ). Since MP1 is the source MP and MP2 is not the destination MP, the processor updates 115 the fields of the management frame of the signal 410 so that it contains the following occupied fields: target MP = 0 and source MP = 1. According to Table 1, Adr1 = MP2 (EA), Adr2 = MP1 (QA), and Adr3 = MP5 (ZA).

The recipient 116 The MP2 receives the management frame sent by the MP1 and sends it to the processor 115 the MP2 continues. The processor 115 determines that the MP2 is not the destination MP of the management frame, and the MP2 sends the management frame via the sender 117 and the antenna 118 to the MP3 ( 420 ). Since the MP2 is not the source MP and the MP3 is not the target MP, the processor updates 115 the fields of the management frame of the signal 420 such that they contain destination MP = 0 and source MP = 0. According to Table 1, Adr1 = MP3 (EA), Adr2 = MP2 (SA), Adr3 = MP5 (ZA) and Adr4 = MP1 (QA).

The recipient 116 the MP3 receives the sent management frame and forwards it to the processor 115 of the MP3. The processor 115 of the MP3 then determines that the MP3 is not the destination MP of the Management frame, and the MP3 sends the management frame to the MP4 ( 430 ). Since the MP3 is not the source MP and the MP4 is not the destination MP, the processor updates 115 of MP3 fields of the management frame of the signal 430 such that they contain destination MP = 0 and source MP = 0. According to Table 1, Adr1 = MP4 (EA), Adr2 = MP3 (SA), Adr3 = MP5 (ZA) and Adr4 = MP1 (QA).

The recipient 116 The MP4 receives the sent management frame and forwards it to the processor 115 the MP4 continues. The processor 115 the MP4 then determines that the MP4 is not the destination MP of the management frame, and the MP4 sends the management frame to the MP5 ( 440 ). Since the MP5 is the target MP, but the MP4 is not the source MP, the processor updates 115 of the MP4 the fields of the management frame of the signal 440 such that they contain destination MP = 1 and source MP = 0. According to Table 1, Adr1 = MP5 (ZA), Adr2 = MP4 (SA) and Adr3 = MP1 (QA).

The recipient 116 The MP5 receives the sent management frame and forwards it to the processor 115 the MP5 continues. The processor 115 the MP5 then determines that the MP5 is the destination MP of the management frame and adopts the management frame. The processor 115 then acts according to the requirement contained in the management frame. For example, if the management frame was a measurement request for power levels on the MP5, then the processor responds 115 the MP1 with the associated measurements.

6 is a signal diagram 500 that has several MPs 110 (referred to as MP1, MP2, MP3, MP4 and MP5) which transmit a management frame according to an alternative embodiment of the present invention. In the present embodiment, an MP 110 Support multiple physical connections to communicate with other MPs, with each physical connection having a MAC address. To be recognized in the mesh, every MP can 110 have a main address.

In the present example, the MP1 may be the MAC address 11 (Adr11), while the MP2 supports three physical connections to communicate with other MPs. A connection for the MP2 is connected to the MP1 and through the MAC address 21 (Adr21). Adr21 may also be a main address associated with MP2. In addition, the MP2 includes two separate physical links connected to the MP3 which serve as the MAC address 22 (Adr22) and MAC address 23 (Adr23) are designated.

In a preferred embodiment can the two separate physical addresses with different communication protocols be connected. For example, the Adr22 may be connected to 802.11b, while Adr23 can be connected to 802.11g.

In the present example, the MP3 also supports four physical connections. He can therefore by a main MAC address 33 (Adr33), but also includes physical connection addresses with the MPs connected to it. Two physical addresses, in connection with the MP2 as address 32 (Adr32) and address 33 (Adr33), an address 34 (Adr34) in connection with the MP4 and the physical connection address 31 (Adr31) with the MP5. The MP4 can by the MAC address 41 (Adr41), and the MP5 can be marked by the Mac address 51 (Adr51).

In the present example, the MP1 sends a management frame dedicated to the MP3 according to the present invention. Since the MP1 (Adr11) is the source MP and the MP2 (Adr21) is not the destination MP, the processor points 115 of MP1, the fields according to Table 1 such that the destination MP = 0 and the source MP = 1. Consequently, Adr1 = Adr21 (EA-MP2), Adr2 = Adr11 (QA-MP1), Adr3 = Adr33 (ZA -MP3). The processor 115 then sends the management frame over the sender 117 and the antenna 118 to the MP2 ( 510 ).

The recipient 116 The MP2 receives the broadcast and sends it to the processor 115 the MP2 continues. The processor 115 decodes the management frame and determines that it is not intended for the MP2. The processor 115 then update the fields in the management frame and send it to the MP3 ( 520 ). Since the MP2 communicates with the MP3 over the physical connection identified by the MAC address Adr32, the processor recognizes 115 of the MP2 does not use the MP3 as the destination address. Consequently, the processor instructs 115 of the MP2 to the respective fields target MP = 0 and source MP = 0 too. According to Table 1, Adr1 = Adr32 (EA-MP3), Adr2 = Adr22 (SA-MP2), Adr3 = Adr33 (ZA-MP3) and Adr4 = Adr11 (QA-MP1).

The recipient 116 of the MP3 receives the sent management frame from the antenna 118 and directs it to the processor 115 of the MP3. The processor 115 the MP3 decodes the management frame and although the destination MP field equals zero, and determines that the management frame is intended for the MP3, because the main MAC address of the MP3 (Adr33) occupies the Adr3 field, which is the destination address (ZA).

Although that in the signal diagram of 6 The format of the management frame used as described above in Table 1 should be noted that changes in format may be used. The management frame format may be changed such that additional formats, such as the Adr1 field indicating the QA, the Adr2 field indicating the EA, or any combination of the address fields of the destination MP and source MP fields to be recorded.

Still referring to 6 can some MPs 110 have more than one MP with whom they are in communication. For example, the MP3 is represented as communicating with the MP2, MP4 and MP5. Accordingly, any mesh connection between each MP, such as MP2-MP3, MP3-MP4, and MP3-MP5, is unique relative to any other mesh connection in the wireless communication system. As the mesh management framework 200 indicates the destination MP, it is only necessary to mark the address of a neighbor MP to uniquely identify the mesh connection. That is, to mark the mesh connection between the MP3 and the MP4 in a management frame sent to the MP3, a mesh connection identifier (ID) only needs to specify the address of the MP4 (Adr44). The mesh connection ID of the connections between the MP3 and the MP2 is called Adr21 (MAC address of the MP2), while the mesh connection ID between the MP3 and the MP4 is called Adr41 (MAC address of the MP4) and the mesh connection ID ID between the MP3 and the MP5 is called Adr51 (MAC address of the MP5).

For example, the MP1 may send a management frame to the Adr33 (MP3) requesting maintenance operations or similar measurement requirements for the mesh connection between the MP3 and the MP4. Since the MP3 would be designated as the ZA in the management frame, the MP1 need only specify the mesh connection ID for the MP4 (Adr41) to uniquely identify the connection between the MP3 and the MP4. This can be done by either adding an extension containing the mesh connection ID to the management frame 200 or by including the mesh connection ID in an information element (IE).

Alternatively, a group of meshes may be assigned a unique mesh connection ID to identify that group. Still referring to 6 For example, the mesh connections between the MP3 and all its neighbor MPs (MP2, MP4 and MP5) become a mesh connection ID 99 assigned. If the mesh connection ID 99 identifies the MP3, it will detect all connections to the MP2, MP4 and MP5.

7 shows a management frame 600 which is modified to include a mesh connection identifier. The management framework includes a frame control field 610 , a permanent field 620 , an Adr1 field 630 , an Adr2 field 640 , an Adr3 field 650 , a sequence control field 660 , an Adr4 field 670 , a payload field 680 and a frame checksum field (FCS field) 690 , The payload field 680 is further extended so that it is next to the payload 684 a mesh connection ID field 682 includes. In this embodiment, the frame control field 610 specify the destination MP as the payload field 680 to be decoded.

In an alternative embodiment of the present invention, the mesh connection ID field may be provided with an information element. 8th shows an information element 700 which is modified to be an element identifier field 710 , a length field 720 , a mesh connection ID field 730 and administrative information 740 includes. In this case, the management information such as a measurement request / response, an action request / answer, or the like, together with the mesh connection ID may be sent to the destination MP to uniquely identify the mesh connection on which the measurement / action is requested ,

The The present invention may be implemented in any type of wireless Be implemented communication system. By way of example, the present invention in any type of 802 system or any other Type of wireless communication system can be implemented. The The present invention may also be implemented in software or as one on one Processor running application to be implemented. The present The invention may further be implemented on an integrated circuit, such as an application specific integrated circuit (ASIC), several integrated circuits, a Logically Programmable Gate Array (LPGA), several LPGAs, discrete components, or a combination (or integrated) r Circuit (s), LPGA (s) and discrete component (s) implemented become.

According to the invention becomes a mesh point (MP) for configured the use in a wireless communication system such that he Sends administrative information. The MP comprises a transmitter which is such is configured that he sends a management frame to another MP which specifies a destination MP and a source MP, a receiver that configures so is that he Management frame receives from another MP, and one with the sender and the receiver connected processor that works with both the receiver and the transmitter in Communication is. The processor is configured to receive the Transmitter controls such that he Management frame sends. The administrative framework contains at least a media access control (MAC) address of a destination MP.

Even though the features and elements of the present invention in the preferred embodiments can be described in certain combinations, each feature or element alone (without the other features and elements of preferred embodiments) or in various combinations with or without other features and elements of the present invention are used. For example certain stitches in a preferred embodiment the present invention by a unique Maschenverbin tion ID characterized. However, the mesh connection can also by the Destination MP address in connection with a predetermined extension or by an independent identifier, such as a random number generated to the mesh connection to be marked. The random number can be the MAC address as a seed from which the mesh connection ID should be generated.

Claims (5)

Mesh point (MP) for use in a wireless Communication system having multiple MPs, the MP such is configured that he sends and receives a management frame, the MP comprising: one A transmitter configured to provide a management frame to another MP which sends a destination MP and a source MP indicates; a receiver, which is configured to be Receive management frame from another MP; and one with the Transmitter and the receiver connected processor that works with both the receiver and the transmitter in Communication is where the processor is configured so that he processing the management frames and controlling the sender so that he Management frame sends; and the administrative framework being at least a media access control (MAC) address of a destination MP contains. The MP of claim 1, wherein the processor further comprises is configured that he Management framework of the recipient receives. The MP of claim 1 or 2, wherein the processor further is configured so that he determines whether the MP is the target MP of a management frame, and Management frame fields updated if the MP is not the destination MP is. The MP of claim 3, wherein the processor further comprises is configured that he Management frame fields with a source MP address, a destination MP address, a sender MP address and a recipient MP address updated. The MP of any one of claims 1 to 4, wherein the processor is further configured to have a source MP of a management frame certainly.