DE202006005726U1 - Mesh point for use in wireless communication system, has processor to control transmitter in such a manner that transmitter transmits concatenated frames to points in wireless communication system - Google Patents

Abstract

The point has a transmitter (117) to transmit concatenated frames to multiple points, and a receiver to receive the concatenated frames from the points. A processor (115) controls the transmitter in such a manner that the transmitter transmits the concatenated frames to the points in a wireless communication system. The frames have control section frames and/or data division frames, which identify other points in the system.

Description

The The present invention relates to wireless communication networks. In particular, the present invention relates to a device for sending chained frames in a wireless communication system. Likewise a corresponding procedure is discussed.

wireless Local area networks (WLANs) are becoming more widespread because of wireless technology constantly evolving and variants of wireless networks can be present. For example, could a conventional one WLAN based on a structured infrastructure system, which includes a base station, which communicates with wireless devices and traffic between directs them. An additional Type of wireless network is an ad hoc network in which a wireless device with one or more additional devices communicates in a point-to-point process, wherein the wireless devices are dynamic with the network connect and disconnect from him.

When a combination of the conventional System structure and an ad hoc network, a mesh network user equipment, end stations, Access points (APs) and base stations, all as mesh points (MPs) in the wireless system. Mesh nets have become due to essential properties, such as the low-cost Coverage extension for WLANs, the low-priced and self-starting WLANs with less Complexity, and due to their high fault tolerance and redundancy an increasing support acquired in the standardization community.

In A WLAN mesh becomes a set of two or more MPs over IEEE 802.11 connections are interconnected. Each mesh point (MP) in a mesh network and sends its own traffic while acting as a routing device or as a forwarding node for other devices.

Of the IEEE 802.11 standard (Wi-Fi standard) also specifies support for point-to-multipoint transmission as part of asynchronous services. A point-to-multipoint packet includes one Group address that delivers the same package to more than one destination. This is particularly useful, for example, if a particular Type of traffic (e.g., streaming services) from multiple nodes in to receive the network.

In WLAN systems can be the definition of point-multipoint broadcasts the following include: "One Media access control address (MAC address) at which the group bit is set. A point-to-multipoint MAC service data unit (MSDU) has a point-to-multipoint destination address. A point-to-multipoint MAC protocol data unit (MPDU) or a control frame has a point-to-multipoint receiver address. "So send an access point (AP) (in infrastructure mode) or a station (STA) or a client (in ad hoc mode) a frame with a point-to-multipoint destination via the Air, which then from the receivers which subscribes to this service and the point-to-multipoint address to have.

It However, there is a need to chained frames in a wireless Communications system to send, not the limitations Of the prior art is subjected. It is a task the present invention, the deficiencies of the prior state of Technology to overcome. The The object underlying the present invention is achieved by the Features of the claims solved.

The The present invention relates to a device for transmitting a chained frame in a wireless communication system that has multiple mesh points (MPs). In one embodiment comprises an MP a transmitter configured to receive the Chained frames sent to the multiple MPs, a receiver that is configured so that he receives the chained frame from the multiple MPs, and one with the sender and the receiver connected processor that communicates with both the receiver and the transmitter. The processor is configured to control the transmitter such that this one linked frames to the multiple MPs in the wireless communication system sends, and the linked frame contains a control subframe and / or a data subframe which r at least one other MP in the features wireless communication system.

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

2 shows a signal diagram of the prior art for transmitting data in a wireless communication system;

3 a functional block diagram of a Mesh point (MP) constructed in accordance with the present invention;

4 shows a linked frame structure according to the present invention;

5 FIG. 4 is a signal diagram of MPs communicating with one another using point-to-point frame concatenation according to the present invention; FIG.

6 Figure 12 is a signal diagram of MPs communicating with one another using point-to-multipoint control subframe chaining in accordance with the present invention; and

7 FIG. 4 is a signal diagram of MPs communicating using point-to-multipoint control and data sub-frame concatenation in accordance with the present invention. FIG.

One Mesh point (MP) here refers to a wireless Transceiver unit (WTRU), which is a user device, a Mobile station, a fixed or mobile subscriber unit, a pager or any other type of device that is capable in a wireless Environment to work includes, but not limited to that is. Furthermore For example, an MP may refer to a base station that has a node B, a site controller, an access point or any other type of interface device in a wireless environment, but not limited to this is.

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

1 shows a wireless communication system 100 which is constructed according to the present invention. The wireless communication system 100 includes several MPs 110 that are capable of wireless communication with each other.

2 Figure 11 is a prior art signal diagram for transmitting data in a wireless communication system 200 , The prior art signal diagram represents an MP1, MP2 and an MP3 which send signals to each other. In particular, the MP3 first sends certain data for the MP1 to the MP2 ( 210 ). The MP1 sends a transmit request data signal (RTS data signal) to the MP2 ( 220 ). The MP2 sends a ready-to-transmit data signal (CTS data signal) to the MP1 ( 230 ). The MP1 then sends its data ( 240 ), and the MP2 acknowledges (ACK) the data ( 250 ).

When the transfer is complete, the MP2 sends an RTS data signal to the MP1 ( 260 ) to send the data from the MP3 ( 210 ). The MP1 sends a CTS data signal to the MP2 ( 270 ). The MP2 sends the data received from the MP3 to the MP1 ( 280 ), and the MP1 acknowledges the data ( 290 ).

3 is a functional block diagram of an MP 110 which is constructed according to the present invention.

In addition to the nominal components contained in a typical MP, the MP 110 ' a processor 115 configured to send and receive concatenated signals as point-to-point, point-to-multipoint or broadcast broadcasts, a receiver 116 in communication with the processor 115 , a transmitter 117 in communication with the processor 115 , a store 119 in communication with the processor 115 and an antenna 118 that both in communication with the receiver 116 as well as the transmitter 117 stands to the sending and receiving of wireless data to the MP 110 ' and to enable this.

4 shows a linked frame structure 400 according to the present invention. The linked frame structure 400 includes a frame control field 410 , a duration / identifier field 420 , an address field 1 ( 430 ), an address field 2 ( 440 ), a frame identifier field 450 , a payload 460 and a frame checksum (FCS) 470 , The payload 460 may further comprise a plurality of subframes.

The frame control field 410 includes a linked frame. The concatenated frame includes information for multiple MPs, which may include control information such as RTS, CTS, and ACK signals, management information, or data information. In addition, the linked frame can be encrypted. For example, single-key encryption can be used to encrypt the entire frame. In this case, the encrypted frame may be decoded by the MP addressed in the point-to-point transmission (eg, pair key), or by all MPs in the addressed point-to-multipoint transmission group (eg, group key).

alternative the header of the frame can be decrypted. In this case Should the individual chained frames with a point-to-point transmission key (pairwise key) or a point-to-multipoint broadcast or a broadcast key (group key).

The duration / identifier field 420 contains duration information typically contained in an IEEE 802.11 persistent field. This duration is related to the total duration of the chained frame.

The address field 1 ( 430 ) identifies the recipient address and can be point-to-point or point-to-multipoint, while the address field 2 ( 440 ) identifies the sender address, which is a point-to-point address.

The frame identifier field 450 includes information about the payload 460 affect. For example, the frame identifier field 450 the recipients to whom the particular frame 400 is sent, the length of the payload 460 and list the location and duration and nature of the sub-frames.

The FCS 470 checks the completeness of the data. For example, if the information in the subframes 1-n of each MP 110 in the wireless communication system 100 can be decoded, then the FCS 470 only at the end of the frame 400 in the frame 400 be recorded. Alternatively, in the case where not all subframes 1-n of all MPs 110 in the wireless communication system 100 to be decoded, one FCS per subframe will be used.

As discussed above, the payload 460 several subframes, such as the subframe 1 ( 461 ), the subframe 2 ( 465 ) and the subframe n ( 471 ). The subframes are either data, control, or administrative subframes, depending on the frame control type, and the location of each subframe, as discussed above, is the frame identifier field 470 described. For example, subframe 1 is 461 ) a control sub-frame containing signaling information such as an RTS, a CTS or an ACK advertisement. In particular, the control subframe includes an MP tag field 462 , a frame control field 463 which is essentially similar to the frame control box 410 is, and an FCS field 464 substantially similar to the FCS field described above 470 is.

Subframe 2 ( 465 ) is a concatenated data subframe that controls user traffic through the MP Identifier field 466 marked MP, a transmitter address field (SA field) 467 indicating the point-to-point address of the outgoing MP, a length field 468 , a MAC Service Data Unit field (MSDU field) 469 and an FCS field 472 which also belongs to the FCS field 470 similar, may contain.

It should be noted that each Combination of FCS fields, either in the header or in the subframe, can be used. In addition, in an alternative embodiment none at all FCS field can be used.

The MP identification fields 462 and 466 identify the subframe receiver address, which may be the next hop address or the end destination address, and which may be point to point or point to multipoint. Additionally, in a point-to-multipoint transmission, each MP can uniquely define an adjacent MP with an MP identifier that requires less memory than a typical identifier, such as a MAC address having 6 bytes.

5 is a signal diagram 500 of several MPs 110 (as MP 110 ' , MP 110 '' and MP 110 ''' ) communicating with each other using the point-to-point frame concatenation according to the present invention. The MP 110 ''' sends data of traffic flow 2 (TS2) to the MP 110 ' ( 510 ). The recipient 116 of the MP 110 ' receives the TS2 data via the antenna 118 and directs the TS2 to the processor 115 further. The processor 115 can store the TS2 data for re-transmission to memory 119 to save. The recipient 116 of the MP 110 ' then receives over the antenna 118 an RTS traffic flow signal 1 (TS1) from the MP 110 '' ( 520 ) and directs the RTS for the TS1 to the processor 115 further.

The processor 115 of the MP 110 ' then identifies the MP 110 '' in the TS1 RTS signal and compares it to the next hop address for the TS2 data. Consequently, the MP identi fied 110 ' the MP 110 '' as the intended recipient for the TS2 data. Because the TS2 data from the MP 110 ' received, the processor updated 115 of the MP 110 ' a CTS response such that it takes the time required to complete the TS1 data transmission / reception along with the time required to transmit the TS2 data at the end of the transmission into the daisy-chain.

The processor 115 of the MP 110 ' sends the CTS signal for the TS1 via the transmitter 117 and the antenna 118 to the MP 110 '' ( 530 ). The MP 110 '' receives the CTS for the TS1 ( 530 ) and sends the TS1 data to the MP 110 ' ( 540 ). The recipient 116 receives the TS1 data via the antenna 118 and directs it to the processor 115 further.

Prior to sending an ACK for the TS1 data, the processor concatenates 115 the ACK control message with a data subframe corresponding to that for the MP 110 '' contains certain data ( 550 ). Then the processor sends 115 the chained frame over the transmitter 117 and the antenna 118 , If the TS2-Da previously in memory 119 of the MP 110 ' then the processor extracts 115 the TS2 data from the memory 119 before sending it to the MP 110 '' sends. Accordingly, the ACK signal and the TS2 data signal become a single data transfer from the MP 110 ' to the MP 110 '' concatenated. The MP 110 '' determines that the of the MP 110 ' sent information in the control subframe and the data subframe are determined for him by each of its identifier in the MP identifier fields 462 and 466 recognizes.

6 is a signal diagram 600 of several MPs 110 (as MP 110 ' , MP 110 '' and MP 110 ''' ) communicating with each other using the point-to-multipoint control subframe chaining according to the present invention. The MP 110 '' sends an RTS for the TS1 to the MP 110 ' ( 610 ). The recipient of the MP 110 ' receives the RTS for the TS1 from the MP 110 '' ( 610 ) over the antenna 118 and directs it to the processor 115 further.

The processor 115 of the MP 110 ' sends over the transmitter 117 and the antenna 118 a CTS signal for the TS1 to the MP 110 '' ( 620 ). The duration of the CTS is the time required to complete the TS1 data transmission / reception together with the time required to transmit the TS2 data at the end of the transmission of the TS1 data.

The MP 110 '' receives the CTS for the TS1 ( 620 ) and sends the TS1 data to the MP 110 ' ( 630 ). The recipient 116 of the MP 110 ' receives the sent TS1 data ( 630 ) over the antenna 118 and directs it to the processor 115 further. The processor 115 can store the TS1 data for re-transmission to memory 119 to save.

The processor 115 then sends over the transmitter 117 and the antenna 118 both to the MP 110 '' as well as the MP 110 ''' a point-to-multipoint chaining frame ( 640 ). The point-to-multipoint daisy-chain includes a control sub-frame that supports the MP 110 '' in the MP ID field of the control subframe 461 and a TS1-ACK for the MP 110 '' contains, and a control subframe containing the MP 110 ''' in the MP tag field of the control subframe and the TS1 RTS for the MP 110 ''' contains. The MPs 110 '' and 110 ''' each receive the sent point-to-multipoint daisy-chain and decode the frame body to read via its unique MP ID ( 462 ) in the control subframe to determine which control subframes apply to them. Consequently, the control subframe for the MP 110 '' and the control subframe for the MP 110 ''' from the MP 110 ' be combined into a single concatenated point-to-multipoint frame. In addition, the frame body of the chained frames may include encryption to enable it to be read by all MPs 110 can be read by the sending MP 110 ' in the point-to-multipoint group.

7 is a signal diagram 700 of several MPs 110 (as MP 110 ' , MP 110 '' and MP 110 ''' ) communicating with each other using point-to-multipoint control and data subframe chaining according to the present invention. The MP 110 '' sends TS1 data to the MP 110 ' ( 710 ). The recipient of the MP 110 ' receives the sent TS1 data ( 710 ) over the antenna 118 and directs it to the processor 115 further. The processor 115 can store the TS1 data for re-transmission to memory 119 to save.

The processor 115 then sends over the transmitter 117 and the antenna 118 both to the MP 110 '' as well as the MP 110 ''' a point-to-multipoint chaining frame ( 720 ). The point-to-multipoint daisy-chain ( 720 ) includes a control subframe that holds the MP 110 '' in the MP tag field of the control subframe and a TS1 ACK for the MP 110 '' contains, and a data subframe containing the MP 110 ''' in the MP ID field of the data subframe and the TS1 data for the MP 110 ''' contains.

The MPs 110 '' and 110 ''' each receive the sent point-to-multipoint daisy-chain and decode the frame body to read via its unique MP ID ( 462 ) in the control subframe or the MP identifier ( 466 ) in the data subframe to determine which subframes apply to them. Consequently, the control subframe for the MP 110 '' and the data subframe for the MP 110 ''' from the MP 110 ' be combined into a single concatenated point-to-multipoint frame. In addition, the frame body of the chained frames may include encryption to enable it to be read by all MPs 110 can be read by the sending MP 110 ' in the point-to-multipoint group.

The present invention may be implemented as desired in any type of wireless communication system. By way of example, the present invention may be implemented in any type of 802-type system, including, but not limited to, 802.11, 802.15, or 802.16, or any other type of wireless communication system. The present invention may also be implemented as an application resident on a processor, on an integrated circuit, such as an application specific integrated circuit (ASIC), multiple integrated circuits, a logical program mable gate array (LPGA), multiple LPGAs, discrete components, or an integrated circuit / integrated circuit combination, LPGA (s) and discrete component / discrete components.

According to the present The invention will be a mesh point (MP) for use in a wireless Communication system configured to a chained frame sends. The MP includes a transmitter configured to connect the chained frame sends to the multiple MPs, a receiver that is configured to that he receives the chained frame from the multiple MPs, and one with the sender and the receiver connected processor that communicates with both the sender and the receiver. The processor is configured to control the transmitter such that this the chained frame to the multiple MPs in the wireless communication system sends, and the linked frame contains a control subframe and / or a data subframe containing at least one other MP in the wireless Identify communication system.

Even though the features and elements of the present invention in the preferred embodiments described in certain combinations, each feature or element alone (without the other features and elements of preferred embodiments) or in different combinations with or without other features and Elements of the present invention can be used.

Claims (3)

Mesh point (MP) for use in a wireless Communication system having multiple MPs, the MP such is configured that he sends a chained frame, where the MP has: one Transmitter configured to connect the chained frame sends to the multiple MPs; a receiver that configures like this is that he is the chained frame receives from the multiple MPs; and one with the Transmitter and the receiver connected processor that communicates with both the sender and the receiver, wherein the processor is configured to control the transmitter such that this the chained frame to the multiple MPs in the wireless communication system sends; and wherein the linked frame is a control subframe and / or a data subframe containing at least one other Mark MP in the wireless communication system. The MP of claim 1, further comprising a processor connected memory communicating with the processor. An MP according to claim 1 or 2, further comprising one with receiver and the transmitter associated with the antenna and the receiver communicates with the sender.