WO2008049327A1 - Méthode de transport de données et méthode de réponse entre le site émetteur et le site récepteur - Google Patents

Méthode de transport de données et méthode de réponse entre le site émetteur et le site récepteur Download PDF

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Publication number
WO2008049327A1
WO2008049327A1 PCT/CN2007/002997 CN2007002997W WO2008049327A1 WO 2008049327 A1 WO2008049327 A1 WO 2008049327A1 CN 2007002997 W CN2007002997 W CN 2007002997W WO 2008049327 A1 WO2008049327 A1 WO 2008049327A1
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frame
physical
data
superframe
frame body
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PCT/CN2007/002997
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English (en)
French (fr)
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Dongshan Bao
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Dongshan Bao
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L27/00Modulated-carrier systems
    • H04L27/26Systems using multi-frequency codes
    • H04L27/2601Multicarrier modulation systems
    • H04L27/2602Signal structure
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W28/00Network traffic management; Network resource management
    • H04W28/02Traffic management, e.g. flow control or congestion control
    • H04W28/06Optimizing the usage of the radio link, e.g. header compression, information sizing, discarding information
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W84/00Network topologies
    • H04W84/02Hierarchically pre-organised networks, e.g. paging networks, cellular networks, WLAN [Wireless Local Area Network] or WLL [Wireless Local Loop]
    • H04W84/10Small scale networks; Flat hierarchical networks
    • H04W84/12WLAN [Wireless Local Area Networks]

Definitions

  • the present invention belongs to the field of wireless communication technologies, and in particular to an Orthogonal Frequency Division Multiplexing (OFDM) wireless local area network system.
  • OFDM Orthogonal Frequency Division Multiplexing
  • Wireless LAN has broad development prospects due to its flexible access and no wiring.
  • the IEEE 802.il working group proposed a wireless LAN solution for wireless LAN application requirements, which is the 802.11 wireless LAN standard.
  • the 802.11 wireless LAN standard there are four main standards for the 802.11 WLAN physical layer, namely 802. 11, 802. l ib, 802. l lg and 802. l la, the standard for the media access (MAC) layer is mainly 802. 11 and 802. lle.
  • 802.11 defines three working modes of frequency hopping spread spectrum, direct sequence spread spectrum, and infrared; 802. l ib extends 802.11 direct sequence spread spectrum operation to maximize its physical layer The data rate reaches 11Mbps (the former can only reach 2Mbps); 802.llg further expands 802. lib.
  • 802.11g and 802.l ib both work in the 2. 4G band; 802.11a standard works in the 5G band, using OFDM mode, the physical layer maximum data rate is 54Mbps; 802.llg OFDM mode and 802.11a
  • the working frequency band In terms of the MAC layer standard, 802.11 defines the way in which the working station occupies the channel in the 802.11 network, that is, through the random contention occupied channel (DCF) and the AP through the central control occupied channel (PCF), 802. It is mainly a solution proposed for the user service quality problem of 802.11 network, and proposes the HCF working mode to realize the user service quality in LAN communication.
  • DCF random contention occupied channel
  • PCF central control occupied channel
  • the physical frame of 802.11 - 0FDM (0FDM mode with 802.11a and 802.11g) consists of three parts: Preamble, SIGNAL symbol and data (see Figure 1), where Preamble is used for frame synchronization, carrier synchronization, timing. Synchronization and channel estimation, etc.; SIGNAL is an OFDM symbol containing information about the modulation scheme, error correction code rate, and MAC frame length used in the data portion; the data portion carries the MAC frame to be transmitted.
  • the physical layer frame structure of the current 802.11- 0FDM is mainly for medium and low-order signal modulation. Designed by the system, 'When the system uses high-order modulation to achieve the data rate, the following problems occur: In the 802.11 system, in order to achieve MAC layer access, a certain access overhead must be paid. Including: ACK packet, RTS packet, .CTS packet, time gap between data packets, packet collision caused by channel competition in the MAC layer, and backoff before transmitting data packet in DCF working mode. The 802.11 system sends a packet in a certain MAC layer mode, and the time taken by the MAC layer overhead is determined in an average sense.
  • the 802.11 system When the 802.11 system adopts high-order modulation for the physical frame of the data to be transmitted, the time for transmitting the data symbols will be shorter, and the time occupied by the MAC layer overhead remains unchanged, so the data of the MAC layer cannot be spoiled.
  • the physical layer data rate is improved by equal amplitude, which results in limited MAC layer data vomiting. Since the 802.11/802.1 ie protocol specifies the maximum frame length for the MAC frame, the 802.11 system cannot solve the above problem by simply increasing the frame length of the MAC frame.
  • the MAC layer of the 802.11 system transmits the data of the network layer through the DATA packet, and each DATA packet transmits 2000 bytes of network layer data (the maximum data length specified by 802.11 and 802.1 ie is 2312 bytes respectively). And 2324 bytes), if only the ACK response and the time gap of the data packet are considered in the MAC layer, the 802.11-OFDM system reaches 54 Mbps in the physical layer (using 64QAM modulation, 3/4 code rate) When the effective data rate, the MAC layer can only achieve a data vomiting of 39. 8 Mbps. It can be seen that when the physical layer adopts high-order modulation and high code rate, the physical layer frame structure of the current 802.11-OF simple system will severely limit the data throughput that the MAC layer can achieve.
  • the invention provides a construction method of a physical layer superframe of an OFDM wireless local area network, which solves the problem that the current wireless local area network system adopts high-order modulation and high code rate when the physical layer is limited in MAC layer data. Summary of the invention
  • the physical layer superframe is composed of a superframe frame and a superframe frame body; the superframe frame header is located in the super frame.
  • the front end of the frame, the superframe frame is connected to the rear of the superframe frame header;
  • the superframe frame body is composed of a plurality of physical frame frame bodies by being glued back and forth;
  • each physical frame frame body includes a data attribute body and a data
  • the front and back bonding of different physical frame frames is implemented by data attribute bodies;
  • the data attribute body is composed of one or several OFDM symbols;
  • the data body is composed of one or several 0FDM symbols.
  • the frame header of the 0FDM wireless local area network physical frame is used as the super frame header.
  • the physical frame frame body in the superframe frame body may be sent to different receiving sites.
  • the structure of the data attribute body has a flag indicating whether the tail of the current physical frame frame body is adhered to the frame of the subsequent physical frame; If the flag indicates that the trailing part of the current physical frame body is bound with the subsequent physical frame body, the data field indicating the position information of the subsequent physical frame body exists in the current data attribute body.
  • the orthogonal frequency division multiplexing wireless local area network may be an 802.11a/802.11g OFDM network, or may be another orthogonal frequency division multiplexing wireless local area network.
  • a method for constructing a physical layer superframe in an 802.11a/802.11g OFDM network the superframe header is a Preamble portion of an 802.11a/802.llg OFDM physical frame; a physics in the superframe frame body
  • the frame frame body may be sent to different receiving stations; the physical frame frame body is composed of the SIGNAL symbol of the 802.11a/802.11g OFDM physical frame and the subsequent data portion, and the SIGNAL symbol is the data attribute body, and thereafter
  • the data part is the data body.
  • the method for realizing the binding of different physical frame frames by the SIGNAL symbol is used: the original reserved bits are used to indicate whether the tail of the current physical frame body is bonded with subsequent physical The flag bit of the frame frame body; if the flag bit indicates that the tail of the current physical frame frame body is bonded with the subsequent physical frame frame body, the LENGTH field is used to indirectly mark the position information of the subsequent physical frame frame body.
  • each receiving station responds to the transmitting station by responding to a data frame group; the data frame group includes All data frames received from the end of the last response until the start of the current response; the receiving station can also respond when other rights to send data are obtained.
  • the method for allocating response rights After the transmitting station sends a physical layer superframe, the receiving station corresponding to the physical frame frame body of a specific location obtains the response right.
  • the method for allocating the response authority when responding to the physical layer superframe obtains the response right from the receiving station corresponding to the physical frame frame of a specific location.
  • the method for allocating the response authority when responding to the physical layer superframe obtains the response right from the receiving station corresponding to the physical frame frame of a specific location.
  • the receiving station corresponding to the last physical frame frame in the physical layer superframe is designated to obtain the response right.
  • the 802.11a/802.11g OFDM network replies to a group of data frames by means of a group response frame having the following characteristics: a data frame group to be acknowledged in its frame Start label and end label, where the start label refers to the first data frame of the data frame group The label, the end label refers to the label of the last data frame of the data frame group; the start label and the end label are represented by two data fields in the frame.
  • a construction and implementation method of physical layer superframe in OFDM wireless local area network system is proposed to overcome the problem of MAC layer data vomiting when the physical layer reaches high data rate in the existing OFDM wireless local area network.
  • Physical frames in an OFDM wireless local area network can be generally represented as two parts, a physical frame header and a physical frame frame.
  • the physical frame header is used to implement synchronization, channel estimation and other functions.
  • the physical frame frame body may only contain the data body to be transmitted (as shown in FIG. 2), or may include two parts of the data attribute body and the data body (as shown in FIG. 3), wherein the data attribute body is used to define the data body.
  • Certain attributes, such as their modulation, encoding, etc., are provided to the receiving site for signal detection.
  • the frame body of the super frame is formed by removing the frame headers from several physical frames and then bonding them back and forth. Adding a frame header to a superframe frame body constitutes a superframe.
  • the superframe header directly uses the physical frame header of the OFDM wireless local area network.
  • the physical layer superframe constructed by the above method is composed of a superframe frame header and a plurality of physical frame frame bodies, and each physical frame frame body is composed of a data attribute body and a data body.
  • the superframe header is used for synchronization and channel estimation of the superframe.
  • the data body in the body frame body is composed of a number of 0FDM symbols carrying the MAC layer data to be transmitted.
  • the data attribute body in the body frame body is composed of one or several 0FDM symbols, and the front and back bonding functions of the physical frame frame body are completed. There is a flag bit in the data attribute body to indicate whether the tail of the current physical frame frame body is adhered to the subsequent physical frame frame body.
  • the Preamble part is the physical frame header, and the SIGNAL symbol
  • the part is the data attribute body part of the physical frame, and the part carrying the data is the data body part of the physical frame, and the SIGNAL symbol is used for the modulation and coding mode of the subsequent data and the frame length of the carried MAC frame.
  • the SIGNAL symbol is used for the modulation and coding mode of the subsequent data and the frame length of the carried MAC frame.
  • a set of physical frame frames can be constructed from a set of MAC frames, and the superframes can be directly formed by bonding back and forth without constructing them into a set of physical frames.
  • the physical frame body in the superframe can be sent to the site or sent to different sites.
  • the present invention designs a group response mechanism for the physical layer superframe.
  • the response mechanism when the transmitting station sends data to each station in the local area network, only the receiving station corresponding to the physical frame frame body of a specific location has the answering right, and it must use the answering authority right from the last time. All data frames from the current transmitting site are acknowledged after the end of the response until the implementation of this response.
  • the group response mechanism also includes that, since a superframe can be used, the receiving station can utilize its obtained data transmission opportunity to respond to the previously received data frame. '
  • a response to a data frame group can be achieved by a group response frame, which is obtained by defining a new data field based on the 802.11 protocol ACK frame.
  • FIG. 1 Frame structure of physical frame of 802.11-OFDM system
  • Fig. 2 The frame structure of the physical frame of the OFDM wireless local area network system (the physical frame frame body only contains the data body part)
  • Fig. 3 The frame structure of the physical frame of the OFmi wireless local area network system (the physical frame frame body contains the data attribute body and the data body)
  • FIG. 4 is a method for constructing a physical layer superframe from a set of physical frames having the structure of FIG. 3.
  • FIG. 5 is a method for constructing a physical layer superframe from a set of physical frames having the structure of FIG. 2.
  • FIG. 6 is constructed by a set of MAC frames. Implementation method of a physical layer superframe
  • Figure 7 802.11-0FDM system implementation of a physical layer superframe by a set of MAC frames
  • Figure 8 802. 11- 0FDM standard structure of SIGNAL symbols
  • Figure 9 Structure of the SIGNAL symbol of the design of the present invention
  • FIG. 10 Frame structure of DATA frame in 802.11 MAC layer protocol
  • Figure 12 Frame structure of a group response frame
  • Figure 4 and Figure 5 show the implementation of constructing a physical layer superframe from a set of physical frames in an OFDM WLAN.
  • a set of physical frame frames can be constructed from a set of MAC frames, and the superframes can be directly formed by front and back bonding without first constructing them into a set of physical frames.
  • Figure 6 shows an implementation of constructing a physical layer superframe from K MAC frames.
  • the three steps are completed: the first step is to encode and modulate each MAC frame into a corresponding data body; the second step is to add a data attribute body to each data body to form each physical frame frame body, and then Each physical frame frame body is glued back and forth to form a superframe frame body; the third step is to add a superframe frame header to the front of the superframe frame body to form a superframe.
  • the data attribute body may contain definitions of certain attributes of the data body (when the physical frame of the network adopts the structure shown in FIG. 3), or may not include such a definition, Used only as a bond between physical frame frames (when the physical frame of the network uses the structure shown in Figure 2).
  • the front and back bonding of each physical frame frame body can be completed by setting the position information of the last physical frame frame body to which the tail is bonded in the data attribute body of the previous physical frame frame body, such as at the end of the physical frame frame body 1.
  • the position of the physical frame body 2 is indicated in the data attribute body 1, and the physical frame body is marked in the data attribute body 2 when the physical frame body 3 is bonded to the end of the physical frame body 2. 3 position, and so on.
  • the physical frame header of the OFMi WLAN system can be directly used as the superframe header.
  • the physical frame frame in the superframe can be implemented in units of 0FDM symbols, or in units of subcarrier symbols.
  • the frame body bonding in units of 0FDM symbols if the length of a physical frame body cannot occupy exactly an integer number of 0FDM symbols, the information data needs to be filled in the construction of its last 0FDM symbol.
  • the interleaver If the interleaver is not used, no signal can be sent on the subcarriers of the last OFmi symbol that are not full.
  • the physical frame of the 802.11- 0FDM system uses the Preamble structure as the physical frame header and the SIGNAL symbol as the data attribute body. From the construction method shown in Fig. 6, it is not difficult to obtain an implementation process of constructing a physical layer superframe from a set of MAC frames in the 802.11- 0FDM system as shown in FIG.
  • FIG. 7 different physical frame frame bodies are connected by SIGNAL symbols.
  • Pick up. 802.11-OF makes the structure of the system physical frame SIGNAL symbol as shown in Figure 8, which consists of RATE field, LENGTH field, reserved bit, parity bit (Parity) and tailing 0 for convolutional code decoding (Signal Tail) ) Five parts.
  • the RATE field indicates the data rate of the physical layer, which equivalently represents the modulation mode and convolutional code rate used for the current physical frame transmission data
  • the LENGTH field indicates the frame length of the transmitted MAC frame.
  • the transmitting station When the transmitting station sends a physical layer superframe or a normal physical frame to other stations in the local area network, it must use the SIGNAL symbol to indicate to each receiving station whether the tail of the current physical frame frame body is bonded with a subsequent physical frame frame body to guide Receiving data reception from the site.
  • the existing reserved bits in the SIGNAL symbol can be used to indicate this information.
  • the position of the next physical frame frame body must be indicated to each receiving station in the SIGNAL symbol of the current physical frame frame body.
  • any receiving station can use the information of its RATE field and LENGTH field to calculate the length of the current physical frame body after receiving the current SIGNAL symbol, so that the starting position of the next physical frame body can be found.
  • the LENGTH field in the SIGNAL symbol actually provides the location information of the subsequent physical frame frame body indirectly to the receiving station, and thus, in the bonding of the physical frame frame body of the 802.11-OFDM system by the SIGNAL symbol, it is not necessary Deliberately set the position information of its subsequent physical frame frame body in the SIGNAL symbol, as shown in Figure 7.
  • the structure of the SIGNAL symbol in the 802.11-0FDM system using the physical layer superframe is shown in Fig. 9.
  • the Next Frame field is used to indicate whether the tail of the current physical frame frame body is adhered to the subsequent physical frame frame body, and 1 indicates that the subsequent physical frame frame body is bonded, and 0 indicates that the subsequent physical frame frame body is not bonded.
  • Table 1 SIGNAL Symbol The meaning of the newly defined Next Frame field
  • the front-back bonding of the physical frame frame body in the superframe is implemented in units of OFDM symbols and implemented in units of subcarrier symbols.
  • the length of the current physical frame body is: OF makes the symbol, where the gate represents the current value
  • R x 4 is not less than when
  • the length of the physical frame body is x 48 wood subcarrier symbols
  • the working principle is as follows: (1) After the transmitting station sends a physical layer superframe, only one receiving station has the right to respond immediately; (2) The receiving station replies to all data frames from the current transmitting station received from the end of the last response until the start of the response when the receiving right or other opportunity to transmit data is obtained. Since the receiving station can also transmit data in a superframe manner, it can always respond to data frames that have already been received while it is transmitting data to any station.
  • the response authority is allocated as follows: After transmitting a physical layer superframe, the transmitting station corresponds to the physical frame frame body of a specific location. The receiving site gets the replies. This particular location can be based on the specific characteristics of the WLAN system. Since the possibility that the first data attribute body in the physical layer superframe is correctly decoded is always greater than other data attribute bodies, an allocation method of the group response authority is to specify the physical layer superframe and the first physical body. The receiving station corresponding to the frame frame body obtains the response right. This method of assigning acknowledgment rights allows the group acknowledgment rights to be used to the greatest extent possible.
  • the MAC layer of the 802.11 WLAN system uses a trailing acknowledgment mechanism, gp:
  • the receiving station responds after the SIFS interval after receiving its own data frame.
  • the advantages of using a trailing response are: The receiving station can accurately grasp the edge of the transmitted signal, thereby reducing the probability of data collision.
  • the trailing response mechanism can also be agreed to be used for group response, that is, an allocation method for group response rights in the 802.11-OFDM network is obtained.
  • each receiving station of the 802.11-OFDM system After receiving the physical layer superframe from a certain transmitting station, each receiving station of the 802.11-OFDM system obtains a response right with the receiving station corresponding to the last physical frame frame in the superframe.
  • the 802.11 protocol marks the sequence number information by setting a Sequence Control field in the DATA frame.
  • the frame structure of the DATA frame in the 802.11 protocol is shown in FIG.
  • the structure of the Sequence Control field is as shown in FIG. 11, which includes two subfields of Fragment Number and Sequence Number, which are 4 bits and 12 bits, respectively.
  • the Sequence Number subfield indicates the sequence number of the current DATA frame
  • the Fragment Number subfield indicates the fragment number of the current DATA frame.
  • the receiving station's response to a group of data frames can be achieved by using a Group Ack (GroupAck) frame.
  • the frame structure of the group response frame defined by the present invention is shown in Fig. 12. It is constructed by adding three fields of Sequence Control Sequence Control 2 and Group Ack Bitmap to the ACK frame of the 802.11 protocol.
  • the Sequence Control 1 field and the Sequence Control 2 field both adopt the structure of the Sequence Control field in FIG. 11, where Sequence Control 1 indicates the start label of the data frame group to be answered (ie, the label of the first data frame). ), Sequence Control 2 represents the end label of the data frame group that is answered (ie, the label of the last data frame).
  • a 1-bit flag is reserved for each DATA frame from the sequence of Sequence Control 1 to the sequence of Sequence Control 2. When the flag is 1, it indicates that the corresponding DATA frame has been Correct reception, when the flag is 0, it indicates that the corresponding DATA frame is not received correctly. If there are /V possible labels from Sequence Control 1 to Sequence Control 2, the length of the Group Ack Bitmap field is "W/8" 1 byte.

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Description

在发射站点和接收站点之间传输数据的方法和应答方法 技术领域
本发明属于无线通技术领域, 特别涉及正交频分复用(OFDM)无线局域网系 统。 背景技术
随着社会生活越来越广泛的对于信息的需求, 网络已经越来越成为人们日 常生活不可缺少的一部分。 无线局域网因其接入灵活、 不需要布线等优点, 具有 广阔的发展前景。
IEEE802. il工作组针对无线局域网的应用需求提出了其无线局域网的解决 方案, 这就是 802. 11无线局域网标准。 到目前为止, 802. 11无线局域网物理层的 标准主要有四个, 即 802. 11, 802. l ib, 802. l lg和 802. l la, 媒体接入(MAC)层的 标准主要有 802. 11和 802. lle。 在物理层标准方面, 802. 11定义了跳频扩频、 直 接序列扩频和红外三种工作方式; 802. l ib对 802. 11的直接序列扩频工作方式进 行扩展,使其物理层最高数据速率达到 11Mbps (前者只能达到 2Mbps); 802. llg则 对 802. lib作进一步的扩展, 在兼容 802, l ib的基础上, 加入了 OFDM工作方式, 物 理层最高数据速率可达 54Mbps, 802. llg和 802. l ib均工作在 2. 4G频段; 802. 11a 标准工作在 5G频段,采用 OFDM工作方式,物理层最高数据速率为 54Mbps; 802. llg 的 OFDM工作方式与 802. 11a采用了完全相同的实现方式, 差别只在于工作频段不 同。 在 MAC层标准方面, 802. 11定义了 802. 11网络中工作站点占用信道的方式, 即通过随机竞争占用信道(DCF)和 AP通过中央控制占用信道(PCF)两种方式, 802. l ie主要是针对 802. 11网络的用户服务质量问题而提出的解决方案, 提出了 HCF工作方式来实现局域网通信中的用户服务质量。
802. 11 - 0FDM (含 802. 11a和 802. llg的 0FDM方式)系统的物理帧由 Preamble、 SIGNAL符号和数据三部分组成(见图 1), 其中, Preamble用于帧同步、 载波同步、 定时同步和信道估计等; SIGNAL是一个 0FDM符号, 其内包含了数据部分所釆用的 调制方式、纠错码码率和 MAC帧帧长等的信息;数据部分承载了所要传送的 MAC帧。
应该看到, 现行 802. 11- 0FDM的物理层帧结构主要是针对中、 低阶的信号调 制方式设计的, '当系统为达到髙数据速率而釆用高阶调制时, 会产生以下问题: 在 802. 11系统中, 为实现 MAC层的接入, 必须付出一定的接入开销,这包括: ACK包、 RTS包、. CTS包、 数据包间的时间间隙、 MAC层由于信道竞用而产生的数据 包碰撞、 DCF工作方式下发送数据包前的退避等。 802. 11系统在一定的 MAC层工作 方式下每发送一个数据包, 其 MAC层开销占用的时间在平均意义上是确定的。 当 802. 11系统对其传输数据的物理帧采用高阶调制时, 其传输数据符号的时间将变 短, 而 MAC层开销所占的时间保持不变, 因而 MAC层的数据吐香不能随着物理层数 据速率的提髙而得到等幅的提高, 从而造成 MAC层数据呑吐的受限。 由于 802. 11/802. l ie协议为 MAC帧规定了最大帧长, 因此 802. 11系统不能通过简单地 加大 MAC帧帧长的办法来解决上述问题。
下面通过一个实际例子来描述 MAC层数据呑吐受限的问题。 考虑 802. 11系统 的 MAC层通过 DATA包发送网络层的数据, 每个 DATA包均发送 2000个字节的网络层 数据(802. 11和 802. l ie规定的最大数据长度分别为 2312字节和 2324字节), 若在 MAC层仅仅考虑 ACK应答、 数据包之伺的时间间隙这两项开销, 则 802. 11- OFDM系 统在物理层达到 54Mbps (采用 64QAM调制、 3/4码率)的有效数据速率时, 其 MAC层 只能实现 39. 8Mbps的数据呑吐。 由此可见, 当物理层采用高阶调制、 高码率时, 现行的 802. 11- OF簡系统的物理层帧结构将严重地限制其 MAC层可以达到的数据 呑吐量。
本发明给出了一种 OFDM无线局域网物理层超帧的构造方法, 解决了现行无 线局域网系统在物理层采用高阶调制、 高码率时 MAC层数据呑吐受限的问题。 发明内容
为了实现上述目的, 提出了本发明。
根据本发明, 提出了一种正交频分复用无线局域网系统中物理层超帧的构 造方法, 该物理层超帧由超帧帧 和超帧帧体两部分构成; 超帧帧头位于超帧的 前端, 超帧帧体接在超帧帧头的后部; 超帧帧体由若干个物理帧帧体通过前后粘 接而构成; 每个物理帧帧体包含一个数据属性体和一个数据体; 不同物理帧帧体 的前后粘接通过数据属性体来实现; 数据属性体由一个或若干个 OFDM符号所构 成; 数据体由一个或若干个 0FDM符号所构成。 - 优选地, 将该 0FDM无线局域网物理帧的帧头作为该超帧帧头。 , 优选地, 超帧帧体中的物理帧帧体可以是发往不同的接收站点的。
优选地, 对于通过数据属性体实现不同物理帧帧体前后粘接的方法: 该数 据属性体的结构中存在一个标示当前物理帧帧体的尾部是否粘接有后续物理帧 帧体的标志位; 若该标志位标示当前物理帧帧体的尾部粘接有后续物理帧帧体, 则在当前数据属性体中存在标示后续物理帧帧体位置信息的数据域。
优选地, 该正交频分复用无线局域网可以是 802. lla/802. llg OFDM网络, 也可以是其它正交频分复用无线局域网。
优选地, 对于 802. lla/802. llg OFDM网络中物理层超帧的构造方法: 该超 帧帧头为 802. lla/802. llg OFDM物理帧的 Preamble部分; 该超帧帧体中的物理帧 帧体可以是发往不同的接收站点的; 其物理帧帧体由 802. lla/802. llg OFDM物理 帧的 SIGNAL符号和其后的数据部分所构成, SIGNAL符号为数据属性体, 其后的数 据部分为数据体。
优选地, 对于 802. lla/802.' llg OFlk网络中通过 SIGNAL符号实现不同物理 帧帧体前后粘接的方法: 将原保留比特用作标示当前物理帧帧体的尾部是否粘接 有后续物理帧帧体的标志位; 若该标志位^示当前物理帧帧体的尾部粘接有后续 物理帧帧体, 则用 LENGTH域间接标示后续物理帧帧体的位置信息。
优选地, 发射站点发送完一个物理层超帧后, 只有一个接收站点有权限进 行即时的应答;每一次接收站点对发射站点的应答,是对一个数据帧组进行应答; 该数据帧组包含了从上一次应答结束之后到当前应答幵始之前接收到的所有数 据帧; 接收站点也可以在获得其它发送数据的权限时进行应答。
优选地, 对于应答权限的分配方法: 发射站点发送完一个物理层超帧后, 与某一特定位置的物理帧帧体相对应的接收站点获得应答权限。
优选地, 对物理层超帧进行应答时应答权限的分配方法, 与某一特定位置 的物理帧帧体相对应的接收站点获得应答权限。 以两个例子来说明:
(1) 指定与物理层超帧中第一个物理帧帧体对应的接收站点获得应答权限;
(2) 在 802. lla/802. l lg OFDM网络中, 指定与物理层超帧中最后一个物理 帧帧体对应的接收站点获得应答权限。
优选地, 802. lla/802. llg OFDM网络中对一个数据帧组进行应答的方法, 通过具有以下特征的群组应答帧来进行应答: 在其帧中分别标示了将要进行应答 的数据帧组的起始标号与终止标号, 这里, 起始标号指数据帧组的第一个数据帧 的标号, 终止标号指数据帧组的最后一个数据帧的标号; 该起始标号与终止标号 通过该帧中的两个数据域来表示。
提出了一种 OFDM无线局域网系统物理层超帧的构造和实现方法, 以克服现 行 OFDM无线局域网存在的当物理层达到高数据速率时 MAC层数据呑吐受限的问 题。
OFDM无线局域网中的物理帧可一般性地表示为物理帧帧头和物理帧帧体两 部分。 物理帧帧头用于实现同步、 信道估计等功能。 物理帧帧体可以只包含所要 传送的数据体(如图 2所示), 也可以包含数据属性体和数据体两部分(如图 3所 示), 其中, 数据属性体用于定义数据体的某些属性, 如其釆用的调制、 编码方 式等, 提供给接收站点用于信号检测。
对于图 3所示的物理帧结构, 通过将若干个物理帧去掉帧头后再前后粘接, 即构成超帧的帧体。对超帧帧体加上帧头,即构成超帧。该超帧帧头直接采用 OFDM 无线局域网的物理帧帧头。 由 K个物理帧构造一个物理层超帧的实现过程可以表 示为图 4所示的过程。 ·
对于图 2所示的物理帧结构,'将若干个物理帧去掉帧头后, 首先在每个数据 体前加入一个空白的数据属性体、 构成新的物理帧帧体, 然后再前后粘接构成超 帧帧体。 最后, 对超帧帧体加上帧头, 构成超帧。 这里, 空白的数据属性体用于 实现物理帧帧体间的粘接。 由 K个物理帧构造一个物理层超帧的实现过程可以表 示为图 5所示的过程。 '
由上述方法构造的物理层超帧由一个超帧帧头和若干个物理帧帧体所构 成, 每个物理帧帧体又由一个数据属性体和一个数据体两部分构成。 超帧帧头用 于该超帧的同步和信道估计等。 物理帧帧体中的数据体由若干个 0FDM符号所构 成,承载所要传送的 MAC层数据。物理帧帧体中的数据属性体由一个或若干个 0FDM 符号所构成, 由其完成物理帧帧体的前后粘接功能。 在该数据属性体中存在一个 标志位, 用以标示当前物理帧帧体的尾部是否粘接有后续物理帧帧体。 除最后一 个数据属性体外, 超帧中的每一个数据属性体中均放置了关于其尾部所粘接的物 理帧帧体位置的信息。 发射站点在通过将物理帧帧体前后粘接构成超帧时, 首先 修改数据属性体中的标志位, 接着再向其加入关于后续物理帧帧体所在位置的信 息。 ·
在 802. 11- 0FDM系统的物理帧中, 其 Preamble部分为物理帧帧头, SIGNAL符 号部分为物理帧的数据属性体部分, 其后承载数据的部分为物理帧的数据体部 分, SIGNAL符号对其后数据所要釆用的调制、 编码方式和所承载的 MAC帧的帧长 等作出定义。 对于一组 802. 11- OFDM物理帧, 采用图 4所示的方法, 将其去掉 Preamble, 然后前后粘接起来, 最后再在其前端加上一个 Preamble, 即可构成一 个 802. 11- OFDM系统的物理层超帧。
在实际的超帧构造中, 可由一组 MAC帧构造出一组物理帧帧体后, 直接通过 前后粘接而构成超帧, 而不需要先将它们构造成一组物理帧。
超帧中的各个物理帧帧体可以是发往^一站点的, 也可以是发往不同站点 的。 为解决超帧承载的物理帧不发往同一站点时所存在的应答问题, 本发明对物 理层超帧设计了一种群组应答机制。 在该应答机制中, 当发射站点向局域网内的 各个站点发送数据时, 只有与某个特定位置的物理帧帧体所对应的接收站点拥有 应答权限, 且它必须利用该应答权限对从上一次应答结束之后到本次应答实施之 前来自当前发射站点的所有数据帧进行应答。 群组应答机制还包括, 由于可以使 用超帧, 接收站点可以利用它获得的 何发送数据的机会对其在此前所接收到的 数据帧进行应答。 '
在 802. 11-0FDM系统中, 可通过群组应答帧来实现对一个数据帧组的应答, 该群组应答帧则通过在 802. 11协议 ACK帧的基础上定义新的数据域而得到。 附图说明
通过参考以下结合附图对所釆用的优选实施例的详细描述, 本发明的上述 目的、 优点和特征将变得显而易见, 其中:
图 1 802. 11- OFDM系统物理帧的帧结构
图 2 OFDM无线局域网系统物理帧的帧结构(物理帧帧体仅包含数据体部分) 图 3 OFmi无线局域网系统物理帧的帧结构(物理帧帧体包含数据属性体和数 据体两部分)
图 4 由一组具有图 3结构的物理帧构造一个物理层超帧的实现方法 图 5 由一组具有图 2结构的物理帧构造一个物理层超帧的实现方法 图 6 由一组 MAC帧构造一个物理层超帧的实现方法
图 7 802. 11-0FDM系统中由一组 MAC帧构造一个物理层超帧的实现方法 图 8 802. 11- 0FDM标准中 SIGNAL符号的结构 图 9 本发明设计的 SIGNAL符号的结构
图 10 802. 11MAC层协议中 DATA帧的帧结构
图 11 802. 11系统 DATA帧中 Sequence Control域的结构
图 12 群组应答帧的帧结构 具体实施方式
图 4和图 5给出了 OFDM无线局域网中由一组物理帧构造物理层超帧的实现过 程。 在实际的超帧构造中, 可由一组 MAC帧构造出一组物理帧帧体后, 直接通过 前后粘接构成超帧, 而不需要先将它们构造成一组物理帧。
图 6给出了由 K个 MAC帧构造一个物理层超帧的实现方法。 通过三个步骤来完 成: 第一步是将各个 MAC帧经过编码、 调制启构造成对应的数据体; 第二步是对 各个数据体加上数据属性体构成各个物理帧帧体, 然后再将各个物理帧帧体前后 粘接起来, 构成超帧帧体; 第三步是在超帧帧体前部加上超帧帧头, 构成超帧。
在图 6所示的超帧构造中, 数据属性体可能包含了对数据体的某些属性的定 义(当网络的物理帧采用图 3所示的结构时), 也可能未包含这样的定义、 仅用作 物理帧帧体间的粘接(当网络的物理帧采用图 2所示的结构时)。 各个物理帧帧体 的前后粘接可通过在前一个物理帧帧体的数据属性体中设置其尾部粘接的后一 个物理帧帧体的位置信息来完成, 如在物理帧帧体 1的尾部粘接物理帧帧体 2时在 数据属性体 1中标示物理帧帧体 2的位置, 在物理帧帧体 2的尾部粘接物理帧帧体 3 时在数据属性体 2中标示物理帧帧体 3的位置, 依次类推。 在由超帧帧体加上超帧 帧头的操作中, 可直接使用 OFMi无线局域网系统的物理帧帧头作为该超帧帧头。
超帧中物理帧帧体 前后粘接可以以 0FDM符号为单位来实现, 也可以以子 载波符号为单位来实现。 在以 0FDM符号为单位来实现帧体粘接中, 若一个物理帧 帧体的长度不能正好占满整数个 0FDM符号, 则需在它的最后一个 0FDM符号的构造 中对信息数据作填充操作, 以解决交织器的工作问题。 如果不使用交织器, 则可 以在最后一个 OFmi符号的没有占满的子载波上不发送信号。
802. 11- 0FDM系统的物理帧采用 Preamble结构作为物理帧帧头、 SIGNAL符号 作为数据属性体。 由图 6所示的构造方法, 不难得到如图 7所示的 802. 11- 0FDM系 统中由一组 MAC帧构造物理层超帧的实现过程。
在图 7的实现方法中, 不同的物理帧帧体之间通过 SIGNAL符号进行前后联 接。 802. 11- OF讓系统物理帧 SIGNAL符号的结构如图 8所示, 其由 RATE域、 LENGTH 域、 保留位、 校验位 (Parity)和用于卷积码解码的置尾 0 (Signal Tail)五个部分 构成。 RATE域标示的是物理层的数据速率, 等价地表示了当前物理帧传输数据所 采用的调制方式和卷积码码率, LENGTH域标示的是传输的 MAC帧的帧长。
当发射站点向局域网内的其它站点发送物理层超帧或普通物理帧时, 它必 须利用 SIGNAL符号向各接收站点标示当前物理帧帧体的尾部是否粘接有后续的 物理帧帧体, 以引导接收站点的数据接收。 SIGNAL符号中现有的保留位正可以用 来标示该信息。 我们把新定义的由该 志位所构成的域称为 Next Frame域。
在 Next Frame域标示当前物理帧巾贞体的尾部粘接有后续物理帧帧体的情况 下, 必须在当前物理帧帧体的 SIGNAL符号中向各接收站点标示出下一个物理帧帧 体的位置。注意到任何接收站点在收到当前 SIGNAL符号后都可以利用其 RATE域和 LENGTH域的信息计算出当前物理帧帧体的长度, 从而也就可以找到下一个物理帧 帧体的起始位置。 因此, SIGNAL符号中的 LENGTH域实际上向接收站点间接地提供 了后续物理帧帧体的位置信息, 从而, 在由 SIGNAL符号实现 802. 11- OFDM系统的 物理帧帧体的粘接中, 不必特意在 SIGNAL符号中设置其后续物理帧帧体的位置信 息, 如图 7所示。
釆用物理层超帧的 802. 11-0FDM系统中 SIGNAL符号的结构如图 9所示。其中, Next Frame域用来表示当前的物理帧帧体的尾部是否粘接有后续物理帧帧体, 用 1表示粘接有后续物理帧帧体, 用 0表示没有粘接后续物理帧帧体, 如表 1所示。 注意到, 发射站点在发送普通物理帧时, 其将 Next Frame域设置为 0, 而每个超 帧的最后一个物理帧帧体中的 SIGNAL符 的 Next Frame域也必须设置为 0 表 1 SIGNAL符号中新定义的 Next Frame域的含义
Figure imgf000009_0001
超帧中物理帧帧体的前后粘接分为以 OFDM符号为单位来实现和以子载波符 号为单位来实现两种。 设 SIGNAL符号中 RATE域标示的物理帧帧体的数据速率为 R (Mbps) , LENGTH域标示的 MAC帧帧长为 L (bytes) , 则当采用以 OFDM符号为单位进 行物理帧帧体的粘接时,
L x 8
当前物理帧帧体的长度为: 个 OF讓符号, 式中, 门表示距当前值最
R x 4 近的不小于当
前值的整数; 当釆用以子载波符号为单位进行物理帧帧体的粘接时, 当前
Zx 8
物理帧帧体的长度为 x 48 木子载波符号,
R x4 由于物理层超帧的设计允许在一个超帧中传输发往不同站点的物理帧, 因 此, 在超帧系统中必须釆用与 802. 11MAC层协议不同的应答机制。
我们采用群组应答机制来实现接收站点对发射站点的应答, 其工作原理是: (1) 发射站点在发送完一个物理层超帧后, 只有一个接收站点有权限进行即时的 应答; (2) 接收站点在获得应答权限或其它发送数据的机会时, 对从上一次应答 结束之后到本次应答开始之前所接收到的来自当前发射站点的所有数据帧进行 应答。 由于接收站点也能以超帧方式发送数据, 因此, 它总是可以在其对任何站 点发送数据的同时, 对已经接收到的数据帧进行应答。
OFDM无线局域网系统釆用群组应答机制对物理层超帧进行应答时, 按如下 方式分配应答权限: 发射站点在发送完一个物理层超帧后, 与某一特定位置的物 理帧帧体相对应的接收站点获得应答权限。 该特定的位置可根据无线局域网系统 的具体特点来定。 由于物理层超帧中第一个数据属性体获得正确解码的可能性总 是大于其它的数据属性体, 因此, 群组应答权限的一种分配方法是指定物理层超 帧中与第一个物理帧帧体相对应的接收站点获得应答权限。该种应答权限的分配 方法可使得群组应答权限得到最大可能的使用。
802. 11无线局域网系统的 MAC层釆用了一种尾随式应答的机制, gp : 接收站 点在接收到属于自己的数据帧后, 在 SIFS时间间隔后进行应答。 釆用尾随式应答 的优点是: 接收站点能够准确地把握发射信号的边沿, 从而减少了数据碰撞的概 率。 当将物理层超帧和群组应答机制用于 802. 11网络时, 也可约定采用尾随式应 答机制进行群组应答, 即得到 802. 11- OFDM网络中群组应答权限的一种分配方法: 在 802. 11- OFDM系统的各个接收站点接收到来自某个发射站点的物理层超帧后, 与超帧中最后一个物理帧帧体所对应的接收站点获得应答权限。
在 802. 11系统中, 当发射站点向接收站点发送一组 DATA帧时, 需要对其进 行编号, 表示其在这一组 DATA帧中的位置。 802. 11协议通过在 DATA帧中设置 Sequence Control域来标示该序号信息。 802. 11协议中 DATA帧的帧结构见图 10。 其 Sequence Control域的结构如图 11所示, 其包含了 Fragment Number和 Sequence Number两个子域, 分别为 4比特和 12比特。 其中 Sequence Number子域表示的是当 前 DATA帧的序列号, Fragment Number子域表示的则是当前 DATA帧的分片号。
在采用超帧的 802. 11- 0FDM系统中, 接收站点对一个数据帧组的应答可通过 采用群组应答(GroupAck)帧来实现。 本发明定义群组应答帧的帧结构如图 12所 示,它是通过在 802. 11协议的 ACK帧中加入 Sequence Control Sequence Control 2和 Group Ack Bitmap三个域而构造成的。 在该结构中, Sequence Control 1域 和 Sequence Control 2域均采用图 11中 Sequence Control域的结构, 其中, Sequence Control 1表示所应答的数据帧组的起始标号(即第一个数据帧的标 号), Sequence Control 2则表示所应答的数据帧组的终止标号(即最后一个数据 帧的标号)。 在 Group Ack Bitmap域中, 为从标号为 Sequence Control 1到标号 为 Sequence Control 2之间的每个 DATA帧保留了 1比特的标志位, 当该标志位为 1 时, 表示对应的 DATA帧已经被正确接收, 当该标志位为 0时, 表示对应的 DATA帧 没有被正确接收。 设从 Sequence Control 1到 Sequence Control 2共存在 /V个可 能的标号, 则 Group Ack Bitmap域的长度为「W/8"1字节。 尽管以上已经结合本发明的优选实施例示出了本发明, 但是本领域的技术 人员将会理解, 在不脱离本发明的精神和范围的情况下, 可以对本发明进行各种 修改、 替换和改变。 因此, 本发明不应由上述实施例来限定, 而应由所附权利要 求及其等价物来限定。

Claims

1、 一种在正交频分复用 OFDM无线局域网系统中利用物理层超帧来在发射站 点和接收站点之间传输数据的方法, 其中该物理层超帧包括超帧帧头和超帧帧 体 所述方法包括步骤:
将若干个物理帧帧体通过权前后粘接构成超帧帧体进而形成物理层超帧, 其 中每个物理帧帧体包含数据属性体和数据体, 不同物理帧帧体的前后粘接通过数 据属性体来实现;
利用所形成的超帧帧体在所述正交频分复用无线局域网系统中的发射站点 和接收站点之间传输数据。 求
2、 根据权利要求 1所述的方法, 其特征在于该数据属性体由一个或若干个 OFDM符号所构成; 并且该数据体由一个或若干个 OF腿符号所构成。
3、 根据权利要求 1所述的方法, 其特征在于该超帧帧头位于物理层超帧的 前端, 超帧帧体接在超帧帧头的后部。
4、 根据权利要求 1所述的方法, 其特征在于使用正交频分复用无线局域网 物理帧的帧头作为该超帧帧头。
5、 根据权利要求 1所述的方法, 其特征在于该超帧帧体中的各个物理帧帧 体是发往不同的接收站点的。
6、 根据权利要求 1所述的方法, 其特征在于该数据属性体的结构中存在一 个标示当前物理帧帧体的尾部是否粘接有后续物理帧帧体的标志位; 若该标志位 标示当前物理帧帧体的尾部粘接有后续物理帧帧体, 则在当前数据属性体中存在 标示后续物理帧帧体位置信息的数据域。
7、 根据权利要求 1所述的方法, 其特征在于该正交频分复用无线局域网是
802. 1 la/802, llg OFDM网络。
8、 根据权利要求 7所述的方法, 其特征在于
该超帧帧头为 802. lla/802. llg OFDM物理帧的 Preamble部分;
该超帧帧体中的物理帧帧体是发往不同的接收站点的;
其物理帧帧体由 802. lla/802. llg OFDM物理帧的 SIGNAL符号和其后的数据 部分所构成, SIGNAL符号为数据属性体, 其后的数据部分为数据体。
9、 根据权利要求 8所述的方法, 其特征在于不同物理帧帧体前后粘接是通 过 SIGNAL符号实现的, 其中, 将原保留比特用作标示当前物理帧帧体的尾部是否 粘接有后续物理帧帧体的标志位; 若该标志位标示当前物理帧帧体的尾部粘接有 后续物理帧帧体, 则用 LENGTH域间接标示后续物理帧帧体的位置信息。
10、 一种在正交频分复用 OFDM无线局域网系统中由接收站点对来自发射站 点的物理层超帧进行应答的方法, 其中所述该物理层超帧包括超帧帧头和超帧帧 体, 所述方法包括步骤: '
由发射站点将若干个物理帧帧体通过前后粘接构成超帧帧体进而形成物理 层超帧, 其中每个物理帧帧体包含数据属性体和数据体, 不同物理帧帧体的前后 粘接通过数据属性体来实现;
由发射站点向接收站点发送所形成的物理层超帧;
针对由发射站点发送来的物理层超帧, 仅具有应答权限的接收站点对发射 站点进行应答。
11、 根据权利要求 10所述的方法, 其特征在于每一次当接收站点对发射站 点进行应答时, 对一个数据帧组进行应答;
该数据帧组包含了从上一次应答结束之后到当前应答开始之前接收到的所 有数据帧。
12、 根据权利要求 10所述的方法, 其特征在于所述具有应答权限的接收站 点是与在物理层超帧中处于特定位置的物理帧帧体相对应的接收站点。
13、 根据权利要求 12所述^方法, 其特征在于所述与在物理层超帧中处于 特定位置的物理帧帧体相对应的接收站点是与物理层超帧中第一个物理帧帧体 对应的接收站点。
14、 根据权利要求 12所述的方法, 其特征在于在 802. l la/802. l lg OFDM网 络中, 所述与在物理层超帧中处于特定位置的物理帧帧体相对应的接收站点是与 物理层超帧中最后一个物理帧帧体对应的接收站点。
15、 根据权利要求 11所述的方法, 其特征在于在 802. lla/802. l lg OFDM网 络中, 接收站点对发射站点进行应答是通过群组应答帧来实现的, 在该群组应答 帧中分别标示了将要进行应答的数据帧组的起始标号与终止标号, 其中起始标号 指数据帧组的第一个数据帧的标号, 终止标号指数据帧组的最后一个数据帧的标 号。
16、 根据权利要求 15所述的方法, 其特征在于该起始标号与终止标号通过 该群组应答帧中的两个数据域来表示。
17、 根据权利要求 10所述的方法, 其特征在于该超帧帧体中的各个物理帧 帧体是发往不同的接收站点的。
PCT/CN2007/002997 2006-10-20 2007-10-19 Méthode de transport de données et méthode de réponse entre le site émetteur et le site récepteur WO2008049327A1 (fr)

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