JP2007329723A - Wireless communication method, dynamic band assigning method, data transmitting method, wireless communication system, base station, and terminal station - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve throughput characteristics between a base station and a wireless terminal connected to the base station by a wireless circuit by reducing an overhead accompanied by a collision. <P>SOLUTION: The base station 1 predict next data generation timing from past traffic characteristics by wireless terminals 2-1 to 2-N and allocates a slot to a wireless frame corresponding to predicted timing. When the base station 1 allocates the slot before a back-off time passes, the wireless terminals 2-1 to 2-N transmit generated data scheduled to be transmitted at a back-off time later, or transmit RREQ and then transmit the generated data with a slot allocated by the base station 1 on the basis of the RREQ. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a radio communication method, a dynamic band allocation method, a data transmission method, a radio communication system, a base station, and a terminal station that enable dynamic band allocation.

  In recent years, ubiquitous wireless networks and wireless sensor networks that provide users with a variety of applications have attracted attention in fields such as equipment control, transportation, environmental conservation, food / agriculture, earthquake monitoring, and medical welfare. These networks are composed of a base station and a large number of wireless terminals connected to a fixed network.

  Wireless terminals in the network are battery-powered and low power consumption / low function terminals that have minimal functions such as data measurement and transmission of measurement data to the base station. (1) The amount of data is small, (2) data is generated periodically, and (3) the transmission interval is relatively long. However, since there are many such wireless terminals, the total traffic tends to increase. Furthermore, since these networks aim to collect data from as many wireless terminals as possible, it is necessary to accommodate as many wireless terminals as possible in one base station. Therefore, in these networks, a MAC (Media Access Control) protocol capable of realizing a high throughput while accommodating a large number of wireless terminals in one base station is required.

  As a MAC protocol that satisfies this requirement, a dynamic slot allocation method, which is one of centralized control methods with high resource utilization efficiency, is used. In this method, TDMA-TDD (Time Division Multiple Access-Time Division Duplex) is used as an access method, and a base station dynamically allocates slots (bandwidths) according to a request from a wireless terminal. FIG. 13 shows an example of the frame configuration. The MAC frame is divided into an uplink and a downlink. The downlink includes a broadcast section and a demand assignment section, and the uplink includes a demand assignment section and a random access section.

  In order to transmit and receive data and control information, Bch (Broadcast control channel), RFch (Random access Feedback channel), Fch (Frame control channel), Cch (Control Channel: control channel), Dch (Data channel: data channel), and RCH (Random access channel) are used. Bch notifies base station attributes (base station ID, frame number, etc.) to the radio terminal, and Fch uses slot assignment information in the demand assignment section in which slot allocation is performed in units of radio terminals (the radio terminal that performed the allocation). , Slot position, slot length, allocation channel, etc.) to notify the random access information (random access result of previous frame, random access start position and number of slots, etc. in this frame) Used. Cch is control information for each wireless terminal such as bandwidth request information (Resource Request: RREQ) and ARQ (Automatic Repeat Request), and Dch is used to transmit and receive user data. Rch is a channel for random access, and is used for a wireless terminal to transmit the RREQ.

  As the dynamic slot allocation method, there is an access method using random access in order for a wireless terminal to make a bandwidth request to a base station. Since this method can flexibly and efficiently accommodate non-periodic data generated in bursts, it is widely applied as a dynamic slot allocation method that satisfies the above requirements. FIG. 14 shows an example of an access sequence using this method. In this example, the base station transmits Bch, RFch, and Fch in order from the beginning of the MAC frame. By receiving the RFch, the wireless terminal under the base station can know the random access start position and the number of slots in the frame. When the wireless terminal has data to be transmitted, bandwidth request information for requesting a bandwidth for data transmission to the base station: RREQ is transmitted by Rch, so that the wireless terminal has a transmission waiting time based on the Exponential backoff algorithm. A certain back-off time is determined autonomously to avoid a collision with another wireless terminal.

  When the back-off time is completed, the wireless terminal transmits the RREQ using the corresponding Rch (MAC Frame 1 in FIG. 14). When there is a collision with Rch from another wireless terminal, retransmission is performed. When the base station successfully receives the RREQ, the base station notifies the RF channel of the next frame (MAC Frame 2 in FIG. 14) of the successful reception of the RREQ, and assigns a slot: Dch corresponding to the bandwidth request value from the RREQ. Further, in the next frame (MAC Frame 3 in FIG. 14) to which the Dch is assigned, an ARQ Cch for transmitting an arrival confirmation for data to the wireless terminal is assigned.

The configuration in which the base station allocates Dch in accordance with the RREQ bandwidth request value from the wireless terminal receives the RREQ from the wireless terminal, writes the bandwidth request value of the wireless terminal corresponding to the memory, and requests the bandwidth request by round robin. This is realized by reading the value. After allocating Dch, the base station allocates RREQ Rch to the remaining bandwidth.
M. Yamamoto, S. Machida, and H. Ikeda, “Access control scheme for multimedia ATM wireless local area networks,” IEICE Trans. Commun, vol.E81-B, no.11, pp, 2048-2055, Nov.1997 .

  However, in the above-described dynamic slot allocation method by random access, there is a high possibility that Rch will collide, especially when there are a large number of wireless terminals under the base station, and overhead associated with the collision occurs. This overhead is caused by the transmission waiting time based on the Exponential backoff algorithm, which degrades the throughput characteristics.

  The present invention has been made to solve the above problems, and its purpose is to reduce overhead associated with collision, and to improve throughput characteristics between a base station and a wireless terminal connected to the base station by a wireless line. An object of the present invention is to provide a radio communication method, a dynamic band allocation method, a data transmission method, a radio communication system, a base station, and a terminal station that can be improved.

  In order to solve the above problem, according to the present invention, a plurality of terminal stations are connected to a base station via a common radio channel, and the base station uses a slot to which a bandwidth has been allocated among slots for uplink communication in a radio frame as a demand. The assigned section and the remaining slots are managed as random access sections, the requested uplink communication slots are allocated to the bandwidth request information from the terminal station, and the terminal station backoffs when data to be transmitted occurs After the elapse of time, the bandwidth request information is randomly accessed and transmitted to the slots in the random access section. If the transmission fails, the random access transmission is performed again after the elapse of the back-off time. In the wireless communication method for transmitting the data using a reserved slot, the base station transmits the past traffic of the terminal station. The next data generation timing is predicted from the clock characteristics, and the slot is allocated to the radio frame corresponding to the predicted timing, and the terminal station is allocated a slot from the base station before the back-off time elapses. In some cases, the generated data scheduled to be transmitted after the lapse of the back-off time is transmitted, or the bandwidth request information is transmitted and the generated data is transmitted in the slot allocated from the base station based on the bandwidth request information. And a wireless communication method.

  Further, the present invention provides the above-described invention, wherein the base station uses the latest N pieces (N is an integer of 2 or more) of generated data information as past traffic characteristics of the terminal station, and the generated data The next data generation timing is predicted by using the longest interval among the intervals as the interval until the next data generation.

  Further, according to the present invention, in the above-described invention, when the terminal station cannot transmit all generated data in a slot allocated before the back-off time elapses, a capacity component corresponding to a bandwidth of the allocated slot is used. A part of the generated data is transmitted, and after the back-off time has elapsed, random access transmission is performed, and the remaining generated data is transmitted in the slot allocated from the base station.

  Further, according to the present invention, in the above-described invention, when the terminal station cannot transmit all generated data in a slot allocated before the back-off time elapses, a capacity component corresponding to a bandwidth of the allocated slot is used. Transmitting a part of the generated data, transmitting bandwidth request information for requesting a band necessary for transmitting the remaining generated data, and transmitting the remaining generated data in the slot allocated in the next radio frame and thereafter. It is characterized by.

  Further, in the present invention described above, in the above-described invention, when the terminal station cannot transmit all the generated data in the allocated slot before the back-off time elapses, the terminal station has a capacity corresponding to the generated data capacity in the allocated slot. Bandwidth request information for requesting a band is transmitted, and generated data is transmitted in slots assigned in subsequent radio frames.

  In the present invention, a plurality of terminal stations are connected to a base station through a common radio channel, and the base station uses a slot assigned for bandwidth allocation among slots for uplink communication in a radio frame as a demand assignment section and the remaining slots. As a random access section, and a dynamic bandwidth allocation method of a base station that allocates a requested uplink communication slot for bandwidth request information from the terminal station, which is based on the past traffic characteristics of the terminal station. The dynamic band allocation method is characterized in that the data generation timing is predicted and slot allocation is performed to the radio frame corresponding to the predicted timing.

  Further, according to the present invention, in the above-described invention, the latest N pieces (N is an integer of 2 or more) of generated data information is used as past traffic characteristics of the terminal station, and among the intervals between the generated data, The next data generation timing is predicted using the longest interval as the interval until the next data generation.

  In the present invention, a plurality of terminal stations are connected to a base station through a common radio channel, and the base station uses a slot assigned for bandwidth allocation among slots for uplink communication in a radio frame as a demand assignment section and the remaining slots. As a random access section, assigning a requested uplink communication slot to the bandwidth request information from the terminal station, and when the terminal station generates data to transmit, the bandwidth request information after the back-off time elapses Random access transmission to a slot in the random access section, if the transmission fails, the random access transmission again after the back-off time has passed, and if the transmission is successful, using the slot allocated from the base station A data transmission method for a terminal station that transmits data, wherein a slot is transmitted from the base station before the back-off time elapses. Is assigned, the generated data scheduled to be transmitted after the back-off time has passed is transmitted, or the bandwidth request information is transmitted and the slot allocated from the base station based on the bandwidth request information is transmitted. A data transmission method characterized by transmitting generated data.

  Further, according to the present invention, in the above-described invention, when all of the generated data cannot be transmitted in the slot allocated before the back-off time elapses, the generated data corresponding to the bandwidth of the allocated slot is stored. And transmitting the remaining generated data in the slot allocated from the base station after the back-off time has elapsed.

  Further, according to the present invention, in the above-described invention, when all of the generated data cannot be transmitted in the slot allocated before the back-off time elapses, the generated data corresponding to the bandwidth of the allocated slot is stored. And bandwidth request information for requesting a bandwidth necessary for transmitting the remaining generated data, and the remaining generated data is transmitted in slots allocated in the next radio frame and thereafter.

  Further, according to the present invention, in the above-described invention, when all of the generated data cannot be transmitted in the slot allocated before the back-off time elapses, a bandwidth for requesting a bandwidth corresponding to the capacity of the generated data in the allocated slot. The request information is transmitted, and the generated data is transmitted in the slot allocated after the next radio frame.

  Further, the present invention connects a plurality of terminal stations through a common wireless line, manages the bandwidth assigned slot among the slots for uplink communication in the radio frame as a demand assignment section, and manages the remaining slots as a random access section, Random access of bandwidth request information to slots in the random access section after the back-off time when a base station that allocates a requested uplink communication slot for bandwidth request information from the terminal station and data to be transmitted occur If the transmission is unsuccessful, the data is transmitted using random access means for performing random access transmission again after the back-off time has elapsed, and if the random access transmission is successful, the data is transmitted using the slot allocated from the base station. A wireless communication system comprising a terminal station having a transmitting means, The station predicts the next data generation timing from the past traffic characteristics of the terminal station, assigns a slot to a radio frame corresponding to the predicted timing, and the transmission means of the terminal station passes a back-off time If a slot has been allocated from the base station before, the generated data scheduled to be transmitted after the lapse of the back-off time is transmitted, or band request information is transmitted and the base station is transmitted based on the band request information. 1 is a wireless communication system characterized in that generated data is transmitted in slots assigned by

  Further, the present invention provides the above-described invention, wherein the base station uses the latest N pieces (N is an integer of 2 or more) of generated data information as past traffic characteristics of the terminal station, and the generated data The next data generation timing is predicted by using the longest interval among the intervals as the interval until the next data generation.

  Further, the present invention is the above-described invention, wherein the transmission means of the terminal station corresponds to the bandwidth of the allocated slot when the generated data cannot be transmitted in the allocated slot before the back-off time elapses. A part of the generated data for the capacity to be transmitted, random access transmission by the random access means after the back-off time has elapsed, and the remaining generated data is transmitted in the slot allocated from the base station To do.

  Further, the present invention is the above-described invention, wherein the transmission means of the terminal station corresponds to the bandwidth of the allocated slot when the generated data cannot be transmitted in the allocated slot before the back-off time elapses. A part of the generated data for the capacity to be transmitted is transmitted and the bandwidth request information for requesting the bandwidth necessary for transmitting the remaining generated data is transmitted, and the remaining generated data is transmitted in the slot allocated in the next radio frame and thereafter. It is characterized by transmitting.

  Further, in the present invention described above, when the transmission means of the terminal station cannot transmit all of the generated data in the allocated slot before the back-off time elapses, the generated data is transmitted in the allocated slot. Bandwidth request information for requesting a bandwidth corresponding to the bandwidth is transmitted, and generated data is transmitted in slots allocated in the subsequent radio frames and thereafter.

  Further, the present invention connects a plurality of terminal stations through a common wireless line, manages the bandwidth assigned slot among the slots for uplink communication in the radio frame as a demand assignment section, and manages the remaining slots as a random access section, A base station that allocates a requested uplink communication slot for bandwidth request information from the terminal station, predicting the next data generation timing from the past traffic characteristics of the terminal station, and corresponding to the predicted timing The base station is characterized in that slot allocation is performed for a radio frame to be transmitted.

  Further, according to the present invention, in the above-described invention, the latest N pieces (N is an integer of 2 or more) of generated data information is used as past traffic characteristics of the terminal station, and among the intervals between the generated data, The next data generation timing is predicted using the longest interval as the interval until the next data generation.

  Further, the present invention connects a plurality of terminal stations through a common wireless line, manages the bandwidth assigned slot among the slots for uplink communication in the radio frame as a demand assignment section, and manages the remaining slots as a random access section, Random access of bandwidth request information to slots in the random access section after the back-off time when a base station that allocates a requested uplink communication slot for bandwidth request information from the terminal station and data to be transmitted occur If the transmission is unsuccessful, the data is transmitted using random access means for performing random access transmission again after the back-off time has elapsed, and if the random access transmission is successful, the data is transmitted using the slot allocated from the base station. A terminal station in a wireless communication system comprising a terminal station having a transmission means When the slot is allocated from the base station before the back-off time elapses, the transmission means transmits the generated data scheduled to be transmitted after the back-off time elapses, or the bandwidth request A terminal station that transmits information and transmits generated data in a slot allocated from the base station based on the bandwidth request information.

  Further, in the present invention described above, in the above-described invention, when the transmission unit cannot transmit all the generated data in the slot allocated before the back-off time elapses, a capacity component corresponding to the bandwidth of the allocated slot is used. A part of the generated data is transmitted, and after the back-off time has elapsed, the random access means performs random access transmission, and the remaining generated data is transmitted in the slot allocated from the base station.

  Further, in the present invention described above, in the above-described invention, when the transmission unit cannot transmit all the generated data in the slot allocated before the back-off time elapses, a capacity component corresponding to the bandwidth of the allocated slot is used. Transmitting a part of the generated data, transmitting bandwidth request information for requesting a band necessary for transmitting the remaining generated data, and transmitting the remaining generated data in the slot allocated in the next radio frame and thereafter. It is characterized by.

  Further, in the present invention described above, when the transmission means cannot transmit all generated data in the slot allocated before the back-off time elapses, it corresponds to the band of the generated data in the allocated slot. The bandwidth request information for requesting the bandwidth corresponding to the capacity to be transmitted is transmitted, and the generated data is transmitted in the slot allocated in the next radio frame and thereafter.

  According to this invention, the base station predicts the next data generation timing from the past traffic characteristics of the terminal station, assigns a slot to the radio frame corresponding to the predicted timing, and the terminal station If a slot is allocated from the base station before the elapse of time, the generated data scheduled to be transmitted after the lapse of the back-off time is transmitted, or band request information is transmitted and the band request information is transmitted based on the band request information. The generated data is transmitted in the slot allocated from the base station. This makes it possible to predict the next data generation from the traffic characteristics of the data generated by the terminal station, assign bandwidth request information and data transmission slots to the demand assignment section in the prediction frame, and reduce overhead by avoiding collisions Thus, the throughput characteristics can be improved. In addition, the terminal station basically makes a bandwidth request using random access, but if there is slot allocation (polling) from the base station during the bag-off, the random access is stopped to cancel the random access. This has the effect of reducing traffic.

  According to the present invention, the base station uses the latest N pieces (N is an integer of 2 or more) of generated data information as the past traffic characteristics of the terminal station, and the longest interval among the intervals between the generated data. Is the interval until the next data generation, and the next data generation timing is predicted. By determining the prediction frame based on the longest occurrence interval, it is possible to completely cope with any occurrence interval within the measurement interval, and it is possible to minimize the waste of bandwidth.

  Also, according to the present invention, when the terminal station cannot transmit all the generated data in the slot allocated before the back-off time has elapsed, a part of the generated data for the capacity corresponding to the bandwidth of the allocated slot Is transmitted at random after the back-off time has elapsed, and the remaining generated data is transmitted in the slot allocated from the base station. As a result, even when the capacity of data to be transmitted is larger than the bandwidth of the allocated slot, it is possible to continue the process for transmission by random access and transmit all data.

  Also, according to the present invention, when the terminal station cannot transmit all the generated data in the slot allocated before the back-off time has elapsed, a part of the generated data for the capacity corresponding to the bandwidth of the allocated slot And the bandwidth request information for requesting the bandwidth required for transmitting the remaining generated data is transmitted, and the remaining generated data is transmitted in the slots allocated in and after the next radio frame. As a result, even when the amount of data to be transmitted is large, it is possible to transmit all the data because a further required bandwidth is requested.

  Further, according to the present invention, when the terminal station cannot transmit all the generated data in the slot allocated before the back-off time elapses, the terminal station requests a band for the capacity of the generated data in the allocated slot. Information is transmitted, and generated data is transmitted in slots allocated in the subsequent radio frames and thereafter. As a result, even if the capacity of data to be transmitted is larger than the bandwidth of the allocated slot, all the data can be transmitted because the required bandwidth is requested again.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic block diagram illustrating a wireless communication system according to an embodiment of the present invention. The wireless communication system includes a base station 1 and wireless terminals 2-1 to 2-N (hereinafter referred to as wireless terminals 2 when representative of wireless terminals). . The base station 1 is a device that includes a bandwidth allocating unit that executes a dynamic slot allocation method to be described later, and a transmitting / receiving unit that transmits and receives control information and data to and from the wireless terminal 2. The radio terminal 2 receives a control information from the base station 1 and a random access unit that transmits control information for random access in a random access section after the back-off time has elapsed, and is assigned based on the received control information And a transmission / reception unit that transmits RREQ or data.

(Embodiment on the base station side)
Next, a dynamic slot allocation method in the base station 1 that improves the throughput characteristics between the base station 1 and the wireless terminal 2 will be described. In the dynamic slot allocation method according to the present embodiment, the base station 1 predicts the next data generation from the traffic characteristics of the wireless terminal 2 by calculation described later, and performs slot allocation in advance in the demand assignment section of the predicted frame. In this way, the collision is eliminated and the transmission of the next data is made more efficient.

  When the base station 1 receives data from the wireless terminal 2, the base station 1 calculates a data generation interval from the data generation time information attached to the data. Further, the base station 1 predicts a frame in which the next data is generated from the latest fixed period (a fixed number) of data generation intervals, and a slot for RREQ or a slot for data in the demand assignment section of the predicted frame. Are assigned in advance.

  The wireless terminal 2 transmits the time information when the data is generated at the time of data transmission together with the data. As this time information, the Bch frame number when the MAC layer of the wireless terminal 2 receives data from the upper layer is used. When the wireless terminal 2 receives user data from the upper layer, the wireless terminal 2 starts an access sequence using random access for bandwidth request. If an RREQ or data slot is allocated from the base station 1 before the back-off time elapses, random access is stopped and RREQ or data is transmitted to the allocated slot. .

Next, a method for determining a frame in which next data is generated, that is, a predicted frame, performed by the base station 1 for each wireless terminal in the present embodiment will be described with reference to FIG. Here, the base station 1 receives the Mth data having the generation time information: FD _(M) from a certain wireless terminal 2, and then the (M + 1) th data (occurrence time) in the current frame: _Fcur. Information: FD _{(M + 1)} ) is received. Upon receiving the data, the base station 1 calculates a data generation interval (GI) (Step Sa1) and holds the latest N GIs in the memory (Step Sa2: Yes). The GI is calculated from the occurrence time information: FD _{(M + 1)} −FD _(M) . In the base station 1, GI _max having the longest occurrence interval is selected from the latest N GIs, and a frame (predicted frame: PF _next ) in which the next data, that is, (M + 2) -th data is generated, is expressed as _{FD (M + 1). )} + GI _max is determined (step Sa3). In step Sa2, if the number is less than N, the process is terminated (step Sa2: No).

If PF _next is not a frame after the current frame: F _cur (step Sa4: No), it is determined that data has already been generated and held, and the predicted frame is changed to the next frame: F _cur +1 ( Step Sa5). Finally, the base station 1 updates the predicted frame information on the memory (step Sa6).

If PF _next is a frame after the current frame: F _cur (step Sa4: Yes), the predicted frame is left as it is. Finally, the base station 1 updates the predicted frame information on the memory (step Sa6). When the RREQ is received from the wireless terminal 2 by random access after the prediction frame is updated, the prediction frame is deleted. When the RREQ by random access is not received from the wireless terminal 2 before the prediction frame, the base station 1 tries to allocate a slot for RREQ or a slot for data in the prediction frame.

(First embodiment on the wireless terminal side)
Next, as a first embodiment of the radio terminal, a radio terminal 2a to which an RREQ slot for data transmission is assigned in a prediction frame will be described. Since the allocation is in the demand assignment section, Cch is used. FIG. 3 is a flowchart showing RREQ transmission processing in the wireless terminal 2a.

  First, when the wireless terminal 2a receives user data from an upper layer, it starts an access sequence using random access for RREQ transmission (step Sb1). First, the number of backoff slots (BO_Num) waiting for transmission is determined by the backoff algorithm, and the determined number of backoff slots is set (step Sb2).

  The wireless terminal 2a receives Bch, RFch, and Fch (step Sb3). By receiving Bch, the attributes (base station ID, frame number, etc.) of the base station 1 are acquired in the wireless terminal 2a. By receiving RFch, the random access start position and Rch number in the current frame are acquired. Also, by receiving Fch, it is determined whether there is an RREQ Cch assignment addressed to itself in the current frame (step Sb4).

  In the current frame, the flow differs depending on whether or not Cch is assigned. If there is Cch assignment (step Sb4: Yes), the random access sequence is stopped, and the access sequence by Cch polling shown in FIG. 4 is started. The wireless terminal 2a transmits the RREQ in the designated Cch in the current frame (MACFrame 1 in FIG. 4) (step Sb5). In the base station 1, when the RREQ Cch is allocated in the prediction frame, the ARQ Cch for notifying the reception result of the Cch in the next frame (MAC Frame 2 in FIG. 4) is the same as the RREQ Cch described above. Assign as a pair. In the base station 1, when the RREQ can be normally received, the Dch for user data corresponding to the bandwidth request value of the RREQ is allocated to the demand assignment section. In addition, an ARQ Cch for notifying the wireless terminal 2a of the Dch reception result is allocated.

  On the other hand, if there is no Cch assignment in the current frame, transmission by random access is attempted. The Rch number (RA_Num) in the current frame and the backoff slot number (BO_Num) are compared (step Sb6). If the Rch number is smaller than the backoff slot number (step Sb6: Yes), transmission in the current frame is performed. First, the number of back-off slots is updated with the number of slots obtained by subtracting the number of Rch from the number of back-off slots (step Sb8). If the number of Rch is equal to or greater than the number of backoff slots (step Sb6: No), transmission in the current frame is possible, and therefore, RREQ is transmitted using the Rch with the number of backoff slots (step Sb7).

  In the base station 1, Dch for user data is allocated according to the RREQ bandwidth request value from the radio terminal 2a. When receiving the RREQ, the base station 1 writes the bandwidth request value in the memory corresponding to the received wireless terminal 2a. At the time of Dch allocation, the bandwidth request value on the memory is read by round robin, FIFO (First-In-First-Out), or the like. In the slot assignment, after assigning Dch for user data, after assigning Cch for RREQ of the radio terminal 2a whose scheduling frame is a prediction frame to the remaining band, the remaining band is used for RREQ. Assign to Rch.

(Second embodiment on the wireless terminal side)
Next, as a second embodiment of the wireless terminal, a wireless terminal 2b to which a slot for user data is assigned in a prediction frame is shown. FIG. 5 is a flowchart showing RREQ or data transmission processing in the wireless terminal 2b.

  First, when the wireless terminal 2b receives user data from an upper layer, the wireless terminal 2b starts an access sequence using random access for RREQ transmission (step Sc1). First, the backoff slot number (BO_Num) waiting for transmission is determined and set by the backoff algorithm (step Sc2).

  The wireless terminal 2b receives Bch, RFch, and Fch (step Sc3). By receiving Bch, the wireless terminal 2b acquires the attributes (base station ID, frame number, etc.) of the base station 1. By receiving RFch, the random access start position and Rch number in the current frame are acquired. Also, by receiving Fch, it is determined whether or not there is Dch assignment for data addressed to itself in the current frame (step Sc4).

  In the current frame, the flow differs depending on whether or not Dch is assigned. If there is Dch assignment (step Sc4: Yes) and transmission is performed in the current frame, the random access sequence is stopped and the access sequence by Dch polling is started. On the other hand, if there is no Dch assignment in the current frame (step Sc4: No), transmission by random access is attempted. The Rch number (RA_Num) in the current frame and the backoff slot number (BO_Num) are compared (step Sc6). If the Rch number is smaller than the backoff slot number (step Sc6: Yes), transmission in the current frame is performed. First, the number of back-off slots is updated with the number of slots obtained by subtracting the number of Rch from the number of back-off slots (step Sc8). If the number of Rch is greater than or equal to the number of backoff slots (step Sc6: No), since transmission in the current frame is possible, RREQ is transmitted using the Rch of the number of backoff slots (step Sc7).

  If there is a Dch assignment in step Sc4, the access sequence shown in FIG. 6 is started, and the wireless terminal 2b transmits data using the designated Dch (step Sc5).

  Furthermore, in step Sc4, when there is a Dch assignment, the size assigned in the Dch may be compared with the transmission data size. If the allocated size is equal to or larger than the transmission data size, the data can be completely transmitted in the current frame, and the access sequence shown in FIG. Is transmitted by the designated Dch.

  On the other hand, when the allocated size is smaller than the transmission data size, it is impossible to completely transmit the data in the current frame. Therefore, the following transmission methods can be used.

(Transmission method 1) For example, there is a method of continuing the random access sequence in order to perform transmission by random access without performing transmission using the assigned Dch.

(Transmission method 2) Further, there is a method of performing divided transmission of data for the assigned Dch. In this method, the following two methods can be further employed.

  In the first method, after the divided data is transmitted to the assigned Dch, the remaining data is transmitted by random access. In this method, the random access sequence is started after the divided data is transmitted.

  The second method transmits an RREQ in which the divided data and the bandwidth request value of the remaining data are set to the assigned Dch. In this method, the access sequence shown in FIG. The RREQ is set and the bandwidth request value for the remaining data is set together with the divided data, and transmitted in the allocation Dch. In the second embodiment, when both the access sequence shown in FIG. 7 and the access sequence shown in FIG. 6 are supported, even if data can be transmitted using the assigned Dch shown in FIG. Band request value = 0) may be transmitted. When data is divided, it is necessary to add an information element that allows the base station 1 to detect that the data is divided in the divided data.

(Transmission method 3) Further, there is a method of transmitting an RREQ including a Cch bandwidth request value to the assigned Dch. FIG. 8 shows an access sequence of this method. This method does not divide the data into transmittable data as in (Transmission method 2) described above, but uses the allocated Dch for transmission of RREQ (Cch). In this method, it is not necessary to divide and transmit data, and it is not always necessary to add RREQ to the data. However, since the base station 1 may receive Cch by Dch, it is necessary to add an information element for identifying a channel type in transmission data.

  In the base station 1, when allocating Dch or Cch for data in the prediction frame, ARQ Cch for notifying the reception result of Dch or Cch in the next frame is referred to as Dch or Cch for data described above. Assign as a pair.

  The slot length of Dch allocated in the prediction frame in the base station 1 is the data length received last time, the data length declared from the wireless terminal 2b at the start of communication, the data length at the time of contract, the total received data, the specified time, or the specified number of receptions. It is determined by the average data length.

  The base station 1 assigns Dch slots for user data, and then assigns Dch to the remaining bandwidth based on the predicted frame. However, when data division occurs in the second method (transmission method 2) described above, Dch for divided data is assigned with priority over the predicted frame. After assigning with the prediction frame, Dch is assigned to the remaining band according to RREQ. Then, the remaining bandwidth is allocated to the RREQ Rch.

  In the first and second embodiments on the two wireless terminals, the sequence for notifying the reception result for data is shown. However, the reception result is required at the transmission source as in UDP (User Datagram Protocol). In the data transmission not to be performed, a sequence in which there is no reception notification slot for data is obtained.

(simulation result)
The simulation results of the method according to the present invention (when the wireless terminals 2a and 2b of the first and second embodiments are applied) and the conventional method are shown below. FIG. 9 is a diagram showing the relationship between MAC-PDU and PHY-PDU applied to the simulation. FIG. 10 is a diagram showing simulation parameters. FIG. 11 shows the simulation results of the throughput characteristics performed under the conditions of FIGS. 9 and 10, and FIG. 12 shows the simulation results of the delay characteristics.

  As shown in FIG. 10, the traffic of the wireless terminals 2a and 2b is evaluated for a case where the data length is 40 bytes and the data generation interval (average is 100 sec) follows a constant (Posson) and Poisson distribution (Poisson). Further, traffic load: 1.0 represents a wireless transmission capacity (9600 bits), and using this, the number of wireless terminals is calculated as follows. That is, it is calculated by calculating the wireless transmission rate (9600 bps) × traffic load / data length (40 bytes) / average of data generation interval (100 sec).

  FIG. 11 shows that the method according to the present invention can achieve a higher throughput than the conventional method regardless of the traffic characteristics. From FIG. 12, it can be seen that the method according to the present invention has a lower delay than the conventional method regardless of the traffic characteristics.

  With the configuration of each of the above embodiments, the occurrence of the next data is predicted from the traffic characteristics of the wireless terminals 2a and 2b, and the overhead is reduced by collision avoidance every time RREQ or user data is assigned to the demand assignment section in the predicted frame. And throughput characteristics can be improved. Also, with this configuration, periodic traffic can be efficiently accommodated by the polling method. In addition, the data generation interval from the wireless terminals 2a and 2b in the latest fixed period is measured, and the prediction frame is determined based on the longest generation interval so that any occurrence interval within the measurement interval can be completely accommodated. By doing so, it is possible to minimize the waste of bandwidth due to polling. In addition, the wireless terminals 2a and 2b basically make a bandwidth request using random access, but if there is polling from the base station 1 during the back-off period, the random access is stopped and transmission by polling is performed. Therefore, the delay characteristic can be reduced.

  The configuration of the above embodiment is described based on the frame configuration of the prior art shown in FIG. 13, but the present invention is not limited to this embodiment. For example, the order of Bch, RFch, Fch, etc. is changed. Even a frame like this can be applied.

1 is a schematic block diagram showing a wireless communication system of the present invention. It is the flowchart which showed the process by embodiment by the side of the base station of this invention. It is the flowchart which showed the process by 1st Embodiment by the side of the radio | wireless terminal of this invention. It is the figure which showed the access sequence which concerns on the radio | wireless terminal of 1st Embodiment. It is the flowchart which showed the process by 2nd Embodiment by the side of the radio | wireless terminal of this invention. It is the figure which showed the access sequence (the 1) which concerns on the radio | wireless terminal of 2nd Embodiment. It is the figure which showed the access sequence (the 2) which concerns on the radio | wireless terminal of 2nd Embodiment. It is the figure which showed the access sequence (the 3) which concerns on the radio | wireless terminal of 2nd Embodiment. It is the figure which showed the relationship between MAC-PDU and PHY-PDU applied to the simulation of 1st and 2nd embodiment. It is the figure which showed the parameter applied to the simulation. It is the figure which showed the result of the throughput characteristic of the same simulation. It is the figure which showed the result of the delay characteristic of the same simulation. It is the figure which showed the frame structure in a prior art. It is the figure which showed the access sequence in a prior art.

Explanation of symbols

1 Base station 2-1 to 2-N Wireless terminal

Claims (22)

A plurality of terminal stations are connected to a base station via a common radio channel, and the base station manages a slot to which a bandwidth has been allocated among uplink communication slots in a radio frame as a demand assignment section and the remaining slots as a random access section. Then, the requested uplink communication slot is allocated to the bandwidth request information from the terminal station, and when the data to be transmitted is generated, the terminal station transmits the bandwidth request information within the random access interval after the back-off time has elapsed. Wireless communication that performs random access transmission to the slot, transmits the data again after the back-off time elapses if transmission fails, and transmits the data using the slot allocated from the base station if transmission is successful In the method
The base station predicts the next data generation timing from the past traffic characteristics of the terminal station, performs slot allocation to a radio frame corresponding to the predicted timing,
If a slot is allocated from the base station before the back-off time elapses, the terminal station transmits generated data scheduled to be transmitted after the back-off time elapses or transmits bandwidth request information The generated data is transmitted in the slot allocated from the base station based on the bandwidth request information. The base station
As the past traffic characteristics of the terminal station, the latest N generated data information (N is an integer of 2 or more) is used, and the longest interval among the generated data is set as the interval until the next data generation. The wireless communication method according to claim 1, wherein the data generation timing is predicted. The terminal station
If all of the generated data cannot be transmitted in the allocated slot before the back-off time elapses, a part of the generated data for the capacity corresponding to the bandwidth of the allocated slot is transmitted, and random access transmission is performed after the back-off time elapses The remaining generated data is transmitted in the slot allocated from the base station. The wireless communication method according to claim 1, wherein: The terminal station
If all the generated data cannot be transmitted in the allocated slot before the back-off time elapses, a part of the generated data corresponding to the allocated slot bandwidth is transmitted and the remaining generated data is transmitted. The wireless communication method according to claim 1, further comprising: transmitting bandwidth request information for requesting a bandwidth required for transmitting and transmitting remaining generated data in a slot allocated in a subsequent wireless frame. The terminal station
If all of the generated data cannot be transmitted in the allocated slot before the back-off time elapses, bandwidth request information requesting a bandwidth corresponding to the capacity of the generated data is transmitted in the allocated slot, and is allocated in the next radio frame and later. The wireless communication method according to claim 1, wherein generated data is transmitted in a slot. A plurality of terminal stations are connected to a base station via a common radio channel, and the base station manages a slot to which a bandwidth has been allocated among uplink communication slots in a radio frame as a demand assignment section and the remaining slots as a random access section. A base station dynamic band allocation method for allocating a requested uplink communication slot for band request information from the terminal station,
A dynamic band allocation method, wherein the next data generation timing is predicted from past traffic characteristics of the terminal station, and slot allocation is performed to a radio frame corresponding to the predicted timing. As the past traffic characteristics of the terminal station, the latest N generated data information (N is an integer of 2 or more) is used, and the longest interval among the generated data is set as the interval until the next data generation. The dynamic band allocation method according to claim 6, wherein the data generation timing is predicted. A plurality of terminal stations are connected to a base station via a common radio channel, and the base station manages a slot to which a bandwidth has been allocated among uplink communication slots in a radio frame as a demand assignment section and the remaining slots as a random access section. Then, the requested uplink communication slot is allocated to the bandwidth request information from the terminal station, and when the data to be transmitted is generated, the terminal station transmits the bandwidth request information within the random access interval after the back-off time has elapsed. Random access transmission to the slot, if the transmission fails, the random access transmission again after the back-off time has elapsed, and if the transmission is successful, the terminal station that transmits the data using the slot allocated from the base station The data transmission method of
When a slot is allocated from the base station before the back-off time elapses, the generated data scheduled to be transmitted after the back-off time elapses or the bandwidth request information is transmitted and the bandwidth request information is transmitted. The generated data is transmitted in the slot allocated from the base station based on the above. If all of the generated data cannot be transmitted in the allocated slot before the back-off time elapses, a part of the generated data for the capacity corresponding to the bandwidth of the allocated slot is transmitted, and random access transmission is performed after the back-off time elapses 9. The data transmission method according to claim 8, wherein the remaining generated data is transmitted in a slot allocated from the base station. If all the generated data cannot be transmitted in the allocated slot before the back-off time elapses, a part of the generated data corresponding to the allocated slot bandwidth is transmitted and the remaining generated data is transmitted. 9. The data transmission method according to claim 8, further comprising: transmitting bandwidth request information for requesting a bandwidth required for transmitting and transmitting the remaining generated data in a slot allocated after the next radio frame. If all of the generated data cannot be transmitted in the allocated slot before the back-off time elapses, bandwidth request information requesting a bandwidth corresponding to the capacity of the generated data is transmitted in the allocated slot, and is allocated in the next radio frame and later. 9. The data transmission method according to claim 8, wherein the generated data is transmitted in a slot. A plurality of terminal stations are connected by a common radio line, and among the slots for uplink communication in the radio frame, the allocated slots are managed as demand assignment sections, and the remaining slots are managed as random access sections. If the base station that allocates the requested uplink communication slot for the request information and the data to be transmitted occur, the bandwidth request information is randomly accessed to the slot in the random access section after the back-off time elapses, and the transmission fails. A random access means for performing random access transmission after the back-off time has elapsed, and a transmission means for transmitting the data using a slot allocated from the base station when the random access transmission is successful. A wireless communication system comprising a station,
The base station predicts the next data generation timing from the past traffic characteristics of the terminal station, performs slot allocation to a radio frame corresponding to the predicted timing,
The transmission means of the terminal station, when a slot is allocated from the base station before the back-off time elapses, transmits generated data scheduled to be transmitted after the back-off time elapses, or a bandwidth request A wireless communication system, wherein information is transmitted and generated data is transmitted in a slot allocated from the base station based on the bandwidth request information. The base station
As the past traffic characteristics of the terminal station, the latest N generated data information (N is an integer of 2 or more) is used, and the longest interval among the generated data is set as the interval until the next data generation. The wireless communication system according to claim 12, wherein the data generation timing is predicted. The transmission means of the terminal station is
If all of the generated data cannot be transmitted in the allocated slot before the back-off time elapses, a part of the generated data for the capacity corresponding to the bandwidth of the allocated slot is transmitted, and the random access is performed after the back-off time elapses. The wireless communication system according to claim 12, wherein random access transmission is performed by the means, and the remaining generated data is transmitted in a slot allocated from the base station. The transmission means of the terminal station is
If all the generated data cannot be transmitted in the allocated slot before the back-off time elapses, a part of the generated data corresponding to the allocated slot bandwidth is transmitted and the remaining generated data is transmitted. 13. The wireless communication system according to claim 12, wherein bandwidth request information for requesting a bandwidth necessary for transmission is transmitted, and remaining generated data is transmitted in slots allocated in subsequent radio frames. The transmission means of the terminal station is
If all the generated data cannot be transmitted in the allocated slot before the back-off time elapses, band request information for requesting a bandwidth corresponding to the generated data band is transmitted in the allocated slot, and the next radio frame is transmitted. 13. The wireless communication system according to claim 12, wherein the generated data is transmitted in slots assigned thereafter. A plurality of terminal stations are connected by a common radio line, and among the slots for uplink communication in the radio frame, the allocated slots are managed as demand assignment sections, and the remaining slots are managed as random access sections. A base station that allocates a requested slot for request information to request information,
A base station that predicts the next data generation timing from past traffic characteristics of the terminal station, and performs slot allocation to a radio frame corresponding to the predicted timing. As the past traffic characteristics of the terminal station, the latest N generated data information (N is an integer of 2 or more) is used, and the longest interval among the generated data is set as the interval until the next data generation. The base station according to claim 17, wherein the data generation timing is predicted. A plurality of terminal stations are connected by a common radio line, and among the slots for uplink communication in the radio frame, the allocated slots are managed as demand assignment sections, and the remaining slots are managed as random access sections. If the base station that allocates the requested uplink communication slot for the request information and the data to be transmitted occur, the bandwidth request information is randomly accessed to the slot in the random access section after the back-off time elapses, and the transmission fails. A random access means for performing random access transmission after the back-off time has elapsed, and a transmission means for transmitting the data using a slot allocated from the base station when the random access transmission is successful. A terminal station in a wireless communication system comprising a station,
The transmission means includes
When a slot is allocated from the base station before the back-off time elapses, the generated data scheduled to be transmitted after the back-off time elapses or the bandwidth request information is transmitted and the bandwidth request information is transmitted. The generated data is transmitted in a slot allocated from the base station based on the terminal station. The transmission means includes
If all of the generated data cannot be transmitted in the allocated slot before the back-off time elapses, a part of the generated data for the capacity corresponding to the bandwidth of the allocated slot is transmitted, and the random access is performed after the back-off time elapses. The terminal station according to claim 19, wherein the terminal station performs random access transmission and transmits the remaining generated data in a slot allocated from the base station. The transmission means includes
If all the generated data cannot be transmitted in the allocated slot before the back-off time elapses, a part of the generated data corresponding to the allocated slot bandwidth is transmitted and the remaining generated data is transmitted. 20. The terminal station according to claim 19, wherein band request information requesting a band required for the transmission is transmitted, and the remaining generated data is transmitted in a slot allocated in the subsequent radio frame. The transmission means includes
If all the generated data cannot be transmitted in the allocated slot before the back-off time elapses, band request information for requesting a bandwidth corresponding to the generated data band is transmitted in the allocated slot, and the next radio frame is transmitted. The terminal station according to claim 19, wherein the generated data is transmitted in a slot allocated thereafter.

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