JP2004040363A - Wireless communications system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wireless communications system provided for enabling a base station unit and a plurality of customer premises units covered by the base station unit to wirelessly communicate data with efficiency using data traffic channels. <P>SOLUTION: A data traffic channel is assigned to customer premises units C1 to C3 by limiting the data traffic channel capable of being assigned to each of the customer premises units C1 to C3, and the base station unit B and the customer premises units C1 to C3 make wireless communication of data with each other by using the assigned part of the data traffic channels to the customer premises units C1 to C3. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to, for example, a wireless access system such as a subscriber wireless access system that performs wireless communication between a fixedly installed base station apparatus and a fixedly installed subscriber station apparatus, and in particular, For example, by realizing a wireless band guarantee function by flow rate limitation (shaping) related to data communication channel allocation, a best effort type communication function by shared use of data communication channels, and a wireless band guarantee function by class-based scheduling, etc. The present invention relates to a wireless communication system for improving the efficiency of data communication.
[0002]
[Prior art]
In a wireless access system, a wireless medium is used as a medium for transmitting a signal to be communicated. Generally, a wireless medium is allocated to each base station device (wireless base station device) and is shared by a plurality of subscriber station devices (wireless subscriber station devices) existing in a service area managed by each base station device. .
[0003]
For example, when a base station device and a backbone LAN (Local Area Network) or a subscriber station device and a subscriber terminal device are connected by Ethernet (registered trademark) and IEEE 802.3 wired LAN interfaces, wireless communication is performed. The data transmitted and received via the medium is classified into data having an individual address addressed to each subscriber terminal and data having an address assigned to address a plurality of subscriber terminals. Separated.
[0004]
Here, a packet used for communicating data having an individual address addressed to each subscriber terminal device corresponding to the former is called a unicast packet, and an address addressed to a plurality of subscriber station devices corresponding to the latter is referred to as a unicast packet. A packet used to communicate data having a is called a broadcast packet.
[0005]
Further, the base station device needs to be equipped with a function of controlling the assignment of data communication channels in order to effectively use the wireless band. For example, a subscriber station device having a larger number of subscriber terminal devices accommodated in the service area of its own station is considered to generate more traffic (amount of data to be communicated). It is considered that a sufficient data communication service cannot be provided unless it is secured. Therefore, conventionally, it has been studied to allocate a data communication channel by a method of allocating a dedicated radio band to each subscriber station device according to the number of subscriber terminal devices accommodated by each subscriber station device. Was.
[0006]
An outline of a subscriber wireless access system that has been developed in recent years will be described below.
In recent years, for example, a subscriber wireless access system using wireless communication called WLL (Wireless Local Loop) or FWA (Fixed Wireless Access) has been developed and put into practical use. Further, with the spread of the Internet, there is an increasing demand for high-speed, large-capacity communication using wireless media.
[0007]
In the above-described subscriber wireless access system, a base station apparatus (BSE: Base Station Equipment) connected to a backbone network such as a public line network is fixedly installed at a high place such as a building roof or a tower, and a plurality of subscribers are installed. A customer station device (CPE: Customer Premises Equipment) is fixedly installed at a high place such as the roof of a subscriber's house building, and a communication terminal device (subscriber terminal device) such as a personal computer (PC) is installed in the subscriber station device. ) And a LAN to which such a communication terminal device is connected.
[0008]
Here, the base station device and the subscriber station device are, for example, an outdoor unit (ODU: Out Door Unit) fixedly installed at a high place such as a building roof or a tower, and an indoor unit (ODU) fixedly installed inside a building or the like. IDU: In Door Unit) with a cable. The outdoor unit of the base station device or the subscriber station device includes a wireless processing unit that performs wireless communication processing using an antenna, and mainly manages wireless communication processing. Further, the indoor unit of the base station device mainly controls data communication with the backbone network, and the indoor unit of the subscriber station device mainly controls data communication with the communication terminal device and the LAN.
[0009]
Further, in the above-described subscriber wireless access system, for example, the base station apparatus and the subscriber station apparatus are accommodated in the same base station apparatus by performing wireless communication using a communication method of performing time-division transmission using a wireless frame. Communicable connection between LANs and the like connected to different subscriber station devices for data communication, and communication between a backbone network connected to the base station device and a LAN and the like connected to the subscriber station device It is possible to perform data communication by connecting as possible.
[0010]
[Problems to be solved by the invention]
However, when a data communication channel is allocated by a method of allocating a dedicated wireless band to each subscriber station device as shown in the above-described conventional example, the following problems (1) to (3) occur. there were.
(1) For example, when data communication channels are fixedly allocated, there is a problem that it is impossible to cope with burst traffic as described below. In other words, where the use status of the subscriber terminal device accommodated by the subscriber station device or the number of subscriber terminal devices accommodated by the subscriber station device fluctuates, burst traffic of the LAN may occur. Despite such bursty traffic, the wireless band is occupied by a specific subscriber station device, so that a certain wireless medium allocated to the base station device cannot be effectively used. was there.
[0011]
(2) In contrast to the above (1), when a wireless medium is used as a shared band, for example, as described below, when a burst traffic is handled, another subscriber station apparatus is used. Wireless bandwidth cannot be guaranteed. That is, when a large number of wireless bands are allocated to a specific subscriber station device in response to the bursty traffic of the LAN, the available wireless band for each subscriber station device fluctuates, There is a problem that the minimum wireless band required for data communication cannot be guaranteed.
[0012]
(3) In the conventional data communication channel allocation, for example, with respect to a subscriber station apparatus accommodated in the same base station apparatus, a part of the radio band is reserved as a dedicated band for a specific subscriber station apparatus. However, there is a problem that the remaining wireless band cannot be used as a shared band.
[0013]
The present invention has been made to solve such a conventional problem. When a base station device and a plurality of subscriber station devices communicate data wirelessly using a data communication channel, the efficiency of data communication is improved. It is an object of the present invention to provide a wireless communication system capable of allocating a data communication channel to be converted. Note that, specifically, the present invention realizes providing a wireless communication system or the like that can solve any of the problems (1) to (3) or two or more of the problems.
[0014]
[Means for Solving the Problems]
In order to achieve the above object, in a wireless communication system according to the present invention, when a base station device and a plurality of subscriber station devices accommodated in the base station device wirelessly communicate data using a data communication channel, The data communication channel is allocated as follows.
That is, a data communication channel that can be assigned to each subscriber station device is limited to allocate a data communication channel to the subscriber station device, and the base station device and the subscriber station device communicate with the data communication channel to the subscriber station device. Wirelessly communicate data using the assigned part of.
[0015]
Therefore, by limiting the data communication channel that can be assigned to each subscriber station device and allocating the data communication channel, it is possible to differentiate, for example, the wireless band guaranteed between the subscriber station devices, For example, it is also possible to dynamically assign a data communication channel in accordance with a communication situation while limiting the assignment of a data communication channel to each subscriber station apparatus, thereby making it possible to increase the efficiency of data communication.
[0016]
Here, between the base station device and the subscriber station device, there are uplink communication for communicating data from the subscriber station device to the base station device and downlink communication for communicating data from the base station device to the subscriber station device. Either one may be performed, or both may be performed. The present invention can be applied to either one of uplink communication and downlink communication, or can be applied to both.
[0017]
Various modes may be used to limit the data communication channels that can be allocated to each subscriber station device. For example, a mode that limits the number of data of a communication unit that can be allocated, Modes that limit the number of slots that can be allocated, modes that limit the number of packets that can be allocated, modes that limit the amount of data communication that can be allocated, modes that limit the time zones that can be allocated, and various types of data communication. A mode in which the type of the data communication channel that can be allocated when there is a channel may be used.
[0018]
As one configuration example, in the wireless communication system according to the present invention, the upper limit of the amount of data communication channels that can be allocated to each subscriber station device is set, and the amount of data communication channels allocated to each subscriber station device is set. Restrict to less than or less than the upper limit set for each subscriber station device. Note that the quantity may include a number.
[0019]
Here, the upper limit of the amount of the data communication channel that can be allocated includes, for example, the upper limit of the number of data in the communication unit that can be allocated, the upper limit of the number of slots that can be allocated, and the number of packets that can be allocated. , The upper limit of the data traffic that can be allocated, and the like.
Various values may be used as the upper limit.
In addition, as an aspect of limiting the amount of the data communication channel to be allocated to the upper limit or less or less than the upper limit, for example, an aspect of limiting the amount to the upper limit or less may be used, or an aspect of limiting the amount to less than the upper limit may be used. You may.
[0020]
Next, another configuration example of the wireless communication system according to the present invention will be described.
In the wireless communication system according to the present invention, as one configuration example, the data communication between the base station device and the subscriber station device is performed by waiting for communication for each data of the communication unit in which the communication request is generated, and the communication during the communication standby is performed. The process is shifted to the communication process for each data of the communication unit. In addition, an upper limit number of data of the communication unit that can be communicated for each subscriber station device is set. In addition, the communication management unit manages communication standby information including information for identifying the subscriber station device that is in communication standby with respect to the subscriber station device accommodated in the base station device. Then, based on the communication standby information, the number of data in the communication unit that can communicate with each subscriber station device is limited to an upper limit or less or less than an upper limit set for each subscriber station device. Then, a data communication channel is allocated to the subscriber station apparatus in the communication standby state, which is accommodated in the base station apparatus, for each data of the communication unit in the communication standby state.
[0021]
Here, as the upper limit number of data of communication units that can be communicated for each subscriber station device, for example, the upper limit number of the cumulative number of data of communication units that can be communicated, or the maximum number of data that can be communicated within a predetermined period And the upper limit on the number of data of communication units that can be simultaneously communicated.
Also, various values may be used as the upper limit number.
In addition, as an aspect of limiting the communication unit to be communicable to the number of data equal to or less than the upper limit number or less than the upper limit number, for example, an aspect of limiting to less than the upper limit number may be used, or an aspect of limiting to less than the upper limit number may be used. May be used.
[0022]
As an example of the configuration, in the wireless communication system according to the present invention, the number of data in the communication unit that is communicable with each subscriber station device is counted, and the count value is set to each subscriber station device. Based on the result of the comparison with the upper limit number, it is determined whether or not data of the communication unit can be communicated to each of the subscriber station devices. Further, the count value for each subscriber station device is set to zero at predetermined time intervals.
[0023]
Here, based on the result of comparing the count value of the number of data of the communication unit which can communicate with each subscriber station device and the upper limit number set in each subscriber station device, As a method of determining whether or not data of the communication unit can be communicated to the station device, for example, when the count value is equal to or less than (upper limit number-1) or less than (upper limit number-1), While it is determined that the data of one or more communication units can be made communicable, if the count value exceeds (upper limit number -1) or is equal to or more than (upper limit number -1), the communication unit is in that state. A method of determining that the data cannot be further made communicable can be used.
[0024]
Setting the count value of each subscriber station device to zero corresponds to, for example, initializing the count value to zero.
Various time intervals and timings may be used as the predetermined time intervals and timings for setting the count value for each subscriber station device to zero, for example, different time intervals and different timings for each subscriber station device. Timing may be used, or the same time interval or the same timing may be used for a plurality of subscriber station devices.
[0025]
Further, in the wireless communication system according to the present invention, as one configuration example, a plurality of classes for dividing the subscriber station apparatus are provided, a data communication channel is assigned to each class, and a data communication channel for each class is assigned to each class. The data communication channel is allocated to the subscriber station devices classified into each class in the allocation part of the above. In such a configuration, the data communication channel can be allocated by limiting the data communication channel that can be allocated to each subscriber station device classified into each class for each class. In addition, it is possible to realize a wireless band guarantee for each subscriber station device.
[0026]
Further, the present invention provides a base station apparatus as described above.
In the base station apparatus according to the present invention, when wirelessly communicating data with a plurality of subscriber station apparatuses using a data communication channel, a data communication channel is allocated as follows.
That is, the data communication channel allocating means limits the data communication channel that can be allocated to each subscriber station device accommodated in the base station device, and allocates the data communication channel to the subscriber station device. Data is wirelessly communicated using the subscriber station device and a portion allocated to a data communication channel for the subscriber station device.
[0027]
Further, in the base station apparatus according to the present invention, as one configuration example, an upper limit value of the amount of data communication channels that can be allocated is set for each subscriber station apparatus accommodated in the base station apparatus, Restricts the amount of data communication channels allocated to each subscriber station device to an upper limit or less or less than an upper limit set for each subscriber station device.
[0028]
Further, in the base station apparatus according to the present invention, as one configuration example, data communication with the subscriber station apparatus waits for communication for each data of the communication unit in which the communication request is generated, and the communication unit in the communication standby state The process is shifted to the communication process for each data item. In addition, an upper limit number of data of the communication unit that can be communicated is set for each subscriber station device. Further, the communication device information management means manages communication standby information including information for identifying the subscriber station device which is in communication standby with respect to the subscriber station device accommodated in the base station device. Then, based on the communication standby information, the data communication channel allocating means sets the number of data in the communication unit to be communicable with each subscriber station device equal to or less than the upper limit number set in each subscriber station device. Alternatively, a data communication channel is allocated to the subscriber station apparatus which is accommodated in the base station apparatus and which is in the communication standby state, for each data of the communication unit which is in the communication standby state, with the number being limited to less than the upper limit number.
[0029]
Further, in the base station apparatus according to the present invention, as one configuration example, the data communication channel allocating means counts the number of data of the communication unit which can communicate with each subscriber station apparatus, and It is determined whether or not the data of the communication unit can be communicated to each of the subscriber station devices based on the result of comparison with the upper limit set for each of the subscriber station devices. The count value for the station device is set to zero at predetermined time intervals.
[0030]
Further, in the base station apparatus according to the present invention, as one configuration example, a plurality of classes for dividing the subscriber station apparatus are provided, and a data communication channel is allocated to each class. Then, the data communication channel allocating means allocates the data communication channel to the subscriber station apparatus classified into each class in the data communication channel allocating portion for each class for each class.
[0031]
Further, other configuration examples, such as the wireless communication system according to the present invention, including the configuration described above, will be described.
In addition, the following configuration can be applied to the above-described wireless communication system according to the present invention.
In addition, the following configuration contributes to achieving the above-described object of the present invention.
[0032]
In the wireless communication system according to the present invention, when a base station device and a plurality of subscriber station devices accommodated in the base station device wirelessly communicate data using a data communication channel, data is transmitted as follows. Assign communication channels.
That is, the data communication between the base station apparatus and the subscriber station apparatus is made to wait for the communication for each data of the communication unit for which the communication request has been issued, and is shifted to the communication processing for each data of the communication unit in the communication waiting state. Perform communication standby information including information for identifying the subscriber station device in communication standby with respect to the subscriber station device accommodated in the base station device, and based on the communication standby information, Allocate a data communication channel to the subscriber station device during communication standby accommodated in the base station device for each data of the communication unit, and the base station device and the subscriber station device Data is wirelessly communicated using the allocated portion of the data communication channel.
[0033]
Therefore, in a configuration in which the communication standby and the transition to the communication process are performed for each data of the communication unit in the communication standby, the data communication with respect to the subscriber station device in the communication standby for the data of the communication unit in the communication standby is performed. Since channel allocation is performed, even when, for example, there is bursty traffic on the LAN, the wireless medium allocated to the base station apparatus can be used effectively, thereby improving the efficiency of data communication. Can be achieved.
[0034]
Here, various numbers may be used as the number of the plurality of subscriber station devices accommodated in the base station device.
Further, between the base station apparatus and the subscriber station apparatus, there are either uplink communication for communicating data from the subscriber station apparatus to the base station apparatus or downlink communication for communicating data from the base station apparatus to the subscriber station apparatus. Either one or both may be performed. The present invention can be applied to either one of uplink communication and downlink communication, or can be applied to both.
[0035]
Also, various amounts of data may be used as the data of the communication unit, and not only a fixed amount of data but also a variable amount of data may be used. As an example, when data is communicated for each packet, the data communicated by each packet can be used as data of a communication unit, and the amount of data of the communication unit is the data that can be communicated in one packet. The data amount may be used, and the data amount may vary within a range equal to or less than the maximum data amount that can be communicated in one packet, for example, according to the communication status.
[0036]
Further, as data of a communication unit in which a communication request has occurred, for example, in uplink communication, data of a communication unit in which a communication request has occurred on the subscriber station side is used. For example, in downlink communication, a communication request on the base station apparatus side has occurred. The data of the communication unit in which is generated is used. Then, for each data of the communication unit, when a communication request is generated, the communication standby is started, and when the order of the communication processing comes, the processing is shifted to the communication processing.
[0037]
Further, the communication standby information may be composed of, for example, only information for identifying the subscriber station apparatus that is in the communication standby state, or may include other information.
Various information may be used as the information for identifying the subscriber station device that is in the communication standby state. For example, information that directly indicates whether or not each subscriber station device is in the communication standby state may be used. Or information that indirectly indicates whether or not communication is waiting, such as, for example, information on the number and amount of data waiting for communication related to each subscriber station device. .
Further, as the communication standby information, for example, each of the subscriber station devices accommodated in the base station device may be individually managed, or the entire subscriber station device accommodated in the base station device may be managed. They may be managed collectively.
[0038]
Further, as a method of allocating a data communication channel to the subscriber station device, various methods may be used, for example, a method of allocating a data communication channel to each subscriber station device for each time zone, For example, when data communication using slots is performed, a method of allocating a data communication channel to each subscriber station device for each slot, or for example, when data communication using a plurality of frequencies is performed, A method of allocating a data communication channel to each subscriber station device can be used. In these methods, the time zone in which the data communication channel allocated to each subscriber station device can be used, the slot in which the data communication channel allocated to each subscriber station device can be used, and the The frequency at which the allocated data communication channel can be used corresponds to a portion where the data communication channel is allocated to each subscriber station device.
[0039]
Further, in the wireless communication system according to the present invention, in the above-described configuration, the base station apparatus and the subscriber station apparatus accommodated in the base station apparatus perform wireless communication using a plurality of frames sequentially communicated. The frame includes a data communication slot used for forming a data communication channel and communicating data of the communication unit, and the communication standby information includes a communication standby state in each subscriber station apparatus during the communication standby state. The information includes the number of data of the communication unit in the data. In addition, as the assignment of the data communication channel, each time one data of the communication unit waiting for communication is transferred to the communication processing, the subscriber station device related to the waiting communication accommodated in the base station device is periodically cycled. And assigning the data communication slot included in the earliest frame to which the data communication slot has not been allocated to the switched subscriber station apparatus (that is, the data communication slot has not been allocated yet). Then, the base station apparatus and the subscriber station apparatus wirelessly communicate data using the data communication slot allocated to the subscriber station apparatus.
[0040]
Therefore, in a configuration in which data communication is performed using the data communication slots included in each frame to be sequentially communicated, the subscriber station apparatus periodically changes each time one data of the communication unit in the communication standby is shifted to the communication processing. One is switched in a random order and an unallocated data communication slot is allocated, so that, for example, even when there is a burst of traffic, each subscriber station apparatus in a communication standby state is evenly distributed. A data communication channel (here, a data communication slot) can be assigned, and thereby, efficiency of data communication can be improved.
[0041]
Here, as the frame, various structures may be used.In general, a frame includes a data communication slot forming a data communication channel and a control slot forming a channel for communicating control information. included.
Further, as the size of the data communication slot, that is, the amount of data that can be communicated by one data communication slot, various data amounts may be used. Further, the number of data communication slots included in one frame may be one, or may be two or more. Further, for example, one frame may include a plurality of data communication slots having different sizes.
[0042]
Further, as information on the number of data of the communication unit in the communication standby state in each subscriber station apparatus in the communication standby state, for example, the information of the communication unit in the communication standby state in each subscriber station apparatus accommodated in the base station apparatus Information such as the number of pieces of data indicating the number of data can be used.
[0043]
In addition, as a method of switching one of the subscriber station devices that are accommodated in the base station device during communication standby in a periodic order, for example, the subscriber station devices that are involved in communication standby are arranged in a predetermined order. Switching from the top to the tail, and then repeating the switching back to the top again, and for such a switching, the subscriber station device in which the data of the communication unit waiting for communication no longer exists. May be excluded from the switching target, and a method may be used in which a subscriber station device in which a communication request is newly generated and data of a communication unit in a communication standby state is generated is newly added to the switching target. .
[0044]
Further, as the earliest frame to which the data communication slot has not been allocated, for example, the data communication slot has not been allocated to any subscriber station apparatus yet, and is the first frame among the sequentially communicated frames. A frame scheduled to be communicated in the near future corresponds to the frame.
[0045]
In the wireless communication system according to the present invention, when a base station device and a plurality of subscriber station devices accommodated in the base station device wirelessly communicate data using a data communication channel, the following is performed. Perform data communication channel assignment. That is, a plurality of classes for dividing the subscriber station apparatus are provided, a data communication channel is allocated to each class, and each class is classified into each class in a portion where the data communication channel is allocated to each class. A data communication channel is assigned to the subscriber station device, and the base station device and the subscriber station device wirelessly communicate data using the data communication channel assigned to the subscriber station device.
[0046]
Therefore, the data communication channel is allocated to the subscriber station devices classified into each class within the range of the data communication channel portion allocated to each class, and therefore, for example, each class corresponds to burst traffic. Even in such a case, since the assignment of data communication channels in other classes is not affected, it is possible to guarantee the minimum wireless band required for data communication in other classes, Thereby, efficiency of data communication can be improved.
[0047]
Here, various classes may be used for classifying the subscriber station devices. For example, a class that classifies the subscriber station devices belonging to the same company or the same organization into the same class may be used. Can be used.
Also, various numbers may be used as the number of the plurality of classes.
[0048]
Further, as a method of allocating a data communication channel to each class, for example, a method of allocating a data communication channel so that the maximum amount of data capable of performing data communication by each class may be used, Alternatively, a method of differentiating each class by allocating a data communication channel so that the maximum amount of data capable of data communication differs for each class may be used.
[0049]
Further, the number of subscriber station devices classified into each class may be, for example, one, or may be two or more. Further, the number of subscriber station devices classified into each class may be fixedly set, for example, or may be set variably. Normally, a plurality of subscriber station devices are classified into one or more classes among the plurality of classes.
Further, for example, for a class in which only one subscriber station device is divided, the portion where the data communication channel is allocated to the class can be regarded as the portion where the data communication channel is allocated to the one subscriber station device.
[0050]
Further, in the wireless communication system according to the present invention, in the above configuration, the maximum number of subscriber station devices that can be classified for each class is set, and the maximum classifiable number for each class is set for each class. The number of subscriber station devices equal to or less than the number of subscriber station devices is classified.
Therefore, by setting the maximum number of subscriber stations that can be classified for each class, for example, a sufficient data communication channel allocated to the subscriber stations that are classified into each class for each class A portion can be secured, and thereby the efficiency of data communication can be improved.
[0051]
Here, as the maximum number of subscriber station devices that can be classified for each class, for example, 1 may be set, and for example, a number of 2 or more may be set. The maximum number of subscriber station devices that can be classified for each class may be fixedly set, for example, or may be set variably.
[0052]
In the wireless communication system according to the present invention, in the above configuration, there is a class in which only one subscriber station device is divided and a class in which a plurality of subscriber station devices are divided.
Therefore, for example, in a class in which only one subscriber station device is partitioned, the data communication channel portion assigned to the class by the one subscriber station device is exclusively used, while two or more subscriber station devices are partitioned. In the class, the data communication channel portion assigned to the class by the two or more subscriber station devices is shared, so that the class in which only one subscriber station device is divided and the two or more subscriber station devices are divided. By using both the class and the class, for example, with respect to the subscriber station apparatus accommodated in the same base station apparatus, while securing a part of the radio band as a dedicated band for a specific subscriber station apparatus, It is possible to realize that a band is used as a shared band by a plurality of subscriber station devices.
[0053]
Further, the present invention provides a base station apparatus as described above.
In the base station apparatus according to the present invention, when wirelessly communicating data with a plurality of subscriber station apparatuses using a data communication channel, data communication with the subscriber station apparatus is performed for each data of a communication unit in which a communication request occurs. The communication process is performed for each data of the communication unit in the communication standby state, and a data communication channel is allocated as follows.
That is, in the base station apparatus, the communication standby information management means manages communication standby information including information for identifying the subscriber station apparatus in communication standby with respect to the subscriber station apparatus accommodated in the base station apparatus, and The communication channel allocating unit allocates a data communication channel to the subscriber station apparatus during communication standby accommodated in the base station apparatus for each data of the communication unit during communication standby based on the communication standby information, Wireless communication means wirelessly communicates data using the subscriber station device and a portion of the data communication channel allocated to the subscriber station device.
[0054]
Further, in the base station apparatus according to the present invention, in the above configuration, wireless communication is performed by a plurality of frames sequentially communicated with the subscriber station apparatus accommodated in the base station apparatus, and each frame performs data communication. The communication standby information managed by the communication standby information management means includes a data communication slot used to communicate data of the communication unit by configuring a channel, and includes a communication standby in each subscriber station apparatus during a communication standby. The information includes the number of data of the communication unit in the data. Further, the data communication channel allocating means, as the data communication channel allocation, every time one of the data of the communication unit in the communication standby is shifted to the communication processing, the subscriber associated with the communication standby contained in the base station apparatus. The data radio communication means performs switching of one station device in a periodic order, and allocating a data communication slot included in the earliest frame to which the data communication slot has not been allocated to the switched subscriber station device. Wirelessly communicates data using a subscriber station device and a data communication slot allocated to the subscriber station device.
[0055]
Further, in the base station apparatus according to the present invention, when wirelessly communicating data with a plurality of subscriber station apparatuses using a data communication channel, a plurality of classes for dividing the subscriber station apparatus are provided, and each class is provided with a plurality of classes. A data communication channel is allocated to the subscriber station device, and the data communication channel is allocated to the subscriber station device as follows.
That is, in the base station device, the data communication channel allocating means allocates a data communication channel to the subscriber station device classified into each class in the data communication channel allocating portion for each class for each class. Wireless communication means wirelessly communicates data using the subscriber station device and a portion of the data communication channel allocated to the subscriber station device.
[0056]
In the base station apparatus according to the present invention, in the above configuration, the maximum number of subscriber station apparatuses that can be classified for each class is set, and the maximum classifiable number for each class is set for each class. The number of subscriber station devices equal to or less than the number of subscriber station devices is classified.
In the base station apparatus according to the present invention, in the above configuration, there is a class in which only one subscriber station apparatus is divided and a class in which a plurality of subscriber station apparatuses are divided.
[0057]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment according to the present invention will be described with reference to the drawings.
First, a first embodiment of the present invention will be described.
FIG. 1 shows an example of a wireless access system to which the present invention is applied. Specifically, a base station apparatus B, a backbone network N composed of a LAN or the like connected to the base station apparatus B, A plurality of subscriber station devices C1 to C3 accommodated in the base station device B; lines L1 to L3 such as Ethernet (registered trademark) and a LAN connected to the subscriber station devices C1 to C3; A plurality of subscriber terminal devices T1 to T3, T11 to T13, and T21 to T23 connected to the station devices C1 to C3 via respective lines L1 to L3 are shown. FIG. 2 also shows an antenna A provided in the base station device B and antennas A1 to A3 provided in each of the subscriber station devices C1 and C2.
[0058]
In this example, for convenience of explanation, only one base station device B is shown. However, usually, a plurality of base station devices are provided, and these base station devices communicate via the backbone network N. Connected as possible.
Also, various numbers may be used as the number of the subscriber station devices C1 to C3 and the number of the subscriber terminal devices T1 to T3, T11 to T13, and T21 to T23.
[0059]
As shown in the figure, the base station apparatus B includes a storage unit 1 configured using a memory, for example, and a control unit 2 configured using a CPU (Central Processor Unit), for example. I have. The storage unit 1 also includes a wireless subscriber station management table 11 for managing information on the subscriber station devices C1 to C3 accommodated in the own station (the base station device B), and a schedule of wireless bands for a plurality of classes. , And a class-based channel scheduling management table 13 for managing a data communication channel schedule for each class. The bandwidth scheduling management table 12 and the class-based channel scheduling management table 13 will be described later in detail in a second embodiment of the present invention.
[0060]
Each of the subscriber station devices C1 to C3 has a function of wirelessly transmitting and receiving data to and from the base station device B, and is connected to the subscriber terminal device via, for example, an Ethernet (registered trademark) interface. It has a bridge function for filtering and forwarding data from T1 to T3, T11 to T13, and T21 to T23.
[0061]
As shown in the figure, each of the subscriber station devices C1 to C3 includes a storage unit 21 configured using a memory, for example, and a control unit 22 configured using a CPU or the like, for example. . Further, the storage unit 21 has a subscriber terminal management table for managing information on the subscriber terminal devices T1 to T3, T11 to T13, and T21 to T23 connected to the own station (the respective subscriber station devices C1 to C3). 31 are stored. The subscriber terminal management table 31 stores and manages, for example, identification information of the subscriber terminal devices T1 to T3, T11 to T13, and T21 to T23 connected to the own station.
[0062]
FIG. 2 shows an example of a format of a data communication channel 40 that is a wireless channel used for data transmission and reception performed between the base station device B and the subscriber station devices C1 to C3. As shown in the figure, the data communication channel 40 of the present example includes, from the beginning, a bit synchronization signal 41 for establishing bit synchronization and a frame synchronization signal 42 for establishing frame synchronization. , A channel type identifier signal 43 that is a signal for identifying a type of a channel (for example, a type such as a data channel or a control channel), and a wireless subscriber station identifier that is a signal for specifying the destination subscriber station device C1 to C3. A signal 44, a data signal 45 as a data signal, and an error detection code signal 46 as a code signal for performing error detection are arranged side by side.
[0063]
Here, the data signal 45 includes, for example, an Ethernet (registered trademark) packet transmitted from the subscriber terminal devices T1 to T3, T11 to T13, and T21 to T23 on the subscriber station devices C1 to C3 side, or An Ethernet (registered trademark) packet transmitted from the backbone network N on the base station apparatus B side is stored.
[0064]
When data having addresses assigned to the plurality of subscriber terminal devices T1 to T3, T11 to T13, and T21 to T23 is transmitted from the base station device B by a broadcast packet, for example, "0xFFFF (h: 16 (Base number) "is set in the wireless subscriber station identifier signal 44, while data having individual addresses addressed to each of the subscriber terminals T1 to T3, T11 to T13, T21 to T23 is transmitted by a unicast packet to the base station. When transmitting from the station device B, for example, the values of the identifiers of the subscriber station devices C1 to C3 accommodating the subscriber terminal devices T1 to T3, T11 to T13, and T21 to T23 which are destinations are transmitted to the wireless subscriber station identifier signal Set to 44. In this example, by using such settings, the subscriber station devices C1 to C3, which are the receiving sides of the data communication channel, determine the value of the identifier stored in the wireless subscriber station identifier signal 44, thereby making the identification unspecified. The receiving operation by a large number of subscriber station devices C1 to C3 or specific subscriber station devices C1 to C3 can be controlled.
[0065]
FIG. 3 shows an example of a format of a radio frame 50 used for radio channel control performed between the base station device B and the subscriber station devices C1 to C3. As shown in the figure, a radio frame 50 of this example includes, from the top, a broadcast control channel 51 that is a channel for performing broadcast and control, a frame control channel 52 that is a channel for performing frame control, and a base station device B. A downlink data communication channel 53, which is a channel for communicating downlink communication data from the subscriber station devices C1 to C3, and uplink communication data from the subscriber station devices C1 to C3 to the base station device B or the downlink communication data described above. An uplink / downlink data communication channel 54, which is a channel for communication, and a link control channel 55, which is a channel for performing link control, are arranged side by side.
[0066]
In the broadcast control channel 51, the base station B notifies the entire wireless cell (service area) of the synchronization establishment timing of the wireless frame 50 and the value of the frame counter which is the serial number of the wireless frame 50. And notification of operation information such as the identifier of the own station (the base station apparatus B), and the data communication channel 54 by any of the subscriber station apparatuses C1 to C3 in the radio frame 50 including the broadcast control channel 51. For example, notification of band allocation information indicating whether use is possible is performed.
[0067]
In the frame control channel 52, the base station device B notifies the subscriber station devices C1 to C3 of the band allocation information of the link control channel 55, and the local station device (the base station device B) notifies the subscriber station devices C1 to C3. For example, notification of information on the result of authentication of C1 to C3 and the subscriber terminal devices T1 to T3, T11 to T13, and T21 to T23 is performed.
[0068]
In the downlink data communication channel 53, data is communicated from the base station device B to the subscriber station devices C1 to C3 using Ethernet (registered trademark) packets or the like.
In the uplink / downlink data communication channel 54, data is communicated from the subscriber station devices C1 to C3 to the base station device B using an Ethernet (registered trademark) packet or the like, or from the base station device B to the subscriber station device C1. To C3 by using Ethernet (registered trademark) packets or the like.
[0069]
In the link control channel 55, a request for allocating a radio band for using the uplink / downlink data communication channel 54 for uplink communication data communication from the subscriber station devices C1 to C3 to the base station device B, The information of the authentication request of the subscriber station devices C1 to C3 is notified.
In this example, by sequentially communicating the radio frames 50 having such a configuration, the base station apparatus B and the subscriber station apparatuses C1 to C3 communicate with each other, for example, time division multiple access / time division duplex (TDMA / TDD: Radio line control is performed by a Time Division Multiple Access / Time Division Duplex method.
[0070]
Next, two examples of the format of the wireless subscriber station management table 11 stored in the storage unit 1 of the base station device B will be described with reference to FIGS.
In this example, the wireless subscriber station management table 11 is provided for each of the subscriber station devices C1 to C3.
[0071]
FIG. 4 shows an example of the format of the wireless subscriber station management table 11a stored in the storage unit 1 of the base station device B.
In the example shown in the figure, the wireless subscriber station management table 11a corresponding to each of the subscriber station devices C1 to C3 is, from the top, a pointer (uplink next) indicating the next wireless subscriber station management table related to uplink communication data. 61, a pointer (upstream prev) 62 indicating the previous wireless subscriber station management table regarding the upstream communication data, a pointer (downstream next) 63 indicating the next wireless subscriber station management table regarding the downstream communication data, A pointer (downstream prev) 64 indicating the previous wireless subscriber station management table, a wireless subscriber station ID 65, an affiliation class 66, an upstream data queue counter 67, and a downstream data queue counter 68 are arranged side by side.
[0072]
Here, when there are a plurality of subscriber station apparatuses C1 to C3 having the uplink communication data in the communication standby state to be transmitted, the base station apparatus B transmits both the wireless subscriber station management table by the uplink next61 and the uplink prev62. Create a matrix consisting of a directed list. Specifically, for the uplink communication data, the radio subscriber station management table corresponding to the subscriber station device in the following order is compared with the radio subscriber station management table provided for a certain subscriber station device. Is indicated by an upstream next61, and a wireless subscriber station management table corresponding to the subscriber station apparatus in the previous order is indicated by an upstream prev62.
[0073]
Similarly, when there are a plurality of subscriber station devices C1 to C3 in which the base station device B has downlink communication data waiting to be received in the base station device B, the base station device B performs wireless subscription by the downstream next63 and the downstream prev64. Create a matrix composed of a bidirectional list in the administrator station management table. Specifically, with respect to the downlink communication data, the radio subscriber station management table corresponding to the subscriber station device in the following order is compared with the radio subscriber station management table provided for a certain subscriber station device. Is indicated by a downlink next 63, and a wireless subscriber station management table corresponding to the subscriber station device in the previous order is indicated by a downlink prev 64.
[0074]
When allocating a radio band for performing uplink communication or downlink communication to the subscriber station devices C1 to C3, the base station device B of the present example uses a matrix of the above-described uplink communication data and downlink communication data. The wireless bands are allocated in accordance with the order of the matrix, starting from the subscriber station device indicated in the leading wireless subscriber station management table.
[0075]
In the wireless subscriber station ID 66, information of an identifier assigned to each of the subscriber station apparatuses C1 to C3 that communicate within the service area of the base station apparatus B is set.
In the belonging class 67, information of a class to which the subscriber station devices C1 to C3 managed by the wireless subscriber station ID 66 belong is set. The class will be described in detail in a second embodiment of the present invention described later.
[0076]
The uplink data queue counter 67 stores the number of data (data queuing number (data queuing number) in a state where transmission of data is waiting by the subscriber station devices C1 to C3 managed by the wireless subscriber station ID 66 with respect to the uplink communication data. Traffic)) information is set.
Similarly, the downlink data queue counter 68 stores, in the downlink communication data, data in a state in which the base station B waits for data transmission to the subscriber station devices C1 to C3 managed by the wireless subscriber station ID 66. (The number of data queuing (traffic)) is set.
[0077]
In this example, when counting the number of data set as the information of the above-described uplink data queue counter 67 and the information of the downlink data queue counter 68, one packet (in this example, one slot of one data communication channel) is counted. The number of data is counted as one data, that is, data to be transmitted as a single data, that is, data to be transmitted in one packet.
[0078]
In this example, with respect to downlink communication data, data addressed to the subscriber terminal devices T1 to T3, T11 to T13, and T21 to T23 received by the base station device B via the backbone network N (subscriber station devices C1 to C23). The number of data queuing is counted based on the state of occurrence of (data transmitted to C3) and the like. On the other hand, for uplink communication data, request information of uplink data communication that the base station apparatus B receives from the subscriber station apparatuses C1 to C3 The number of data queuing is counted on the basis of the occurrence status of data.
[0079]
For example, the base station apparatus B according to the present embodiment stores information on the subscriber station apparatuses C1 to C3 in which one or both of the value of the uplink data queue counter 67 and the value of the downlink data queue counter 68 are not zero (= 0). While the information is managed by the wireless subscriber station management table 11a, information relating to the subscriber station devices C1 to C3 in which both of these values are zero is not managed by the wireless subscriber station management table 11a. By controlling addition and deletion of information on the subscriber station devices C1 to C3 to and from the queue of the subscriber station management table 11a and scheduling wireless band allocation to the subscriber station devices C1 to C3, a plurality of subscriber stations can be controlled. Best-effort communication sharing a wireless band is realized by the devices C1 to C3.
[0080]
FIG. 5 shows another example of the format of the wireless subscriber station management table 11b stored in the storage unit 1 of the base station device B.
Here, in the wireless subscriber station management table 11b shown in the figure, the same components 61 to 68 as those of the wireless subscriber station management table 11a shown in FIG. A value 71, an upstream bandwidth allocation cumulative value 72, a downstream bandwidth allocation upper limit 73, and a downstream bandwidth allocation cumulative value 74 are arranged side by side.
[0081]
In the uplink bandwidth allocation upper limit value 71, information on the upper limit value of the wireless bandwidth that can be allocated and used in uplink data communication is set for each of the subscriber station devices C1 to C3.
In the uplink bandwidth allocation cumulative value 72, information of a counter indicating the cumulative value of the wireless bandwidth allocated in the uplink data communication is set for each of the subscriber station devices C1 to C3.
In the downlink bandwidth allocation upper limit value 73, information on the upper limit value of the wireless bandwidth that can be allocated and used in downlink data communication is set for each of the subscriber station devices C1 to C3.
In the downlink bandwidth allocation cumulative value 74, information of a counter indicating the cumulative value of the wireless bandwidth allocated in downlink data communication is set for each of the subscriber station devices C1 to C3.
[0082]
Then, the base station apparatus B of the present example restricts the allocation of the data communication channel for each of the subscriber station apparatuses C1 to C3. Is compared with the value of the uplink bandwidth allocation cumulative value 72, and in downlink communication, the downlink bandwidth allocation upper limit value 73 and the downlink bandwidth allocation cumulative value 74 for each of the subscriber station devices C1 to C3 in downlink communication. To control the allocation by comparing the value of
[0083]
Referring to FIG. 6, an example of a procedure of a process of controlling the bidirectional list (bandwidth sharing queue) of the wireless subscriber station management table 11 by the control unit 2 of the base station device B will be described.
In the figure, in order to realize the best-effort communication in which the wireless band is shared, the control unit 2 of the base station B transmits the subscriber station devices C1 to C1 to the matrix of the wireless subscriber station management table 11. An example of a flow of a process of controlling addition and deletion of information related to C3 and causing a plurality of subscriber station devices C1 to C3 to share a wireless band is illustrated.
[0084]
In the following, a description will be given of processing relating to uplink communication as a representative, but processing relating to downlink communication is the same as processing relating to uplink communication. In the following, processing relating to downlink communication is additionally described in a format such as "(or ...)", and "uplink ..." in the description is replaced with "downlink ..." in "(or ...)". For example, processing related to downlink communication is realized.
[0085]
In addition, in the following, for the sake of simplicity, a case will be described in which only the upstream data queue counter 67 (or the downstream data queue counter 68) is managed. It is also possible to manage both together.
[0086]
The control unit 2 of the base station apparatus B first obtains the wireless subscriber station management table 11 at the head based on the bidirectional list of the wireless subscriber station management table 11, and obtains the wireless subscriber station management table 11 A wireless band for communicating uplink communication data (or downlink communication data) is allocated to the subscriber station devices C1 to C3 managed in (1) (step S1) and stored in the wireless subscriber station management table 11. The value of the upstream data queue counter 67 (or the downstream data queue counter 68) is updated so as to be decreased by 1 (step S2).
Next, the control unit 2 of the base station apparatus B determines whether or not the updated value of the uplink data queue counter 67 (or the downlink data queue counter 68) has become zero (Step S3).
[0087]
As a result of this determination (step S3), when it is determined that the updated value of the uplink data queue counter 67 (or the downlink data queue counter 68) has become zero, the control unit 2 of the base station apparatus B transmits the radio signal. Assuming that it is no longer necessary to allocate a wireless band for uplink communication (or downlink communication) to the subscriber station devices C1 to C3 managed by the subscriber station management table 11, the wireless subscriber station management table 11 is wirelessly assigned. It is deleted from the bidirectional list (bandwidth sharing queue) of the subscriber station management table 11 (step S4), and the next wireless subscriber station management table 11 following the deleted wireless subscriber station management table 11 is transmitted as the next 61 (or downstream). Next 63) is updated as the top wireless subscriber station management table 11 in the bandwidth sharing queue (step 63). -Up S5).
[0088]
On the other hand, as a result of the above determination (step S3), when it is determined that the updated value of the uplink data queue counter 67 (or the downlink data queue counter 68) is 1 or more, the control unit 2 of the base station device B Is the first wireless subscriber station management table 11 next to the wireless subscriber station management table 11 indicated by the upstream next 61 (or downstream next 63) in the bandwidth sharing queue. (Step S5).
[0089]
In this example, the list length of the bidirectional list (bandwidth sharing queue) of the wireless subscriber station management table 11 shares the wireless band allocated to the uplink communication (or downlink communication) of the base station device B. This indicates the number of the subscriber station devices C1 to C3, and the longer the list length is, the more the one subscriber station device C1 to C3 is allocated in a case where the radio band is equally allocated to each of the subscriber station devices C1 to C3. The wireless band that can be allocated per C3 becomes smaller.
[0090]
Referring to FIG. 7, an example of a procedure of a process in which the control unit 2 of the base station device B of this example performs a flow rate restriction on the band allocation of the data communication channel for each of the subscriber station devices C1 to C3 will be described. The process shown in the figure is executed, for example, after the “acquisition of the head wireless subscriber station management table (step S1)” in the procedure shown in FIG.
[0091]
In the following, a description will be given of processing relating to uplink communication as a representative, but processing relating to downlink communication is the same as processing relating to uplink communication. In the following, processing relating to downlink communication is additionally described in a format such as "(or ...)", and "uplink ..." in the description is replaced with "downlink ..." in "(or ...)". For example, processing related to downlink communication is realized.
[0092]
The control unit 2 of the base station device B, for example, until the search for the subscriber station devices C1 to C3 corresponding to all the wireless subscriber station management tables 11 in the bandwidth sharing queue is completed (step S11). Is performed.
That is, the control unit 2 of the base station device B firstly sets the uplink bandwidth allocation upper limit 71 (or the downlink bandwidth allocation upper limit 73) and the uplink bandwidth allocation cumulative value 72 (for the subscriber station devices C1 to C3 to be processed). Alternatively, the downlink bandwidth allocation cumulative value 74) is acquired from the wireless subscriber station management table 11 of the subscriber station devices C1 to C3 (step S12), and the two values are compared in magnitude (step S13).
[0093]
As a result of this comparison, if the uplink bandwidth allocation cumulative value 72 (or the downlink bandwidth allocation cumulative value 74) is equal to or greater than the uplink bandwidth allocation upper limit 71 (or the downlink bandwidth allocation upper limit 73), the allocation is already the upper limit value. , The control unit 2 of the base station device B performs flow restriction so as not to allocate a radio band to the subscriber station devices C1 to C3.
[0094]
Further, in this case, the control unit 2 of the base station apparatus B refers to the pointers to the next subscriber station apparatuses C1 to C3 from the bandwidth sharing queue and wirelessly joins the next subscriber station apparatuses C1 to C3. The remote station management table 11 is acquired (step S17), and the process returns to the above-described process (step S11) to repeat the same process.
When the bandwidth sharing queue has been searched to the end (step S11), the control unit 2 of the base station apparatus B ends the scheduling process for the allocation of the wireless bandwidth.
[0095]
On the other hand, as a result of the comparison (step S13), when the uplink bandwidth allocation cumulative value 72 (or downlink bandwidth allocation cumulative value 74) is smaller than the uplink bandwidth allocation upper limit value 71 (or downlink bandwidth allocation upper limit value 73). Since the allocation has not yet reached the upper limit, the control unit 2 of the base station apparatus B allocates the wireless band without restricting the flow rate, and obtains the uplink bandwidth allocation cumulative value 72 (or the downlink bandwidth allocation). The counter value of the accumulated value 74) is increased by 1 (step S14).
[0096]
Further, the control unit 2 of the base station device B measures the time, for example, and updates the uplink bandwidth allocation cumulative value 72 (or downlink bandwidth allocation cumulative value 74) of each of the subscriber station devices C1 to C3 for, for example, a predetermined time. Clear to zero value at intervals. Specifically, the control unit 2 of the base station device B determines whether or not it is time to clear the uplink bandwidth allocation cumulative value 72 (or downlink bandwidth allocation cumulative value 74) of each of the subscriber station devices C1 to C3. For example, the determination is made every elapse of a predetermined time (step S15), and when the timing comes, the uplink bandwidth allocation cumulative value 72 (or downlink bandwidth allocation cumulative value 74) of each of the subscriber station devices C1 to C3 is cleared ( Step S16).
[0097]
When a data communication channel is allocated to each of the subscriber station devices C1 to C3 due to such a flow rate restriction on the allocation of the data communication channel, for example, the uplink bandwidth allocation accumulated value 72 (or , The downlink bandwidth allocation cumulative value 74) does not always exceed the uplink bandwidth allocation upper limit 71 (or the downlink bandwidth allocation upper limit 73), and the uplink bandwidth allocation cumulative value 72 (or the downlink bandwidth allocation The flow rate of the wireless band can be limited within the time interval for clearing the accumulated value 74), and the flow rate of the wireless band that can be used by each of the subscriber station devices C1 to C3 is, for example, a fixed amount or a substantially fixed amount. Can be limited to
[0098]
As described above, in the wireless access system of this example, for example, a plurality of base station apparatuses B and a plurality of subscriber station apparatuses C1 to C3 connected to the subscriber terminal apparatuses T1 to T3, T11 to T13, and T21 to T23. In the configuration in which wireless communication is performed between the base station device B and the subscriber station devices C1 to C3, a data communication channel (in this example, a downlink data communication channel 53 or an uplink / downlink data communication channel 54) is provided. By scheduling the allocation for each data queue (traffic), it is possible to realize a best-effort communication function in which a plurality of subscriber stations C1 to C3 share a wireless band.
[0099]
Further, in the radio access system of the present example, when a best effort type communication function of sharing a radio band by a plurality of subscriber station devices C1 to C3 is used, the data communication channel is assigned to the subscriber station device. By limiting the flow rate for each of C1 to C3 (that is, for each flow), a wireless band can be guaranteed for each of the subscriber station devices C1 to C3, and a wireless band to be guaranteed between the subscriber station devices C1 to C3. Can be differentiated.
[0100]
Here, in this example, the downlink data communication channel 53 included in the radio frame 50 is used as a data communication channel for communicating downlink communication data, and the uplink / downlink data communication channel 54 included in the radio frame 50 is used. It is used as a data communication channel for communicating uplink communication data or downlink communication data.
[0101]
In this example, data communicated using a packet communicated through one slot of the downlink data communication channel 53 and data communicated using a packet communicated through a slot of one uplink / downlink data communication channel 54 Are used as data of communication units.
Further, in this example, in the uplink communication or the downlink communication, a communication request is generated for each data (data queue) in the communication unit, and the data in the communication standby state is shifted to the communication processing for each data in the communication unit. .
[0102]
In this example, information managed by the wireless subscriber station management table 11 is used as communication standby information, and the value of the uplink data queue counter 67 and the value of the downlink data queue counter 68 are 1 or more. Thus, it is identified that the corresponding subscriber station device C1 to C3 is in the communication standby state.
[0103]
In this example, a slot of one downlink data communication channel 53 included in the radio frame 50 and a slot of one uplink / downlink data communication channel 54 included in the radio frame 50 correspond to a data communication slot.
Further, in this example, for each data of the communication unit, one of the subscriber station devices C1 to C3 which is in the communication standby state is switched one by one in the periodic order set in the bidirectional list of the wireless subscriber station management table 11. The first available data communication slot is assigned to the switched subscriber station device C1 to C3.
In this example, the subscriber station devices C1 to C3 and the base station device B wirelessly communicate data using a data communication slot, which is a portion where data communication channels are allocated to the subscriber station devices C1 to C3.
[0104]
Further, in the base station apparatus B of this example, a communication standby information management unit is configured by a function of managing information in the wireless subscriber station management table 11, and a function of allocating a data communication channel for each data of a communication unit. A data communication channel allocating means is configured by a function of restricting a data communication channel to be allocated to each of the subscriber station devices C1 to C3. A function of wirelessly communicating data constitutes a data wireless communication unit.
[0105]
Next, a second embodiment of the present invention will be described.
The wireless access system of this example has, for example, a configuration similar to that shown in the first embodiment, and has a function of performing the same operation as that shown in the first embodiment.
In the following, description of the configuration and operation described in the first embodiment will be omitted, and the characteristic configuration and operation of the wireless access system of this example will be described in detail. Note that, in this example, for convenience of explanation, components such as the base station device B and the subscriber station devices C1 to C3 are shown using the same reference numerals as those shown in the first embodiment.
[0106]
In this example, three classes 1, 2, and 3 for classifying the subscriber station devices C1 to C3 are provided, and each of the subscriber station devices C1 to C3 accommodated by the base station device B is any one of them. Are divided into classes 1-3. Further, the information of the classes 1 to 3 to which each of the subscriber station devices C1 to C3 belongs is set to the belonging class 66 stored in the wireless subscriber station management table 11 as shown in FIG. 4 or FIG. .
Further, in this example, the radio band allocated to the base station device B is divided, and each of the plurality of classes 1 to 3 in which the subscriber station devices C1 to C3 wirelessly communicating with the base station device B are divided. Assigned to.
[0107]
FIG. 8 shows an example of a format of the bandwidth scheduling management table 12 stored in the storage unit 1 of the base station device B. As shown in the figure, the band scheduling management table 12 includes an offset 81 indicating information of a sequential number corresponding to the frame counter notified by the radio frame 50, and a data communication channel in the radio frame 50 corresponding to the sequential number. It is configured so as to be associated with an allocation candidate 82 indicating information of classes 1 to 3 to be allocated.
[0108]
More specifically, in the example shown in the figure, the class “1” and the class “2” correspond to the values of the offsets 81 of “0”, “1”, “2”,. , Class “3”,..., Class “1” are allocated as allocation candidates 82. Note that n is, for example, a value of 2 or more.
Based on the correspondence between the offset 81 and the allocation candidate 82, the base station apparatus B guarantees that a dedicated radio band is allocated to each of the classes 1 to 3 at a predetermined frame period, for example, A function of differentiating the amount of the wireless band to be guaranteed between ３ and ３ is realized. Note that various frames may be used as such a frame period.
[0109]
FIG. 9 shows an example of the format of the class-specific channel scheduling management table 13 stored in the storage unit 1 of the base station device B. As shown in the figure, the class-based channel scheduling management table 13 is composed of a plurality of channel scheduling tables provided to manage information on each of the classes 1 to 3. In the example of FIG. It comprises a class 1 channel scheduling management table 90a, a class 2 channel scheduling management table 90b, and a class 3 channel scheduling management table 90c.
[0110]
As shown in the figure, the channel scheduling management tables 90a to 90c of each of the classes 1 to 3 include, from the top, an entry size 91, an entry number 92, an upstream head pointer 93, and a downstream head pointer 94. It is configured side by side.
[0111]
In the entry size 91, information on the maximum number of the subscriber station devices C1 to C3 that can share the wireless band in the corresponding classes 1 to 3, that is, the classes can be classified into the classes 1 to 3 Information of the maximum number of the subscriber station devices C1 to C3 is set.
The number of entries 92 includes information on the number of subscriber station devices C1 to C3 currently sharing the radio band in the corresponding classes 1 to 3, ie, the subscribers currently classified into the classes 1 to 3 Information on the number of the station devices C1 to C3 is set.
[0112]
When the bidirectional list (bandwidth sharing queue) of the wireless subscriber station management table 11 relating to the uplink communication is classified into each of the classes 1 to 3 according to the information of the belonging class 66, the uplink head pointer 93 has the corresponding class 1 A pointer indicating the first one of the subscriber station devices C1 to C3 among one or a plurality of subscriber station devices C1 to C3, which are classified into.
Similarly, when the bidirectional list (bandwidth sharing queue) of the wireless subscriber station management table 11 relating to downlink communication is classified into each of the classes 1 to 3 according to the information of the belonging class 66, the downlink head pointer 94 corresponds to A pointer indicating the first one of the subscriber station devices C1 to C3 among one or a plurality of subscriber station devices C1 to C3 classified into classes 1 to 3 is set.
[0113]
Here, the uplink head pointer 93 is used to allocate the data communication channel 54 of the uplink communication for each of the classes 1 to 3 in the radio frame 50, and similarly, the downlink head pointer 94 is used for the downlink frame 94 in the radio frame 50. It is used for allocating the data communication channels 53 and 54 of communication for each of the classes 1 to 3.
[0114]
Further, in this example, according to the information of the entry size 91 set for each of the classes 1 to 3, for example, the classes 1 to 3 in which the maximum number of the subscriber station devices C1 to C3 that can be classified are one. In 3, the wireless band allocated to the classes 1 to 3 is occupied by one subscriber station device C1 to C3 classified into the classes 1 to 3, while, for example, the largest subscriber station that can be classified In the classes 1 to 3 in which the number of the devices C1 to C3 is 2 or more, the radio bands allocated to the classes 1 to 3 are shared by the two or more subscriber station devices C1 to C3 classified into the classes 1 to 3. You.
[0115]
Referring to FIG. 10, an example of a procedure of processing for scheduling band allocation of a data communication channel for each of classes 1 to 3 by control unit 2 of base station apparatus B will be described. FIG. 2 shows an example of the flow of the processing performed by the control unit 2 of the base station device B.
[0116]
First, the control unit 2 of the base station device B increases the value of the frame counter of the radio frame 50 by 1, and calculates a sequential number stored as the offset 81 in the bandwidth scheduling management table 12 (step S21). The sequential number is, for example, a remainder value when the value of the frame counter is divided by the number of frames included in a predetermined frame period.
[0117]
Next, based on the information on the allocation candidates 82 stored in the band schedule management table 12, the control unit 2 of the base station apparatus B determines the class set as the band allocation candidate corresponding to the calculated sequential number. 1 to 3 are specified, and the specified classes 1 to 3 are determined as the classes to which the data communication channels are allocated in the radio frame 50 corresponding to the sequential numbers (step S22).
[0118]
Next, the control unit 2 of the base station device B determines the classes 1 to 3 for performing the data communication service in the radio frame 50 as described above, and then determines the subscriber station device C1 that is classified into the classes 1 to 3. To C3, the subscriber station devices C1 to C3 managed by the leading wireless subscriber station management table 11 are specified, and a data communication channel is assigned to the specified subscriber station devices C1 to C3 ( Step S23, Step S24, Step S26 to Step S28).
[0119]
Specifically, the control unit 2 of the base station device B determines whether the specified class is “class 1” (step S23), and if so, the subscription classified into “class 1”. The first wireless subscriber station management table 11 among the wireless subscriber station management tables 11 for the local station devices C1 to C3 is acquired, and the subscriber station devices C1 to C1 corresponding to the acquired first wireless subscriber station management table 11 are acquired. The data communication channel assigned to the "class 1", that is, the downlink data communication channel 53 or the uplink / downlink data communication channel 54 in this example is assigned to C3 (step S24).
[0120]
Further, as a result of the above determination (step S23), when it is determined that the specified class is not “class 1”, the control unit 2 of the base station device B determines whether the specified class is “class 2”. It is determined whether or not it is not (step S26). If so, the first wireless subscriber station management table 11 in the wireless subscriber station management tables 11 for the subscriber station devices C1 to C3 classified into "class 2". And assigns the data communication channel assigned to the "class 2" to the subscriber station devices C1 to C3 corresponding to the acquired leading wireless subscriber station management table 11 (step S27).
[0121]
Further, as a result of the above determination (step S26), when it is determined that the specified class is not “class 2”, the control unit 2 of the base station device B determines that the specified class is “class 3”. Considering that, the first wireless subscriber station management table 11 among the wireless subscriber station management tables 11 for the subscriber station devices C1 to C3 classified into “class 3” is acquired, and the acquired first wireless subscriber station management table is acquired. The data communication channel allocated to the "class 3" is allocated to the subscriber station devices C1 to C3 corresponding to the management table 11 (step S28).
[0122]
Next, the control unit 2 of the base station device B uses the same channel scheduling process procedure as shown in FIG. Control processing of addition or deletion of information to the bidirectional list (bandwidth sharing queue in the class) of the wireless subscriber station management table 11 in steps 1 to 3 is performed (step S25).
[0123]
As described above, in the wireless access system of the present example, for example, a plurality of base station devices B and a plurality of subscriber station devices C1 to C3 connected to the subscriber terminal devices T1 to T3, T11 to T13, and T21 to T23. In a configuration in which wireless communication is performed between the base station device B and the subscriber station devices C1 to C3, a data communication channel for the subscriber station devices C1 to C3 (a downlink data communication channel 53 and an uplink By scheduling the assignment of the / downlink data communication channel 54) for each of the classes 1 to 3, the occupied wireless band can be guaranteed for each of the classes 1 to 3, and is guaranteed between the classes 1 to 3. It is possible to differentiate the radio band.
[0124]
Further, in the radio access system of the present example, one or a plurality of subscriber stations C1 to C3 are grouped, and a radio band allocated as an exclusive one for each of the classes 1 to 3 is allocated to one or a plurality of subscriber stations. By allocating to each group of the devices C1 to C3, a radio band occupied by one subscriber station device C1 to C3 and shared by a plurality of subscriber station devices C1 to C3 under the same base station device B Communication in which the wireless band to be used is mixed can be realized.
[0125]
Also in the wireless access system of this example, the data communication channel is assigned to each of the subscriber station devices C1 to C3 (that is, for each flow) by limiting the flow rate, so that the wireless band is assigned to each of the subscriber station devices C1 to C3. It can be guaranteed, and the guaranteed wireless band can be differentiated between the subscriber station devices C1 to C3 to be differentiated.
[0126]
Here, in this example, the radio band allocated to the base station apparatus B is divided and allocated to each of the classes 1 to 3, and further, in each of the classes 1 to 3, the radio band is allocated to each of the classes 1 to 3. A radio band is allocated to one or a plurality of subscriber station devices C1 to C3, which are divided into classes 1 to 3, respectively.
Further, in this example, the maximum number of subscriber station devices C1 to C3 that can be classified into each of the classes 1 to 3 is set in each of the classes 1 to 3, and the number of subscriber stations equal to or less than the maximum number is set. The station devices C1 to C3 are classified.
[0127]
Further, in the base station apparatus B of this example, the data communication channel allocating means is provided by the function of allocating the data communication channel to the subscriber station apparatuses C1 to C3 classified into each of the classes 1 to 3 for each of the classes 1 to 3. The data wireless communication means is configured by a function of wirelessly communicating data with the subscriber station devices C1 to C3 using the allocated portion of the data communication channel.
[0128]
Here, the configurations of the wireless communication system, the base station device, the subscriber station device, and the like according to the present invention are not necessarily limited to those described above, and various configurations may be used.
Further, the application field of the present invention is not necessarily limited to the above-described fields, and the present invention can be applied to various fields. As an example, this example shows a case where the present invention is applied to a subscriber wireless access system in which a base station device and a subscriber station device are fixedly set and a subscriber terminal device is connected to the subscriber station device. However, the present invention can be applied to various wireless communication systems such as a mobile communication system.
[0129]
In addition, as various processes performed in the wireless communication system, the base station device, the subscriber station device, and the like according to the present invention, for example, a processor stores in a ROM (Read Only Memory) in a hardware resource including a processor and a memory. A configuration controlled by executing the executed control program may be used, or each functional unit for executing the processing may be configured as an independent hardware circuit.
Further, the present invention can be understood as a computer-readable recording medium such as a floppy (registered trademark) disk or a CD (Compact Disc) -ROM storing the above-mentioned control program or the program (the program itself). The processing according to the present invention can be performed by inputting the program from the recording medium to the computer and causing the processor to execute the program.
[0130]
【The invention's effect】
As described above, according to the radio communication system and the like according to the present invention, when a base station device and a plurality of subscriber station devices accommodated in the base station device communicate data wirelessly using a data communication channel. The data communication channel that can be assigned to each subscriber station device is limited to assign a data communication channel to the subscriber station device, and the base station device and the subscriber station device establish a data communication channel for the subscriber station device. Since the data is wirelessly communicated using the assigned portion, for example, the radio band to be guaranteed between the subscriber station devices can be differentiated, and for example, the assignment of the data communication channel to each subscriber station device is restricted. It is also possible to dynamically allocate data communication channels according to communication conditions, etc., thereby increasing the efficiency of data communication. Rukoto can.
[0131]
In a wireless communication system and the like according to the present invention, when a base station apparatus and a plurality of subscriber station apparatuses accommodated in the base station apparatus wirelessly communicate data using a data communication channel, the base station apparatus The data communication with the subscriber station apparatus is performed by waiting for communication for each data of the communication unit in which the communication request is generated, and shifting to the communication processing for each data of the communication unit in the communication standby state, and Manages communication standby information including information for identifying a subscriber station device that is in communication standby with respect to the subscriber station device accommodated in the device, and, based on the communication standby information, manages each data of the communication unit in communication standby. Allocating a data communication channel to the subscriber station device that is accommodated in the base station device and waiting for communication, and the base station device and the subscriber station device transmit data to the subscriber station device. Since the data is wirelessly communicated using the assigned portion of the communication channel, it is possible to effectively use the wireless medium assigned to the base station device even when, for example, there is bursty traffic on the LAN. Therefore, efficiency of data communication can be improved.
[0132]
In the wireless communication system according to the present invention, in the above-described configuration, the base station apparatus and the subscriber station apparatus accommodated in the base station apparatus perform wireless communication with a plurality of frames sequentially communicated, Each frame includes a data communication slot used to communicate a data of the communication unit by forming a data communication channel, and the communication standby information includes a communication in each of the subscriber station devices during a communication standby. Information on the number of data of the communication unit in the standby state is included, and the data of the communication unit in the standby state is accommodated in the base station apparatus every time one of the data in the communication unit in the standby state is shifted to the communication processing as the data communication channel allocation One of the subscriber station devices that is in the communication waiting state is switched in a periodic order, and the earliest data communication slot is not allocated to the switched subscriber station device. A data communication slot included in a frame is allocated, and the base station device and the subscriber station device wirelessly communicate data using the data communication slot allocated to the subscriber station device. For example, even when there is a burst of traffic, a data communication channel (data communication slot) can be equally allocated to each subscriber station apparatus in a communication standby state. Communication efficiency can be improved.
[0133]
According to the wireless communication system and the like according to the present invention, when a base station device and a plurality of subscriber station devices accommodated in the base station device wirelessly communicate data using a data communication channel, the subscriber station A plurality of classes for classifying devices are provided, a data communication channel is allocated to each class, and a subscriber station device classified into each class in a data communication channel allocation portion for each class for each class. Since a data communication channel is allocated, and the base station apparatus and the subscriber station apparatus wirelessly communicate data using a data communication channel allocated to the subscriber station apparatus, for example, a burst is provided for each class. , Even when responding to typical traffic, the assignment of data communication channels in other classes Since Hibiki is not given, it is such to guarantee the minimum radio bandwidth required for data communication in other classes, which makes it possible to improve the efficiency of the data communication.
[0134]
In the wireless communication system according to the present invention, in the above-described configuration, the maximum number of subscriber station devices that can be classified for each class is set, and each class can be separately classified. Since the number of subscriber station devices equal to or less than the maximum number of subscriber station devices is classified, a sufficient data communication channel portion to be allocated to the subscriber station devices classified into each class for each class is secured. Thus, the efficiency of data communication can be improved.
[0135]
Further, in the wireless communication system according to the present invention, in the above-described configuration, there is a class in which only one subscriber station device is divided and a class in which a plurality of subscriber station devices are divided. For example, with respect to a subscriber station apparatus accommodated in the same base station apparatus, it is possible to secure a part of the wireless band as a dedicated band for a specific subscriber station apparatus and use the remaining wireless band as a shared band. Can be realized.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a configuration example of a wireless access system according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating an example of a format of a data communication channel used for data communication between a base station device and a subscriber station device.
FIG. 3 is a diagram showing an example of a format of a radio frame used for radio channel control between a base station device and a subscriber station device.
FIG. 4 is a diagram showing an example of a format of a wireless subscriber station management table stored in a base station device.
FIG. 5 is a diagram showing another example of the format of the wireless subscriber station management table stored in the base station device.
FIG. 6 is a flowchart illustrating an example of a procedure of a process of controlling a bandwidth sharing queue performed by a control unit of the base station device.
FIG. 7 is a flowchart illustrating an example of a procedure of a process performed by the control unit of the base station device to limit the flow rate of the wireless band of the data communication channel for each subscriber station device.
FIG. 8 is a diagram showing an example of a format of a bandwidth scheduling management table stored in a base station device.
FIG. 9 is a diagram illustrating an example of a format of a class-based channel scheduling management table stored in a base station device.
FIG. 10 is a flowchart illustrating an example of a procedure of a process of scheduling band allocation of a data communication channel for each class performed by a control unit of the base station apparatus.
[Explanation of symbols]
B base station device, C1 to C3 subscriber station device,
A, A1 to A3 ... antenna,
T1 to T3, T11 to T13, T21 to T23 ... subscriber terminal devices,
N .. backbone network, L1 to L3 .. line,
1, 21, storage section, 2, 22, control section,
11, 11a, 11b ... wireless subscriber station management table,
12. Bandwidth scheduling management table,
13. Class-specific channel scheduling management table,
31 ··· Subscriber terminal management table,

Claims (3)

A wireless communication system in which a base station device and a plurality of subscriber station devices accommodated in the base station device wirelessly communicate data using a data communication channel,
Limiting the data communication channels that can be assigned to each subscriber station device and assigning a data communication channel to the subscriber station device;
The base station device and the subscriber station device wirelessly communicate data using a data communication channel assignment portion for the subscriber station device,
A wireless communication system, comprising: The wireless communication system according to claim 1,
Set the upper limit of the amount of data communication channels that can be assigned to each subscriber station device, and set the amount of data communication channels to be assigned to each subscriber station device equal to or less than the upper limit value set for each subscriber station device, or Limit below the upper limit,
A wireless communication system, comprising: A base station device that wirelessly communicates data using a plurality of subscriber station devices and a data communication channel,
Data communication channel allocating means for allocating a data communication channel to the subscriber station device by limiting a data communication channel that can be allocated to each subscriber station device accommodated in the base station device;
Data wireless communication means for wirelessly communicating data using the subscriber station device and a portion of the data communication channel allocated to the subscriber station device;
A base station device comprising:

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