JP2004248105A - Radio base station, mobile terminal, radio communication system and radio communicating method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an efficient radio base station that prevents a processing delay due to the attachment of a time stamp. <P>SOLUTION: This radio base station is provided with a plurality of transmission buffers 16 for storing the packets to be transmitted, an arrival interval measuring part 11 for measuring a packet arrival interval, a determining part 12 for determining largeness/smallness between the packet arrival interval measured by the arrival interval measuring part 11 and a prescribed threshold, a storing part 17 for storing the time when a subsequent packet arrives as the data arrival time about a transmission buffer for storing the packet when the determining part 12 determines that the arrival interval is larger than the prescribed threshold, and a scheduling processing part 14 for performing preferential control of packet transmission on the basis of the data arrival time about the respective transmission buffers 16 stored in the storing part 17. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a wireless communication system including a plurality of mobile stations and a wireless base station, and to the mobile station, the wireless communication station, and a wireless communication method.
[0002]
[Prior art]
2. Description of the Related Art In a future wireless communication system in which multimedia services are expected to be realized, it is indispensable to perform communication control in consideration of various required qualities (QoS: Quality of Service). In particular, in real-time communication such as voice communication, video conference, and streaming, transmission delay from the transmission side to the reception side is the most important QoS factor. That is, in order to satisfy the QoS requirement of the real-time application, it is important to suppress the transmission delay from the transmission side to the reception side to be equal to or less than the maximum value of the required delay (maximum allowable delay). Furthermore, in future mobile communication systems, various types of traffic, such as voice, image, data transmission, and mail, are all being unifiedly handled in the form of packets. Since various types of packet traffic flow on the same wireless channel, QoS-aware control becomes more indispensable. QoS factors such as transmission delay, transmission rate, error rate, and non-reception rate are all per packet. Will be considered.
[0003]
The present invention focuses on transmission delay in a wireless link. In order to support the transmission delay of real-time communication, it is not enough to secure the transmission rate in the wireless link. This is because the transmission rate does not correspond to the rate at which packets are generated per unit time on the transmitting side, and the amount of data remaining in the transmission buffer increases, or the reception quality of the wireless link deteriorates. This is because there is a case where the receiving side cannot receive correctly and the residence time in the transmission buffer increases. This will be specifically described with reference to FIGS. 9A and 9B. FIG. 9A illustrates a state of a transmission buffer destined for the mobile stations 91 to 93 prepared in the radio base station 90. FIG. 9B illustrates each of the mobile stations 91 to 93 and the radio base station in this example. FIG. 3 is a diagram for explaining a transmission rate with a station 90. As shown in FIG. 9B, a downlink channel is assumed here, and it is assumed that transmission rates of 2 Mbps, 32 kbps, and 1 Mbps are secured for the mobile stations 91 to 93, respectively. As shown in FIG. 9A, the packet arrives at the transmission buffer for each of the mobile stations 91 to 93 prepared by the radio base station 90. At this time, the transmission rate of the packet arriving at the transmission buffer from the core network is independent of this transmission rate. As in the case of the mobile station 91 in FIG. 9A, when packets arrive from the core network at a rate (1.5 Mbps) smaller than the transmission rate (2 Mbps) of the wireless link, packet transmission is performed smoothly. 9 (a), when packets successively arrive at the transmission buffer at a rate (4 Mbps) higher than the transmission rate (1 Mbps) of the wireless link, the packets stay in the transmission buffer and the transmission delay increases. Would.
[0004]
In order to solve such a problem, a method of writing an arrival time or the like as a time stamp for each packet so as to recognize a delay time after the packet arrives at a transmission buffer of a base station is conventionally known from Patent Document 1 or the like. I was
[0005]
[Patent Document 1]
JP 2002-34062 A
[0006]
[Problems to be solved by the invention]
However, it takes a considerable time to add time stamps to all the generated packets, and as a result, there is a possibility that the processing delay is increased by the time to add the time stamps. FIG. 10A is a diagram showing a time when a packet arrives, and FIG. 10B is a diagram showing a time stamp given to the packet. As shown in FIG. 10B, when a process of adding a time stamp to each of a large number of packets arriving at the transmission buffer is performed, a delay is caused by the processing alone, and the delay shown in FIG. Although the packets arrived at the same time as packets 1 to 13, the time stamps assigned as shown in FIG. 10B are shifted, and the time stamps are not correctly assigned. The amount of data transmitted and received in mobile communication systems is steadily increasing in consideration of applications such as video distribution, and if time stamps are added to all generated packets, the problem of increased processing delay will increase in the future. It is expected to be even more serious.
[0007]
Therefore, the present invention provides a radio base station, a mobile station, a radio base station, a mobile station, And a wireless communication system including the above, and a wireless communication method.
[0008]
[Means for Solving the Problems]
A radio base station according to the present invention is a radio base station that performs packet communication with a mobile station, and includes a plurality of transmission buffers that store packets to be transmitted, and an arrival interval measuring unit that measures an arrival interval of packets. Determining means for determining the magnitude of the arrival interval of the packet measured by the arrival interval measuring means and a predetermined threshold; and determining that the arrival interval is equal to or smaller than the predetermined threshold, the packet arrives later. The packet is stored in the same transmission buffer as the packet arriving earlier, and when the arrival interval is determined by the determination means to be greater than the predetermined threshold, the packet arriving later is stored in the same or different transmission buffer as the packet arriving earlier. Packet storing means for storing, and a time at which data storage in the transmission buffer is started is stored as a data arrival time relating to the transmission buffer. That includes a storage unit, and a priority control means for performing priority control of the packet transmission based on the data arrival time for each of the transmission buffers stored in the storage means, characterized in that.
[0009]
Data transmitted and received between a mobile station and a radio base station is divided into a plurality of packets and transmitted and received. A plurality of packets constituting a group of data (hereinafter, referred to as “burst data”) arrive at the radio base station from the core network at arrival intervals equal to or less than a predetermined threshold. In the wireless base station according to the present invention, the arrival interval of the packet is measured by the arrival interval measuring means, and the size of the packet arrival interval and the predetermined threshold is determined by the determining means. It can be determined whether or not it is the first packet of data. That is, if the arrival interval of a certain packet with a packet that has arrived earlier is larger than a predetermined threshold, the packet must be a packet that constitutes burst data different from the previous packet, that is, the first packet of new burst data. If the arrival interval with the previously arrived packet is less than or equal to the predetermined threshold value, it can be understood that the packet is a packet constituting the same burst data as the previous packet. The packet accumulation means accumulates one burst data in the same transmission buffer by accumulating packets transmitted at intervals equal to or less than a predetermined threshold value in the same transmission buffer. The wireless base station according to the present invention has a storage unit, stores the time at which packets have started to be stored in the transmission buffer as a data arrival time (attached a time stamp), and the packets have already been stored in the transmission buffer. In this case, the data arrival time is not stored. That is, the time at which the first packet of the burst data is accumulated in the transmission buffer is stored as the data arrival time, and the arrival time of the other packets is not managed. In the present invention, since one burst data is stored in one transmission buffer, the transmission delay of the burst data can be controlled efficiently by managing the data arrival time of the transmission buffer. With this configuration, it is possible to reduce the processing delay due to the time stamp addition and perform priority control of packet transmission based on the arrival time of the first packet of the burst data. As an example of the priority control, there is a method of taking out a packet from a transmission buffer having an earlier data arrival time and transmitting the packet first, thereby solving the problem of transmission delay.
[0010]
A radio base station according to the present invention is a radio base station that performs packet communication with a mobile station, and includes a plurality of transmission buffers that store packets to be transmitted, and an arrival interval measuring unit that measures an arrival interval of packets. Determining means for determining the magnitude of the arrival interval of the packet measured by the arrival interval measuring means and a predetermined threshold; and determining that the arrival interval is equal to or smaller than the predetermined threshold, the packet arrives later. The packet is stored in the same transmission buffer as the packet arriving earlier, and when the arrival interval is determined by the determination means to be greater than the predetermined threshold, the packet arriving later is stored in the same or different transmission buffer as the packet arriving earlier. Packet storing means for storing, and when the determining means determines that the arrival interval is greater than a predetermined threshold value, the time at which a later packet arrives Storage means for storing as a data arrival time relating to a transmission buffer in which packets of the same type are stored, and priority control means for performing priority control of packet transmission based on the data arrival time relating to each transmission buffer stored in the storage means. , Is characterized.
[0011]
In the wireless base station according to the present invention, the arrival interval of the packet is measured by the arrival interval measuring means, and the size of the packet arrival interval and the predetermined threshold is determined by the determining means. It can be determined whether or not it is the first packet of data. That is, if the arrival interval of a certain packet with a packet that has arrived earlier is larger than a predetermined threshold, the packet must be a packet that constitutes burst data different from the previous packet, that is, the first packet of new burst data. If the arrival interval with the previously arrived packet is less than or equal to the predetermined threshold value, it can be understood that the packet is a packet constituting the same burst data as the previous packet. The packet accumulation means accumulates one burst data in the same transmission buffer by accumulating packets transmitted at intervals equal to or less than a predetermined threshold value in the same transmission buffer. The wireless base station according to the present invention has a storage unit, and stores, as a data arrival time, an arrival time of a packet whose arrival interval with the previous packet is larger than a predetermined threshold (adds a time stamp). That is, the time at which the first packet of the burst data arrives is stored as the data arrival time, and the arrival time of other packets is not managed. With this configuration, it is possible to reduce the processing delay due to the time stamp addition and perform priority control of packet transmission based on the arrival time of the first packet of the burst data.
[0012]
The wireless base station further includes a remaining data amount measuring unit that measures the amount of data remaining in the transmission buffer, and the storage unit stores the data arrival when the packet remains in the transmission buffer that stores the packet. The time is stored as a second data arrival time, and when the amount of data measured by the remaining data amount measuring means at the time of storing the second data arrival time is transmitted from the transmission buffer, the second data arrival time May be updated to the data arrival time.
[0013]
When storing the data arrival time, if a packet still remains in the transmission buffer in which the packet is to be stored, the remaining packet is a packet constituting burst data different from the packet to be stored. is there. In such a case, for a packet arriving at an interval larger than a predetermined threshold value, the arrival time is stored as a second data arrival time, whereby two burst data are accumulated in one transmission buffer, and Data arrival time can be managed. In addition, when the amount of data remaining when the second data arrival time is stored is transmitted from the transmission buffer, the second data arrival time is updated to the data arrival time, so that the data arrival time is updated. Priority control can be performed using time.
[0014]
In the above radio base station, the storage means may reset the data arrival time relating to the transmission buffer when transmitting all the packets stored in the transmission buffer.
[0015]
Since one burst data is stored in the same transmission buffer, when all the packets stored in the transmission buffer are transmitted, the burst data composed of those packets has been transmitted, so the data arrival time is reset. Is preferred.
[0016]
A radio base station according to the present invention is a radio base station that performs packet communication with a plurality of mobile stations, and a receiving unit that receives information about a data generation time transmitted from each mobile station; Priority control means for controlling the priority of packet reception from the mobile station based on the data generation time received by the mobile station.
[0017]
The radio base station according to the present invention includes receiving means for receiving information on the data generation time transmitted from the mobile station, and can grasp the time at which the packet to be transmitted has occurred in each mobile station. The wireless base station has priority control means and performs priority control based on the data generation time at each mobile station, thereby reducing transmission delay of data transmitted from the mobile station to the wireless base station. Can be.
[0018]
The mobile station according to the present invention is a mobile station that performs packet communication with a radio base station, and stores a transmission buffer for storing packets to be transmitted and a time at which accumulation of the packets in the transmission buffer is started. It is characterized by comprising storage means for storing the data generation time for the transmission buffer as data generation time, and transmission means for transmitting the information on the data generation time stored in the storage means to the radio base station.
[0019]
The mobile station according to the present invention has storage means and stores the time when the accumulation of the packet in the transmission buffer is started as the data generation time, so that the time when the first packet of the burst data is accumulated is stored ( Since a time stamp is added) and other packets are not managed, processing delay in the mobile station can be reduced. In addition, the mobile station according to the present invention has transmission means for transmitting information relating to the data generation time to the radio base station, so that the radio base station transmits a signal from the mobile station based on the data generation time at each mobile station. Priority control of data transmission to the base station can be performed.
[0020]
Further, the mobile station according to the present invention is a mobile station that performs packet communication with a radio base station, a transmission buffer that stores packets to be transmitted, and an occurrence interval measuring unit that measures an interval of generating packets. Determining means for determining the magnitude of a packet generation interval measured by the generation interval measurement means and a predetermined threshold; and generating a subsequent packet when the determination means determines that the generation interval is larger than the predetermined threshold. Storage means for storing the time as the data generation time, and transmission means for transmitting information on the data generation time stored in the storage means to the radio base station.
[0021]
The mobile station according to the present invention has a determination unit, and determines the magnitude of the packet generation interval measured by the generation interval measurement unit and a predetermined threshold value, so that the packet generated by the mobile station is at the beginning of the burst data. It can be determined whether the packet is a packet. In other words, if the occurrence interval of a certain packet with a previously generated packet is larger than a predetermined threshold, the packet must be a packet constituting burst data different from the previous packet, that is, the first packet of new burst data. In the case where the interval between the packet and the previously generated packet is equal to or smaller than the predetermined threshold value, it is determined that the packet is a packet constituting the same burst data as the previous packet. Further, the mobile station according to the present invention has a storage unit, and stores, as a data generation time, an occurrence time of a packet whose occurrence interval with the previous packet is larger than a predetermined threshold (time stamp is given). That is, the time at which the first packet of the burst data occurs is stored as the data occurrence time, and the occurrence time of the other packets is not managed. With such a configuration, it is possible to reduce the processing delay due to the time stamp addition. In addition, the mobile station according to the present invention has transmission means for transmitting information relating to the data generation time to the radio base station, so that the radio base station transmits a signal from the mobile station based on the data generation time at each mobile station. Priority control of data transmission to the base station can be performed.
[0022]
The mobile station further includes a remaining data amount measuring unit that measures the amount of data remaining in the transmission buffer, and the storage unit stores a data generation time when a packet remains in the transmission buffer that stores the packet. Is stored as the second data generation time, and when the amount of data measured by the remaining data amount measuring means at the time of storing the second data generation time is transmitted from the transmission buffer, the second data generation time is stored. The update may be performed at the data generation time.
[0023]
When the data generation time is stored, if a packet still remains in the transmission buffer, the remaining packet is a packet constituting burst data different from the packet to be stored. In such a case, for packets generated at intervals larger than a predetermined threshold, the time of occurrence is stored as the second data generation time, so that two burst data are accumulated in one transmission buffer, and Data generation time can be managed. In addition, when the amount of data remaining when the second data generation time is stored is transmitted from the transmission buffer, the second data generation time is updated to the data generation time, so that the data generation time is updated. Priority control can be performed using time.
[0024]
In the mobile station, the storage unit may reset the data generation time for the transmission buffer when transmitting all the packets stored in the transmission buffer.
[0025]
When all of the packets stored in the transmission buffer have been transmitted, the burst data included in those packets has been transmitted, so it is preferable to reset the data generation time.
[0026]
A wireless communication system according to the present invention includes the wireless base station and the mobile station, and gives priority to packet communication from the wireless base station to the mobile station and / or packet communication from the mobile station to the wireless base station. It is characterized by controlling.
[0027]
A wireless communication system according to the present invention includes the above-described wireless base station and mobile station. As a result, the arrival or occurrence time of the first packet of the burst data is stored (time stamp is given), and no time stamp is given to other packets, so that the processing delay in the radio base station or the mobile station is reduced, and the QoS is reduced. Can be realized.
[0028]
A wireless communication method according to the present invention is a wireless communication method for performing packet communication in a wireless communication system having a wireless base station and a mobile station, wherein the wireless base station measures an arrival interval of a packet arriving at the wireless base station. An arrival interval measurement step, a determination step in which the radio base station determines the magnitude of the arrival interval of the packet measured in the arrival interval measurement step and a predetermined threshold, and a determination that the arrival interval is equal to or less than the predetermined threshold in the determination step If the packet arrived later is stored in the same transmission buffer as the packet that arrived earlier, and if the arrival interval was determined to be greater than the predetermined threshold in the determination step, the packet that arrived later arrived earlier Packet accumulation step to accumulate in the same or different transmission buffer as the packet and accumulation of data in the transmission buffer start Storing the stored time as the data arrival time for the transmission buffer by the radio base station, and the radio base station performs priority control of packet transmission based on the data arrival time for each transmission buffer stored in the storage step It has a priority control step and a transmission step in which the radio base station transmits a packet to the mobile station in the order controlled in the priority control step.
[0029]
In the wireless communication method according to the present invention, the arrival interval of the packet is measured in the arrival interval measuring step, and the magnitude of the packet arrival interval and the predetermined threshold value is determined in the determining step, so that the packet arriving at the wireless base station is burst. It can be determined whether or not it is the first packet of data. That is, if the arrival interval of a certain packet with a packet that has arrived earlier is larger than a predetermined threshold, the packet must be a packet that constitutes burst data different from the previous packet, that is, the first packet of new burst data. If the arrival interval with the previously arrived packet is less than or equal to the predetermined threshold value, it can be understood that the packet is a packet constituting the same burst data as the previous packet. In the packet storing step, one burst data is stored in the same transmission buffer by storing packets transmitted at intervals equal to or less than a predetermined threshold value in the same transmission buffer. The wireless communication method according to the present invention includes a storing step, in which the time when packets are started to be stored in the transmission buffer is stored as a data arrival time (time stamp is given), and the packets are already stored in the transmission buffer. In this case, the data arrival time is not stored. That is, the time at which the first packet of the burst data is accumulated in the transmission buffer is stored as the data arrival time, and the arrival time of the other packets is not managed. With this configuration, it is possible to reduce the processing delay in the wireless base station due to the addition of the time stamp, and to perform the priority control of the packet transmission based on the arrival time of the first packet of the burst data.
[0030]
Further, the wireless communication method according to the present invention is a wireless communication method for performing packet communication in a wireless communication system having a wireless base station and a mobile station, wherein the wireless base station determines the arrival interval of packets arriving at the wireless base station. An arrival interval measuring step for measuring, a determining step in which the radio base station determines the magnitude of the packet arrival interval measured in the arrival interval measuring step and a predetermined threshold, and the arrival interval being equal to or smaller than the predetermined threshold in the determining step If it is determined that the packet arrived later is stored in the same transmission buffer as the packet that arrived earlier, and if it is determined in the determination step that the arrival interval is greater than the predetermined threshold, the packet that arrived later is stored first. A packet accumulation step of accumulating in the same or different transmission buffer as an arriving packet, and an arrival interval in the determination step When it is determined that the packet is larger than the predetermined threshold, the radio base station stores the time at which the subsequent packet arrives as the data arrival time for the transmission buffer in which the packet is stored, and A priority control step in which the wireless base station performs priority control of packet transmission based on the data arrival time of the transmission buffer, and a transmission step in which the wireless base station transmits a packet to the mobile station in the order controlled in the priority control step, Characterized by having
[0031]
In the wireless communication method according to the present invention, the arrival interval of the packet is measured in the arrival interval measuring step, and the magnitude of the packet arrival interval and the predetermined threshold value is determined in the determining step, so that the packet arriving at the wireless base station is burst. It can be determined whether or not it is the first packet of data. That is, if the arrival interval of a certain packet with a packet that has arrived earlier is larger than a predetermined threshold, the packet must be a packet that constitutes burst data different from the previous packet, that is, the first packet of new burst data. If the arrival interval with the previously arrived packet is less than or equal to the predetermined threshold value, it can be understood that the packet is a packet constituting the same burst data as the previous packet. In the packet storing step, one burst data is stored in the same transmission buffer by storing packets transmitted at intervals equal to or less than a predetermined threshold value in the same transmission buffer. The wireless communication method according to the present invention includes a storage step, and stores, as a data arrival time, an arrival time of a packet whose arrival interval with a previous packet is larger than a predetermined threshold (time stamp is added). That is, the time at which the first packet of the burst data arrives is stored as the data arrival time, and the arrival time of other packets is not managed. According to such a method, it is possible to reduce the processing delay due to the addition of the time stamp and to perform the priority control of the packet transmission based on the arrival time of the first packet of the burst data.
[0032]
The wireless communication method further includes a remaining data amount measuring step of measuring the amount of data remaining in the transmission buffer by the wireless base station, and in the storing step, when a packet remains in the transmission buffer storing the packet. Means that the radio base station stores the data arrival time as the second data arrival time and transmits the amount of data measured by the remaining data amount measurement means from the transmission buffer when the second data arrival time is stored. Further, the second data arrival time may be updated to the data arrival time.
[0033]
When storing the data arrival time, if a packet still remains in the transmission buffer storing the packet, the remaining packet is a packet constituting burst data different from the packet to be stored. In such a case, for a packet arriving at an interval larger than a predetermined threshold value, the arrival time is stored as a second data arrival time, whereby two burst data are accumulated in one transmission buffer, and Data arrival time can be managed. In addition, when the amount of data remaining when the second data arrival time is stored is transmitted from the transmission buffer, the second data arrival time is updated to the data arrival time, so that the data arrival time is updated. Priority control can be performed using time.
[0034]
The wireless communication method may further include an arrival time reset step in which, when all the packets stored in the transmission buffer have been transmitted, the wireless base station resets the data arrival time for the transmission buffer.
[0035]
Since one burst data is stored in the same transmission buffer, when all the packets stored in the transmission buffer are transmitted, the burst data composed of those packets has been transmitted, so the data arrival time is reset. Is preferred.
[0036]
A wireless communication method according to the present invention is a wireless communication method for performing packet communication in a wireless communication system having a wireless base station and a mobile station, wherein the mobile station measures the generation interval of packets in the mobile station. And a storage step in which the mobile station stores the time at which the accumulation of data in the transmission buffer is started as the data generation time for the transmission buffer, and the mobile station stores information on the data generation time stored in the storage step in the radio base station. , And a priority control step in which the wireless base station gives priority to packet reception from the mobile station based on the data generation time transmitted in the transmission step.
[0037]
Since the radio communication method according to the present invention has a storage step of storing the time at which accumulation of packets in the transmission buffer is started in the mobile station as the data generation time, the time at which the first packet of burst data is accumulated Is stored (a time stamp is added) and other packets are not managed, so that a processing delay in the mobile station can be reduced. Also, in the radio communication method according to the present invention, in the transmitting step, the information on the data generation time is transmitted from the mobile station to the radio base station. , Priority control of data transmission from the mobile station to the wireless base station can be performed.
[0038]
A wireless communication method according to the present invention is a wireless communication method for performing packet communication in a wireless communication system having a wireless base station and a mobile station, wherein the mobile station measures the generation interval of packets in the mobile station. A determination step in which the mobile station determines the magnitude of the packet generation interval measured in the generation interval measurement step and a predetermined threshold; and if the generation interval is determined to be larger than the predetermined threshold in the determination step, The mobile station stores the time at which the packet has occurred as the data generation time, the mobile station transmits information on the data generation time stored in the storage step to the radio base station, and Priority control in which the radio base station prioritizes packet reception from the mobile station based on the data occurrence time A method, characterized by having a.
[0039]
The wireless communication method according to the present invention has a determining step, and determines the magnitude of a packet occurrence interval and a predetermined threshold value in the mobile station measured in the occurrence interval measuring step, so that a packet generated in the mobile station is determined. Is the first packet of the burst data. In other words, if the occurrence interval of a certain packet with a previously generated packet is larger than a predetermined threshold, the packet must be a packet constituting burst data different from the previous packet, that is, the first packet of new burst data. In the case where the interval between the packet and the previously generated packet is equal to or smaller than the predetermined threshold value, it is determined that the packet is a packet constituting the same burst data as the previous packet. Further, the wireless communication method according to the present invention has a storage step of storing, as a data generation time, a time of occurrence of a packet whose occurrence interval with the previous packet is greater than a predetermined threshold (giving a time stamp). That is, in the storing step, the time at which the first packet of the burst data has occurred is stored as the data occurrence time, and the occurrence time of the other packets is not managed. With such a method, it is possible to reduce the processing delay due to the time stamp addition. Further, since the radio communication method according to the present invention has a transmission step of transmitting information on a data generation time to the radio base station, in the priority control step, the radio base station performs a process based on the data generation time in each mobile station. Thus, priority control of data transmission from the mobile station to the wireless base station can be performed.
[0040]
The wireless communication method further includes a remaining data amount measuring step in which the mobile station measures the amount of data remaining in the transmission buffer, and the storing step includes a step of: The mobile station stores the data generation time as a second data generation time, and transmits the amount of data measured by the remaining data amount measurement unit from the transmission buffer when the second data arrival time is stored. , The second data generation time may be updated to the data generation time.
[0041]
When the data generation time is stored, if a packet still remains in the transmission buffer, the remaining packet is a packet constituting burst data different from the packet to be stored. In such a case, for packets generated at intervals larger than a predetermined threshold, the time of occurrence is stored as the second data generation time, so that two burst data are accumulated in one transmission buffer, and Data generation time can be managed. In addition, when the amount of data remaining when the second data generation time is stored is transmitted from the transmission buffer, the second data generation time is updated to the data generation time, so that the data generation time is updated. Priority control can be performed using time.
[0042]
The wireless communication method may further include an occurrence time reset step in which, when all packets stored in the transmission buffer have been transmitted, the mobile station resets the data generation time for the transmission buffer.
[0043]
When all of the packets stored in the transmission buffer have been transmitted, the burst data included in those packets has been transmitted, so it is preferable to reset the data generation time.
[0044]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, preferred embodiments of a wireless communication system according to the present invention will be described in detail with reference to the drawings. In the description of the drawings, the same elements will be denoted by the same reference symbols, without redundant description.
[0045]
FIG. 1 is a diagram showing an outline of a wireless communication system 1 to which the present invention is applied. Here, a cellular system in which various applications are used in each mobile station 30 and various QoS requests exist will be described as an example. The mobile station 30 uses applications that require real-time properties such as voice communication, video conference, and streaming, and it is of the utmost importance to support delay time for these mobile stations 30.
[0046]
FIG. 2 is a diagram illustrating a configuration of the wireless communication system 1 according to the first embodiment, and illustrates a configuration of the wireless base station 10 and the mobile station 30 when transmitting a packet from the wireless base station 10 to the mobile station 30 in a downlink. FIG. As shown in FIG. 2, the radio base station 10 includes an arrival interval measurement unit 11, a determination unit 12, a packet classification unit 13, a scheduling processing unit 14, a radio resource allocation processing unit 15, a transmission buffer 16, a storage unit 17, a transmission It has a unit 18 and a receiving unit 19. The transmission buffer 16 has a function of temporarily storing packets arriving from the core network until the packets are transmitted to the mobile station 30. The transmission buffer 16 includes a plurality of transmission buffers 16A to 16E, and can perform not only transmission in the order of arrival of packets but also priority control for transmitting packets with high urgency. Here, the number of the transmission buffers 16A to 16E is arbitrary and is not limited to five. The arrival interval measuring unit 11 has a function of measuring an arrival interval of a packet arriving from the core network. Information on the packet arrival interval Ti measured here is input to the determination unit 12. Based on the packet arrival interval Ti input from the arrival interval measuring unit 11, the determining unit 12 determines whether the arriving packet is a packet constituting the same burst data as the earlier arriving packet, or Has a function of determining whether a packet constitutes different burst data. Specifically, when the packet arrival interval Ti is equal to or smaller than a predetermined threshold Tth, it is determined that the packet constitutes the same burst data as the previously arrived packet, and the packet arrival interval Ti is smaller than the threshold Tth. If it is larger, it is determined that the packet constitutes burst data different from the previously arrived packet. The packet classifying unit 13 has a function of classifying the arriving packet and storing it in any of the transmission buffers 16A to 16E. The packet classifying unit 13 classifies packets constituting the same burst data so as to be stored in the same transmission buffers 16A to 16E. The storage unit 17 has a function of storing the time at which the accumulation of packets is started in each of the transmission buffers 16A to 16E as the data arrival time. It is preferable that each data arrival time stored in the storage unit 17 be reset when all the packets in the transmission buffer have been transmitted. The scheduling processing unit 14 has a function of performing priority control of packet transmission based on the data arrival time stored in the storage unit 17. Specifically, among the transmission buffers 16A to 16E, it is preferable to preferentially transmit the packets stored in the transmission buffer with the oldest data arrival time, so that the packets stay in the transmission buffer 16 for a long time and the communication quality is high. Can be prevented. The radio resource allocation processing unit 15 has a function of allocating radio resources for transmitting a packet.
[0047]
The mobile station 30 has a QoS control information creation unit 31, a transmission unit 32, and a reception unit 33. The transmitting unit 32 and the receiving unit 33 have a function of communicating with the wireless base station 10. The QoS control information creation unit 31 has a function of creating information on communication quality such as information on a transmission error rate and reception power as QoS control information. The created QoS control information is transmitted to the radio base station 10 by the transmission unit 32.
[0048]
Next, an operation of transmitting a packet from the wireless base station 10 to the mobile station 30 by the wireless communication system 1 will be described with reference to FIG. 3, and a wireless communication method according to an embodiment of the present invention will be described. FIG. 3 is a flowchart showing the operation of the radio base station 10.
[0049]
First, the wireless base station 10 receives a packet arriving from the core network (S10), and measures an arrival interval of the arriving packet (S12). The arrival interval Ti with the packet that arrived first is calculated. Next, the determining unit 12 determines whether or not the arriving data is a packet that constitutes the same burst data as the previously arriving data. Specifically, the magnitude of the arrival interval Ti is compared with a predetermined threshold Tth (S14). If the arrival interval Ti is equal to or smaller than the threshold Tth, the packet constitutes the same burst data as the previous packet. If the arrival interval Ti is larger than the threshold value Tth, it is determined that the packet constitutes burst data different from the previous packet. If it is determined that the burst data is different, it is understood that the packet is the first packet of the burst data.
[0050]
When it is determined that the arrival interval Ti is equal to or smaller than the threshold value Tth, the packet classification unit 13 stores the packet in the same transmission buffer 16 as the packet in which the previous packet is stored (S16). If it is determined that the arrival interval Ti is larger than the threshold value Tth, the packet classification unit 13 stores the packet in an arbitrary transmission buffer 16 having a sufficient capacity (S18). At this time, it is determined whether there is any remaining packet in the transmission buffer 16 where the packet should be stored (S20). If there is no remaining packet in the transmission buffer 16, the current time is stored in the storage unit 17 as the data arrival time To for the transmission buffer 16 (S22). If there are remaining packets in the transmission buffer 16, the current time is stored in the storage unit 17 as the second data arrival time Tn, and the remaining data amount is stored in the counter D (S24). Here, the information stored in the storage unit 17 will be described with reference to FIGS. 4A and 4B. FIG. 4A shows a state where the second burst data is accumulated in the transmission buffer 16A in which the first burst data is accumulated. Referring to FIG. 4A, it can be seen that the head buffer of the first burst data arrives at time To and the head buffer of the second burst data arrives at time Tn. In such a case, as shown in FIG. 4B, the storage unit 17 stores information on the time To and the time Tn and the amount of remaining data (first burst data) as a counter D. Although not shown in FIG. 4B, these pieces of information are stored in the transmission buffers 16B to 16E in the same manner. In the present embodiment, the second data arrival time Tn is stored for the following reason. If the current time is set to the data arrival time To when there are remaining packets, the remaining packets are also controlled based on the new data arrival time To, which causes a problem that packet transmission is delayed. For example, referring to FIG. 4B, the data arrival time To of the remaining packet is 16:32:22, but the data arrival time is updated by the current time 16:32:24 at which the second burst data arrives. Then, the remaining packets are also scheduled based on the new data arrival time 16:32:24, and are controlled as if they were stored at the current time, regardless of whether the packets have already stayed for 2 seconds, and transmitted. Is delayed. In the present embodiment, in order to avoid such a situation, the data arrival time To is not updated until the remaining packet is transmitted by the processing in step S24.
[0051]
Next, the wireless base station 10 performs scheduling by the scheduling processing unit 14 and performs priority control of a packet to be transmitted (S26). Here, the scheduling processing unit 14 preferentially extracts the packet from the transmission buffer 16 having the old data arrival time To stored in the storage unit 17. Subsequently, the radio resource allocation processing unit 15 allocates a radio resource for performing communication with the mobile station 30, and the transmitting unit 18 transmits a packet (S26). When a packet is extracted from the transmission buffer 16 in which the remaining data amount is stored in the counter D and transmitted, the counter D is reduced by the number of transmitted packets (S28). Then, it is determined whether or not the counter D has become 0 (S30). When the counter D becomes 0, the second data arrival time Tn is substituted for the data arrival time To and updated (S32). As a result, the packets stored in the transmission buffer 16 are preferentially controlled by the new data arrival time To. The wireless base station 10 according to the present embodiment receives a packet arriving from the core network (S10), and repeats the flow described above. In FIG. 3, for the sake of convenience, the process returns to step S10 of packet arrival. However, even when a packet does not always arrive from the core network, scheduling for packet transmission and packet transmission are performed.
[0052]
The wireless base station 10 (wireless communication system 1) according to the first embodiment stores the data arrival time of the burst data stored in each transmission buffer 16 in the storage unit 17, and performs the scheduling process based on the data arrival time. Since the unit 14 performs the priority control process, the QoS request can be satisfied by controlling the delay time from the arrival of the packet from the core network to the transmission to the mobile station 30. In addition, since the time at which the first packet of the burst data arrives is stored as the data arrival time and the arrival time of each packet is not managed, the processing delay caused by adding a time stamp to each packet is eliminated. Can support delay time.
[0053]
Similarly, the wireless communication method according to the first embodiment can also eliminate the processing delay caused by adding a time stamp to each packet and support the delay time to satisfy the QoS requirement.
[0054]
In the above embodiment, the case where a plurality of burst data is accumulated in each of the transmission buffers 16A to 16E has been described. However, when only one burst data is accumulated in each of the transmission buffers 16A to 16E, the following is performed. The wireless base station 10 can be operated by a simple flow. FIG. 5 is a flowchart illustrating the operation of the radio base station 10.
[0055]
First, when the radio base station 10 receives a packet arriving from the core network (S10), the arrival interval measuring unit 11 measures the arrival interval Ti of the packet, and the determining unit 12 determines that the arrival interval Ti is equal to the threshold Tth. Is performed, the packet is stored in the transmission buffer 16 (S16). The flow up to this point is the same as the flow described in FIG. When storing a packet in any of the transmission buffers 16A to 16E, it is determined whether or not the packet exists in the transmission buffer (S32). If there is no packet in the transmission buffer, the data arrival time for the transmission buffer is updated with the current time (S34) and stored in the storage unit 17. If there is a packet in the transmission buffer 16, the process proceeds to the next step without performing the process related to the data arrival time.
[0056]
Next, the scheduling processing unit 14 performs priority control of packet transmission based on the data arrival time stored in the storage unit 17. Then, based on the control by the scheduling processing unit 14, the radio resource allocation processing unit 15 allocates the radio resources and transmits the packet to the mobile station 30 (S36).
[0057]
With the configuration in which the storage unit 17 stores the time at which packets start being accumulated in the transmission buffer 16 as the data arrival time, the data arrival time can be stored with a simple configuration.
[0058]
Next, a wireless communication system 1 according to a second embodiment of the present invention will be described. FIG. 6 is a diagram showing a configuration of the radio base station 10a and the mobile station 30a when transmitting a packet from the mobile station 30a to the radio base station 10a on the uplink.
[0059]
The wireless base station 10a includes a mobile station classifying unit 20, a scheduling processing unit 14, a wireless resource allocation processing unit 15, a transmitting unit 18, and a receiving unit 19. The mobile station classifying unit 20 has a function of classifying mobile stations based on QoS information received from each mobile station based on a maximum allowable delay or the like. The scheduling processing unit 14 has a function of performing priority control on reception of a packet transmitted from the mobile station 30a based on the QoS control information transmitted from the mobile station 30a. The radio resource allocation processing unit 15 has a function of allocating radio resources for receiving a packet from the mobile station 30a.
[0060]
The mobile station 30a includes an occurrence interval measurement unit 34, a determination unit 35, a transmission buffer 36, a storage unit 37, a QoS control information creation unit 31, a transmission unit 32, and a reception unit 33. The transmission buffer 36 has a function of temporarily storing packets generated in the mobile station 30a until the packets are transmitted to the radio base station 10a. Here, the case where the number of the transmission buffers 36 is one will be described as an example, but the number of the transmission buffers 36 is not limited to one and may be plural. The occurrence interval measuring unit 34 has a function of measuring an occurrence interval Ti of a packet generated in the mobile station 30a. Information on the measured packet generation interval Ti is input to the determination unit 35. The case where a packet is generated in the mobile station 30a is, for example, a case where a mail is created or an image is captured in the mobile station 30a. Based on the packet generation interval Ti input from the generation interval measurement unit 34, the determination unit 35 determines whether the generated packet is a packet constituting the same burst data as the previously generated packet, or Has a function of determining whether a packet constitutes different burst data. Specifically, when the packet generation interval Ti is equal to or less than a predetermined threshold Tth, it is determined that the packet constitutes the same burst data as the previously generated packet, and the packet generation interval Ti is set to be smaller than the threshold Tth. If it is larger, it is determined that the packet constitutes burst data different from the previously generated packet. The storage unit 37 has a function of storing the time when the accumulation of the packet is started in the transmission buffer 36 as the data generation time. Note that the data generation time stored in the storage unit 37 is preferably reset when all the packets in the transmission buffer 36 have been transmitted. The QoS control information creation unit 31 has a function of creating information on communication quality such as information on a transmission error rate and reception power as QoS control information. Here, the information on the data generation time stored in the storage unit 37 is also included in the QoS control information. The created QoS control information is transmitted by the transmission unit 32 to the radio base station 10a.
[0061]
Next, an operation of the wireless communication system 2 according to the second embodiment will be described with reference to FIG. 7, and a wireless communication method according to the second embodiment will be described.
[0062]
First, a packet is generated in the mobile station 30a (S40). The mobile station 30a stores the generated packet in the transmission buffer 36 (S42). At this time, it is determined whether or not a remaining packet exists in the transmission buffer 36 (S44). If there is no remaining packet in the transmission buffer 36, the data generation time is updated to the current time and stored in the storage unit 37 (S46). If there is a packet in the transmission buffer 36, the process proceeds to the next step without performing the processing on the data generation time.
[0063]
Next, the QoS control information creation unit 31 creates QoS control information (S48). At this time, the information on the data generation time stored in the storage unit 37 is included in the QoS control information. The mobile station 30a transmits the created QoS control information to the wireless base station 10a (S48).
[0064]
Upon receiving the QoS control information transmitted from the mobile station 30a (S50), the radio base station 10a schedules which mobile station 30a receives the packet by the scheduling processing unit 14 (S52). Then, the radio base station 10a receives the packet transmitted from the mobile station 30a according to the scheduling in the scheduling processing unit 14 (S54, S56). Although not shown in FIG. 7, the radio base station 10a transmits a control signal to the mobile station 30a determined to communicate by the scheduling processing unit 14, and the mobile station 30a is transmitted based on the control signal. Transmits a packet to the wireless base station 10a (S54), and the wireless base station 10a receives the packet (S56).
[0065]
The radio communication system 2 according to the second embodiment stores a data generation time at which data has occurred in the mobile station 30a, and transmits the data generation time to the radio base station 10a by including the data generation time in the QoS control information. The station 10a can perform priority control of packet reception based on the data generation time transmitted from the mobile station 30a. As a result, it is possible to control the delay time from when a packet is generated in the mobile station 30a to when the packet is transmitted to the radio base station 10a, thereby satisfying the QoS requirement. Also, the time at which the first packet of the burst data occurs is stored as the data occurrence time, and the occurrence time of each packet is not managed, so that processing delay caused by adding a time stamp to each packet is eliminated, Can support delay time.
[0066]
Similarly, in the wireless communication method according to the present embodiment, processing delay caused by adding a time stamp to each packet can be eliminated, and delay time can be supported.
[0067]
In the second embodiment, the data generation time is updated when the packet does not exist in the transmission buffer 36. However, the data generation time may be updated based on the packet generation interval. FIG. 8 is a flowchart illustrating another example of the operation of the wireless communication system 2 according to the second embodiment. When a packet is generated in the mobile station 30a (S60), the data generation interval Ti of the packet is measured by the generation interval measuring unit 34 (S62). Next, the determination unit 35 determines the magnitude of the data generation interval Ti and the threshold value Tth (S64). If the data generation interval Ti is equal to or smaller than the threshold value Tth, the data generation time is not updated. If the data generation interval Ti is larger than the threshold value Tth, it is determined whether or not there is any remaining data in the transmission buffer 36 (S66). If there is no remaining data, the data generation time To is updated with the current time (S66). S68). If there is remaining data in the transmission buffer 36, the current time is stored in the storage unit 37 as the second data arrival time Tn, and the remaining data amount is stored in the counter D (S70). Then, the generated packet is stored in the transmission buffer 36 (S72). After that, the mobile station 30a creates QoS control information including the data generation time To and transmits it to the radio base station 10a (S74). Upon receiving the QoS information transmitted from the mobile station 30a (S76), the radio base station 10a schedules packet reception based on the data generation time included in the received QoS information (S78), and the mobile station 30a The transmitted packet is received (S80, S82).
[0068]
Next, the mobile station 30a decrements the counter D by the number of transmitted packets (S84), and determines whether the counter D is 0 (S86). When the counter D becomes 0, the second data generation time Tn is substituted for the data generation time To and updated (S88). By transmitting the QoS information including the data occurrence time To to the base station 10a, the mobile station 30a is scheduled by the new data occurrence time To.
[0069]
As described above, the wireless communication system, the wireless base station, and the mobile station of the present invention have been described in detail with the embodiments. However, the present invention is not limited to the above embodiments.
[0070]
In the above embodiment, the case where priority control is performed based on the data arrival time has been described as an example. However, priority control may be performed using the data arrival time and the remaining data amount.
[0071]
In the above embodiment, in order to facilitate understanding of the features of the present invention, delay control in a downlink for transmitting a packet from the radio base station 10 to the mobile station 30 and transmission of a packet from the mobile station 30a to the radio base station 10a are described. Although the delay control in the uplink is described in separate embodiments, a wireless base station, a mobile station, and a wireless communication system that can perform delay control of packet transmission in both the uplink and the downlink are configured. You may.
[0072]
【The invention's effect】
The present invention is effective as a control method for supporting real-time communication in a packet radio communication system in which various QoS requirements exist. Generally, when a request is made to reduce the delay time in real-time traffic, a process of measuring a buffer residence time and adding a time stamp to manage the arrival time at the transmission buffer is performed. Conventionally, an enormous process of adding a time stamp to each packet has been performed. However, according to the present invention, only the time at which a plurality of packets arrives is stored while supporting delay time. It can be done with simple processing. Further, by storing the remaining data, the arrival time of each burst data can be grasped without giving a time stamp to all packets.
[Brief description of the drawings]
FIG. 1 is a diagram showing an outline of a wireless communication system to which the present invention is applied.
FIG. 2 is a diagram illustrating a configuration of a wireless communication system according to the first embodiment.
FIG. 3 is a flowchart illustrating another operation of the radio base station according to the first embodiment.
FIGS. 4A and 4B are diagrams for explaining information stored in a storage unit.
FIG. 5 is a flowchart showing an operation of the radio base station according to the first embodiment.
FIG. 6 is a diagram illustrating a configuration of a wireless communication system according to a second embodiment.
FIG. 7 is a flowchart showing an operation of the radio base station according to the second embodiment.
FIG. 8 is a flowchart illustrating another operation of the radio base station according to the second embodiment.
FIG. 9 is a diagram for explaining a cause of a transmission delay in real-time communication.
FIG. 10 is a diagram for explaining a problem in conventional time stamping.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Wireless communication system, 10 ... Wireless base station, 11 ... Arrival interval measurement part, 12 ... Judgment part, 13 ... Packet classification part, 14 ... Scheduling processing part, 15 ··· Wireless resource allocation processing unit, 16: transmission buffer, 17: storage unit, 18: transmission unit, 19: reception unit, 20: mobile station classification unit, 30: mobile Station, 31: QoS control information creation unit, 32: transmission unit, 33: reception unit, 34: occurrence interval measurement unit, 35: determination unit, 36: transmission buffer, 37 ... Storage unit.

Claims (15)

A radio base station that performs packet communication with a mobile station,
A plurality of transmission buffers for storing packets to be transmitted,
Arrival interval measuring means for measuring the arrival interval of the packet,
Determining means for determining the magnitude of the arrival interval of the packet measured by the arrival interval measuring means and a predetermined threshold,
When the determining unit determines that the arrival interval is equal to or less than a predetermined threshold, the later arriving packet is stored in the same transmission buffer as the packet that arrived first, and the determining unit determines that the arrival interval is larger than the predetermined threshold. Packet storage means for storing a packet arriving later in the same or different transmission buffer as a packet arriving earlier,
Storage means for storing the time at which accumulation of data in the transmission buffer was started as data arrival time for the transmission buffer,
Priority control means for performing priority control of packet transmission based on the data arrival time for each transmission buffer stored in the storage means,
Comprising,
A wireless base station characterized by the above-mentioned. A radio base station that performs packet communication with a mobile station,
A plurality of transmission buffers for storing packets to be transmitted,
Arrival interval measuring means for measuring the arrival interval of the packet,
Determining means for determining the magnitude of the arrival interval of the packet measured by the arrival interval measuring means and a predetermined threshold,
When the determining unit determines that the arrival interval is equal to or less than a predetermined threshold, the later arriving packet is stored in the same transmission buffer as the packet that arrived first, and the determining unit determines that the arrival interval is larger than the predetermined threshold. Packet storage means for storing a packet arriving later in the same or different transmission buffer as a packet arriving earlier,
A storage unit that stores a time at which a subsequent packet arrives as a data arrival time for a transmission buffer in which the packet is accumulated, when the arrival unit determines that the arrival interval is greater than a predetermined threshold;
Priority control means for performing priority control of packet transmission based on the data arrival time for each transmission buffer stored in the storage means,
Comprising,
A wireless base station characterized by the above-mentioned. Further comprising a remaining data amount measuring means for measuring the amount of data remaining in the transmission buffer,
The storage means stores the data arrival time as a second data arrival time when a packet remains in the transmission buffer for storing the packet, and stores the second data arrival time when storing the second data arrival time. Updating the second data arrival time to the data arrival time when transmitting the data of the amount measured by the remaining data amount measurement means from the transmission buffer;
The radio base station according to claim 2, wherein: 4. The wireless communication device according to claim 1, wherein, when all of the packets stored in the transmission buffer are transmitted, the storage unit resets a data arrival time of the transmission buffer. 5. base station. A wireless base station that performs packet communication with a plurality of mobile stations,
Receiving means for receiving information about the data generation time transmitted from each of the mobile stations,
Priority control means for performing priority control of packet reception from the mobile station based on the data generation time received by the reception means,
A radio base station comprising: A mobile station that performs packet communication with a radio base station,
A transmission buffer for storing packets to be transmitted,
Storage means for storing the time at which the accumulation of packets in the transmission buffer was started as the data generation time for the transmission buffer;
Transmission means for transmitting information on the data occurrence time stored in the storage means to the radio base station,
Comprising,
A mobile station, characterized in that: 7. The mobile station according to claim 5, wherein the storage unit resets a data generation time of the transmission buffer when transmitting all packets stored in the transmission buffer. 8. A mobile station that performs packet communication with a radio base station,
A transmission buffer for storing packets to be transmitted,
Generating interval measuring means for measuring the generating interval of the packet,
Determining means for determining the magnitude of a packet generation interval measured by the generation interval measurement unit and a predetermined threshold,
When the occurrence interval is determined by the determination unit to be greater than a predetermined threshold, a storage unit that stores a time at which a subsequent packet occurs as a data occurrence time,
Transmission means for transmitting information on the data occurrence time stored in the storage means to the radio base station,
Comprising,
A mobile station, characterized in that: A wireless communication system comprising the wireless base station according to any one of claims 1 to 4 and a mobile station, wherein priority is given to packet communication from the wireless base station to the mobile station. A wireless communication method for performing packet communication in a wireless communication system having a wireless base station and a mobile station,
An arrival interval measuring step in which the radio base station measures an arrival interval of a packet arriving at the radio base station,
A determination step in which the radio base station determines the magnitude of the arrival interval of the packet measured in the arrival interval measurement step and a predetermined threshold,
When it is determined in the determining step that the arrival interval is equal to or smaller than the predetermined threshold, the packet arriving later is accumulated in the same transmission buffer as the packet arriving earlier, and the arrival interval is larger than the predetermined threshold in the determining step. A packet storing step of storing a packet arriving later in the same or different transmission buffer as a packet arriving earlier,
A storage step in which the radio base station stores a time at which accumulation of data in the transmission buffer is started as a data arrival time for the transmission buffer;
A priority control step in which the wireless base station performs priority control of packet transmission based on the data arrival time for each transmission buffer stored in the storage step,
A transmission step in which the radio base station transmits a packet to the mobile station according to the order controlled in the priority control step,
Having,
A wireless communication method, comprising: A wireless communication method for performing packet communication in a wireless communication system having a wireless base station and a mobile station,
An arrival interval measuring step in which the radio base station measures an arrival interval of a packet arriving at the radio base station,
A determination step in which the radio base station determines the magnitude of the arrival interval of the packet measured in the arrival interval measurement step and a predetermined threshold,
When it is determined in the determining step that the arrival interval is equal to or smaller than the predetermined threshold, the packet arriving later is accumulated in the same transmission buffer as the packet arriving earlier, and the arrival interval is larger than the predetermined threshold in the determining step. A packet storing step of storing a packet arriving later in the same or different transmission buffer as a packet arriving earlier,
When the arrival interval is determined to be greater than a predetermined threshold in the determining step, a storing step in which the wireless base station stores a time at which a subsequent packet arrives as a data arrival time for a transmission buffer in which the packet is stored; ,
A priority control step in which the wireless base station performs priority control of packet transmission based on the data arrival time for each transmission buffer stored in the storage step,
A transmission step in which the radio base station transmits a packet to the mobile station according to the order controlled in the priority control step,
Having,
A wireless communication method, comprising: The wireless base station further comprises a remaining data amount measuring step of measuring the amount of data remaining in the transmission buffer,
In the storing step, when a packet remains in the transmission buffer storing the packet, the radio base station stores the data arrival time as a second data arrival time, and stores the second data arrival time as a second data arrival time. Updating the second data arrival time to the data arrival time when transmitting the data of the amount measured by the remaining data amount measuring means from the transmission buffer when storing the data;
The wireless communication method according to claim 11, wherein: 13. The radio communication system according to claim 10, further comprising an arrival time reset step of resetting a data arrival time of the transmission buffer when the radio base station transmits all the packets stored in the transmission buffer. The wireless communication method according to claim 1. A wireless communication method for performing packet communication in a wireless communication system having a wireless base station and a mobile station,
An occurrence interval measuring step in which the mobile station measures an occurrence interval of a packet in the mobile station,
A storage step in which the mobile station stores a time at which accumulation of data in the transmission buffer is started as a data generation time for the transmission buffer;
A transmitting step in which the mobile station transmits information on the data generation time stored in the storing step to the radio base station,
A priority control step in which the wireless base station performs priority control on packet reception from the mobile station based on the data generation time transmitted in the transmission step,
A wireless communication method comprising: A wireless communication method for performing packet communication in a wireless communication system having a wireless base station and a mobile station,
An occurrence interval measuring step in which the mobile station measures an occurrence interval of a packet in the mobile station,
A determination step in which the mobile station determines the magnitude of a packet occurrence interval measured in the occurrence interval measurement step and a predetermined threshold,
When the occurrence interval is determined to be greater than a predetermined threshold in the determination step, a storage step in which the mobile station stores a time when a subsequent packet occurs as a data generation time,
A transmitting step in which the mobile station transmits information on the data generation time stored in the storing step to the radio base station,
A priority control step in which the wireless base station performs priority control on packet reception from the mobile station based on the data generation time transmitted in the transmission step,
A wireless communication method comprising:

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