JP2009100299A - Radio control apparatus, radio communication apparatus and radio control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the accuracy of QoS guarantee by determining transmission time satisfying QoS on the mobile station side based on the generation time of a radio band allocation request signal. <P>SOLUTION: A transmission request message buffer part 12 stores a signal for requesting radio band allocation to a base station. A request QoS information conversion part 11 and a dead line table processing part 13 determines time for transmitting a signal to the base station based on QoS information for regulating quality (QoS) which should be satisfied by communication with the base station and the time of generating the signal. A radio band allocation request signal generation part 14 controls the transmission timing of the signal stored in the transmission request message buffer part 12 based on the time determined by the request QoS information conversion part 11 and the dead line table processing part 13. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a radio control apparatus, a radio communication apparatus, and a radio control method that request a base station to allocate a radio band.

  Conventionally, in a radio system in which a plurality of mobile stations are connected to the same base station, uplink scheduling is performed by the base station based on a radio band allocation request signal transmitted from the mobile station to the base station. In general, the mobile station is notified of the result, and the mobile station generally transmits uplink data using the radio band given as the result (see, for example, Patent Document 1).

Regarding the timing for transmitting the radio band allocation request signal, generally, when the transmitted data is generated in the mobile station, the request is transmitted at some timing thereafter. In particular, in IEEE802.16-OFDMA (Orthogonal Frequency Division Multiple Access), 1 burst (burst) is defined in the uplink subframe, and the mobile station uses CDMA (Code Division Multiple Access) in the burst. A request signal is transmitted to the base station. Burst is a data allocation area defined by IEEE 82.16.
JP 2001-44914 A

  As described above, in a wireless system in which a plurality of mobile stations are connected to the same base station, in general, regarding the transmission timing of the radio band allocation request signal transmitted from the mobile station side to the base station, what When data to be transmitted is generated in the mobile station and a radio band allocation request signal is generated without being considered, the radio band allocation request signal is transmitted to the base station at some timing. However, there is no guarantee that the base station normally receives the radio band allocation request signal transmitted at that timing.

  Conventionally, the time when the radio band allocation request signal is generated and the timing when the base station receives the radio band allocation request signal from the mobile station are regarded as the same time, and the radio band allocation request signal from the mobile station is regarded as the base station. The base station controls QoS (Quality of Service, quality of service) related to communication from the mobile station to the base station based on the timing time received by the mobile station. Therefore, when the time when the radio band allocation request signal is generated at the mobile station and the timing when the base station receives the radio band allocation request signal from the mobile station are shifted, a data shift that is the basis of QoS control occurs. Therefore, there is a problem that the QoS guarantee related to the communication from the mobile station to the base station may not be satisfied.

  In IEEE802.16-OFDMA, the mobile station transmits a radio band allocation request signal to the base station using CDMA (Code Division Multiple Access). Therefore, the mobile station transmits a radio band allocation request signal but is not received due to a collision. Can also occur. Therefore, the radio band allocation request signal that has not been received due to the collision needs to be retransmitted by the mobile station to the base station, and the use efficiency of radio resources related to transmission of the uplink radio band allocation request signal is poor. was there. Further, the mobile station does not know whether the base station has received the radio band allocation request signal.

  The present invention has been made to solve the above-described problem, and a first object thereof is to provide a radio control apparatus, a radio communication apparatus, and a radio control method capable of improving the accuracy of QoS guarantee. It is a second object of the present invention to provide a radio control apparatus, radio communication apparatus, and radio control method capable of improving the utilization efficiency of radio resources related to transmission of uplink radio band allocation request signals.

  The present invention includes a signal storage unit (transmission request message buffer unit 12) that stores a signal for requesting a base station to allocate a radio band, and QoS information that defines a quality (QoS) to be satisfied by communication with the base station; A transmission time determination unit (request QoS information conversion unit 11, deadline table processing unit 13) that determines a time at which the signal is transmitted to the base station based on the time at which the signal is generated, and the transmission time determination. And a control unit (radio band allocation request signal generation unit) that controls transmission timing of the signal stored in the signal storage unit based on the time determined by the unit. It is.

  Moreover, in the radio control apparatus according to the present invention, the control unit further includes a plurality of the signals stored in the signal storage unit as a transmission signal.

  The present invention further includes a first monitoring unit (radio band allocation result analysis unit 15) that monitors a time required for radio band allocation from the base station, and the control unit further includes the first monitoring unit. The radio control apparatus is characterized in that the transmission timing of the signal stored in the signal storage unit is controlled based on the monitored time required for the radio band allocation.

  The present invention further includes a second monitoring unit (a radio wave environment monitoring unit 16) that monitors a radio wave environment state with the base station, and the control unit further includes the radio wave monitored by the second monitoring unit. The wireless control device controls transmission timing of the signal stored in the signal storage unit based on an environmental state.

  The present invention also provides a wireless communication device including a wireless control device.

  Further, the present invention provides a signal storing step for storing a signal requesting a base station to allocate a radio band, QoS information defining quality (QoS) to be satisfied by communication with the base station, and the signal is generated. A transmission time determining step for determining a time for transmitting the signal to the base station based on the time, and transmission of the signal stored in the signal storing step based on the time determined in the transmission time determining step. And a control step for controlling timing.

  According to the present invention, the transmission time satisfying the QoS is determined on the mobile station side based on the generation time of the radio band allocation request signal, so that the accuracy of QoS guarantee can be improved. Further, according to the present invention, since the radio band allocation request signals are collectively transmitted to the base station, the collision of the radio band allocation request signals is reduced, and the utilization efficiency of radio resources related to the transmission of the uplink radio band allocation request signal is reduced. Improvement is possible.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing a configuration of a wireless communication system according to an embodiment of the present invention. In the illustrated example, the wireless communication system includes a base station 1 and a mobile station 2 that transmits and receives data. A plurality of mobile stations 2 are connected to one base station 1 by radio. The mobile station 2 includes a radio control device.

  The mobile station 2 transmits to the base station 1 a radio band allocation request signal that is a message requesting allocation of a radio band used when transmitting data (packets) from the mobile station 2 to the base station 1. . In this embodiment, based on QoS (Quality of Service, quality of service) requirements that need to be satisfied when data is transmitted from the mobile station 2 to the base station 1, the mobile station 2 can The radio band allocation request signals are collectively transmitted.

FIG. 2 is a diagram showing the transmission timing of the radio band allocation request signal from the mobile station 2 to the base station 1 in the present embodiment.
(Step S101) In the mobile station 2, when a data transmission request from the mobile station 2 to the base station 1 is generated, the mobile station 2 generates a radio band allocation request signal. The generated radio band allocation request signal is stored in the transmission request message buffer unit 12. The radio band assignment request signal includes a connection ID and requested radio band amount information. The connection ID is an ID for identifying communication between the mobile station 2 and the base station 1. The requested wireless bandwidth information is information indicating the amount of wireless bandwidth that the mobile station 2 requests to allocate to the base station 1. The connection ID and the QoS information are associated with each other and stored in a storage unit (not shown) included in the mobile station 2. The QoS information includes allowable delay time information and minimum required throughput information required to satisfy QoS.

  (Step S <b> 102-1) The mobile station 2 collects and transmits the radio band allocation request signals stored in the transmission request message buffer unit 12 to the base station 1. The transmission timing is stored in the transmission request message buffer unit 12 in order to satisfy the QoS of all the radio band allocation request signals while making the transmission interval of the aggregated radio band allocation request signal (Aggregate Bandwidth request) as long as possible. The time (deadline) that must be transmitted is determined based on the earliest radio band allocation request signal. The deadline of each collected radio band allocation request signal is calculated based on the QoS information. In the example shown in the figure, a deadline is determined based on QoS information, and a transmission time is a time when a margin time (margin) is given to the determined deadline. The determination of the deadline, margin and transmission time will be described later.

  Note that the transmission timing may be advanced depending on the radio wave environment used for communication between the mobile station 2 and the base station 1. In the illustrated example, when the radio wave environment is good, the mobile station 2 collects and transmits to the base station 1 the radio band allocation request signals stored in the transmission request message buffer unit 12 at the timing of step S102-2. . The case where the transmission timing is advanced will be described later.

  FIG. 3 is a configuration diagram illustrating the configuration of the wireless control device according to the present embodiment. The radio network controller 10 generates a radio band allocation request signal to be transmitted to the base station 1. The radio control apparatus 10 includes a request QoS information conversion unit 11, a transmission request message buffer unit 12, a deadline table processing unit 13, a radio band allocation request signal generation unit 14, a radio band allocation result analysis unit 15, a radio wave An environment monitoring unit 16 and a storage unit 17 are provided.

  Next, with reference to FIG. 3, a transmission method of a radio band allocation request signal transmitted from the mobile station 2 to the base station 1 and a radio band allocation method from the base station 1 to the mobile station 2 will be described.

  At the start of a session between the mobile station 2 and the base station 1, a connection ID is determined. The connection ID is a number that is determined at the start of a session between the mobile station 2 and the base station 1 and that can uniquely determine a session between the mobile station 2 and the base station 1. Also, when the session between the mobile station 2 and the base station 1 starts, QoS information is set for the connection ID. The QoS information is information indicating the QoS of communication between the mobile station 2 and the base station 1.

  The requested QoS information conversion unit 11 calculates an allowable time from packet generation to transmission to the base station based on QoS information determined at the start of a session between the mobile station 2 and the base station 1. Further, the requested QoS information conversion unit 11 associates the QoS information determined at the start of a session between the mobile station 2 and the base station 1 and the allowable time, and stores them in the storage unit 17 as an allowable time table.

  FIG. 4 is a diagram showing an acceptance time table in the present embodiment. In the illustrated example, it is represented in a table format, and has four attributes: connection ID, “request QoS: allowable delay time”, “request QoS: minimum required throughput”, and allowable time from packet generation to transmission. . In the illustrated example, there are three lines, the connection ID is 0, “request QoS: allowable delay time” is 100 (msec), “request QoS: minimum required throughput” is 100 (kbps), and the packet A line whose allowable time from occurrence to transmission is 100 (msec), a connection ID is 1, “request QoS: allowable delay time” is null, and “request QoS: minimum required throughput” is 80 (kbps). The allowable time from packet generation to transmission is 200 (msec), the connection ID is 2, “request QoS: allowable delay time” is null, and “request QoS: minimum required throughput” is 64 (kbps), and an acceptable time from packet generation to transmission is 300 (msec).

  “Requested QoS: allowable delay time” is information indicating a condition relating to delay among QoS information determined at the start of a session between the mobile station 2 and the base station 1. For example, “request QoS: allowable delay time” of 100 (msec) indicates that the delay is required to be suppressed within 100 msec. In addition, “request QoS: allowable delay time” is null, which indicates that nothing is requested for delay.

  “Requested QoS: minimum required throughput” is information indicating a condition related to throughput among QoS information determined at the start of a session between the mobile station 2 and the base station 1. For example, “request QoS: minimum required throughput” of 100 (kbps) indicates that transmission is required at a transfer rate of at least 100 kbps.

  The “allowed time from packet generation to transmission” is determined by the request QoS information conversion unit 11 based on “request QoS: allowable delay time” and “request QoS: minimum required throughput”. For example, the following method can be considered as a method for determining an allowable time from packet generation to transmission.

  FIG. 5 is a block diagram of the requested QoS information conversion unit 11 in the present embodiment. The maximum allowable delay amount output unit 501 outputs to the multiplexer 504 a transmission time limit for each packet for satisfying the QoS request regarding “request QoS: allowable delay time”. The transmission deadline / permission calculation unit 502 outputs to the multiplexer 504 a transmission deadline for satisfying the QoS request regarding “request QoS: minimum required throughput”. Further, the transmission time limit / permission calculation unit 502 acquires the time when the packet was last transmitted from the transmission packet information table 505, and outputs it to the transmission time limit / permission calculation information holding unit 503. The transmission packet information table 505 stores the time when the mobile station 1 last transmitted a packet and the transmission time limit set for the last transmitted packet. The transmission deadline / permission calculation information holding unit 503 stores the time when the packet was last transmitted, which is input from the transmission deadline / permission calculation unit 502. The transmission time limit / permission calculation information holding unit 503 outputs the stored time to the transmission time limit / permission calculation unit 502.

  First, the maximum allowable delay amount output unit 501 outputs the transmission deadline for each packet to the multiplexer 504. When the communication to which the arrived packet belongs requests a QoS related to “request QoS: allowable delay time”, the allowable delay time is output. When QoS regarding “request QoS: allowable delay time” is not requested, a positive infinity value is output.

  On the other hand, the transmission time limit / permission calculation unit 502 calculates a transmission time limit for each packet and outputs the transmission time limit to the multiplexer 504. The operation of the transmission time limit / permission calculation unit 502 will be described below.

When the communication to which the arrived packet belongs requests a QoS related to “request QoS: minimum required throughput”, the transmission time limit / permission calculation unit 502 converts the time represented by the equation (1) into a frame unit and transmits it. The time limit is output to the multiplexer 504. Here, T is the current time, S _buffer is the amount of radio bandwidth required for transmission of the packet related to the communication obtained from the transmission packet information table, S _packet is the data size of the arrival packet for which transmission permission time is set, and R _min is QoS. The minimum guaranteed rate given by the information, T _last, is the time when the packet related to the communication was last sent. T _last is held in the transmission time limit / permission calculation information holding unit 503.

  Subsequently, the multiplexer 504 compares the transmission deadlines output from the maximum allowable delay amount output unit 501 and the transmission deadline / permission calculation unit 502, and uses the transmission deadline with the earlier deadline as the allowable time from packet generation to transmission. . As a result, it is possible to determine the allowable time from packet generation to transmission.

  In addition, the following method can be considered as a method of determining an allowable time from packet generation to transmission. The maximum allowable delay amount output unit 501 outputs to the multiplexer 504 a transmission time limit for each packet for satisfying the QoS request related to “request QoS: allowable delay time”. The transmission deadline / permission calculation unit 502 outputs to the multiplexer 504 a transmission deadline for satisfying a QoS request related to “request QoS: minimum required throughput”. Also, the transmission time limit / permission calculation unit 502 acquires the transmission time limit set for the last transmitted packet from the transmission packet information table 505, and outputs it to the transmission time limit / permission calculation information holding unit 503. The transmission time limit / permission calculation information holding unit 503 stores the transmission time limit set in the last transmitted packet input from the transmission time limit / permission calculation unit 502. Further, the transmission deadline / permission calculation information holding unit 503 outputs the transmission deadline set for the last transmitted packet stored to the transmission deadline / permission calculation unit 502.

  First, the maximum allowable delay amount output unit 501 outputs the transmission deadline for each packet to the multiplexer 504. When the communication to which the arrived packet belongs requests a QoS related to “request QoS: allowable delay time”, the allowable delay time is output. When QoS regarding “request QoS: allowable delay time” is not requested, a positive infinity value is output.

  On the other hand, the transmission time limit / permission calculation unit 502 calculates a transmission time limit for each packet and outputs the transmission time limit to the multiplexer 504. The operation of the transmission time limit / permission calculation unit 502 will be described below.

When the communication to which the arrived packet belongs requests a QoS of “request QoS: minimum required throughput”, the transmission time limit / permission calculation unit 502 converts the time represented by the expression (2) into a frame unit and transmits it. The time limit is output to the multiplexer 504. Here, D _last is the transmission deadline set for the previous packet belonging to the same communication, S _packet is the data size of the arrival packet for which the transmission deadline is to be set, and R _min is “request QoS: minimum required throughput”. Note that D _last is held in the transmission time limit / permission calculation information holding unit 503.

  Subsequently, the multiplexer 504 compares the transmission deadlines output from the maximum allowable delay amount output unit 501 and the transmission deadline / permission calculation unit 502, and uses the transmission deadline with the earlier deadline as the allowable time from packet generation to transmission. . As a result, it is possible to determine the allowable time from packet generation to transmission.

  Returning to the description of FIG. The transmission request message buffer unit 12 temporarily stores a radio band allocation request signal generated when a data transmission request from the mobile station 2 to the base station 1 is generated. The deadline table processing unit 13 acquires the connection ID and the requested wireless bandwidth information included in the wireless bandwidth allocation request signal stored in the transmission request message buffer unit 12. Also, the deadline table processing unit 13 acquires the allowable time from packet generation to transmission corresponding to the connection ID acquired from the radio band allocation request signal from the allowable time table stored in the storage unit 17. In addition, the deadline table processing unit 13 sets the allowable time from the acquired packet generation to the transmission as the remaining time until the deadline, and associates the acquired connection ID, the requested wireless bandwidth amount, and the remaining time until the deadline, The data is stored in the storage unit 17 as a deadline table. Also, the deadline table processing unit 13 subtracts the time elapsed at regular intervals from the remaining time until the deadline of the deadline table stored in the storage unit 17, and the remaining time until the deadline of the deadline table is Rewrite to the subtracted value. The fixed interval is, for example, every 1 msec.

  FIG. 6 is a diagram showing a deadline table in the present embodiment. In the illustrated example, it is represented in a table format, and has three attributes: a connection ID, a required wireless bandwidth (bytes), and a remaining time (msec) until the deadline. In the example shown in the figure, there are 5 rows, for example, a row in which the connection ID is 0, the required wireless bandwidth is 100 (bytes), and the remaining time until the deadline is 50 (msec). Similarly, four lines are included.

  The radio band allocation request signal generation unit 14 monitors the deadline table stored in the storage unit 17, and out of the remaining time up to the deadline included in the deadline table, the remaining time up to the deadline in any row When the value becomes 0, a radio band allocation request signal is generated. The radio band allocation request signal generation unit 14 reads all radio band allocation request signals stored in the transmission request message buffer unit 12 and combines all the read radio band allocation request signals into one radio band allocation request. Generate a signal. The transmission request message buffer unit 12 erases the read radio band allocation request signal from the transmission request message buffer unit 12 when the radio band allocation request signal generation unit 14 reads the radio band allocation request signal. .

  The radio band allocation request signal generation unit 14 outputs the generated combined radio band allocation request signal to a transmission unit (not shown). The transmission unit transmits the combined radio band allocation request signal output from the radio band allocation request signal generation unit 14 to the base station 1. The base station 1 allocates a radio band to the mobile station 2 based on the received radio band allocation request signal.

  As described above, when transmitting a radio band allocation request signal from the mobile station 2 to the base station 1, a plurality of radio band allocation request signals are transmitted together, so that radio bands transmitted from other mobile stations 2 are transmitted. The probability of collision with the allocation request signal is reduced. Therefore, the loss of the radio band allocation request signal can be reduced. In addition, since the probability of collision with other radio band allocation request signals is reduced, it is possible to improve the utilization efficiency of radio resources related to transmission of uplink radio band allocation request signals.

  Conventionally, the time when the radio band allocation request signal is generated and the timing when the base station receives the radio band allocation request signal from the mobile station are regarded as the same time, and the radio band allocation request signal from the mobile station is regarded as the base station. The base station controls QoS (Quality of Service, quality of service) related to communication from the mobile station to the base station based on the timing time received by the mobile station.

  Therefore, when the time when the radio band allocation request signal is generated at the mobile station and the timing when the base station receives the radio band allocation request signal from the mobile station are shifted, a data shift that is the basis of QoS control occurs. Therefore, the QoS guarantee related to communication from the mobile station to the base station may not be satisfied.

  However, in this embodiment, since the mobile station 2 performs QoS control based on the generation time of the radio band allocation request signal in the mobile station 2, the generation time of the radio band allocation request signal in the mobile station, QoS guarantees can be satisfied even if the timing at which the base station receives the radio band allocation request signal from the base station is shifted.

  In addition, when a margin is taken for the deadline based on the result of the allocation of the radio band, and any of the remaining time until the deadline included in the deadline table is less than the margin, the radio band The allocation request signal generation unit 14 may generate a radio band allocation request signal.

  As a margin determination method, for example, the following method can be considered. The wireless band allocation result analyzing unit 15 performs wireless communication from the transmission time of the wireless band allocation request signal based on the transmission time of the wireless band allocation request signal transmitted by the transmitting unit and the time when the base station 1 has allocated the wireless band. The time until the time when the band is allocated is calculated, and the time distribution is obtained. From the obtained time distribution, a time including a predetermined proportion of all distributions is defined as a margin.

  FIG. 7 is a diagram showing a time distribution from the transmission time of the wireless band allocation request signal to the time when the wireless band is allocated in the present embodiment. The horizontal axis is the time from the transmission time of the radio band allocation request signal to the time when the radio band is allocated, and the vertical axis is the distribution (number of times). In the example shown in the drawing, the time when 90% of the total distribution is included is used as a margin from the deadline.

  The radio band allocation result analysis unit 15 transmits the determined margin to the radio band allocation request signal generation unit 14. The radio band allocation request signal generation unit 14 monitors the deadline table stored in the storage unit 17, and out of the remaining time up to the deadline included in the deadline table, the remaining time up to the deadline in any row When the value falls below the margin, a combined radio band allocation request signal is generated. The radio band allocation request signal generation unit 14 reads all radio band allocation request signals stored in the transmission request message buffer unit 12 and combines all the read radio band allocation request signals into one radio band allocation request. Generate a signal. The transmission request message buffer unit 12 erases the read radio band allocation request signal from the transmission request message buffer unit 12 when the radio band allocation request signal generation unit 14 reads the radio band allocation request signal. . The operation after the combined radio band allocation request signal generation is the same as the operation described above.

  As described above, by providing a margin, the transmission of the radio band allocation request signal does not exceed the deadline, and the accuracy of QoS guarantee can be further improved.

  In addition, when the radio wave environment used for communication between the mobile station 2 and the base station 1 is monitored and the radio wave environment has good timing, the radio band is used regardless of the remaining time until the deadline included in the deadline table. The allocation request signal generation unit 14 may generate a combined radio band allocation request signal.

  As a radio wave environment monitoring method, for example, the following method can be considered. The radio wave environment monitoring unit 16 receives a transmission signal transmitted from the base station 1 to the mobile station 2, a received signal power value, a CNR (Carrier to Noise Ratio) value, a CINR (Carrier to Interference and Noise Ratio) at the mobile station 2. ) Monitor one or more values. When the monitored value is better than the predetermined threshold, the radio wave environment monitoring unit 16 transmits a radio band allocation request signal generation command to the radio band allocation request signal generation unit 14. When the radio band allocation request signal generation command is received, the radio band allocation request signal generation unit 14 generates a combined radio band allocation request signal. The radio band allocation request signal generation unit 14 reads all radio band allocation request signals stored in the transmission request message buffer unit 12 and combines all the read radio band allocation request signals into one radio band allocation request. Generate a signal. The transmission request message buffer unit 12 erases the read radio band allocation request signal from the transmission request message buffer unit 12 when the radio band allocation request signal generation unit 14 reads the radio band allocation request signal. . The operation after the combined radio band allocation request signal generation is the same as the operation described above.

  As described above, since the mobile station 2 transmits a radio band allocation request signal to the base station 1 at a good timing in the radio wave environment, the probability of collision with a radio band allocation request signal transmitted by another mobile station 2 is reduced. can do. Therefore, it is possible to contribute to the reduction in the probability of missing the radio band allocation request signal in the base station 1 and the improvement of the reception CINR.

  The embodiment of the present invention has been described in detail with reference to the drawings, but the specific configuration and method are not limited to this embodiment, and include design changes and the like within the scope of the present invention. It is.

It is the figure which showed the structure of the radio | wireless communications system by one Embodiment of this invention. It is the figure which showed about the transmission timing of the radio | wireless band allocation request signal from a mobile station to a base station in this embodiment. It is the block diagram which showed the structure of the radio | wireless control apparatus in this embodiment. It is the figure which showed the acceptance | permission time table | surface in this embodiment. It is a block diagram of a request | requirement QoS information conversion part in this embodiment. It is the figure which showed the deadline table | surface in this embodiment. It is the figure which showed the time distribution from the transmission time of the radio | wireless band allocation request signal in this embodiment to the time when the radio | wireless band was allocated.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Base station, 2 ... Mobile station, 10 ... Radio control apparatus, 11 ... Request QoS information conversion part, 12 ... Transmission request message buffer part, 13 ... Deadline table processing 14, wireless band allocation request signal generation unit 15, wireless band allocation result analysis unit 16, radio wave environment monitoring unit 17, storage unit 501, maximum allowable delay amount output 502, transmission deadline / permission calculation unit, 503 ... transmission deadline / permission calculation information holding unit, 504 ... multiplexer, 505 ... transmission packet information table

Claims (6)

A signal storage unit for storing a signal for requesting the base station to allocate a radio band;
A transmission time determination unit that determines a time for transmitting the signal to the base station based on QoS information that defines quality (QoS) to be satisfied by communication with the base station, and a time at which the signal is generated;
A control unit for controlling the transmission timing of the signal stored in the signal storage unit based on the time determined by the transmission time determination unit;
A wireless control device comprising: The radio control apparatus according to claim 1, wherein the control unit further combines the plurality of signals stored in the signal storage unit into a transmission signal. A first monitoring unit for monitoring time required for radio band allocation from the base station,
The control unit further controls transmission timing of the signal stored in the signal storage unit based on time required for the radio band allocation monitored by the first monitoring unit. The radio control device according to claim 2. A second monitoring unit for monitoring a radio wave environment with the base station,
The said control part further controls the transmission timing of the said signal which the said signal memory | storage part memorize | stores based on the state of the said radio wave environment monitored by the said 2nd monitoring part. 4. The radio control apparatus according to any one of items 3.   A wireless communication device comprising the wireless control device according to any one of claims 1 to 4. A signal storing step for storing a signal for requesting the base station to allocate a radio band;
A transmission time determination step for determining a time at which the signal is transmitted to the base station based on QoS information defining quality (QoS) to be satisfied by the communication with the base station and a time at which the signal is generated;
A control step for controlling the transmission timing of the signal stored in the signal storage step based on the time determined in the transmission time determination step;
A wireless control method comprising:

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