JP2007043681A - Communication system, base station and mobile station - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a communication system which effectively utilizes a radio channel (frequency) by reducing a probability that a packet can not be reproduced and a delivery confirmed radio transfer block is wasted since a radio transfer block does not reach a transmission destination when dividing a packet into a plurality of radio transfer blocks and transmitting the blocks, respectively. <P>SOLUTION: In a base station 2, a packet to be transmitted is divided into a plurality of radio transfer blocks, priority is determined on the basis of a delivery confirmation amount integration value indicating an integration value for the size of a radio transfer block of which delivery is confirmed to indicate the delivery of the radio transfer block to a mobile station 3, radio resources are assigned to the radio transfer blocks constituting the packet to be transmitted on the basis of the determined priority, and the assigned radio resources are used to transmit the radio transfer blocks. In the mobile station 3, if a radio transfer block from the base station 2 is normally received, a delivery confirmation is transmitted to the base station 2, and a packet is reproduced from radio transfer blocks. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a communication system that takes into account the effective use of a line in a communication system using a wireless line, and more particularly to a communication system that realizes effective use of a line by reducing the amount of data that becomes invalid due to discarding. It is about.

  For example, Patent Document 1 discloses a conventional technique for effectively using a line by reducing the amount of invalid data due to packet discard. In the conventional communication method described in Patent Literature 1, the base station controller generates a radio segment obtained by dividing a received packet into the length of a communication unit on a radio channel, and performs retransmission control on the headers of all the generated radio segments. Set information about and send to the base station. The base station generates a predetermined transfer frame (wireless transfer block) from the wireless segment received from the base station control device, and transmits the generated wireless transfer block to the mobile station. In addition, the base station determines the number of retransmissions of the radio transfer block so that the radio transfer block generated from the radio segment whose position in the packet is behind increases the number of retransmissions, and within the determined number of retransmissions, the base station When the wireless transfer block cannot be normally received, the retransmission of the wireless transfer block is interrupted, and the wireless segment corresponding to the wireless transfer block and all subsequent wireless segments are discarded.

  That is, in the conventional communication method described in Patent Document 1, by increasing the number of retransmissions of the remaining wireless transfer blocks for which delivery has not been completed for packets that have already been delivered for many wireless transfer blocks, The transmission of the wireless transfer block is interrupted due to the excess of the number of retransmissions, reducing the probability that the mobile station cannot reproduce the original packet and the wireless transfer block that has already been confirmed to be used is wasted. (Frequency) is used effectively.

  By the way, in order to perform handover between base stations without data loss, it is necessary to retransmit a packet that could not be delivered between the handover source base station and the mobile station between the handover destination base station and the mobile station. There is. However, transmitting packets between the handover destination base station and mobile station again for packets for which delivery of many radio transfer blocks has already been completed results in use of radio transfer blocks that have already been confirmed for delivery. There was a problem that the wireless line (frequency) was wasted. Further, it has been necessary to transfer a downlink packet that could not be delivered from the handover source base station to the handover destination base station.

  As a prior art for improving such a problem, there is, for example, Patent Document 2. In Patent Document 2, the actual handover execution is delayed until the packet reproduction is completed on the receiving side, thereby reducing the possibility of discarding a short packet, degrading frequency utilization efficiency and increasing delay. A technique is disclosed that makes it possible to prevent as much as possible. That is, in the conventional technique described in Patent Document 2, a wireless line is not wasted by executing a handover after a packet is completed.

Japanese Patent Laying-Open No. 2005-27167 JP 2000-92542 A

  However, in a wireless communication system, it is not always possible to confirm delivery of retransmission control in the order of transmission of wireless transfer blocks. While retransmission is repeated for a certain wireless transfer block, delivery confirmation of the subsequent wireless transfer block may be obtained. Therefore, the conventional communication method described in Patent Document 1 that determines the number of retransmissions according to the position of the wireless transfer block in the packet is sufficiently effective in reducing the probability that the transmitted wireless transfer block is wasted. There was a problem that it could not be demonstrated.

  In addition, the reason why the wireless transfer block cannot be delivered to the receiving side in the wireless communication system is that the number of retransmissions of the wireless transfer block has reached the upper limit of the number of retransmissions due to retransmission control, and the transmitting side has the wireless segment corresponding to the wireless transfer block and There are two cases: discarding all subsequent radio segments, and discarding the radio segment and all subsequent radio segments because the radio segment has remained in the buffer beyond the remaining allowable time. In the conventional communication method described in Patent Document 1 described above, only the upper limit value of the number of retransmissions is changed and the remaining allowable time is not taken into consideration. Therefore, the remaining allowable time is exceeded before reaching the upper limit of the number of retransmissions. In such a case, there is a problem in that the effect of reducing the probability that the wireless transfer block being transmitted is wasted cannot be fully exhibited.

  Also, in a wireless communication system, a packet is generally divided into a plurality of wireless transfer blocks and transmitted, and the modulation method and coding rate are controlled for the wireless transfer block so as to keep the error rate of the wireless transfer block constant. Therefore, there is a problem in that the error rate of the packet varies depending on how many wireless transfer blocks the packet is composed of (number of packet divisions). Specifically, there is a problem that the error rate of a packet increases as the number of wireless transfer blocks constituting the packet increases.

  In the prior art described in Patent Document 2, the handover delay time, which is the difference between the handover request time obtained from the radio channel quality measurement and the actual handover execution time, is the radio channel quality fluctuation between the mobile station and the base station. It becomes unstable due to the influence of. Therefore, if the wireless line quality further deteriorates while the handover is delayed and communication becomes impossible, a lot of wireless lines are wasted in addition to the wireless transfer block delivered during the delay time. There was a problem of becoming.

  The present invention has been made in view of the above, and when a packet is divided into a plurality of wireless transfer blocks and transmitted, the packet cannot be reproduced because the wireless transfer block does not reach the transmission destination. It is a first object of the present invention to obtain a communication system that effectively uses a wireless line (frequency) by reducing the probability that a wireless transfer block that has already been confirmed for delivery will be wasted.

  The second object is to obtain a communication system that keeps the packet error rate constant without being affected by the number of wireless transfer blocks that constitute the packet.

  The third object is to obtain a communication system that shortens the handover delay time and completes the handover before communication becomes impossible due to deterioration of the radio channel quality.

  A fourth object is to obtain a communication system that executes an immediate handover at a handover request time when a packet cannot be completed before communication becomes impossible.

  In order to solve the above-described problems and achieve the object, the present invention provides a communication system in which a mobile station communicates with a partner station via a base station connected to a network. A wireless transfer block generation unit that divides the wireless transfer block into a plurality of wireless transfer blocks, and a delivery confirmation amount integrated value that indicates an integrated value of the size of the wireless transfer block that has been confirmed to be delivered indicating that the wireless transfer block has reached the mobile station A priority is determined based on the scheduler, a scheduler unit that allocates a radio resource to a radio transfer block constituting a packet to be transmitted based on the determined priority, and the radio resource allocated by the scheduler unit, A wireless transfer block transmitter that transmits the wireless transfer block generated by the transfer block generator, and the movement Transmits a delivery confirmation to the base station when the wireless transfer block is normally received from the base station, and sends a retransmission request to the base station when the wireless transfer block is not normally received from the base station. And a packet reproduction unit for reproducing packets from the wireless transfer block received from the base station.

  According to the present invention, the priority is determined based on the delivery confirmation amount integrated value indicating the integrated value of the size of the wireless transfer block for which the delivery confirmation indicating that the wireless transfer block has reached the mobile station is obtained, and the determined priority is determined. Since wireless resources are allocated to the wireless transfer blocks that make up a packet to be transmitted based on the frequency, when the packet is divided into multiple wireless transfer blocks and transmitted, the wireless transfer block does not reach the destination Therefore, it is possible to obtain a wireless communication system that effectively uses a wireless line by reducing the probability that a wireless transfer block that has been confirmed to be delivered without being able to reproduce a packet is wasted.

  Embodiments of a communication system, a base station, and a mobile station according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
A first embodiment of the present invention will be described with reference to FIGS. 1 is a diagram showing a configuration of a communication system according to Embodiment 1 of the present invention. In FIG. 1, the communication system includes a wired network 1, a base station 2, and n (n is a natural number) mobile stations 3 (3-1 to 3-n are shown). The wired network 1 and the base station 2 are connected by a wired line, the base station 2 and the mobile station 3 are connected by a wireless line, and the mobile station 3 is connected to the wired network 1 via the base station 2 and the wired network 1. Mutual communication using packets is performed with a connected fixed terminal (not shown) or a mobile station.

  In the first embodiment, downlink communication in which the base station 2 transmits a packet received from the wired network 1 to the mobile station 3 will be described. FIG. 2 is a block diagram showing a configuration related to downlink communication of the base station 2 shown in FIG. In FIG. 2, the base station 2 has a wired line interface function and receives a signal (packet) from the wired network 1, and a packet for buffering a packet received by the wired signal receiver 201. The size of the wireless transfer block to be transmitted to the buffer 202 and the mobile station 3 is determined, the scheduler unit 208 that executes the scheduling process of the wireless transfer block, and the wireless of the size determined by the scheduler unit 208 from the packet selected by the scheduler unit 208 A wireless transfer block generation unit 203 that generates a transfer block, a retransmission control unit 204 that performs retransmission control with the mobile station 3 in units of wireless transfer blocks, and a wireless that transmits a wireless transfer block generated by the wireless transfer block generation unit 203 Transfer block transmitter 2 7, a radio signal transmission / reception unit 206 that has a radio channel interface function and transmits / receives a signal to / from the mobile station 3, a retransmission control signal reception unit 205 that extracts retransmission control information from a signal received by the radio signal transmission / reception unit 206, and A radio channel quality information receiving unit 209 is provided for extracting radio channel quality information of the downlink radio channel from the signal received by the radio signal transmitting / receiving unit 206.

  FIG. 3 is a block diagram showing a configuration relating to downlink communication of the mobile station 3 shown in FIG. In FIG. 3, the mobile station 3 has a wireless channel interface function and transmits / receives a signal to / from the base station 2, and wireless transfer extracts a wireless transfer block from the signal received by the wireless signal transmitter / receiver 301. Received by the block receiver 302, the retransmission controller 304 that performs retransmission control with the base station 2, the retransmission control signal transmitter 303 that transmits the retransmission control information generated by the retransmission controller 304, and the wireless transfer block receiver 302 A packet reproduction unit 305 that reproduces a packet from the received wireless transfer block, a packet reception unit 306 that receives the packet reproduced by the packet reproduction unit 305 and outputs the packet to an upper layer processing unit (not shown), and a downlink radio channel Measure radio channel quality information and send the measured radio channel quality information to base station 2 That includes a channel quality information transmission unit 307.

  Next, the operation of Embodiment 1 of the communication system according to the present invention will be described. When a packet is received via the wired signal receiving unit 201 of the base station 2, the packet buffer 202 buffers the received packet and notifies the scheduler unit 208 that a new packet has been received. The scheduler unit 208 initializes and stores the delivery confirmation amount integrated value in association with the new packet.

  On the other hand, when receiving a signal from the mobile station 3 via the radio signal transmitting / receiving unit 206 of the base station 2, the radio channel quality information receiving unit 209 transmits the radio channel quality information of the mobile station 3 from the signal received from the mobile station 3. The radio channel quality information of the downlink radio channel measured by the unit 307 is extracted, and the extracted radio channel quality information is output to the scheduler unit 208.

  Also, the retransmission control signal receiving unit 205 of the base station 2 extracts retransmission control information from the signal received from the mobile station 3 via the radio signal transmitting / receiving unit 206 and outputs the extracted retransmission control information to the retransmission control unit 204. .

  The retransmission control unit 204 of the base station 2 determines whether or not to perform retransmission in units of radio transfer blocks based on the retransmission control information. In the case of a delivery confirmation indicating that the retransmission control information has received the wireless transfer block normally, the retransmission control unit 204 of the base station 2 outputs the delivery confirmation information to the scheduler unit 208, and the scheduler unit 208 adds the delivery confirmation information to the delivery confirmation information. Based on this, the delivery confirmation amount integrated value stored in association with the packet is updated. If the retransmission control information is a retransmission request for requesting retransmission of a wireless transfer block, a predetermined retransmission process is executed for the wireless transfer block requested to be retransmitted.

  When a predetermined radio transfer block scheduling time is reached, the scheduler unit 208 of the base station 2 determines the size of the radio transfer block based on the radio channel quality information. The scheduler unit 208 determines the priority of the packet based on the delivery confirmation amount integrated value stored in association with each packet buffered in the packet buffer 202, which will be described in detail later. According to the priority, a scheduling process for allocating radio resources to radio transfer blocks generated from the packet is executed. Then, the scheduler unit 208 outputs to the wireless transfer block generation unit 203 wireless transfer block generation information including a packet for generating a wireless transfer block to which wireless resources are allocated by scheduling processing and the size of the wireless transfer block, and wireless transfer. Transmission information including information on the block and the assigned radio resource is output to retransmission control section 204.

  The wireless transfer block generation unit 203 of the base station 2 generates a wireless transfer block from the packet buffered in the packet buffer 202 based on the wireless transfer block generation information, and outputs the generated wireless transfer block to the retransmission control unit 204. To do.

  The retransmission control unit 204 of the base station 2 outputs the transmission information and the radio transfer block to the radio transfer block transmission unit 207. The wireless transfer block transmission unit 207 transmits the wireless transfer block to the mobile station 3 via the wireless signal transmission / reception unit 206 based on the transmission information.

  The radio transfer block reception unit 302 of the mobile station 3 extracts the radio transfer block from the signal received via the radio signal transmission / reception unit 301 and outputs the radio transfer block to the retransmission control unit 304. The retransmission control unit 304 determines whether the wireless transfer block has been normally received (whether the data is incorrect). When the wireless transfer block can be normally received, the retransmission control unit 304 outputs the wireless transfer block to the packet reproduction unit 305 and notifies the retransmission control signal transmission unit 303 that the wireless transfer block has been normally received. .

  The packet reproducing unit 305 of the mobile station 3 reproduces a packet from the wireless transfer block. When the wireless transfer block generation unit 203 of the base station 2 generates a wireless transfer block, information (wireless transfer block number) indicating the number of the wireless transfer block in the packet is stored in the wireless transfer block. Is included. The packet reproducing unit 305 of the mobile station 3 reproduces a packet from the wireless transfer block using this information. When all the wireless transfer blocks constituting the packet are normally received and the packet is reproduced, the packet reproducing unit 305 outputs the reproduced packet to the packet receiving unit 306.

  On the other hand, when the wireless transfer block cannot be normally received, the retransmission control unit 304 of the mobile station 3 discards the wireless transfer block and also indicates that the wireless transfer block has not been normally received. Notify

  The retransmission control signal transmission unit 303 of the mobile station 3 notifies the retransmission request as retransmission control information and the reception of the wireless transfer block when it is notified that the wireless transfer block cannot be normally received. If it has been received, a delivery confirmation is transmitted as retransmission control information to the base station 2 via the wireless signal transmission / reception unit 301.

  Next, the operation of the scheduler unit 208 of the base station 2 will be described in detail with reference to the flowcharts of FIGS. 4 and 6 and FIGS. 5 and 7. When notified from the packet buffer 202 that a new packet has been received (step S100), the scheduler unit 208 initializes the delivery confirmation amount integrated value in association with the new packet (in this case, “0”). Store (step S101).

  Upon receipt of the delivery confirmation information from the retransmission control unit 204 (step S102), the scheduler unit 208 adds the delivery confirmation amount to the delivery confirmation amount integrated value stored in association with the packet of the wireless transfer block that has received the delivery confirmation information. The delivery confirmation amount integrated value is updated by addition (step S103).

  Here, a change in the delivery confirmation amount integrated value when attention is paid to one packet (packet addressed to the mobile station 3-1) with reference to FIG. 5 will be described. In FIG. 5, the packet 4 in the base station 2, the wireless transfer blocks 41a to 41c, the wireless transfer blocks 42a, 42b-1 to 42b-3, 42c on the wireless line, the wireless transfer block 43a in the mobile station 3-1, 43b, 43c and the number in the packet 44 in the mobile station 3-1 indicate the size of each wireless transfer block or packet when the packet size of the packet 4 is normalized to “1”, and the amount of delivery confirmation The numbers in parentheses of the integrated value and the wireless transfer blocks 42a, 42b-1 to 42b-3, 42c indicate the integrated value of the delivery confirmation amount when the packet 4 is normalized to “1”.

  The packet 4 arriving at the base station 2 from the wired network 1 is divided into wireless transfer blocks 41a to 41c having a size determined based on the wireless line quality information and transmitted on the wireless line. The base station 2 determines the size of the wireless transfer block to “0.5” based on the wireless channel quality information, and transmits the first wireless transfer block 41a constituting the packet 4 to the wireless line as the wireless transfer block 42a. . Since the wireless transfer block 41a is the first wireless transfer block of the packet 4, the delivery confirmation amount integrated value associated with the packet 4 is “0”.

  The mobile station 3-1 receives the wireless transfer block 42 a on the wireless line. Since the wireless transfer block 42a was successfully received as the wireless transfer block 43a, the mobile station 3-1 transmits a delivery confirmation 45a of the wireless transfer block 43a to the base station 2.

  The base station 2 determines the size of the radio transfer block to “0.2” based on the radio channel quality information, and sets the second radio transfer block 41b constituting the packet 4 as the radio transfer block 42b-1 Send to. At this time, since the base station 2 has not received the delivery confirmation 45 a from the mobile station 3-1, the delivery confirmation amount integrated value associated with the packet 4 remains “0”.

  Upon receipt of the delivery confirmation 45a, the base station 2 obtains the size of the corresponding wireless transfer block 41a from the delivery confirmation 45a to obtain the delivery confirmation amount, and adds the delivery confirmation amount to the delivery confirmation amount integrated value to obtain the delivery confirmation amount integrated value. Update.

  Since the base station 2 transmits the wireless transfer block 41a and the wireless transfer block 41b before receiving the delivery confirmation 45a, the base station 2 confirms whether the delivery confirmation 45a corresponds to the wireless transfer block 41a. It is necessary to identify whether it corresponds to the wireless transfer block 41b. Which wireless transfer block the delivery confirmation 45a corresponds to is acquired when the mobile station 3-1 receives the wireless transfer block 43a as information for identifying the wireless transfer block 41a in the delivery confirmation 45a. The wireless transfer block number to be included may be included. Then, the base station 2 stores the size of the wireless transfer block in association with the wireless transfer block number when the wireless transfer block 41a is generated, and determines the size of the wireless transfer block from the wireless transfer block number in the delivery confirmation 45a. The delivery confirmation amount integrated value is updated so as to obtain “0.5”.

  The base station 2 determines the size of the wireless transfer block to be “0.3” based on the wireless channel quality information, and sets the third (in this case, last) wireless transfer block 41c constituting the packet 4 as a wireless transfer block. 42c is transmitted to the wireless line. At this time, since the base station 2 has not received the delivery confirmation of the wireless transfer block 41b, the delivery confirmation amount integrated value associated with the packet 4 remains “0.5”.

  The mobile station 3-1 receives the wireless transfer block 42b-1 on the wireless line. Since the wireless transfer block 42b-1 on the wireless line could not be normally received, a retransmission request for the wireless transfer block 42b-1 is transmitted to the base station 2. Thereafter, the mobile station 3-1 receives the wireless transfer block 42 c on the wireless line. Since the wireless transfer block 42c was successfully received as the wireless transfer block 43c, the mobile station 3-1 transmits a delivery confirmation 45c of the wireless transfer block 43c to the base station 2.

  The base station 2 receives the retransmission request of the wireless transfer block 42b-1, and retransmits the wireless transfer block 41b as a wireless transfer block 42b-2 on the wireless line. At this time, since the base station 2 has not received the delivery confirmation 45c, the delivery confirmation amount integrated value associated with the packet 4 remains “0.5”.

  When receiving the delivery confirmation 45c, the base station 2 obtains the size of the corresponding wireless transfer block 41c from the delivery confirmation 45c and sets it as the delivery confirmation amount, and updates the delivery confirmation integrated value by adding the delivery confirmation amount to the delivery confirmation amount integrated value. To do. In this case, since the delivery confirmation amount integrated value is “0.5” and the size of the wireless transfer block 41c is “0.3”, the delivery confirmation amount integrated value is updated to “0.8”.

  The mobile station 3-1 receives the wireless transfer block 42 b-2 on the wireless line. Since the mobile station 3-1 could not normally receive the wireless transfer block 42 b-2 on the wireless line, the mobile station 3-1 transmits a retransmission request for the wireless transfer block 42 b-2 to the base station 2. The base station 2 receives the retransmission request of the wireless transfer block 42b-2 and retransmits the wireless transfer block 41b as a wireless transfer block 42b-3 on the wireless line. At this time, the delivery confirmation amount integrated value associated with the packet 4 is “0.8”.

  The mobile station 3-1 receives the wireless transfer block 42 b-3 on the wireless line. Since the wireless transfer block 42b-3 on the wireless line was successfully received as the wireless transfer block 43b, the mobile station 3-1 transmits a delivery confirmation 45b of the wireless transfer block 43b to the base station 2.

  When receiving the delivery confirmation 45b, the base station 2 obtains the size of the corresponding wireless transfer block 41b from the delivery confirmation 45b and sets it as the delivery confirmation amount, and updates the delivery confirmation integrated value by adding the delivery confirmation amount to the delivery confirmation amount integrated value. To do. In this case, since the delivery confirmation amount integrated value is “0.8” and the size of the wireless transfer block 41b is “0.2”, the delivery confirmation amount integrated value is “1”. That is, it means that the wireless transfer blocks 41a to 41c constituting the packet 4 have been delivered to the mobile station 3-1. Therefore, when the delivery confirmation amount integrated value becomes “1”, the base station 2 determines that the transmission of the packet 4 is completed, and discards the delivery confirmation amount integrated value stored in association with the packet 4. To do.

  On the other hand, the mobile station 3-1 receives the wireless transfer block 43 b normally, thereby completing the reception of the wireless transfer blocks 43 a to 43 c constituting the packet and reproducing the packet 44.

  Similarly to the case where the packet addressed to the mobile station 3-1 described above is focused, the scheduler unit 208 of the base station 2 receives a delivery confirmation from each mobile station 3, and the radio transfer block corresponding to the delivery confirmation is received. The delivery confirmation amount integrated value stored in association with the packet to be configured is updated.

  Returning to FIG. 4, when a predetermined scheduling time is reached (step S <b> 104), the scheduler unit 208 is based on the delivery confirmation amount integrated value stored in association with each packet buffered in the packet buffer 202. Then, the priority of the packet is determined, and scheduling processing for allocating radio resources to the radio transfer block generated from the packet according to the determined priority is executed (step S105).

  With reference to the flowchart of FIG. 6, the operation of the scheduling process executed by the scheduler unit 208 will be described in detail. The scheduler unit 208 uses the delivery confirmation amount integrated value stored in association with each packet buffered in the packet buffer 202 as a priority when scheduling the wireless transfer block. That is, it is determined that the priority is higher as the delivery confirmation integrated value is larger. The scheduler unit 208 selects the wireless transfer block constituting the highest priority packet as a processing target block (step S200).

  The scheduler unit 208 determines whether there is a remaining radio resource (step S201). When there is a remaining radio resource, the scheduler unit 208 allocates a radio resource to the radio transfer block selected as the processing target block (step S202).

  The scheduler unit 208 selects, as a new processing target block, a wireless transfer block that configures a packet having a higher priority next to a packet configured by the wireless transfer block selected as the current processing target block (step S203).

  The scheduler unit 208 allocates radio resources to the radio transfer block selected as the processing target block until there is no remaining radio resource, and the priority is next to the packet configured by the radio transfer block selected as the current processing target block. The operation of selecting a wireless transfer block that constitutes a packet having a high value as a new processing target block is repeated (steps S201 to S203).

  FIG. 7 is a diagram illustrating a change in scheduling priority when the base station 2 accommodates three mobile stations 3-1 to 3-3. In FIG. 7, which radio transfer block (mobile station 3-1 to 3-) is based on the delivery confirmation amount integrated value corresponding to packets addressed to the mobile stations 3-1 to 3-3 having periodic scheduling times t1 to t4. 3) is preferentially handled, and the numerical values in the circles indicate the order in which the scheduler unit 208 allocates radio resources.

  At the scheduling time t1, the delivery confirmation amount integrated value of the packet addressed to the mobile station 3-1 is “0.3”, and the delivery confirmation amount integrated value of the packet addressed to the mobile station 3-2 is “0.0”. Yes, the delivery confirmation amount integrated value of the packet addressed to the mobile station 3-3 is “0.0”. The scheduler unit 208 determines that the higher the delivery confirmation amount integrated value is, the higher the priority is. Therefore, here, first, the radio resource is assigned with the radio transfer block constituting the packet addressed to the mobile station 3-1 as a processing target block. Next, radio resources are allocated using the radio transfer block constituting the packet addressed to the mobile station 3-2 as a processing target block, and finally, the radio transfer block constituting the packet addressed to the mobile station 3-3 is used as a processing target block. Allocate resources. When the priorities are the same (in this case, the mobile station 3-2 and the mobile station 3-3), the priorities are determined in a predetermined order.

  At the scheduling time t2, all the wireless transfer blocks constituting the packet addressed to the mobile station 3-1 are delivered to the mobile station 3-1, and the packet buffer 202 buffers a new packet addressed to the mobile station 3-1. Since there is no ring, there is no delivery confirmation amount integrated value corresponding to the packet addressed to the mobile station 3-1. Further, since the delivery confirmation of the wireless transfer block transmitted before the scheduling time t2 is received from the mobile station 3-3, the delivery confirmation amount integrated value of the packet addressed to the mobile station 3-3 becomes “0.9”. Yes. Since the delivery confirmation amount integrated value of the packet addressed to the mobile station 3-2 is “0.0”, the scheduler unit 208 uses the radio transfer block that constitutes the packet addressed to the mobile station 3-3 as a processing target block. Then, the radio resource is allocated with the radio transfer block constituting the packet addressed to the mobile station 3-2 as the processing target block.

  At the scheduling time t3, since the packet addressed to the mobile station 3-1 is buffered in the packet buffer 202 between the scheduling time t2 and the scheduling time t3, the delivery confirmation amount integrated value of the packet addressed to the mobile station 3-1. The value is initialized (“0”). Also, since the delivery confirmation of the wireless transfer block transmitted before the scheduling time t3 is received from the mobile station 3-2, the delivery confirmation amount integrated value of the packet addressed to the mobile station 3-2 becomes “0.5”. Yes. Therefore, the scheduler unit 208 first assigns radio resources with the radio transfer block constituting the packet addressed to the mobile station 3-3 having the highest priority (the delivery confirmation amount integrated value is large) as a processing target block, and then gives priority. A radio resource is assigned with a radio transfer block constituting a packet addressed to a mobile station 3-2 having a higher degree as a processing target block, and finally a radio transfer block constituting a packet addressed to the mobile station 3-1 having the lowest priority is processed. A radio resource is allocated as a target block.

  At the scheduling time t4, since the delivery confirmation is received from the mobile station 3-1 and the mobile station 3-2 between the scheduling time t3 and the scheduling time t4, the delivery confirmation amount integrated value of the packet addressed to the mobile station 3-1. Is “0.1”, and the delivery confirmation amount integrated value of the packet addressed to the mobile station 3-2 is “0.8”. In addition, since all the wireless transfer blocks constituting the packet addressed to the mobile station 3-3 are delivered to the mobile station 3-3, the packet buffer 202 newly buffers the packet addressed to the mobile station 3-3. The delivery confirmation amount integrated value of the packet addressed to -3 is “0.0”.

  The scheduler unit 208 first assigns radio resources using the radio transfer block constituting the packet addressed to the mobile station 3-2 having the highest priority as a processing target block, and then packets addressed to the mobile station 3-1 having the highest priority. The wireless resource is assigned with the wireless transfer block that constitutes the processing target block, and finally the wireless resource is assigned with the wireless transfer block addressed to the mobile station 3-3 having the lowest priority as the processing target block.

  As described above, in the first embodiment, priority is given based on the delivery confirmation amount integrated value indicating the integrated value of the size of the wireless transfer block for which the delivery confirmation indicating that the wireless transfer block has reached the mobile station has been obtained. Since the wireless resource is allocated to the wireless transfer block that constitutes the packet to be transmitted based on the determined priority, the movement is performed when the packet is divided into a plurality of wireless transfer blocks and transmitted. Since the wireless transfer block does not reach the station 3, the packet cannot be reproduced, and the probability that the wireless transfer block that has already been confirmed for delivery is wasted can be reduced and the wireless line can be used effectively.

  In the first embodiment, the higher the value of the delivery confirmation amount integrated value, the higher the priority, so that the wireless transfer blocks belonging to packets with a high percentage of delivery confirmation are transmitted preferentially. Therefore, when the wireless transfer block is unavoidably discarded, the wireless transfer block belonging to the packet with a small rate of delivery confirmation is discarded, and the mobile station 3 cannot discard the packet and is discarded. As a result, the frequency can be effectively used or the throughput at the packet level can be improved.

  In the first embodiment, the packet normalization value is used as the delivery confirmation amount, but an actual data amount may be used.

  In the first embodiment, the case where the base station 2 divides the packet received from the wired network 1 into wireless transfer blocks has been described as an example. However, as illustrated in FIG. 8, the wired network illustrated in FIG. A base station control device 5 is provided between the network 1 and the base station 2, and the base station control device 5 divides the packet received from the wired network 1 into a plurality of divided segments and transmits it to the base station 2. May be a communication system that generates a wireless transfer block from a plurality of divided segments.

  In this case, the base station control device 5 includes an identifier for identifying the break of the packet in the divided segment so that the base station 2 obtains the packet size of one packet from the plurality of divided segments by this identifier. do it.

Embodiment 2. FIG.
A second embodiment of the present invention will be described with reference to FIGS. In the first embodiment, the downlink communication in which the base station 2 transmits the packet received from the wired network 1 to the mobile station 3 has been described. In the second embodiment, uplink communication in which the mobile station 3 transmits a packet to the wired network 1 via the base station 2 will be described. The configuration of the communication system according to the second embodiment is the same as that of the communication system according to the first embodiment illustrated in FIG.

  FIG. 9 is a block diagram showing a configuration related to uplink communication of the mobile station 3 of the communication system according to the present invention. In FIG. 9, the mobile station 3 buffers the packet generator 311 that generates a packet to be transmitted, the packet buffer 312 that buffers the packet generated by the packet generator 311, and the packet buffer 312 according to an instruction from the controller 319. A wireless transfer block generating unit 313 that generates a wireless transfer block from the received packets, a retransmission control unit 314 that performs retransmission control with the base station 2 in units of wireless transfer blocks, and a radio generated by the wireless transfer block generating unit 313 A wireless transfer block transmission unit 317 that transmits a transfer block, a transmission request transmission unit 320 that transmits a transmission request to the base station 2, a wireless signal transmission / reception unit 316 that has a wireless interface function and transmits / receives a signal to / from the base station 2, a wireless From the signal received by the signal transmitting / receiving unit 316, A retransmission control signal receiving unit 315 that extracts control information, a transmission instruction receiving unit 318 that extracts a transmission instruction from a signal received by the wireless signal transmission / reception unit 316, and a wireless transmission based on the transmission instruction extracted by the transmission instruction receiving unit 318. A control unit 319 is provided for controlling transmission of the transfer block and for comprehensively controlling each component in the mobile station 3.

  FIG. 10 is a block diagram showing a configuration related to uplink communication of the base station 2 of the communication system according to the present invention. In FIG. 10, the base station 2 has a wireless channel interface function and transmits / receives a signal to / from the mobile station 3, and a transmission request reception that extracts a transmission request from a signal received by the wireless signal transmission / reception unit 211. 218, a wireless transfer block receiving unit 213 that extracts a wireless transfer block from a signal received by the wireless signal transmitting / receiving unit 211, a retransmission control unit 214 that performs retransmission control with the mobile station 3, and a retransmission control unit Retransmission control signal transmission unit 212 that transmits retransmission control information, packet reproduction unit 215 that reproduces a packet from a wireless transfer block received by wireless transfer block reception unit 213, and reproduction by packet reproduction unit 215 that has a wired line interface function A wired signal transmission unit 216 that transmits the packet thus transmitted to the wired network 1 Based on the transmission request extracted by the transmission request receiving unit 218 and the arrival state of the packet, the scheduler unit 219 that executes the scheduling process of the radio transfer block transmitted by the mobile station 3, and the information scheduled by the scheduler unit 219 are transmitted. A transmission instruction transmission unit 217 that transmits to the mobile station 3 as an instruction is provided.

  Next, the operation of the communication system according to the second embodiment of the present invention will be described. First, the operation when a packet to be transmitted occurs in the mobile station 3 will be described.

  When the mobile station 3 receives data to be transmitted from an upper layer processing unit (not shown), the packet generation unit 311 of the mobile station 3 generates a packet from the data to be transmitted and outputs the packet to the packet buffer 312.

  The packet buffer 312 of the mobile station 3 notifies the control unit 319 that a new packet has been buffered. The control unit 319 generates a transmission request notifying that a new packet has been buffered, that is, a packet to be transmitted to the base station 2, and outputs the transmission request to the transmission request transmission unit 320. The control unit 319 includes packet size information indicating the packet size in the transmission request. The transmission request transmission unit 320 of the mobile station 3 transmits a transmission request to the base station 2 via the wireless signal transmission / reception unit 316.

  When the transmission request is received via the radio signal transmission / reception unit 211 of the base station 2, the transmission request reception unit 218 outputs the received transmission request to the scheduler unit 219. The scheduler unit 219 stores the delivery confirmation amount integrated value and the packet size in association with the mobile station 3 that has transmitted the transmission request. At this time, the delivery confirmation amount integrated value is initialized and stored.

  Next, an operation in which the mobile station 3 transmits a wireless transfer block constituting a packet will be described. When receiving a transmission instruction via the radio signal transmission / reception unit 316 of the mobile station 3, the transmission instruction reception unit 318 outputs the received transmission instruction to the control unit 319. The control unit 319 outputs the wireless transfer block size included in the transmission instruction to the wireless transfer block generation unit 313 as wireless transfer block generation information.

  The wireless transfer block generation unit 313 of the mobile station 3 generates a wireless transfer block from the packet buffered in the packet buffer 312 based on the wireless transfer block generation information, and sends the generated wireless transfer block to the retransmission control unit 314. Output.

  When receiving the wireless transfer block, the retransmission control unit 314 of the mobile station 3 performs processing necessary for retransmission and then outputs the wireless transfer block to the wireless transfer block transmitting unit 317. The wireless transfer block transmitting unit 317 is a wireless signal transmitting / receiving unit. The wireless transfer block is transmitted to the base station 2 via 316.

  The radio transfer block reception unit 213 of the base station 2 extracts a radio transfer block from the signal received via the radio signal transmission / reception unit 211 and outputs the radio transfer block to the retransmission control unit 214. The retransmission control unit 214 determines whether the wireless transfer block has been successfully received. When the wireless transfer block can be normally received, the retransmission control unit 214 outputs the wireless transfer block to the packet reproduction unit 215. In addition, the retransmission control unit 214 notifies the retransmission control signal transmission unit 212 that the radio transfer block has been normally received, and identifies the mobile station 3 that is the transmission source of the radio transfer block that has been successfully received. And the delivery confirmation information including the size of the received wireless transfer block are notified to the scheduler unit 219.

  When all the wireless blocks constituting the packet are normally received and the packet is reproduced, the packet reproduction unit 215 of the base station 2 transmits the reproduced packet to the wired network 1 via the wired signal transmission unit 216.

  When notified that the wireless transfer block has been successfully received, the scheduler unit 219 of the base station 2 updates the delivery confirmation amount integrated value stored in association with the mobile station 3.

  On the other hand, when the wireless transfer block cannot be normally received, the retransmission control unit 214 of the base station 2 discards the wireless transfer block and also indicates that the wireless transfer block has not been normally received. Notify

  The retransmission control signal transmission unit 212 of the base station 2 notifies the retransmission request as retransmission control information when the wireless transfer block has not been normally received, and notifies that the wireless transfer block has been successfully received. If it has been received, a delivery confirmation is transmitted as retransmission control information to the mobile station 3 via the wireless signal transmission / reception unit 211.

  The retransmission control unit 314 of the mobile station 3 determines whether or not to perform retransmission in units of radio transfer blocks based on the retransmission control information received via the radio signal transmission / reception unit 316 and the retransmission control signal reception unit 315. When the retransmission control information is a retransmission request for requesting retransmission of the radio transfer block, the retransmission control unit 314 performs predetermined retransmission processing on the radio transfer block for which retransmission is requested.

  Next, the operation of the scheduler unit 219 of the base station 2 will be described in detail with reference to the flowchart of FIG. 11 and FIG. When receiving a transmission request from the transmission request receiving unit 218 (step S300), the scheduler unit 219 initializes the transmission request in association with the mobile station 3 that transmitted the transmission request (in this case, “0”) The packet size information included in the transmission request is stored (step S301).

  When it is notified from the retransmission control unit 214 that the wireless transfer block has been normally received (sending the delivery confirmation to the mobile station 3) (step S302), the scheduler unit 219 transmits the delivery confirmation to the mobile station 3 that transmits the delivery confirmation. The delivery confirmation amount integrated value is updated by adding the delivery confirmation amount to the delivery confirmation amount integrated value stored in association with each other (step S303).

  Here, with reference to FIG. 12, a change in the delivery confirmation amount integrated value when attention is paid to the packet from the mobile station 3-1 will be described. In FIG. 12, the packet 6 in the mobile station 3-1, the wireless transfer blocks 61a, 61b-1 to 61b-3, 61c, the wireless transfer blocks 62a, 62b-1 to 62b-3, 62c on the wireless line, the base station The numbers in the wireless transfer blocks 63a to 63c in 2 and the packet 64 in the base station 2 indicate the size of each wireless transfer block or packet when the packet size of the packet 6 is normalized to “1”. The delivery confirmation amount integrated value and the numbers in parentheses of the wireless transfer blocks 62a, 62b-1 to 62b-3, 62c represent the delivery confirmation amount integrated value when the packet 6 is normalized to "1".

  The mobile station 3-1 transmits a transmission request 65 to the base station 2 when the packet 6 to be transmitted is generated. Upon receiving the transmission request 65, the base station 2 sets “0” to the delivery confirmation amount integrated value stored in association with the mobile station 3-1. The base station 2 uses the radio transfer block size information (radio transfer block size information) determined based on the radio channel quality information at predetermined scheduling times and the radio resource information allocated by the scheduling process (radio resource information). ) Including transmission instructions 66a, 66b-1 to 66b-3, 66c are transmitted to the mobile station 3-1.

  When the mobile station 3-1 receives the transmission instruction 66 a whose wireless transfer block size information is “0.5”, the mobile station 3-1 generates a wireless transfer block 61 a of size “0.5” as the first wireless transfer block constituting the packet 6. Then, the generated wireless transfer block 61a is transmitted as a wireless transfer block 62a to the wireless line.

  The base station 2 receives the wireless transfer block 62a on the wireless line. Since the wireless transfer block 62a was successfully received as the wireless transfer block 63a, the delivery confirmation amount “0.5” is added to the delivery confirmation amount integrated value “0.0” of the mobile station 3-1, and the delivery confirmation is performed. The amount integrated value is updated to “0.5”.

  When the mobile station 3-1 receives the transmission instruction 66 b-1 with the wireless transfer block size information “0.2”, the mobile station 3-1 has a wireless transfer block of size “0.2” as the second wireless transfer block constituting the packet 6. 61b-1 is generated, and the generated wireless transfer block 61b-1 is transmitted to the wireless line as a wireless transfer block 62b-1.

  The base station 2 receives the wireless transfer block 62b-1 on the wireless line. Since the base station 2 could not normally receive the wireless transfer block 62b-1, the base station 2 transmits a retransmission request to the mobile station 3-1. Since the wireless transfer block 62b-1 could not be received normally, the delivery confirmation amount integrated value corresponding to the mobile station 3-1 remains “0.5”.

  When the mobile station 3-1 receives the transmission instruction 66 c whose wireless transfer block size information is “0.3”, the mobile station 3-1 has the size “0.3” as the third (in this case, the last) wireless transfer block constituting the packet 6. The wireless transfer block 61c is generated, and the generated wireless transfer block 61c is transmitted as a wireless transfer block 62c to the wireless line.

  The base station 2 receives the wireless transfer block 62c on the wireless line. Since the wireless transfer block 62c was successfully received as the wireless transfer block 63c, the delivery confirmation amount “0.3” is added to the delivery confirmation amount integrated value “0.5” corresponding to the mobile station 3-1. The delivery confirmation amount integrated value is updated to “0.8”.

  When the mobile station 3-1 receives the transmission instruction 66 b-2 whose wireless transfer block size information is “0.2”, the wireless transfer block 61 b that is the second wireless transfer block constituting the packet 6 requested to be retransmitted. -2 is transmitted to the wireless line as a wireless transfer block 62b-2.

  The base station 2 receives the wireless transfer block 62b-2 on the wireless line. Since the base station 2 could not normally receive the wireless transfer block 62b-2, it transmits a retransmission request to the mobile station 3-1. Since the wireless transfer block 62b-2 could not be received normally, the delivery confirmation amount integrated value corresponding to the mobile station 3-1 remains “0.8”.

  When the mobile station 3-1 receives the transmission instruction 66 b-3 whose wireless transfer block size information is “0.2”, the wireless transfer block 61 b that is the second wireless transfer block constituting the packet 6 requested to be retransmitted. -3 is transmitted to the wireless line as a wireless transfer block 62b-3.

  The base station 2 receives the wireless transfer block 62b-3 on the wireless line. Since the wireless transfer block 62b-3 was successfully received as the wireless transfer block 63b, the delivery confirmation amount “0.2” is added to the delivery confirmation amount integrated value “0.8” corresponding to the mobile station 3-1. To do. Thereby, the delivery confirmation amount integrated value becomes “1”. That is, it means that the wireless transfer blocks 61a to 61c constituting the packet 6 have arrived. Accordingly, when the delivery confirmation amount integrated value becomes “1”, the base station 2 determines that reception of all the wireless transfer blocks constituting the packet has been completed, and determines to the mobile station 3-1. The delivery confirmation amount integrated value stored in association is discarded. Then, the packet 64 is reproduced using the wireless transfer blocks 63a to 63c.

  The scheduler unit 219 of the base station 2 receives the transmission request from each mobile station 3 in the same manner as when focusing on the packet from the mobile station 3-1 described above, and obtains the delivery confirmation amount integrated value associated with the mobile station 3. Initialization is performed, and the corresponding delivery confirmation amount integrated value is updated each time the wireless transfer block is normally received.

  Returning to FIG. 11, when the predetermined scheduling time is reached (step S304), the scheduler unit 219 determines the priority of the packet based on the delivery confirmation amount integrated value stored in association with the mobile station 3. Then, a scheduling process for allocating radio resources to the mobile station 3 according to the determined priority is executed (step S305). Since the scheduling process is the same as the operation described with reference to the flowchart of FIG. 6, the description thereof is omitted here.

  As described above, in the second embodiment, the base station 2 determines the size of the wireless transfer block based on the packet length and the wireless channel quality information included in the transmission request received from the mobile station 3, The priority is determined based on the delivery confirmation amount integrated value indicating the integrated value of the size of the wireless transfer block that has successfully received the wireless transfer block transmitted by the mobile station 3, and the mobile station 3 transmits based on the determined priority. A radio resource is allocated to a radio transfer block constituting a packet to be transmitted, and a transmission instruction including the size of the radio transfer block and the radio resource allocation is transmitted to the mobile station 3. The mobile station 3 generates a wireless transfer block by dividing a packet to be transmitted based on the wireless transfer block size included in the transmission instruction, and generates a wireless transfer block generated based on the allocation of the wireless resource included in the transmission instruction. Transmit to the base station 2. As a result, when the packet is divided into a plurality of wireless transfer blocks and transmitted, the wireless transfer block that has already been confirmed to be delivered without being able to reproduce the packet because the wireless transfer block does not reach the destination is wasted. It is possible to effectively use a wireless line with a reduced probability of becoming.

  In the second embodiment, the priority is increased as the value of the delivery confirmation amount integrated value is larger, and the wireless transfer blocks belonging to the packets having a higher percentage of delivery confirmation are preferentially transmitted. Therefore, when a wireless transfer block is unavoidably discarded, a wireless transfer block belonging to a packet with a small rate of delivery confirmation is discarded, and the wireless transfer block that cannot be assembled in the base station 2 and discarded. As a result, the frequency can be effectively used or the throughput at the packet level can be improved.

  In the second embodiment, the case where the mobile station 3 divides the packet into wireless transfer blocks has been described as an example. However, as shown in FIG. 8, the wired network 1 and the base shown in FIG. A system including the base station control device 5 between the station 2 and the station 2 may be used. In this case, the wireless transfer block generation unit 313 of the mobile station 3 generates a divided segment obtained by dividing the packet to be transmitted, generates a wireless transfer block by dividing the generated divided segment, and the packet reproduction unit of the base station 2 215 may reproduce the divided segment from the wireless transfer block and transmit it to the base station control device 5 so that the base station control device 5 reproduces the packet from the divided segment.

Embodiment 3 FIG.
A third embodiment of the present invention will be described with reference to FIGS. In the first and second embodiments, by assigning radio resources by increasing the priority of radio transfer blocks that constitute a packet with a high rate of delivery confirmation, packets that cannot be reproduced and discarded The amount of transfer blocks was reduced to effectively use the frequency and improve the throughput at the packet level.

  However, since the allowable residence time after the packet arrives from the wired network 1 to the base station 2 or after the packet to be transmitted in the mobile station 3 is not considered, before reaching the upper limit of the number of retransmissions If the allowable residence time is exceeded, the probability that the wireless transfer block being transmitted is wasted cannot be reduced.

  In order to improve such a problem, in the third embodiment, the allowable residence time is considered in the scheduling priority for assigning the wireless transfer block to the wireless resource. Specifically, an allowable residence time from when a packet arrives at the transmission side device until delivery confirmation is obtained is provided, and a packet exceeding the allowable residence time is discarded. The time until the staying packet is discarded due to exceeding the staying allowable time is defined as a staying grace time.

  Since the configuration of the communication system according to the third embodiment is the same as that of the communication system shown in FIG. 1, the description thereof is omitted here. Further, the configurations of base station 2 and mobile station 3 for downlink communication are the same as base station 2 and mobile station 3 of the first embodiment shown in FIGS. The configurations of the base station 2 and the mobile station 3 are the same as those of the base station 2 and the mobile station 3 of the second embodiment shown in FIGS.

  Since the difference between the third embodiment and the first or second embodiment is the operation for determining the priority of the scheduling process described with reference to the flowchart of FIG. 6, the priority is given here. Only the operation of the scheduling process including the determination operation of the degree will be described by taking the downlink communication as an example.

  When notified by the packet buffer 202 that the new packet has been received, the scheduler unit 208 initializes and stores the delivery confirmation amount integrated value, and uses the time keeping function of the own station to allow the new packet to stay. Measurement is always started and the allowable residence time of each packet is always grasped.

  FIG. 13 shows an example of an allowable staying time when attention is paid to a certain packet. In FIG. 13, for the packets buffered in the packet buffer 202 of the base station 2, the measurement of the allowable residence time is started from the arrival of the packet. If the delivery confirmation of all the wireless transfer blocks constituting the packet cannot be received from the mobile station 3 within the allowable residence time from the arrival of the packet, the scheduler unit 208 discards the corresponding packet. The remaining allowable residence time becomes smaller as the current time approaches the disposal time. The scheduler unit 208 assigns a radio resource to a radio transfer block with a higher priority as the allowable remaining residence time is smaller.

  The operation of the scheduling process according to the third embodiment will be described with reference to the flowchart of FIG. The scheduler unit 208 obtains a priority for each wireless transfer block constituting the packet from the allowable staying remaining time and the delivery confirmation amount integrated value (step S400). Specifically, the priority Ptotal of each wireless transfer block is calculated by the following equation using the counts of two priority indexes, that is, the allowable remaining residence time and the delivery confirmation amount integrated value.

Ptotal = α × Pact + Β × Pdelay (formula)
In the above equation, Pact indicates the priority based on the delivery confirmation amount integrated value, Pdelay indicates the priority based on the allowable residence time, α indicates the priority coefficient (weighting) based on the delivery confirmation amount integrated value, Indicates a priority coefficient (weighting) based on the remaining allowable remaining time. That is, the scheduler unit 208 determines the priority based on the delivery confirmation amount integrated value in descending order of the delivery confirmation amount integrated value, and determines the priority based on the remaining allowable remaining time in descending order of the remaining allowable remaining time. A value obtained by weighting and adding the priority based on the integrated value and the priority based on the remaining allowable remaining time is set as the priority of the wireless transfer block.

  The scheduler unit 208 selects a wireless transfer block constituting a packet with the highest priority as a processing target block (step S401). That is, the block to be processed is selected with a high priority assigned to each wireless transfer block having a small priority Ptotal value calculated by the above formula.

  The scheduler unit 208 determines whether there is a remaining radio resource (step S402). When there is a remaining radio resource, the scheduler unit 208 allocates a radio resource to the radio transfer block selected as the processing target block (step S403).

  The scheduler unit 208 selects, as a new processing target block, a wireless transfer block that configures a packet having a higher priority next to a packet configured by the wireless transfer block selected as the current processing target block (step S404).

  The scheduler unit 208 allocates radio resources to the radio transfer block selected as the processing target block until there is no remaining radio resource, and the priority is next to the packet configured by the radio transfer block selected as the current processing target block. The operation of selecting a wireless transfer block that constitutes a packet having a high value as a new processing target block is repeated (steps S402 to S404).

  As described above, in the third embodiment, the priority is determined based on the remaining allowable residence time indicating the time from the current time to the time at which the wireless transfer block can stay, and the delivery confirmation amount integrated value. Therefore, when the packet is divided into a plurality of wireless transfer blocks and transmitted, the wireless transfer block is not transmitted to the transmission destination. It is possible to effectively use the wireless line by reducing the probability that the wireless transfer block that has already been confirmed to be delivered without being able to reproduce the packet because it does not reach it will be wasted.

  In the third embodiment, the priority is determined based on the allowable staying remaining time and the delivery confirmation amount integrated value. However, the wireless line quality information and the delivery confirmation amount integrated value, or the wireless line quality information, The priority may be determined by a combination of the allowable residence time and the delivery confirmation amount integrated value. When wireless channel quality information is used, the priority may be set higher as the wireless channel quality information indicates that the channel state is better.

Embodiment 4 FIG.
A fourth embodiment of the present invention will be described with reference to FIG. In the first to third embodiments, the priority for allocating radio resources to the radio transfer blocks constituting the packet is determined using the delivery confirmation amount and the remaining allowable residence time. In the fourth embodiment, the transmission quality is controlled using the priority.

  Since the configuration of the communication system of the fourth embodiment is the same as that of the communication system shown in FIG. 1, the description thereof is omitted here. Further, the configurations of base station 2 and mobile station 3 for downlink communication are the same as base station 2 and mobile station 3 of the first embodiment shown in FIGS. The configurations of the base station 2 and the mobile station 3 are the same as those of the base station 2 and the mobile station 3 of the second embodiment shown in FIGS.

  The difference between the fourth embodiment and the first or third embodiment is that the scheduler unit 208 receives the radio channel quality information using the priority determined by using the delivery confirmation amount and the staying allowable remaining time. Since the wireless channel quality information extracted by the unit 209 is corrected and the transmission quality is controlled using the corrected wireless channel quality information, here, only the transmission quality is controlled by taking downlink communication as an example. Will be explained.

  The scheduler unit 208 includes a radio channel quality information table in order to control transmission quality using radio channel quality information. As shown in FIG. 15, the modulation method, coding rate, and transmission power are registered in the wireless channel quality information table in association with the wireless channel quality. The scheduler unit 208 corrects the radio channel quality information extracted by the radio channel quality information receiving unit 209, and selects a modulation scheme, coding rate, and transmission power registered in association with the corrected radio channel quality information. The wireless transfer block transmitting unit 207 transmits the wireless transfer block via the wireless signal transmitting / receiving unit 206 using the notified modulation scheme, coding rate, and transmission power.

  Next, the operation for correcting the radio channel quality information will be described. The scheduler unit 208 receives the radio channel quality information from the radio channel quality information receiving unit 209. As described in the first to third embodiments, scheduler section 208 determines the priority of the wireless transfer block that constitutes the packet using the delivery confirmation amount and the staying allowable remaining time.

  The scheduler unit 208 corrects the radio channel quality information by adding a predetermined value to the radio channel quality information corresponding to the radio transfer block having a high priority. For example, “2” is added to the value of the wireless channel quality information corresponding to the wireless transfer block having the highest priority, and “1” is then added to the value of the wireless channel quality information corresponding to the wireless transfer block having the highest priority. to add. As a result, the radio channel quality information of the radio transfer block having the radio channel quality information “4” and the highest priority is “6”, the radio channel quality information is “3”, and the priority is The wireless channel quality information of the second highest wireless transfer block is “4”. Therefore, the radio transfer block with the highest priority is transmitted with the modulation scheme “16QAM”, the coding rate “2/3”, and the transmission power “20”, and the radio transfer block with the second highest priority is the modulation scheme. It is transmitted with “16QAM”, coding rate “1/3”, and transmission power “20”.

  As described above, in the fourth embodiment, the radio channel quality information is corrected by adding a predetermined value to the radio channel quality information of the radio transfer block having a high priority, and the transmission quality is based on the corrected radio channel quality information. The higher the priority, the higher the probability of successful reception of the wireless transfer block, and the effective use of the frequency by reducing the amount of wireless transfer blocks that cannot be assembled and discarded. Alternatively, the throughput at the packet level can be improved.

  In the fourth embodiment, the wireless channel quality information is corrected by adding a predetermined value to the value of the wireless channel quality information according to the priority. May be subtracted to correct the radio channel quality information. In this case, correction may be performed in order of increasing priority from the wireless channel quality information corresponding to the wireless transfer block having the lowest priority. That is, the radio channel quality information may be corrected relatively according to the priority.

  In the fourth embodiment, the transmission quality is a modulation scheme, a coding rate, or transmission power, but a diversity effect of frequency or space may be used.

Embodiment 5. FIG.
In a general communication system, retransmission control is performed between a transmission side and a reception side, but a wireless transfer block that exceeds the upper limit of the number of retransmissions is discarded without being retransmitted. Therefore, since the wireless transfer block that exceeds the upper limit of the number of retransmissions does not reach the receiving side, there is a problem that the packet cannot be reproduced and other wireless transfer blocks are wasted.

  In order to improve such a problem, in the fifth embodiment, the upper limit value of the number of retransmissions of the wireless transfer block is controlled using the priority determined using the number of times of delivery and the remaining allowable residence time. Since the configuration of the communication system according to the fifth embodiment is the same as that of the communication system shown in FIG. 1, the description thereof is omitted here. Further, the configurations of base station 2 and mobile station 3 for downlink communication are the same as base station 2 and mobile station 3 of the first embodiment shown in FIGS. The configurations of the base station 2 and the mobile station 3 are the same as those of the base station 2 and the mobile station 3 of the second embodiment shown in FIGS.

  The difference between the fifth embodiment and the first to fourth embodiments is that the scheduler units 208 and 219 use the priority determined using the delivery confirmation amount and the allowable staying remaining time to determine the number of retransmissions. Since the upper limit value is corrected and retransmission is controlled using the corrected upper limit value of the number of retransmissions, only the operation for determining the upper limit value of transmission retransmission control will be described here taking downlink communication as an example. To do.

  As described in the first to third embodiments, the scheduler unit 208 determines the priority of the wireless transfer block that constitutes the packet by using the delivery confirmation amount and the remaining allowable residence time. The scheduler unit 208 corrects the upper limit value of the number of retransmissions by adding a predetermined value to the upper limit value of the number of retransmissions of the high-priority wireless transfer block. The scheduler unit 208 notifies the retransmission control unit 204 of the corrected upper limit value of the number of retransmissions.

  The retransmission control unit 204 performs retransmission control using the notified upper limit value of the number of retransmissions. That is, the retransmission control unit 204 stores the number of transmissions of the wireless transfer block to the mobile station 3 and discards the wireless transfer block when the number of retransmissions exceeds the upper limit of the number of retransmissions.

  As described above, in the fifth embodiment, when a plurality of wireless transfer blocks are generated from a packet and transmitted, the upper limit value of the number of retransmissions is set to be large based on the priority. The upper limit of the number of retransmissions of radio transfer blocks belonging to packets with a large percentage of taken packets is increased, and the radio transfer block has not reached the mobile station 3 so that the packet cannot be reproduced and the radio transfer has already been confirmed. The probability that the block is wasted can be reduced and the wireless line can be used effectively.

  In addition, when a wireless transfer block is unavoidably discarded, a wireless transfer block belonging to a packet with a small rate of delivery confirmation is discarded, and the mobile station 3 cannot discard the packet and cannot discard the wireless transfer block. The amount can be reduced, and the effective use of frequency or the throughput at the packet level can be improved.

  In the fifth embodiment, downlink communication has been described as an example. However, in the case of uplink communication, the scheduler unit 219 performs wireless transfer according to priority as in the case of downlink communication. The upper limit value of the block retransmission number is determined, the determined upper limit value of the retransmission number is notified to the mobile station 3, and the retransmission control unit 314 of the mobile station 3 performs the retransmission control using the notified upper limit value of the retransmission number. What should I do?

Embodiment 6 FIG.
In the sixth embodiment, the transmission quality of the wireless transfer block is changed according to the number of wireless transfer blocks constituting the packet, and the error rate of the packet is kept constant. Since the configuration of the communication system according to the sixth embodiment is the same as that of the wireless communication system shown in FIG. 1, the description thereof is omitted here. Further, the configurations of base station 2 and mobile station 3 for downlink communication are the same as base station 2 and mobile station 3 of the first embodiment shown in FIGS. The configurations of the base station 2 and the mobile station 3 are the same as those of the base station 2 and the mobile station 3 of the second embodiment shown in FIGS.

  In the sixth embodiment, only the operation of determining the number of wireless transfer blocks (number of packet divisions) and transmission quality constituting a packet based on the packet length and the wireless transmission quality information will be described.

  The scheduler unit 208 includes a packet table for selecting the number of radio transfer blocks and transmission quality from the packet length. As shown in FIG. 16, a transmission quality index and the number of packet divisions are registered in the packet table in association with the packet length and the radio channel quality information. In FIG. 16, when the wireless channel quality information is “1” and the packet length is “200 bytes”, the transmission quality index is registered as “2” and the packet division number is “2”. When the wireless channel quality information is “1” and the packet length is “400 bytes”, “2” is registered for the transmission quality index and “4” is registered for the number of packet divisions.

  When notified that the new packet has been received from the packet buffer 202, the scheduler unit 208 uses the packet length of the new packet and the radio channel quality information notified from the radio channel quality information receiving unit 209, as shown in FIG. The packet table shown in (1) is searched to select a transmission quality index and the number of wireless transfer block divisions.

  The scheduler unit 208 selects a predetermined modulation scheme, coding rate, or transmission power using the selected transmission quality index, and notifies the wireless transfer block transmission unit 207 of it. Further, the scheduler unit 208 notifies the wireless transfer block generation unit 203 of the selected packet division number, and the wireless transfer block generation unit 203 divides the packet into the notified packet division number to generate a wireless transfer block.

  The wireless transfer block transmission unit 207 is the wireless transfer block generated by the wireless transfer block generation unit 203 using the modulation scheme, coding rate, or transmission power notified from the scheduler unit 208. It transmits via the radio signal transmission / reception part 206 using the radio | wireless resource allocated by the scheduling process of -3.

  As described above, in the sixth embodiment, the size and the transmission quality of the wireless transfer block for dividing the packet are selected based on the packet length and the wireless channel quality information. Even when the wireless channel quality changes, it is possible to suppress the deterioration of the packet error rate.

  In the sixth embodiment, the transmission quality is a modulation scheme, a coding rate, or transmission power, but a diversity effect of frequency or space may be used.

  In the sixth embodiment, the transmission quality index and the number of packet divisions are selected when the scheduler unit 208 receives a new packet from the packet buffer 202. Alternatively, the transmission quality index and the number of packet divisions may be obtained again using the latest wireless channel quality information.

  Furthermore, although the transmission timing of each divided wireless transfer block is not described in the sixth embodiment, the accuracy of the transmission quality index and the number of packet divisions determined when a new packet is received is maintained. For this reason, wireless transfer blocks divided from the same packet may be transmitted together in a short period of time with little change in wireless channel quality.

Embodiment 7 FIG.
A seventh embodiment of the present invention will be described with reference to FIGS. In the first to sixth embodiments, the case where the mobile station is connected to one base station has been described. However, in this seventh embodiment, the base station to which the mobile station is currently connected is changed to another base station. By increasing the priority of the radio transfer block that has not been reached at the time of the handover request to perform handover to the station, the handover delay time until completion of packet delivery (the handover request time obtained from the radio channel quality measurement and the actual handover execution time) Difference).

  FIG. 17 is a diagram showing a configuration of a communication system according to a seventh embodiment of the present invention. 17, the communication system includes a wired network 1, m (1 <m, m is a natural number) base stations 2a (2a-1 to 2a-m), and n mobile stations 3a (3a- 1 to 3a-n). The wired network 1 and the base station 2a are connected by a wired line, the base station 2a and the mobile station 3a are connected by a wireless line, and the mobile station 3a is connected to the wired network 1 via the base station 2a and the wired network 1. Mutual communication using packets is performed with a connected fixed terminal (not shown) or a mobile station. Further, the mobile station 3a performs handover between the base stations 2a by movement.

  In the seventh embodiment, downlink communication in which the base station 2a transmits a packet received from the wired network 1 to the mobile station 3a will be described. FIG. 18 is a block diagram showing a configuration related to downlink communication of the mobile station 3a shown in FIG. The configuration related to the downlink communication of the mobile station 3a shown in FIG. 18 is the same as the configuration related to the downlink communication of the mobile station 3 of the first embodiment shown in FIG. A handover request unit 308 is added. Components having the same functions as those in the configuration related to the downlink communication of the mobile station 3 of the first embodiment shown in FIG. 3 are given the same reference numerals, and redundant descriptions are omitted.

  The handover request unit 308 is configured to determine the radio channel quality between the base station 2a and the base station 2a that is currently communicating and the base station 2a that is adjacent to the base station 2a that is currently communicating and is communicable with the own station at predetermined intervals. And based on the measured radio channel quality, it is determined whether or not a handover from the currently communicating base station 2a to another base station 2a is requested. If the handover request unit 308 determines to request a handover, the handover request unit 308 transmits a handover request to the base station 2 a via the radio signal transmission / reception unit 301.

  FIG. 19 is a block diagram showing a configuration related to downlink communication of the base station 2a shown in FIG. The configuration related to the downlink communication of the base station 2a shown in FIG. 19 is the same as the configuration related to the downlink communication of the base station 2 of the first embodiment shown in FIG. 210 has been added. Components having the same functions as those in the configuration related to the downlink communication of the base station 2 of the first embodiment shown in FIG. 2 are given the same reference numerals, and redundant descriptions are omitted.

  When the handover control unit 210 receives a handover request from the mobile station 3 a via the radio signal transmission / reception unit 206, the handover control unit 210 outputs the received handover request to the scheduler unit 208. Further, when handover execution permission is received from the scheduler unit 208, the handover control unit 210 performs processing for handover execution.

  When the scheduler unit 208 receives a handover request from the handover control unit 210, the scheduler unit 208 schedules radio transfer blocks with higher priority and / or transmission quality for the mobile station 3a that has made the handover request. In addition, when the delivery of the packet to the mobile station 3a that has made the handover request is completed, the scheduler unit 208 outputs a handover execution permission to the handover control unit 210.

  Next, the operation of Embodiment 7 of the communication system in the present invention will be described. Since the difference between the seventh embodiment and the previous first or third to sixth embodiments is only the operation when the mobile station 3a performs the handover, only the operation related to the handover will be described here.

  When the measurement time for each predetermined period is reached, the handover request unit 308 of the mobile station 3a is adjacent to the currently connected base station 2a and the currently communicating base station 2a and is capable of communicating with the own station. Measure the quality of the radio link between 2a and its own station. The handover request unit 308 determines whether or not to execute handover based on the measured radio channel quality. A general prior art is used to determine whether or not to execute a handover. For example, the radio channel quality with the currently connected base station 2a is equal to or lower than a predetermined threshold, and the radio channel quality with the currently connected base station 2a among the communicable base stations 2a is wireless. It is determined that the handover is executed when there is a base station 2a with good channel quality. When it is determined that the handover is to be executed, the handover request unit 308 transmits a handover request to the base station 2a via the radio signal transmission / reception unit 301.

  When receiving the handover request, the handover control unit 210 of the base station 2 a outputs the received handover request to the scheduler unit 208. When the scheduler unit 208 receives the handover request, the scheduler unit 208 sets the priority of the undelivered radio transfer block constituting the undelivered packet to the mobile station 3a that transmitted the handover request to a high level. Thereby, in the scheduling process executed at the scheduling time, the priority for the mobile station 3a that transmitted the handover request becomes the highest without depending on the delivery confirmation amount integrated value, and the wireless transfer for the mobile station 3a that transmitted the handover request. Radio resources are preferentially allocated to blocks.

  Further, the scheduler unit 208 of the base station 2a sets the transmission quality for the mobile station 3a that has transmitted the handover request to be higher than the current transmission quality. As the transmission quality, a modulation scheme, a coding rate, transmission power, or the like is used. For example, when “64QAM”, “16QAM”, or “QPSK” can be set as the modulation method, and the “64QAM” modulation method is currently set for the mobile station 3a that has transmitted the handover request. The scheduler unit 208 sets a modulation scheme of “16QAM” or “QPSK”. Further, any one of “1/3”, “1/2”, and “2/3” can be set as the coding rate, and the mobile station 3a that has transmitted the handover request is currently set to “2/3”. "Is set, the scheduler unit 208 sets the encoding rate of" 1/3 "or" 1/2 ". As for the transmission power, a transmission power larger than the current transmission power is set.

  When the delivery of the packet to the mobile station 3a that transmitted the handover request is completed, the scheduler unit 208 of the base station 2a outputs a handover execution permission to the handover control unit 210. When the handover control unit 210 receives the handover execution permission, the handover control unit 210 starts a process for executing the handover.

  As described above, in the seventh embodiment, when a handover request is received from the mobile station 3a, a packet that is being transmitted to the mobile station that has transmitted the handover request is formed without depending on the delivery confirmation amount integrated value. Since the priority and / or transmission quality of the undelivered radio transfer block is set high and the handover is executed after the transmission of the packet being transmitted to the mobile station that has transmitted the handover request is completed, the handover delay time Can be shortened, and the possibility that a handover can be executed before the wireless channel quality deteriorates increases, and the communication quality can be improved.

  In addition, the number of undelivered packets in the downlink direction transferred between base stations can be reduced, and the amount of communication in the transmission path between base stations can be reduced.

  In the seventh embodiment, the downlink communication in which user data is transmitted from the base station 2a to the mobile station 3a has been described as an example. However, the uplink in which user data is transmitted from the mobile station 3a to the base station 2a is described. It is possible to carry out the same in the direction communication, and the same effect can be obtained. In this case, the function relating to the uplink communication of the mobile station 3 of the second embodiment shown in FIG. 9 includes the handover request unit 308 of the seventh embodiment, and the embodiment shown in FIG. The function relating to uplink communication of the two base stations 2 may be provided with the handover control unit 210 of the seventh embodiment.

Embodiment 8 FIG.
An eighth embodiment of the present invention will be described with reference to FIGS. In the eighth embodiment, an efficient handover is performed in consideration of a handover delay allowable time. Since the configuration of the communication system according to the eighth embodiment is the same as that of the communication system according to the seventh embodiment, the description thereof is omitted here. The configuration of the mobile station 3a of the eighth embodiment is the same as that of the mobile station 3a of the previous embodiment 7, but the handover request unit 308 has the same function as the handover request unit 308 of the previous embodiment 7. In addition, a function for predicting an allowable handover delay time is added.

  The configuration of base station 2a of the eighth embodiment is the same as that of base station 2a of the previous seventh embodiment, but scheduler unit 208 is in addition to the function of scheduler unit 208 of the previous seventh embodiment. After transmitting the unreachable radio transfer packet for the packet to the mobile station 3a that transmitted the handover request based on the handover delay allowable time included in the handover request and the time required for delivery completion determined from the current traffic load status A function for determining whether or not to execute a handover has been added.

  Next, the operation of the communication system according to the eighth embodiment of the present invention will be described. The operation of the communication system according to the eighth embodiment is almost the same as that of the communication system according to the seventh embodiment. The difference is that the handover requesting unit 308 of the mobile station 3a obtains the handover allowable delay time to Since the scheduling is performed based on the handover allowable delay time notified to the station 2a and notified by the scheduler unit 208 of the base station 2a, only the difference will be described.

  First, the operation of the handover request unit 308 of the mobile station 3a will be described with reference to FIG. FIG. 20 is a diagram illustrating the relationship between degradation of radio channel quality and time. When the mobile station 3a moves, the distance between the base station 2a and the mobile station 3a increases, or the radio environment changes between the base station 2a and the mobile station 3a, as shown in FIG. The wireless channel quality between 3a deteriorates with the passage of time. When the measurement time for each predetermined period is reached, the handover request unit 308 is adjacent to the currently connected base station 2a and the currently communicating base station 2a and can communicate with the own station 2a and the own station. The quality of the wireless link between them is measured. The handover request unit 308 stores a predetermined number of radio channel qualities measured before the current measurement time. When the handover request unit 308 determines to request a handover (current time in FIG. 20), the handover request unit 308 predicts a handover allowable delay time based on the radio channel quality measured before the stored current time. Specifically, the rate of degradation of the radio channel quality is obtained from the stored radio channel quality, and when the radio channel quality is degraded at the obtained rate of degradation of the radio channel quality, the radio channel quality is determined in advance from the current time. A handover allowable delay time indicating a time until a time when the value becomes equal to or less than a predetermined threshold (communication wireless channel quality value) is obtained. The handover request unit 308 transmits a handover request including the obtained handover allowable delay time.

  Next, the operation of the scheduler unit 208 of the base station 2a will be described with reference to FIG. When a handover request including a handover allowable delay time is received from the handover control unit 210, the scheduler unit 208 configures an undelivered radio that constitutes an undelivered packet for the mobile station 3a that has transmitted the current traffic load status and the handover request. Based on the data amount of the transfer block, the time required to complete delivery of an undelivered packet is estimated (step S501).

  The scheduler unit 208 compares the estimated delivery completion time with the handover allowable delay time included in the handover request. As a result of the comparison, if the delivery completion time is larger than the handover allowable delay time (step S502, Yes), that is, all undelivered wireless transfer packets of undelivered packets cannot be transmitted within the handover allowable delay time. The scheduler unit 208 determines that the mobile station 3a cannot complete the packet before the handover even if the transmission of the undelivered radio transfer packet is continued, and controls the handover execution permission in order to immediately start the handover. It outputs to the part 210 (step S503).

  When the delivery completion time is equal to or shorter than the handover allowable delay time (No in step S502), that is, when all the undelivered wireless transfer packets of the undelivered packets can be transmitted within the handover allowable delay time, the scheduler unit 208 Determines that the mobile station 3a can complete the packet before the handover, and, as in the previous embodiment 7, the undelivered radio constituting the undelivered packet to the mobile station 3a that transmitted the handover request Scheduling is executed with the priority and / or transmission quality of the transfer block set high (step S504).

  As described above, in the eighth embodiment, the mobile station 3a obtains the rate of deterioration of the radio channel quality based on the radio channel quality, and can communicate with the currently connected base station from the obtained rate. A handover allowable delay time is predicted, and a handover request including the predicted handover allowable delay time is transmitted. The base station 2a transmits an undelivered radio transfer block constituting a packet being transmitted to the mobile station that has transmitted the handover request. The time required for completion of delivery required for transmission is obtained, and if the time required for delivery completion is equal to or shorter than the allowable handover delay time included in the handover request, the mobile station that has transmitted the handover request does not depend on the delivery confirmation amount integrated value. Set a high priority and / or transmission quality for undelivered radio transfer blocks that make up the packet being transmitted, The handover is executed after the transmission of the packet being transmitted to the mobile station that has transmitted the message is completed, and the handover is immediately performed when the time required for completion of delivery is greater than the allowable handover delay time included in the handover request. Therefore, it is possible to avoid a situation in which the packet is not completed after the handover is delayed.

  In the eighth embodiment, the priority of the undelivered radio transfer block constituting the undelivered packet for the mobile station 3a that has transmitted the handover request when the delivery completion time is equal to or less than the handover allowable delay time and / Or set the transmission quality to be high and perform scheduling, but if there is a margin in the allowable handover delay time, the undelivered radio transfer block of the undelivered packet may be transmitted within the allowable handover delay time Therefore, the priority may be set high according to the allowable handover delay time and the time required for completion of delivery.

  Specifically, for example, when the allowable handover delay time is smaller than a predetermined value, the priority is set high, and when the allowable handover delay time is equal to or larger than the predetermined value, the priority is changed. Rather, scheduling is performed with priority according to the delivery confirmation amount integrated value. Further, the difference between the allowable handover delay time and the required delivery completion time may be used. As a result, the priority of other mobile stations not requesting handover due to the handover request is not unduly lowered, and the fairness of each mobile station can be prevented from being significantly impaired.

  As described above, the communication system according to the present invention is useful for a communication system using a wireless line, and is particularly suitable for a communication system using a wireless transfer block obtained by dividing a packet.

It is a figure which shows the structure of Embodiment 1 of the communication system in this invention. It is a block diagram which shows the structure regarding the communication of the downlink direction of the base station shown in FIG. FIG. 2 is a block diagram showing a configuration related to downlink communication of the mobile station shown in FIG. 1. It is a flowchart for demonstrating operation | movement of the scheduler part of Embodiment 1 of the communication system in this invention. It is a figure for demonstrating the change of the delivery confirmation amount integrated value at the time of paying attention to one certain packet. It is a flowchart for demonstrating operation | movement of the scheduling process of the scheduler part of Embodiment 1 of the communication system in this invention. It is a figure for demonstrating the change of the priority of scheduling. It is a figure which shows another example of the communication system in this invention. It is a block diagram which shows the structure of the uplink communication of the mobile station of Embodiment 2 in this invention. It is a block diagram which shows the structure of the uplink communication of the base station of Embodiment 2 in this invention. It is a flowchart for demonstrating operation | movement of the scheduler part of the base station of Embodiment 2 in this invention. It is a figure for demonstrating the change of the delivery confirmation amount integrated value at the time of paying attention to the packet transmitted from a certain mobile station. It is a figure which shows an example of the residence allowable time when paying attention to one certain packet of Embodiment 3 in this invention. It is a flowchart for demonstrating operation | movement of the scheduling process of the scheduler part of the base station of Embodiment 3 in this invention. It is a figure which shows the structure of the radio channel quality information table with which the scheduler part of the base station of Embodiment 4 in this invention is provided. It is a figure which shows the structure of the packet table with which the scheduler part of the base station of Embodiment 6 in this invention is provided. It is a figure which shows the structure of Embodiment 7 of the communication system in this invention. FIG. 18 is a block diagram showing a configuration related to downlink communication of the mobile station shown in FIG. 17. It is a block diagram which shows the structure regarding the communication of the downlink direction of the base station shown in FIG. It is a figure which shows the deterioration of radio | wireless line quality, and the relationship of time. It is a flowchart for demonstrating operation | movement of the scheduler part of the base station of Embodiment 8 in this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Wired network 2, 2a-1, 2a-m Base station 3-1, 3-2, 3-n, 3a-1, 3a-2, 3a-n Mobile station 5 Base station control apparatus 201 Wired signal receiving part 202 , 312 Packet buffer 203, 313 Wireless transfer block generator 204, 214, 304, 314 Retransmission controller 205, 315 Retransmission control signal receiver 206, 211, 301, 316 Radio signal transceiver 207 Wireless transfer block transmitter 208, 219 Scheduler unit 209 Radio channel quality information reception unit 210 Handover control unit 212, 303 Retransmission control signal transmission unit 213, 302 Wireless transfer block reception unit 215, 305 Packet reproduction unit 216 Wired signal transmission unit 217 Transmission instruction transmission unit 218 Transmission request reception unit 301 Radio channel quality information transmission unit 306 Packet reception unit 08 handover request unit 311 packet generating unit 318 transmission instruction receiving unit 319 control unit 320 transmission request transmitting unit

Claims (16)

In a communication system in which a mobile station communicates with a partner station via a base station connected to a network,
The base station
A wireless transfer block generator for dividing a packet to be transmitted into a plurality of wireless transfer blocks;
Priority is determined based on a delivery confirmation amount integrated value indicating an integrated value of the size of the wireless transfer block for which delivery confirmation indicating that the wireless transfer block has reached the mobile station has been obtained, and based on the determined priority A scheduler unit that allocates radio resources to radio transfer blocks constituting a packet to be transmitted;
A wireless transfer block transmitter that transmits the wireless transfer block generated by the wireless transfer block generator using the wireless resource allocated by the scheduler;
With
The mobile station
When a radio transfer block is normally received from the base station, a delivery confirmation is transmitted to the base station. When a radio transfer block is not normally received from the base station, a retransmission request is transmitted to the base station. A retransmission control unit to
A packet reproducing unit that reproduces a packet from the wireless transfer block received from the base station;
A communication system comprising: When the base station is connected to the network via a base station controller,
The base station controller is
Sending a segment divided into packets to the base station,
The wireless transfer block generation unit of the base station,
Generating the wireless transfer block from the segment,
The packet regeneration unit of the base station,
Regenerating a segment from the radio transfer block received from the base station, and regenerating a packet from the regenerated segment
The communication system according to claim 1. In a communication system in which a mobile station communicates with a partner station via a base station,
The mobile station
When a packet to be transmitted occurs, a transmission request transmitter that transmits a transmission request including the packet length of the packet to be transmitted to the base station;
A wireless transfer block generation unit that generates a wireless transfer block by dividing the packet to be transmitted based on the size of the wireless transfer block included in the transmission instruction notified from the base station;
A wireless transfer block transmitter that transmits to the base station the wireless transfer block generated by the wireless transfer block generator based on the assignment of the wireless resource included in the transmission instruction notified from the base station;
With
The base station
The size of the radio transfer block is determined based on the packet length and radio channel quality information included in the transmission request received from the mobile station, and the radio transfer block that has successfully received the radio transfer block transmitted by the mobile station A scheduler that assigns radio resources to radio transfer blocks constituting packets to be transmitted by the mobile station based on the determined priority, based on a delivery confirmation amount integrated value indicating an integrated value of the size;
A transmission instruction transmission unit that transmits to the mobile station a transmission instruction including the size of the radio transfer block determined by the scheduler unit and radio resource allocation;
A communication system comprising: When the base station is connected to the network via a base station controller,
The wireless transfer block generator of the mobile station is
Generate a divided segment obtained by dividing the packet to be transmitted, divide the generated divided segment to generate a wireless transfer block,
The packet generator of the base station is
Reproducing the segment segment from the radio transfer block received from the mobile station, transmitting the segment segment that has been reproduced to the base station controller,
The base station controller is
Replaying a packet from the segment segment from the base station;
The communication system according to claim 3. The scheduler unit of the base station
Determining the priority on the basis of the allowable remaining residence time indicating the time from the current time to the time at which the wireless transfer block can be retained and the delivery confirmation amount integrated value;
The communication system according to any one of claims 1 to 4. The scheduler unit of the base station
Selecting a transmission quality for transmitting a radio transfer block to which the radio resource is allocated based on the priority;
The communication system according to any one of claims 1 to 5. The transmission quality is
Modulation method, coding rate, or transmission power,
The communication system according to claim 6. The scheduler unit of the base station
Selecting an upper limit value of the number of retransmissions of the wireless transfer block based on the priority;
The communication system according to any one of claims 1 to 7. The scheduler unit of the base station
Selecting the number of divisions and transmission quality of the wireless transfer block based on the packet length of the packet and the wireless channel quality information;
The communication system according to any one of claims 1 to 8. The mobile station
Handover that measures the radio channel quality between the currently connected base station and the base station adjacent to the currently connected base station and its own station, and transmits a handover request for requesting handover based on the measured radio channel quality Request section,
Further comprising
The base station
A handover control unit that executes a handover process for the mobile station that has transmitted the handover request upon receiving a handover execution permission;
Further comprising
The scheduler unit
When the handover request is received, the priority and / or transmission quality of the undelivered radio transfer block constituting the packet being transmitted to the mobile station that has transmitted the handover request is increased without depending on the delivery confirmation amount integrated value. Setting and outputting the handover execution permission to the handover control unit after transmission of a packet being transmitted to the mobile station that has transmitted the handover request is completed;
The communication system according to any one of claims 1 to 9. The mobile station handover request unit is:
Based on the measured radio channel quality, the rate of degradation of the radio channel quality is obtained, and the handover allowable delay time that can be communicated with the currently connected base station is predicted from the obtained rate, and the handover including the predicted handover allowable delay time is performed. Send a request,
The scheduler unit of the base station
A time required for completion of delivery required for transmitting an undelivered radio transfer block constituting a packet being transmitted to the mobile station that has transmitted the handover request is obtained, and the time required for completion of delivery is included in the handover request. If the delay time is shorter than the delay time, the priority and / or transmission quality of the undelivered radio transfer block constituting the packet being transmitted to the mobile station that transmitted the handover request is increased without depending on the delivery confirmation amount integrated value. The handover execution permission is output to the handover control unit after the transmission of the packet being transmitted to the mobile station that has transmitted the handover request is completed, and the delivery completion time is included in the handover request If it is greater than the time, the handover execution permission is immediately given to the handover. And outputs it to the control unit,
The communication system according to claim 10. The scheduler unit of the base station
Adjusting the priority and transmission quality according to the delivery completion required time and the handover allowable delay time when the delivery completion required time is equal to or less than a handover allowable delay time included in the handover request;
The communication system according to claim 11. In a base station that is connected to a wired network by a wired line and connected to a mobile station by a wireless line,
A wireless transfer block generator for dividing a packet to be transmitted into a plurality of wireless transfer blocks;
Priority is determined based on a delivery confirmation amount integrated value indicating an integrated value of the size of the wireless transfer block for which delivery confirmation indicating that the wireless transfer block has reached the mobile station has been obtained, and based on the determined priority A scheduler unit that allocates radio resources to radio transfer blocks constituting a packet to be transmitted;
A wireless transfer block transmitter that transmits the wireless transfer block generated by the wireless transfer block generator using the wireless resource allocated by the scheduler;
A base station comprising: In a base station connected to a mobile station via a wireless line,
The size of the radio transfer block is determined based on the packet length and radio channel quality information included in the transmission request received from the mobile station, and the radio transfer block that has successfully received the radio transfer block transmitted by the mobile station A scheduler that assigns radio resources to radio transfer blocks that constitute a packet to be transmitted by the mobile station based on the determined priority based on a delivery confirmation amount integrated value indicating an integrated value of the size;
A transmission instruction transmission unit that transmits to the mobile station a transmission instruction including the size of the radio transfer block determined by the scheduler unit and radio resource allocation;
A base station comprising: A handover control unit that executes a handover process for a mobile station that has requested a handover upon receiving a handover execution permission;
Further comprising
The scheduler unit
In order to measure the radio channel quality between the base station to which the mobile station is currently connected and the base station adjacent to the currently connected base station and the own station, and to request a handover based on the measured radio channel quality When receiving the handover request to be transmitted, the priority and / or transmission quality of the undelivered radio transfer block constituting the packet being transmitted to the mobile station that has transmitted the handover request without depending on the delivery confirmation amount integrated value. Outputting the handover execution permission to the handover control unit after completing transmission of a packet being transmitted to the mobile station that has transmitted the handover request,
The base station according to claim 13 or 14. In a mobile station connected to a base station via a wireless line,
When a packet to be transmitted occurs, a transmission request transmitter that transmits a transmission request including the packet length of the packet to be transmitted to the base station;
A wireless transfer block generation unit that generates a wireless transfer block by dividing the packet to be transmitted based on the size of the wireless transfer block included in the transmission instruction notified from the base station;
A wireless transfer block transmitter that transmits to the base station the wireless transfer block generated by the wireless transfer block generator based on the assignment of the wireless resource included in the transmission instruction notified from the base station;
A mobile station comprising:

Images