JP2014123859A - Communication base station, collection control device and communication method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable delivery of downlink data in broadcast communication to a level not affecting the operation of an end station without producing congestion even in the case of a large number of end stations.SOLUTION: In a radio communication system including a base station and end stations, performing communication by time division multiplexing, and a collection control device connected to the base station, the collection control device includes: a receiver unit for receiving uplink data from an end station received by the base station; based on the received uplink data, a control unit for setting the multiplicity of downlink data from the base station to the end station, according to the ratio of the number of uplink data reception from the end station to the total number of the end stations; and a transmitter unit for transmitting the downlink data having the set multiplicity to the base station.

Description

  The present invention relates to a communication base station, a collection control device, and a communication method in a communication system in which a base station and a terminal station are connected by a wireless network.

  In a communication system having a base station and a terminal station connected to each other in a wireless network, when transmitting the same data from a base station to a number of terminal stations, the downlink data is not transmitted individually from the viewpoint of efficiency. Broadcast communication that transmits simultaneously is used.

  At this time, depending on the location and situation of the terminal station, the terminal station may not normally receive the downlink data from the base station. For example, when a terminal station is located in a building or vehicle where radio waves are shielded, the terminal station may not receive downlink data. Since the terminal station that has not successfully received the downlink data from the base station may be affected by the subsequent terminal station operation due to the loss of the data, it is desirable to reduce the loss of data.

  As a general technique for dealing with data loss, a technique for retransmitting downlink data is known. The terminal station receives downlink data by broadcast communication from the base station. When the terminal station receiving the data detects an error or omission in the received data, the terminal station requests the base station to retransmit the data. The base station that has received the retransmission request transmits the requested data to the terminal station (see, for example, Patent Document 1).

  As a technique related to broadcast communication, a technique for controlling communication with a terminal station using time-division time slots is known. The base station broadcasts to the terminal station time slot information indicating the timing at which each terminal station sends back the collected information together with information collection request information for the terminal station. When the terminal station receives the request information addressed to itself, the terminal station arranges and transmits the collected information in the corresponding time slot based on the time slot information that has arrived (see, for example, Patent Document 2).

JP 2001-28565 A JP 2007-235224 A

  If a technique for requesting retransmission of downlink data is used in order to cope with data loss, communication traffic increases according to the number of terminal stations that request retransmission, which may cause communication failure. Accordingly, in the broadcast communication, when the number of terminal stations increases, the influence of congestion is large, so that it is difficult to incorporate the retransmission request mechanism.

  It is an object of the present invention to make it possible to distribute downlink data to a level that does not affect the operation of the terminal station without causing congestion even when the number of terminal stations increases in broadcast communication. To do.

  In one aspect of the present invention, a collection control device in a wireless communication system including a base station and a terminal station that perform communication by time division multiplexing and a collection control device connected to the base station is received by the base station. Based on the ratio of the number of uplink data received from the terminal station to the total number of terminal stations based on the received uplink data and the receiving unit that receives the uplink data from the terminal station, the base station Has a control unit for setting the multiplicity of downlink data to be transmitted to the terminal station, and a transmission unit for transmitting the downlink data with the set multiplicity to the base station.

  By controlling the multiplexing of the downlink while checking the uplink status from the terminal station, it is possible to avoid an increase in the total traffic volume and to deliver the downlink data to the terminal station while preventing congestion Can do.

It is a figure which shows the structure of the radio | wireless communications system of 1st embodiment. It is a figure which shows the structural example of the base station and terminal station of 1st embodiment. It is a figure which shows the structural example of the collection control apparatus of 1st embodiment. It is a sequence diagram of the data transfer by the base station, the terminal station, and the collection control device of the first embodiment. It is an example of the time chart of the data transfer by the base station of 1st embodiment, and a terminal station. It is a figure which shows an example of the time chart of the downlink data transmission from the base station of 1st embodiment to a terminal station. It is a figure which shows an example of the time chart of reception of the downlink data from the base station of 1st embodiment to a terminal station, and uplink data transmission from a terminal station to a base station. It is a figure which shows an example of the data content of the system control data of 1st embodiment. It is a figure which shows an example of the data content of the control data of 1st embodiment. It is a figure which shows an example of the data content of the position data of 1st embodiment. It is a figure which shows the Example of the time chart of the base station at the time of changing the multiplicity of 1st embodiment. It is a figure which shows an example of the flowchart which shows the data transmission / reception operation | movement of the collection control apparatus of 1st embodiment. It is a figure which shows an example of the flowchart which shows the data transmission / reception operation | movement of the base station of 1st embodiment. It is a figure which shows an example of the flowchart which shows the data transmission / reception operation | movement of the terminal station of 1st embodiment. It is an example of the multiplicity conversion table of 2nd embodiment. It is a figure which shows an example of the flowchart which shows the data transmission / reception operation | movement of the collection control apparatus of 2nd embodiment. It is a figure explaining the timing of the retransmission request of the downlink data (control data) of the base station and terminal station of 2nd embodiment. It is a figure which shows an example of the data content of the resending request data of 2nd embodiment. It is a figure which shows an example of the flowchart which shows the data transmission / reception operation | movement of the base station of 3rd embodiment. It is a figure which shows an example of the flowchart which shows the data transmission / reception operation | movement of the terminal station of 3rd embodiment. It is a figure which shows an example of the flowchart which shows the data transmission / reception operation | movement of the collection control apparatus of 4th embodiment. It is a figure which shows an example of the flowchart which shows the data transmission / reception operation | movement of the collection control apparatus of 5th embodiment.

[First embodiment]
FIG. 1 is a diagram illustrating a configuration of a wireless communication system according to the first embodiment. The wireless communication system of this embodiment includes a base station 1, a terminal station 2, and a collection control device 3. There are a plurality of base stations and terminal stations, and in FIG. 1, they are represented by base stations 1 (1-1 to 1-2) and terminal stations 2 (2-1 to 2-3). In the wireless communication system according to the present embodiment, data is transmitted by the time division multiplexing method. Hereinafter, the wireless communication system according to the embodiment will be described using an example of performing simulated battle training. For example, in a wireless communication system used in simulated battle training, the number of terminal stations that receive communication data broadcast by one base station may be 4000 or more.

  The base station 1 is connected to the collection control device 3 through a wired line, and transmits and receives radio signals to and from the terminal station 2. The terminal station 2 is, for example, a mobile terminal device that can be carried by a user, and transmits and receives radio signals to and from the base station 1. In addition, it has a function of receiving GPS radio waves transmitted from a GPS (Global Positioning System) satellite and calculating the position of its own device. The collection control device 3 is connected to the base station 1 through a wired line, and performs location management, communication control, and the like of the terminal station 2 via the base station 1. The collection control device 3 is integrated with the base station 1 and can be provided inside the base station 1.

  FIG. 2 is a diagram illustrating a configuration example of the base station 1 and the terminal station 2 according to the present embodiment.

  In FIG. 2, the base station 1 includes a transmission / reception unit 11, a control unit 12, an interface unit (IF unit) 13, and a GPS reception unit 14. The transmission / reception unit 11 transmits and receives wireless signals using a wireless antenna. The transmission / reception unit 11 transmits downlink data to the terminal station 2 according to an instruction from the control unit 12 described later. Further, uplink data transmitted from the terminal station 2 is received. In addition, the transmission / reception part 11 can also be provided separately as a transmission part and a reception part, without integrating.

  The received uplink data is output to the control unit 12. The control unit 12 includes a CPU (Central Processing Unit) and a memory, and controls the transmission / reception unit 11, the interface unit (IF unit) 13, the GPS reception unit 14, and the like in the base station 1. The control unit 12 interprets downlink data received from the collection control device 3, generates a time chart from the downlink data, and generates downlink data to be transmitted to the terminal station 2. Then, downlink data is transmitted to the terminal station based on the generated time chart. The memory is a volatile memory or a non-volatile memory, and stores a control program, control parameters, a station number for identifying the base station 1, a number of a time slot assigned to the base station 1, and the like. The interface unit (IF unit) 13 is used to communicate with the collection control device 3, and is connected to the collection control device 3 through a wired line such as an optical fiber. The GPS receiver 14 is a part for obtaining the position of the base station 1 and receives GPS radio waves transmitted from a plurality of GPS satellites to generate coordinate information of the GPS receiver. In addition, the coordinate information calculated by the GPS receiving unit 14 is output to the control unit 12.

  In FIG. 2, the terminal station 2 includes a transmission / reception unit 21, a control unit 22, and a GPS reception unit 23. The transmission / reception unit 21 transmits and receives wireless signals using a wireless antenna. The transmission / reception unit 21 transmits uplink data to the base station 1 according to an instruction from the control unit 22 described later. In addition, downlink data transmitted from the base station 1 is received. The received downlink data is output to the control unit 22. In addition, the transmission / reception part 21 which the terminal station 2 has can also be provided separately in a transmission part and a reception part, without integrating.

  The control unit 22 includes a CPU and a memory, and controls the transmission / reception unit 21, the GPS reception unit 23, and the like in the terminal station 2. In addition, it interprets downlink data and performs communication processing based on the generated time chart. Furthermore, it has a function of controlling data storage, deletion, etc. according to the serial number assigned to the downlink data.

  The GPS receiving unit 23 is a part for obtaining the position of the terminal station 2, and receives GPS radio waves transmitted from a plurality of GPS satellites to generate coordinate information of the GPS receiving unit. Further, the coordinate information generated by the GPS receiving unit 23 is output to the control unit 22. The terminal station 2 is further connected to the power supply unit 27, the firearm interface 26, and the connection box 24. The power supply unit 44 includes, for example, a lithium ion battery and supplies power to the terminal station 2. In the example shown in FIG. 2, the light receiver 25 and the firearm interface 26 are connected to the connection box 24. The light receiver 25 and the firearm interface 26 will be described later.

  FIG. 3 is a diagram illustrating a configuration example of the collection control device 3 according to the present embodiment. In FIG. 3, the collection control device 3 includes a data collection processing unit 31 and a data accumulation processing unit 32. The data collection processing unit 31 is connected to the base station 1 and collects data transmitted from the base station 1 at a predetermined timing. The data collection processing unit 31 includes an interface unit (IF unit) 311, an uplink data reception unit 312, a data check unit 313, and a downlink data transmission unit 314. The interface unit (IF unit) 311 is used to communicate with each base station 1 and is connected to each base station 1 through a wired line such as an optical fiber. The uplink data reception unit 312 receives uplink data transmitted by each base station 1 via the interface unit (IF unit) 311. The data check unit 313 interprets the uplink data and determines whether the uplink data received from each base station 1 is duplicated. In the case of duplication, it has a function of deleting duplicate data. The downlink data transmission unit 314 transmits data output from the data storage processing unit 32 described later as downlink data to the base station 1 via the interface unit (IF unit) 311. The network control unit 315 is connected to the data accumulation processing unit 32 via the network control unit 328.

  The data accumulation processing unit 32 accumulates the data collected by the data collection processing unit 31 as a database, extracts necessary data from the accumulated data, and changes the multiplicity of downlink data based on the extracted data To do. The data accumulation processing unit 32 includes a data accumulation unit 325, a reception ratio calculation unit 326, a multiplexing control unit 327, a network control unit 328, and a downlink data generation unit 329. The data storage unit 325 stores uplink data transmitted from the base station 1. The reception ratio calculation unit 326 has a function of calculating the reception ratio from the number of received data predicted from the number of terminal stations and the number of uplink data actually received. The multiplexing control unit 327 has a function of controlling the multiplicity of downlink data transmission according to the reception ratio. The downlink data generation unit 329 refers to the contents of the setting data input from the operation terminal 4. Then, downlink data is generated based on the contents of the setting data. The network control unit 328 is connected to the data collection processing unit 31 via the network control unit 315. The network control unit 328 is connected to the operation terminal 4. The operation terminal 4 may be included in the collection control device 3.

  FIG. 4 is an example of a sequence diagram of data transfer by the base station 1, the terminal station 2, and the collection control device 3 in the configuration of the wireless communication system of the embodiment of FIG. The terminal station 2-1 is located in the wireless area of the base station 1-1, and the terminal station 2-2 and the terminal station 2-3 are located in the wireless area of the base station 1-2. It shall be. In the wireless communication system shown in FIG. 4, the terminal station 2-1 transmits uplink data (U1) to the base station 1-1, and the terminal stations 2-2 and 2-3 transmit uplink data (U2, U3). ) To the base station 1-2. Then, the base station 1-1 and the base station 1-2 collect information transmitted from each terminal station and transfer the collected information to the collection control device 3. The collection control device 3 accumulates and analyzes data. Then, the multiplicity of downlink data transmitted from the base station to the terminal station is set or changed according to the ratio of the number of uplink data received from the terminal station to the total number of terminal stations. Based on the multiplicity set by the collection control device 3, the base station 1-1 transmits downlink data (D1) to the terminal station 2-1, and the base station 1-2 transmits downlink data (D2). Is transmitted to the terminal station 2-2 and the terminal station 2-3. Then, the terminal station 2-1, the terminal station 2-2, and the terminal station 2-3 receive the downlink data, and operate based on the content of the received data. When each terminal station receives the same data, the duplicate data is deleted.

  FIG. 5 is an example of a time chart for explaining data transfer by the base station 1 and the terminal station 2.

  Here, the processing sequence of each of base station 1 and terminal station 2 for a configuration including a plurality of base stations and a plurality of terminal stations is shown.

  In the radio communication system of the first embodiment, the base station 1 transmits downlink data to the terminal station 2 using a predetermined time slot. Downlink data transmitted from the base station 1 is, for example, system control data a, position correction data b, control data c, transmission permission data d, and reception confirmation data e.

  The system control data a includes an instruction for the terminal station 2 and is transmitted periodically. The system control data a will be described in detail later. The position correction data b includes an instruction for correcting the position information of the terminal station 2 based on GPS radio waves received by the GPS reference station installed in the base station 1. With this position correction data b, for example, differential GPS with the base station 1 as a reference position is realized. Note that the GPS reference station is not necessarily installed in the base station 1 and may be installed in the collection control device 3. The control data c will be described later in detail. The transmission permission data d includes information for notifying the available time slot (terminal station slot) to the terminal station 2 that has transmitted transmission reservation data f to be described later. The reception confirmation data e includes information that notifies the terminal station 2 that has transmitted training data h described later that the data has been received.

  The terminal station 2 transmits uplink data (transmission reservation data f, position data g, training data h) to the base station 1. The transmission reservation data f includes a request for reserving a time slot for transmitting the training data h. The transmission reservation data f is transmitted using a short time slot assigned in advance to each terminal station. The position data g includes the position information of the terminal station 2 obtained from the GPS receiving unit 23. The position data g is periodically transmitted using a time slot (terminal station slot) previously assigned to each terminal station. The position data g will be described later in detail. The training data h includes information generated in response to a request from the base station 1 and information that the terminal station 2 voluntarily notifies the base station 1 when an event such as exhaustion occurs. When transmitting the training data h, the terminal station 2 requests the terminal station slot from the base station 1 using the transmission reservation data f. Then, the terminal station 2 transmits the training data h using the terminal station slot notified by the transmission permission data d.

  FIG. 6 is an example of a time chart illustrating transmission of downlink data from a plurality of base stations to a plurality of terminal stations. In FIG. 6, predetermined time slots (base station slots) are allocated to the base stations 1-1, 1-2, and 1-3. Then, the base stations 1-1, 1-2, and 1-3 transmit downlink data by shifting the timeline for each assigned base station slot. Accordingly, the base station 1-1 transmits downlink data to the terminal station using its own base station slot. The base station 1-2 then transmits downlink data to the terminal station using its own base station slot different from the base station 1-1. Further, the base station 1-3 transmits downlink data to the terminal station using its own base station slot different from the base station 1-1 and the base station 1-2.

  FIG. 7 is a time chart of downlink data reception from the base station to the terminal station and transmission of uplink data from the terminal station to the base station at a plurality of terminal stations (terminal station 2-1 and terminal station 2-2). It is an example. In FIG. 7, the downlink data received by the terminal station 2 includes system control data a, position correction data b, control data c, transmission permission data d, and reception confirmation data e. The uplink data transmitted by the terminal station 2 includes transmission reservation data f, position data g, and training data h.

  When the system control data a is received by the terminal station 2-1 and the terminal station 2-2, the transmission reservation data f is sent to the base station 1 using a time slot allocated in advance to each terminal station. Sent. The transmission reservation data f includes information generated in response to a request from the base station 1 and information that the terminal station 2 spontaneously notifies the base station 1 when an event such as exhaustion occurs. Sent only when

  When the position correction data b, the control data c, and the reception confirmation data e are received by the terminal station 2-1 and the terminal station 2-2, the position data g of each terminal station corrected based on the position correction data b is obtained. The terminal station 2-1 and the terminal station 2-2 are transmitted to the base station 1 using time slots assigned in advance. When the transmission permission data d is received by the terminal station 2-1 and the terminal station 2-2, each terminal station uses the time slot indicated by the transmission permission data d to each terminal station. Training data h is transmitted to the base station 1.

  FIG. 8 is a diagram illustrating an example of the data content 50 of the system control data a. In FIG. 8, a code for identifying the type of the system control data a is written as the data type ID 51. The base station slot number 52 is information indicating a time slot assigned to each base station. The operation mode instruction 53 instructs the operation mode of the terminal station 2. The time information 54 represents the current date and time.

  FIG. 9 is a diagram illustrating an example of the data content 60 of the control data c. In FIG. 9, a code for identifying the type of the control data c is written as the data type ID 61. The serial number 62 is a serial number assigned to the control data. The control data classification 63 includes various instructions to be notified to the terminal station 2 such as a suppression instruction, an impact instruction, a wear instruction, and the like, and instructs to limit an operation in the simulated battle training. The suppression instruction indicates a situation where a shell is falling close to you and cannot be attacked with a machine gun or a rifle. . Also, the impact instruction is information for instructing the impact of a shell such as a howitzer or a mortar, and near the impact point, it causes wear as described below and causes suppression as described above. For example, in the case of personnel, the wear instruction indicates a state such as death or serious injury. In the case of a vehicle, a destruction state such as a major breakage or a medium breakage is indicated. The date / time information 64 represents the current date and time. The valid period information 65 indicates the valid period of the control data.

  FIG. 10 is a diagram illustrating an example of the data content 70 of the position data g. In FIG. 10, the terminal ID 71 is an individual identifier given to each terminal. The N coordinate 72 indicates the coordinate in the north-south direction. The E coordinate 73 indicates the coordinate in the east-west direction. The H coordinate 74 indicates an altitude coordinate. The terminal station status 75 represents the state of the terminal station, the reliability of position information, and the like. Since the coordinates of N, E, and H indicate a three-dimensional position, other coordinate systems can be used.

  FIG. 11 is an example of a time chart of the base station when the multiplicity is changed. The collection control device 3 changes the multiplicity of downlink data from the base station 1 to the terminal station 2 according to the ratio of the number of uplink data received from the terminal station to the total number of terminal stations. That is, the rate of downlinking the same data in a plurality of slots is changed.

  When the multiplicity is low, many different data can be downlinked. As the control data c, the control data of data 1 and 2 is transmitted in the first cycle, the control data of data 3 and 4 is transmitted in the second cycle, and the control data of data 5 and 6 is transmitted in the third cycle. Has been sent.

  When the multiplicity is increased, a lot of the same data is downlinked. As control data c, control data of data 1 and 2 is transmitted in the first cycle, control data of data 1 and 3 is transmitted in the second cycle, and control data of data 2 and 4 is transmitted in the third cycle. By transmitting, the same control data is transmitted a plurality of times. The transmission method in which the multiplicity of control data is increased is not limited to this example. The control data of data 1 and 2 is transmitted in the first cycle, and the data 1 and 2 are transmitted in the second cycle. Various multiplexing methods such as transmitting control data and transmitting control data of data 3 and 4 in the third cycle are possible.

  FIG. 12 is an example of a flowchart for explaining the data transmission / reception operation of the collection control device 3. In this flowchart, operations not directly related to data transmission / reception are omitted.

  In step S1, a reception operation is started.

  In step S <b> 2, the downlink data generation unit 329 receives setting data corresponding to a user instruction from the operation terminal 4 via the network control unit 328.

  In step S3, the data collection processing unit 31 generates a predetermined sequence time chart. Then, the data processing unit 31 outputs a downlink data generation request to the data storage unit 32 according to the time chart.

  In step S4, the downlink data generation unit 329 creates downlink data based on the received setting data.

  In step S <b> 5, the downlink transmission unit 314 transmits the downlink data created by the downlink data generation unit 329 to the base station 1 via the interface unit (IF unit) 311.

  In step S <b> 6, the uplink data receiving unit receives uplink data from the base station 1 via the interface unit (IF unit) 311.

  In step S7, the data check unit 313 extracts the position data g of the terminal station 2 from the uplink data. At this time, the terminal data ID 71 of the received data is referred to, and the position data g for each terminal station is determined. If there are a plurality of identical terminal IDs in the received data, only one of the data is left and the others are deleted. The extracted position data g is stored in the data storage unit 325 in association with the terminal ID.

  In step S8, the reception ratio calculation unit 326 receives the data according to the ratio of the number of receptions of the position data g from the terminal stations with respect to the total number of terminal stations (however, for the same terminal station ID, the number of receptions from which duplicates are deleted). Calculate the percentage.

  In step S9, the multiplexing control unit 327 compares the first threshold with the reception ratio. When the reception ratio is less than the first threshold, the process proceeds to step S10 (step S9-yes). On the other hand, if the reception ratio is not less than the first threshold, the process proceeds to step S11 (step S9-no).

  In step S10, the multiplexing control unit 327 increases the multiplicity of transmission data. Then, the process proceeds to step S13.

  In step S11, the multiplexing control unit 327 compares the second threshold with the reception ratio. If the reception ratio is greater than or equal to the second threshold, the process proceeds to step S12 (step S11-yes). On the other hand, if the reception ratio is not equal to or greater than the second threshold, the process proceeds to step S13 (step S11-no). Note that the second threshold value is larger than the first threshold value.

  In step S12, the multiplexing control unit 327 reduces the multiplicity of the transmission data. Then, the process proceeds to step S13.

  In step S13, the downlink data generation unit 329 generates downlink data to be transmitted to the base station with the multiplicity indicated by the multiplexing control unit 327. After the process of step S13 is completed, the process returns to step S5.

  FIG. 13 is an example of a flowchart showing the data transmission / reception operation of the base station 1. In this flowchart, operations not directly related to data transmission / reception are omitted.

  In step S101, a reception operation is started.

  In step S <b> 102, the control unit 12 receives the system control data a output from the collection control device 3 via the interface unit (IF unit) 13. At this time, the data type ID 51 of the received data is referred to, and the type of the system control data a is determined.

  In step S103, the control unit 12 refers to the base station slot number 52 set in the system control data a. Then, the base station time chart is generated based on the referenced slot number.

  In step S104, the transmission / reception unit 11 transmits the system control data a to the terminal station in response to an instruction from the control unit 12.

  In step S <b> 105, the transmission / reception unit 11 receives the transmission reservation data f from the terminal station 2. Then, the transmission reservation data f is output to the control unit 12.

  In step S <b> 106, the control unit 12 determines whether the transmission reservation data f from the transmission / reception unit 11 has been received. At this time, when the transmission reservation data f is received, the process proceeds to step S107 (step S106-yes). On the other hand, when the transmission reservation data f is not received, the process proceeds to step S108 (step S106-no).

  In step S <b> 107, the control unit 12 transmits the transmission reservation data f to the collection control device 3 via the interface unit (IF unit) 13.

  In step S <b> 108, the control unit 12 receives control data c from the collection control device 3 via the interface unit (IF unit) 13. Then, the transmission / reception unit 11 is instructed to transmit the data.

  In step S109, the transmission / reception unit 11 transmits control data c to the terminal station in response to an instruction from the control unit 12.

  In step S <b> 110, the control unit 12 receives transmission permission data d from the collection control device 3 via the interface unit (IF unit) 13. Then, the transmission / reception unit 11 is instructed to transmit the data.

  In step S111, the transmission / reception unit 11 transmits the transmission permission data d to the terminal station in response to an instruction from the control unit 12.

  In step S <b> 112, the transmission / reception unit 11 receives the training data h from the terminal station 2. Then, the training data h is output to the control unit 12.

  In step S113, the control unit 12 transmits the training data h to the collection control device 3 via the interface unit (IF unit).

  In step S114, the transmission / reception unit 11 transmits the control data c to the terminal station.

  In step S115, the transmission / reception unit 11 receives the terminal location data g. Then, the position data g is output to the control unit 12.

  In step S <b> 116, the control unit 12 transmits the position data g to the collection control device 3 via the interface unit (IF unit) 13.

  In step S <b> 117, the control unit 12 receives the reception confirmation data e from the collection control device 3 via the interface unit (IF unit) 13. Then, the transmission / reception unit 11 is instructed to transmit the data. In step S <b> 118, the transmission unit 11 transmits reception confirmation data e to the terminal station in accordance with an instruction from the control unit 12. After the process of step S118 is completed, the process returns to step S102.

  Note that steps S115 to S116 are performed a plurality of times corresponding to the number of terminal stations.

  FIG. 14 is an example of a flowchart showing the data transmission / reception operation of the terminal station 2. In this flowchart, operations not directly related to data transmission / reception are omitted.

  In step S201, a reception operation is started. That is, the receiving unit 21 and the control unit 22 start receiving radio signals.

  In step S202, the control unit 22 checks whether or not the received data is system control data a. Then, the data type ID 51 of the received data is referred to determine the system control data a. At this time, if the received data is the system control data a, the process proceeds to step S203 (step S202-yes). On the other hand, if the received data is not the system control data a, the process returns to step S202 (step S202-no).

  In step S203, the control unit 22 starts processing based on the terminal station time chart. At this time, the control unit 22 refers to the operation mode instruction 53 included in the received system control data a, and determines the type of the system control data a.

  In step S <b> 204, the control unit 22 receives output of terminal information representing the wearer's wear state and the like from the light receiver 25 and the firearm interface 26. At this time, if there is a change in terminal information indicating the wearer's wear state or the like, the process proceeds to step S205 (step S204-yes). On the other hand, if there is no change in the terminal information indicating the wearer's wear state or the like, the process proceeds to step S206 (step S204-no).

  In step S205, the control unit 22 instructs the transmission / reception unit 21 to transmit the transmission reservation data f to the base station. Then, the transmission / reception unit 21 transmits the transmission reservation data f to the base station.

  In step S206, the transmission / reception unit 21 and the control unit 22 receive the control data c. At this time, the data type ID 61 of the received data is referred to, and the type of the control data c is determined.

  In step S207, the control unit 22 refers to the serial number 62 of the received data.

  In step S208, the control unit 22 determines whether or not there is a missing in the serial number 62 of the received data. If there is a missing part, the process proceeds to step S209 (step S208-yes), and the control unit 22 stores the missing serial number 62 and proceeds to step S210.

  If it is determined in step S208 that there is no omission in the serial number 62 of the received data (step S208-no), the process proceeds to step S210.

  In step S210, it is determined whether there is an overlap in the serial number 62 of the received data. When there is duplication, the process proceeds to step S211 (step S210-yes), and the control unit 22 deletes the duplicated control data c and proceeds to step S212. If it is determined in step S210 that there is no overlap, the process proceeds to step S212 (step S210-no).

  In step S212, various terminal processes related to the base station transmission mode are performed. After the process of step S212 is completed, the process returns to step S201.

  Note that steps S206 to S211 are performed a plurality of times for the number of control data.

  Next, an example of performing simulated battle training will be described as a system implemented using the wireless communication system of the first embodiment.

  The wireless communication system according to the embodiment is not particularly limited. For example, the base station 1 collects and collects information (position data g and training data h in FIG. 5) transmitted from each terminal station. Transfer to the control unit. The collection control device 3 executes processing for accumulating and analyzing data transferred from the base station 1.

  In the simulated battle training, each combatant carries the terminal station 2. Each terminal station 2 is connected with a light receiver 42 and a firearm interface 26 as shown in FIG. The light receiver 25 is provided at a predetermined location (for example, head, back, arms, legs, etc.) by a jacket or a belt worn by a combatant. The light receiver 42 detects a laser beam output from a laser gun as a pseudo firearm. When the light receiver detects the laser beam, the control unit determines that the combatant is “shot”. The firearm interface 26 is connected to a laser gun. And if a combatant uses a laser gun, a control part will judge that the combatant used the firearm.

  The terminal station 2 notifies the base station 1 of the position of the combatant, the worn state of the combatant, and the like. For example, the position of the combatant is notified to the base station 1 using the position data g shown in FIG. 5 based on the coordinate information from the GPS receiver 23. Further, information indicating the wearer's wear state is created based on input signals from the light receiver 25 and the firearm interface 26, and is notified to the base station 1 using the training data h shown in FIG.

  The base station 1 collects information transmitted from each terminal station 2 and transmits it to the collection control device 3. The collection control device 3 organizes and accumulates the collected information. Then, the collection control device 3 outputs a strategy, a deployment, and a battle situation based on the accumulated information. Combatants can improve their skill in combat training based on the output results. The number of base stations included in the wireless communication system is determined according to the size of the training area, the state of radio wave notification, and the like so that the radio waves reach the entire training area. The number of fighters participating in the training is, for example, tens to thousands.

  In the training, a battle vehicle and a building for indoor battle training are used. Some of these battle vehicles and buildings do not receive radio waves from the base station 1 or GPS satellites. That is, these fighting vehicles and buildings correspond to a radio wave shielding area. A relay station is installed in each battle vehicle and building. Moreover, you may install the terminal station 2 in each battle vehicle and a building. In this case, the terminal station 2 notifies the base station 1 of the position of the battle vehicle, the status of the battle vehicle, and the building (normal, minor damage, major damage, etc.). Thereby, the situation of the simulated battle can be confirmed more accurately.

  This training system is composed of several tens to several thousand terminal stations for several base stations 1. That is, a one-to-many wireless data communication system is constructed. In addition, real-time performance is required for the entire system. Therefore, the downlink data from each base station 1 to the terminal station 2 is basically broadcast to all the terminal stations in the radio area. At this time, an instruction of an operation mode, an instruction of a transmission cycle of position data g, etc. are notified by downlink data (for example, system control data a or control data c shown in FIG. 5) from the base station to each terminal station. The Further, the downlink data can also transmit information such as the position where the simulated shell is dropped and the burst height.

  The terminal station 2 may determine the damage status of the combatant carrying the terminal station based on the position of the station, the defense status (such as the inside of the armored vehicle), and the like. Laser beams are used in a simulated battle between a vehicle and a combatant, or a simulated battle between combatants. At this time, for example, when a laser beam is incident on the light receiver 42 connected to the terminal station 2 and the wearer's wear state changes, the change in state is automatically transmitted to the base station 1 as uplink data. And the collection control apparatus 3 grasps | ascertains the position and state of each combatant based on the uplink data from each terminal station, and recognizes a training condition correctly.

  In this way, by controlling the multiplexing of the downlink while confirming the uplink status from the terminal station, it is possible to avoid an increase in the total amount of communication, and to deliver the downlink data while preventing congestion be able to. In addition, the terminal station can reduce the drop-out of the received downlink data, and can operate according to the operation instruction from the base station.

Here, when the terminal station 2 is located indoors, in an underground mall or the like, it cannot receive radio waves from the base station 1. Thus, the wireless communication system according to the embodiment can include a relay station in order to avoid such a situation. The relay station is provided at a position where wireless communication with the base station 1 is possible and wireless communication with the terminal station 2 is possible. That is, the relay station transmits / receives a radio signal to / from the base station 1 via the external antenna and transmits / receives a radio signal to / from the terminal station 2 via the internal antenna.
[Second Embodiment]
Next, a second embodiment will be described with reference to FIGS. 15 and 16. In the first embodiment described above, a predetermined threshold is compared with the ratio of the number of uplink data received from the terminal station to the total number of terminal stations, and the degree of multiplexing of the downlink data from the base station 1 to the terminal station 2 is determined. Changed. In the second embodiment, the collection control device 3 includes a multiplicity conversion table, and the multiplexing control unit 327 can change the multiplicity using the table.

  FIG. 15 shows an example of the multiplicity conversion table 80. The multiplicity conversion table stores a normal position data reception ratio and a plurality of setting values (setting 1, setting 2, setting 3, and setting 4) in association with each other. The setting value defines a multiplexing state, and indicates a ratio including the same data per base station slot that transmits downlink data. Then, the multiplexing control unit 327 refers to the multiplicity conversion table 80 and changes the multiplicity. For example, when setting 1 is selected from the set values, if the ratio of the number of uplink data received from the terminal station to the total number of terminal stations is 95%, the multiplexing control unit 327 is Refer to the multiplexing state 1.5 of the severe conversion table 80. Then, the multiplexing control unit 327 changes the multiplicity according to the referenced multiplexing state. In this case, the same data is transmitted twice in the three base station slots that transmit the downlink data. In the present embodiment, the multiplicity conversion table has four setting values, but the number of setting values to be held is not limited thereto. Further, the values registered in the table are not limited to the values in this embodiment.

図１６は、第二の実施の形態における、収集制御装置３のデータ送受信動作を示すフローチャートの一例である。なお、このフローチャートでは、データの送受信に直接係わらない動作については省略されている。 Note that a conversion formula may be used instead of the conversion table. An example of the conversion formula is shown in the following formula (1). Note that N is a multiplicity parameter, and the parameter can be arbitrarily changed with a plurality of set values. In this case, the multiplexing control unit 327 calculates the multiplicity from the ratio of the number of uplink data received from the terminal stations (normal reception ratio) with respect to the total number of terminal stations, and downloads based on the calculated multiplicity. Controls link multiplexing.

FIG. 16 is an example of a flowchart illustrating a data transmission / reception operation of the collection control device 3 in the second embodiment. In this flowchart, operations not directly related to data transmission / reception are omitted.

  In step S301, a reception operation is started.

  In step S <b> 302, the downlink data generation unit 329 receives setting data corresponding to a user instruction from the operation terminal 4 via the network control unit 328.

  In step S303, the data collection processing unit 31 generates a sequence time chart.

  In step S304, the downlink data generation unit 329 creates downlink data based on the received setting data.

  In step S305, the downlink transmission unit 314 transmits the created downlink data to the base station 1 via the interface unit (IF unit) 311.

  In step S306, the uplink data receiving unit receives uplink data from the base station 1 via the interface unit (IF unit) 311.

  In step S307, the data check unit 313 extracts the position data g of the terminal station 2 from the uplink data. At this time, the terminal data ID 71 of the received data is referred to, and the position data g for each terminal station is determined. When there are a plurality of identical terminal IDs, only one of the data is left and the others are deleted. The extracted position data g is stored in the data storage unit 325 in association with the terminal ID.

  In step S308, the reception ratio calculation unit 326 receives the data according to the ratio of the number of received position data g from the terminal stations to the total number of terminal stations (however, the reception number from which duplicates are deleted for the same terminal ID). Calculate the percentage.

  In step S309, the multiplexing control unit 327 refers to the multiplicity conversion table 80.

  In step S <b> 310, the multiplexing control unit 327 controls the state of multiplicity according to the ratio of the number of received position data from the terminal station to the total number of terminal stations based on the referenced multiplicity conversion table 80.

  In step S311, the downlink data generation unit 329 generates downlink data to be transmitted to the base station with the multiplicity indicated by the multiplexing control unit 327. After completion of the process in step S311, the process returns to step S305.

  As described above, the collection control apparatus 3 includes the multiplicity conversion table, and by switching the multiplicity using this table, the multiplicity value can be changed in consideration of the communication of the network to be used. it can. As a result, it is possible to perform detailed multiplicity conversion in consideration of communication reachability. The terminal station can reduce the loss of the received downlink data and can operate according to the operation instruction from the base station.

[Third embodiment]
Next, a third embodiment will be described with reference to FIGS. In the third embodiment, the base station stores downlink data inside the base station. When the terminal station detects a loss of downlink data, it is possible to request retransmission of the lost data to the base station using a slot that normally transmits the state of the terminal station. . Then, the base station that has received the retransmission request reads the data that has received the retransmission request from the accumulated downlink data, and transmits the downlink data to the terminal station in consideration of the retransmission request.

  FIG. 17 is a diagram for explaining the timing of requesting retransmission of downlink data (control data) of the base station 1 and the terminal station 2. When the terminal station 2 detects a loss of downlink data (control data), the terminal station 2 transmits the terminal station slot (specifically, in the first embodiment, the terminal station 2 transmits the training data h). Slot) is used to transmit uplink data (retransmission request data) for requesting retransmission of data for the missing serial number.

  The base station 1 receives the uplink data from the terminal station 2, and extracts the downlink data for the serial number for which the retransmission request has been received from the downlink data stored in the base station. Then, the base station transmits downlink data for the serial number in the base station slot in which the downlink data frame is free. The terminal station 2 receives the downlink data from the base station 1 and confirms whether it is the downlink data for the missing serial number. If it is missing downlink data, this is applied.

  FIG. 18 is a diagram illustrating an example of the data content 90 of the retransmission request data. In FIG. 18, the terminal ID 91 is an individual identifier given to each terminal. Occurrence time 92 is the time at which the terminal station detected data loss. The retransmission data start number 93 is the first number of the serial number 62 of the control data c for which retransmission is requested. The retransmission data end number 94 is the last number of the serial number 62 of the control data c requesting retransmission data. The terminal station status 95 represents the state of the terminal station, the reliability of position information, and the like. As the reason for having the retransmission data start number 93 and the retransmission data end number 94 in the data content 90 of the retransmission request data, the serial number 62 of the control data c has a certain range such as 1-10, for example. Because it is. When the serial number 62 of the control data c notifies only a specific number, that number may be notified.

  FIG. 19 is an example of a flowchart showing the data transmission / reception operation of the base station 1 in the third embodiment. In this flowchart, operations not directly related to data transmission / reception are omitted.

  In step S401, a reception operation is started.

  In step S <b> 402, the control unit 12 receives the system control data a output from the collection control device 3 via the interface unit (IF unit) 13. At this time, the data type ID 51 of the received data is referred to, and the type of the system control data a is determined.

  In step S403, the control unit 12 refers to the base station slot number 52 set in the system control data a. Then, system control data is received based on the referenced slot number, and a terminal time chart is generated.

  In step S404, the transmission / reception unit 11 transmits the system control data a to the terminal station in response to an instruction from the control unit 12.

  In step S <b> 405, the transmission / reception unit 11 receives the transmission reservation data f from the terminal station 2. Then, the transmission reservation data f is output to the control unit 12.

  In step S <b> 406, the control unit 12 determines whether the transmission reservation data f from the transmission / reception unit 11 has been received. At this time, when the transmission reservation data f is received, the process proceeds to step S407 (step S406-yes). On the other hand, when the transmission reservation data f is not received, the process proceeds to step S108 (step S406-no).

  In step S <b> 407, the control unit 12 transmits the transmission reservation data f to the collection control device 3 via the interface unit (IF unit) 13.

  In step S <b> 408, the control unit 12 receives control data c from the collection control device 3 via the interface unit (IF unit) 13. Then, the transmission / reception unit 11 is instructed to transmit the data.

  In step S409, the transmission / reception unit 11 transmits control data c to the terminal station in response to an instruction from the control unit 12.

  In step S <b> 410, the control unit 12 receives transmission permission data d from the collection control device 3 via the interface unit (IF unit) 13. Then, the transmission / reception unit 11 is instructed to transmit the data.

  In step S411, the transmission / reception unit 11 transmits the transmission permission data d to the terminal station in response to an instruction from the control unit 12.

  In step S412, the transmission / reception unit 12 receives the training data h or the retransmission request data from the terminal station 2. Then, the received data is output to the control unit 11.

  In step S 413, the control unit 12 receives a retransmission request from the transmission / reception unit 11. At this time, if a retransmission request is received, the process proceeds to step S414 (step S413-yes). On the other hand, when no retransmission request has been received, the process proceeds to step S415 (step S413-no).

  In step S414, the control unit 12 stores the serial number of the control data c requested to be retransmitted. At this time, the retransmission data start number 93 and the retransmission data end number 94 are referred to. Then, the process proceeds to step S416.

  In step S 415, the control unit 12 transmits the training data h to the collection control device 3 via the interface unit (IF unit) 13.

  In step S416, when the control unit 12 detects an empty space in the base station slot, the control unit 12 proceeds to step S417 (step S416-yes). On the other hand, when the sky cannot be detected in the base station slot, the process proceeds to step S418 (step S416-no).

  In step S417, the control unit 12 reads out the control data c of the serial number that received the retransmission request from the downlink data stored in the base station, and adds it as retransmission data.

  In step S418, the transmission / reception unit 11 transmits the control data c to the terminal station.

  In step S419, the transmission / reception unit 11 receives the terminal location data g. Then, the position data g is output to the control unit 12.

  In step S <b> 420, the control unit 12 transmits the position data g to the collection control device 3 through the interface unit (IF unit) 13.

  In step S <b> 421, the control unit 12 receives the reception confirmation data e from the collection control device 3 via the interface unit (IF unit) 13. Then, the transmission / reception unit 11 is instructed to transmit the data.

  In step S422, the transmission unit 11 transmits reception confirmation data e to the terminal station in response to an instruction from the control unit 12. After the process of step S422 is completed, the process returns to step S402.

  Steps S419 to S420 are performed a plurality of times corresponding to the number of terminal stations.

  FIG. 20 is an example of a flowchart showing the data transmission / reception operation of the terminal station 2 in the third embodiment. In this flowchart, operations not directly related to data transmission / reception are omitted.

  In step S501, a reception operation is started. That is, the receiving unit 21 and the control unit 22 start receiving radio signals.

  In step S502, the control unit 22 checks whether or not the received data is system control data a. Then, the data type ID 51 of the received data is referred to determine the system control data a. At this time, if the received data is system control data a, the process proceeds to step S503 (step S502-yes). On the other hand, if the received data is not the system control data a, the process returns to step S502 (step S502-no).

  In step S503, the control unit 22 starts processing based on the terminal station time chart. At this time, the control unit 22 refers to the operation mode instruction 53 included in the received system control data a, and determines the type of the system control data a.

  In step S <b> 504, the control unit 22 receives terminal station information output indicating the wearer's wear state and the like from the light receiver 25 and the firearm interface 26. At this time, if there is a change in terminal information indicating the wearer's wear state or the like, the process proceeds to step S505 (step S504-yes). On the other hand, if there is no change in the terminal information indicating the wearer's wear state or the like, the process proceeds to step S506 (step S504-no).

  In step S505, the control unit 22 instructs the transmission / reception unit 21 to transmit the transmission reservation data f to the base station. Then, the transmission / reception unit 21 transmits the transmission reservation data f to the base station.

  In step S506, the transmission / reception unit 21 and the control unit 22 receive the control data c. At this time, the data type ID 61 of the received data is referred to, and the type of the control data c is determined.

  In step S507, the control unit 22 confirms the serial number 62 of the received data.

  In step S508, the control unit 22 determines whether there is any omission in the serial number 62 of the received data. If there is a missing part, the process proceeds to step S509 (step S508-yes), and the control unit 22 stores the missing serial number 62 and proceeds to step S510.

  If it is determined in step S508 that there is no omission in the serial number 62 of the received data (step S508-no), the process proceeds to step S510.

  In step S510, it is determined whether there is an overlap in the serial number 62 of the received data. When there is duplication, the process proceeds to step S511 (step S510-yes), and the control unit 22 deletes the duplicated control data c and proceeds to step S512. If it is determined in step S510 that there is no overlap, the process proceeds to step S512 (step S510-no).

  In step S512, various terminal processes related to the base station transmission mode are performed.

  In step S513, the control unit 21 that has received the control data c refers to the serial number 62 of the received data. When the serial number 62 is missing, the control unit 22 instructs the transmission / reception unit 21 to transmit retransmission request data to the base station. The transmission / reception unit 21 transmits retransmission request data to the base station 1 in response to an instruction from the control unit 22. After the process of step S513 is completed, the process returns to step S501.

  Note that steps S506 to S511 are performed a plurality of times corresponding to the number of terminal stations.

  As described above, when the notification status of a specific terminal station is poor, the efficiency is improved as a whole by adding retransmission processing, rather than increasing the multiplicity and lowering the performance of the entire communication system. Thereby, the terminal station can reduce the drop-out of the received downlink data, and can operate according to the operation instruction from the base station.

  In the present embodiment, downlink data is accumulated at the base station, and multiplexing processing is performed. For this reason, retransmission processing can be realized without using the collection control device. The system configuration can be simplified, and the price of the system can be reduced. Moreover, it can comprise compactly as a whole. Furthermore, there is an advantage that the amount of downlink data between the collection control device and the base station can be reduced. Further, in this embodiment, when the terminal stations communicating with each base station are different, it is possible to transmit different downlink data at each base station. The reception of the retransmission processing request from the terminal station may be different at each base station. In this case, each base station transmits different retransmission data according to the request of each terminal station. By processing in this way, a lot of downlink data can be communicated as a whole radio system using a plurality of base stations. More data can be transmitted in the same time, and the efficiency of the system can be improved.

[Fourth embodiment]
Next, a fourth embodiment will be described with reference to FIG. In the third embodiment described above, when the terminal station detects a loss of downlink data, it is possible to request the base station to retransmit the lost data. The base station that has received the retransmission request from the station transfers data regarding the retransmission request to the collection control apparatus. Note that the data storage unit 325 stores retransmission request data transmitted from the base station 1. The reception ratio calculation unit 326 has a function of interpreting data contents and rearranging the data according to the data contents. The multiplexing control unit 327 issues an instruction to reproduce the control data based on the data rearranged by the reception ratio calculation unit 326. The downlink data generation unit 329 has a function of regenerating control data in response to an instruction from the multiplexing control unit 327.

  FIG. 21 is an example of a flowchart illustrating a data transmission / reception operation of the collection control device 3 according to the fourth embodiment. In this flowchart, operations not directly related to data transmission / reception are omitted.

  In step S601, a reception operation is started.

  In step S <b> 602, the downlink data generation unit 329 receives setting data corresponding to a user instruction from the operation terminal 4 via the network control unit 328.

  In step S603, the data collection processing unit 31 generates a sequence time chart. Then, the data processing unit 31 outputs a downlink data generation request to the data storage unit 32 according to the time chart.

  In step S604, the downlink data generation unit 329 creates downlink data based on the received setting data.

  In step S605, the downlink transmission unit 314 transmits the created downlink data to the base station 1 via the interface unit (IF unit) 311.

  In step S606, the uplink data receiving unit 312 receives the retransmission request data transmitted from the base station 1 via the interface unit (IF unit) 311.

  In step S607, the data check unit 313 checks for duplication of retransmission request data. At this time, the retransmission data start number 93 and the retransmission data end number 94 are referred to.

  In step S608, the data storage unit 325 accumulates the retransmission request data that was in the retransmission request.

  In step S609, the data accumulation processing unit 32 interprets the setting data. The setting data includes information on how to rearrange the data. Then, the data accumulation processing unit 32 instructs the reception ratio calculation unit 326 to read data from the data accumulation unit 325 based on the interpreted setting data and rearrange the data. When the data is rearranged in the order of the most frequently requested data from the terminal station 2, the process proceeds to step S612 (step S609-yes). On the other hand, if the data cannot be rearranged in the order of the data having the most retransmission requests, the process proceeds to step S610, where the data is rearranged from the data with the oldest time when each terminal station detected the missing data (step S609-no).

  In step S610, the reception ratio calculation unit 326 rearranges the data requested for retransmission from the terminal station 2 from the data with the oldest time at which each terminal station detected the missing data. At this time, the generation time 92 of the retransmission request data is referred to, and data that is older in time is determined.

  In step S611, the downlink data generation unit 329 regenerates the control data c according to an instruction from the multiplexing control unit 327. At this time, the control data c for the serial number for which the retransmission request is received from the downlink data stored in the collection control apparatus is read and added as retransmission data. Then, the process proceeds to step S614.

  In step S <b> 612, the reception ratio calculation unit 326 rearranges the data in the order of the data with the most retransmission requests from the terminal station 2. At this time, the retransmission data start number 93 and the retransmission data end number 94 are referred to.

  In step S613, the downlink data generation unit 329 regenerates the control data c according to an instruction from the multiplexing control unit 327. At this time, the control data c for the serial number for which the retransmission request is received from the downlink data stored in the collection control apparatus is read and added as retransmission data.

  In step S614, the downlink data generation unit 329 creates downlink data including retransmission data. After the process of step S614 is completed, the process returns to step S605.

  Thus, when various retransmission requests are issued from many terminal stations, the multiplicity can be changed. In other words, it is possible to change the multiplicity when checking the data of the retransmission request and when there are many types of retransmission requests. Thereby, the terminal station can reduce the drop-out of the received downlink data, and can operate according to the operation instruction from the base station.

[Fifth embodiment]
Next, a fifth embodiment will be described with reference to FIG. In the fifth embodiment, for a terminal station that does not transmit uplink data or retransmission request data to the base station over multiple times due to battery exhaustion or the like when the terminal station is located outside the radio notification range, It is excluded from the calculation of the ratio of multiplexing change for uplink data.

  FIG. 22 is an example of a flowchart showing the data transmission / reception operation of the collection control device 3. In this flowchart, operations not directly related to data transmission / reception are omitted.

  In step S701, a reception operation is started.

  In step S <b> 702, the downlink data generation unit 329 receives setting data corresponding to a user instruction from the operation terminal 4 via the network control unit 328.

  In step S703, the data collection processing unit 31 generates a sequence time chart.

  In step S704, the downlink data generation unit 329 creates downlink data based on the received setting data.

  In step S705, the downlink transmission unit 314 transmits the created downlink data to the base station 1 via the interface unit (IF unit) 311.

  In step S706, the data check unit 313 extracts the terminal station position data g from the uplink data. In step S707, the duplication check of the position data g is performed. At this time, the terminal ID 91 of the received data is referred to, the duplication of the position data g is determined, and the duplicate position data g is deleted.

  In step S708, the data storage unit 325 accumulates the position data g.

  In step S709, the reception ratio calculation unit 326 extracts a terminal station that has not continuously transmitted uplink data a plurality of times. At this time, a terminal station not transmitting uplink data is detected based on the terminal ID 91 of the received data. The number of times can be arbitrarily determined.

  In step S710, the reception ratio calculation unit 326 excludes the number of extracted terminal stations from the total number of terminal stations, and calculates the ratio of the number of received position data from the terminal stations to the total number of terminal stations.

  In step S711, the multiplexing control unit 327 refers to the multiplicity conversion table 80.

  In step S712, the multiplexing control unit 327 controls the state of multiplicity according to the ratio of the number of received position data from the terminal station to the total number of terminal stations based on the multiplicity conversion table 80.

  In step S713, the downlink data generation unit 329 creates downlink data to be transmitted to the base station with the multiplicity indicated by the multiplexing control unit 327. Then, after the process of step S713 is completed, the process returns to step S705.

  As described above, a terminal station that does not transmit uplink data or retransmission request data to the base station for a plurality of times is excluded from the calculation at the time of calculating the multiplexing change ratio. As a result, it is possible to reduce adverse effects caused by a specific terminal station that lowers the overall communication rate.

DESCRIPTION OF SYMBOLS 1 Base station 2 Terminal station 3 Collection control apparatus 4 Operation terminal 11 Transmission / reception part 12 Control part 13 IF part 14 GPS reception part 21 Transmission / reception part 22 Control part 23 GPS reception part 24 Connection box 25 Light receiver 26 Firearm interface 27 Power supply part 31 Data Collection processing unit 32 Data storage processing unit 50 Data content 51 of system control data Data type ID
52 Base station slot number 53 Operation mode instruction 54 Time information 60 Data content of control data 61 Data type ID
62 Serial number 63 Control data classification 64 Date and time information 65 Valid period information 70 Data content of position data 71 Terminal ID
72 N-coordinate 73 E-coordinate 74 H-coordinate 75 Terminal station status 80 Multiplicity conversion table 90 Data content of retransmission request data 91 Terminal station ID
92 Occurrence time 93 Retransmission data start number 94 Retransmission data end number 95 Terminal station status 311 IF unit 312 Uplink data reception unit 313 Data check unit 314 Downlink data transmission unit 315 Network control unit 325 Data storage unit 326 Reception ratio calculation unit 327 Multiplex control unit 328 Network control unit 329 Downlink data generation unit

Claims (15)

A collection control device in a radio communication system including a base station and a terminal station that perform communication by time division multiplexing, and a collection control device connected to the base station,
A receiving unit for receiving uplink data from the base station received by the base station from the base station;
Based on the received uplink data, according to the ratio of the number of uplink data received from the terminal station to the total number of terminal stations, a control unit that sets the multiplicity of the downlink data transmitted from the base station to the terminal station; ,
A transmitter for transmitting the set multiplicity downlink data to the base station;
A collection control device.
The collection control apparatus according to claim 1, wherein the uplink data is position information data representing a position of a terminal station.
The collection according to claim 1, wherein the transmission unit transmits data corresponding to an identifier indicating missing of data added to uplink data requested to be retransmitted transmitted from a terminal station as downlink data. Control device.
The control unit rearranges the data corresponding to the identifier indicating the missing data added to the uplink data requested to be retransmitted transmitted from the terminal station in the order in which the terminal station detected the missing data, and The collection control device according to claim 3, wherein the unit transmits the rearranged data as downlink data.
The control unit rearranges data corresponding to an identifier indicating missing data added to uplink data requested to be retransmitted transmitted from a terminal station in order of data having a large number of retransmission requests, and the transmission unit reorders the data. 4. The collection control apparatus according to claim 3, wherein the received data is transmitted as downlink data.
The said control part excludes the number of the terminal stations which do not transmit uplink data over multiple times from the number of all terminal stations, and sets the multiplicity of downlink data, It is any one of Claim 1 thru | or 5 characterized by the above-mentioned. The collection control device according to one item.
A base station in a radio communication system composed of a base station and a terminal station that perform communication by time division multiplexing,
A receiver for receiving uplink data from a terminal station;
Set the multiplicity of downlink data from the base station to the terminal station according to the ratio of the number of uplink data received from the terminal station to the total number of terminal stations, and multiplex the downlink data based on the set multiplicity A control unit,
A transmitter that broadcasts downlink data multiplexed by the controller to a terminal station;
Base station with
The base station according to claim 7, wherein the transmission unit and the reception unit are integrated devices.
A communication method in a wireless communication system including a base station and a terminal station that perform communication by time division multiplexing and a collection control device connected to the base station,
The collection control device receives uplink data from the terminal station received by the base station from the base station,
Based on the received uplink data, the collection controller sets the multiplicity of downlink data transmitted from the base station to the terminal station according to the ratio of the number of uplink data received from the terminal station to the total number of terminal stations. And
A communication method for transmitting downlink data having a set multiplicity to the base station.
The communication method according to claim 9, wherein the uplink data is position information data representing a position of a terminal station.
The said collection control apparatus transmits the data corresponding to the identifier which shows the omission of the data added to the uplink data which requests the resending transmitted from the terminal station by downlink data. Communication method.
The collection control device rearranges the data corresponding to the identifier indicating the missing data added to the uplink data requested to be retransmitted transmitted from the terminal station in the order in which the terminal station detected the missing data. The communication method according to claim 9, wherein the changed data is transmitted as downlink data.
The collection control device rearranges the data corresponding to the identifier indicating the missing data added to the uplink data requested to be retransmitted transmitted from the terminal station in the order of the data having the most retransmission requests, and the rearranged data The communication method according to claim 9, wherein downlink data is transmitted.
14. The collection control apparatus according to claim 9, wherein the multiplicity of downlink data is set by excluding the number of terminal stations that do not transmit uplink data over a plurality of times from the total number of terminal stations. The communication method according to claim 1.
A communication method in a radio communication system composed of a base station and a terminal station that perform communication by time division multiplexing,
The base station receives uplink data from a terminal station;
Set the multiplicity of downlink data from the base station to the terminal station according to the ratio of the number of uplink data received from the terminal station to the total number of terminal stations, and multiplex the downlink data based on the set multiplicity ,
A communication method for transmitting multiplexed downlink data to a terminal station.

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