JP5703474B2 - Communication system and communication method - Google Patents

Description

  The present invention relates to a communication system and a communication method. In particular, the present invention relates to a communication system and communication method for a multicast service.

  A multicast service applied to a mobile communication system can distribute information to a large number of mobile terminals using a small number of radio resources. The multicast service provides the same service to a plurality of terminals at the same time when the plurality of terminals simultaneously receive data transmitted from the base station. The multicast service is called a multicast / broadcast service, and the multicast service is a concept including a broadcast service. As a standard of the multicast service, the standardization of MBMS (multimedia broadcast service) in the 3GPP (3rd Generation Partnership Project) standardization organization is the standardization of the 3GPP2 (3rd Generation PartnerBCS standard organization of 3GPP) (See Non-Patent Documents 1, 2, and 3).

  The above-described LTE (Long Term Evolution) multicast system employs a network-driven connection method, and is connected to a base via a BM-SC (Broadcast / Multicast Service Center) via an MBMS GW (Multimedia Broadband Multicast Service Gateway). A connection request is made to the node Node B and connected. The connection request includes the multicast IP address of the content data, and the MBMS GW can receive the content data with respect to the instructed multicast IP address. The content data is transmitted from the content provider and transmitted to the base station via the MBMS GW. The base station receives the content data corresponding to the multicast IP address and distributes the content data using the information of the MBMS service area. The terminal acquires information related to distribution of content data from SIB (System Information Block) information that is control information broadcast from the base station, and receives the content data.

  As other conventional techniques, Patent Documents 1 and 2 describe a base station that is arranged in each communication zone and communicates with a vehicle, a base central station that supervises a plurality of base stations, and a service that provides service information to the base central station. A communication system including a center is disclosed. A base station identification code is added to the transmission format of service information from the service center to the base concentration station, and the base station to which the service information is to be distributed is specified in the base concentration station, thereby existing in the communication zone for each communication zone. The same service information can be transmitted to the vehicle to be operated.

  The broadcast device of Patent Literature 2 transmits an emergency information notification message including a distribution area (area) and emergency information to an exchange corresponding to the distribution area. The exchange transfers the received emergency information notification message to all the connected radio base stations.

JP 2002-269682 A JP 2009-303174 A

3GPP standard TS 22.146 3GPP2 standard C.I. S0054 3GPP standard TS23.146

  However, depending on the type of content distributed by multicast, there is content that desires distribution limited to a specific area. In the above-mentioned conventional multicast service, when a user wants to distribute content data to a certain area, the user can easily obtain the address information of the area, but obtains information on the users who are in that area. Can not do it. For this reason, even if it is known that there is a user who wants to transmit to a certain area, the content data cannot be distributed only to users in that area.

  For example, when it is desired to provide voice guidance by multicasting voice data to a user in an apartment building “ABC” in Tokyo, the address of the apartment “ABC” can be easily checked. However, since information on terminals in the apartment “ABC”, for example, telephone numbers and e-mail addresses, cannot be acquired, transmission of voice guidance cannot be realized.

  Also, in the conventional multicast service, from a physical point of view, a base station or a cell in the base station that distributes content data is selected based on information in the MBMS service area, and an area for transmitting data is selected as a cell in the base station or the base station. It is possible to build in units. However, a method for transmitting to a specific area (area) in the cell is not defined. In addition, content data is distributed to a plurality of terminals located in the base station or a cell in the base station in units of cells in the base station or the base station.

  For this reason, in order to enable reception by a plurality of terminals located in the area, it is necessary to keep the data distribution rate low so that even terminals having a poor radio wave reception environment can receive content data. In addition, since the area where data is transmitted is constructed in units of cells within the base station or base station, content data can be distributed only to terminals that exist in a specific area within the base station or cell within the base station. There wasn't.

  An object of the present invention is to distribute data to an area of a specific address without specifying information of a terminal existing in the area where the data is transmitted.

A typical example of the present invention is as follows. That is, in a communication system that distributes data by multicast, a plurality of base stations, a first terminal that designates and transmits information of a delivery destination address to which the data is to be delivered, and information on the delivery destination address A communication control device that selects a base station to which the data is to be transferred from the plurality of base stations, and transfers the data to the selected base station; and the data transmitted from the selected base station A second wireless terminal that can be received at a point corresponding to the delivery destination address determined based on the delivery destination information in the cell of the selected base station. The base station determines a direction in which radio waves are transmitted based on the latitude, longitude, and altitude of the base station, and the latitude, longitude, and altitude of the point corresponding to the delivery address, and the data is transmitted in the determined direction. The A communication system, characterized by line transmission.

  According to the first embodiment of the present invention, data can be distributed to a region (or point) of a specific address without specifying information of a terminal existing in the region (or point) to which data is transmitted.

It is a block diagram which shows the structure of the communication system which concerns on embodiment. It is a block diagram which shows the structure of the communication control apparatus which concerns on embodiment. It is a block diagram which shows the structure of the base station which concerns on embodiment. It is a block diagram which shows the structure of the radio | wireless terminal which concerns on embodiment. It is a figure which illustrates the base station information table which a communication control apparatus stores. It is a figure which illustrates the address information database which a communication control apparatus stores. It is a figure which illustrates the delivery information table which a communication control apparatus stores. It is a figure which illustrates the base station information table which a base station stores. It is a figure which illustrates the delivery information table which a base station stores. It is a sequence diagram which illustrates the registration method of base station information. It is a sequence diagram which illustrates the delivery method of data.

  FIG. 1 shows a mobile communication system according to an embodiment. The mobile communication system is shown as an example of a communication system that distributes data by multicast, and the present invention is not limited to the mobile communication system.

  The mobile communication system includes base stations 110, 111, 112, and 113, a communication control device 120, and radio terminals 100 and 101 (mobile stations). In the present embodiment, the base stations 110, 111, 112, and 113 and the communication control device 120 are connected by a dedicated line such as an optical fiber, for example. Any one of the base stations 110, 111, 112, and 113 transmits the distribution data (content data to be distributed) received from the distribution-source wireless terminal 100 and the distribution destination address information to the communication control device 120. Send. The communication control device 120 further transfers the distribution data to the base station that distributes the distribution data. When the wireless terminal 101 located in the cell of the base station to which the data is transferred is included in the reception target area corresponding to the distribution destination address, the wireless terminal 101 receives the distribution data.

  FIG. 2 is a block diagram illustrating a configuration of the communication control device 120. The communication control device 120 includes an MPU 161 (microprocessor unit), a memory 162, a line interface 163, a base station information table 151 (FIG. 5 described later), an address information database 152 (FIG. 6 described later), and a distribution information table 153 (described later). 7), which are connected by a connection bus 164 so that they can communicate with each other. The line interface 163 communicates with the base stations 110, 111, 112, and 113 via, for example, a dedicated line. These tables and databases may be stored in a storage device (or storage unit) such as a semiconductor memory or a hard disk.

  The communication control device 120 refers to the address information database 152 and the base station information table 151, and based on the information of the delivery destination address sent from the wireless terminal 100, the delivery destination address (delivery area or delivery location) to which the delivery data is to be delivered. Search for a base station that corresponds to and covers a point. The communication control device 120 transfers the received distribution data to the searched base stations 110, 111, 112, and 113. Specifically, the communication control device 120 refers to the address information database 152 based on the information of the delivery destination address, and obtains the latitude, longitude, and altitude of the point (or region) corresponding to the delivery destination address. Furthermore, the communication control apparatus 120 refers to the base station information table 151 and selects a base station corresponding to the delivery destination address from the obtained latitude, longitude, and altitude.

  FIG. 3 is a block diagram showing the configuration of each base station 110, 111, 112, 113. Each base station 110, 111, 112, 113 includes a main signal processing unit 200. The main signal processing unit 200 includes a plurality of wireless analog units (sectors) 220, 221, 222, a control unit 201, a GPS (global positioning system) receiver unit 202, a digital signal processing unit 230, a line interface unit 231, and Is provided.

  The control unit 201 includes an MPU 235 (microprocessor unit), a memory 236, an input / output interface (I / O) 237, a base station information table 240, and a distribution information table 241. These tables may be stored in a storage device (or storage unit) such as a semiconductor disk or a hard disk. The control unit 201 is connected to the wireless analog units 220, 221, and 222 via the digital signal processing unit 230, and mainly performs call processing. The base station information table 240 manages base station information. The distribution information table 241 manages distribution information related to data distribution. The control unit 201 exchanges signals with the outside through an input / output interface (I / O) 237.

  The control unit 201 is connected to the GPS receiver unit 202 via an input / output interface (I / O) 237. The GPS receiver unit 202 can receive GPS satellite signals via a GPS antenna and obtain information on the latitude, longitude, and altitude of the base station. The digital signal processing unit 230 is a unit that demodulates upstream signals and modulates downstream signals. The line interface 231 is an interface for causing the control unit 201 and the communication control device 120 to communicate with each other.

  In the present embodiment, the number of the wireless analog units 220, 221, and 222 is three. Each of the wireless analog units 220, 221, and 222 corresponds to one of a plurality of sector-shaped sectors (or sector cells) provided by equally dividing the cell in the circumferential direction around the center of the base station. Specifically, the three wireless analog units 220, 221, and 222 correspond to the first sector (sector 1), the second sector (sector 2), and the third sector (sector 3), respectively. . The wireless analog units 220, 221, and 222 have the same configuration.

  The first wireless analog unit 220 includes an antenna 220a (sector antenna), a receiving unit 220b, and a transmitting unit 220c. The antenna 220 a transmits radio waves to the sector 1. The second wireless analog unit 221 includes an antenna 221a, a receiving unit 221b, and a transmitting unit 221c. The antenna 221a (sector antenna) transmits radio waves to the sector 2. The third wireless analog unit 222 includes an antenna 222a, a receiving unit 222b, and a transmitting unit 222c. The antenna 222a (sector antenna) transmits radio waves to the sector 3. The wireless analog units of the base stations 110, 111, 112, and 113 can transmit and receive signals to and from the wireless terminals 100 and 101 by wireless communication.

  The antennas 220a, 221a, and 222a are directional antennas, and in particular, may be array antennas that can adjust the transmission direction of a radio wave beam in a horizontal plane and / or a vertical plane (Japanese Patent Laid-Open Nos. 2002-94448 and 2002). 2000-78072 gazette etc.).

  The reception units 220b, 221b, and 222b of the wireless analog unit include, for example, electronic circuits, receive uplink signals transmitted from the wireless terminals 100 and 101 via the respective antennas 220a, 221a, and 222a, and receive the received analog signals. Is converted into a digital signal and transmitted to the digital signal processing unit 230. As shown in FIG. 3, each wireless analog unit can receive radio waves by a diversity method using a plurality of antennas.

  The transmitters 220c, 221c, and 222c of the wireless analog unit are composed of, for example, an electronic circuit, convert the downlink signal sent from the digital signal processing unit 230 from a digital signal to an analog signal, and pass through the antennas 220a, 221a, and 222a. It converts it into a radio wave and transmits it to the wireless terminals 100 and 101. Further, the transmission units 220c, 221c, and 222c can adjust the transmission direction of radio waves and the magnitude of transmission power of the antennas 220a, 221a, and 222a in accordance with an instruction from the control unit 201. When the antennas 220a, 221a, and 222a are array antennas, the transmitters 220c, 221c, and 222c transmit the antenna radio waves by changing the feeding phase condition to the plurality of antenna elements in the antennas 220a, 221a, and 222a. You can change direction.

  The control unit 201 of each of the base stations 110, 111, 112, and 113 includes a base station information table 240 (FIG. 8 described later) and a distribution information table 241 (FIG. 9 described later), and is received from the communication control device 120. The transmission direction and transmission power in the cell are determined from the latitude, longitude, and altitude information of the distribution destination, and data is wirelessly transmitted. The control unit 201 determines the radio wave transmission direction based on the latitude, longitude, and altitude of the delivery destination and the latitude, longitude, and altitude of the base station. In addition, the control unit 201 can calculate the transmission distance of the radio wave from the latitude difference, the longitude difference, and the altitude difference between the distribution destination and the base station, and can determine the transmission power corresponding to the radio wave transmission distance.

  The control unit 201 selects a sector and a corresponding wireless analog unit based on the determined transmission direction. Further, the control unit 201 can adjust the feeding phase condition to the antenna so that the antenna of the selected wireless analog unit transmits radio waves in a predetermined direction. If the number of sectors is large, the transmission direction of the radio wave is almost determined in the horizontal plane by selecting the sector. Therefore, the control unit 201 only needs to adjust the transmission direction (tilt angle) of the radio wave in the vertical plane. It is not necessary to adjust the transmission direction of radio waves in the horizontal plane. Further, when the altitude is not used by using only the latitude and longitude of the delivery destination, it is not necessary to adjust the radio wave transmission direction in the vertical plane.

  In addition, by synchronizing the time using GPS information (time signal) between base stations, the same data is transmitted at the same timing from a plurality of base stations (for example, 111 and 112) using a multicast channel. You can also. The wireless terminal 101 can receive by combining (soft combine) data transmitted from a plurality of base stations. In this combination of received data, the wireless terminal 101 can combine and restore the same data transmitted at the same timing by a plurality of base stations, and can receive the data even in a poor reception environment.

  FIG. 4 is a block diagram illustrating an example of the configuration of each of the wireless terminals 100 and 101. Each of the wireless terminals 100 and 101 includes a communication antenna 401, a wireless communication unit 402, a speaker 403, a microphone 404, an audio circuit 405, an input unit 406, a display unit 407, a control unit 408, and a memory 409. The GPS antenna 410 and the GPS receiver unit 411 are provided.

  The communication antenna 401 is an antenna for performing wireless communication with the base stations 110, 111, 112, and 113. The distribution-source wireless terminal 100 can wirelessly connect to the base station via the communication antenna 401, transmit the terminal ID, distribution data, and distribution address information, and receive the service ID and the like from the base station 110. . Here, the terminal ID is an identifier or identification information for identifying a terminal, and the service ID is an identifier or identification information for identifying a service. The wireless terminal 101 can receive distribution data and information on the latitude, longitude, and altitude of the distribution destination via the communication antenna 401.

  The wireless communication unit 402 performs processing necessary for wireless communication, such as digital-analog conversion, analog-digital conversion, modulation, and demodulation. The speaker 403 outputs an audio signal as audio. The microphone 404 acquires an audio signal to be distributed. The audio circuit 405 converts the received audio signal into a signal that can be output to the speaker 403, or converts the audio signal input from the microphone 4 into audio data that can be distributed. If the content data distributed by the wireless terminal 100 is audio data, the audio data can be input from the microphone 404 to the wireless terminal 100.

  An input unit 406 is an operation unit (for example, a key or a button) for a user to perform various mode settings, create content data of character information to be distributed, and perform various terminal operations such as calling and answering. ). The input unit 406 receives the information on the address where the data is to be distributed by the user's operation, so that the wireless terminal 100 can specify the information on the address of the distribution destination. The display unit 407 displays information necessary for the terminal operation. The control unit 408 includes, for example, a CPU that executes a program, a memory that stores the program, and the like, and controls the operation of each unit of the wireless terminals 100 and 101.

  The memory 409 stores data temporarily or permanently. For example, the memory 409 can store content data such as character information created by the user. The memory 409 stores information on the address of the delivery destination input from the input unit 406, the display unit 407 displays the stored address information on a menu, and the user inputs the information on the address of the delivery destination. It can also be selected by 406. In addition, the memory 409 stores content data such as character information, images, and moving images. The display unit 407 displays the stored content data information (such as a title) in a menu, and the user displays content data to be distributed. Selection can be made by the input unit 406. Further, in the wireless terminal 101, the memory 409 can store the distributed content data.

  The GPS receiver unit 411 can receive a signal from a GPS satellite via the GPS antenna 410 and obtain information on the latitude, longitude, and altitude of each wireless terminal 100, 101.

  FIG. 5 shows an example of the base station information table 151 held by the communication control device 120. In the base station information table 151, the communication control apparatus 120 displays the information on the latitude, longitude, and altitude of each base station 110, 111, 112, 113 notified from each base station 110, 111, 112, 113. , 111, 112, and 113 are managed in association with ID information (base station ID). In FIG. 5, latitude and longitude are expressed by delimiting degrees, minutes, seconds, and 1/1000 seconds with periods, and altitude is expressed in units of meters (the same applies to FIGS. 6 to 9).

  FIG. 6 is an example of the address information database 152 held by the communication control device 120. In the address information database 152, the communication control device 120 manages mapping information (association information) that associates latitude, longitude, and altitude with the address information of the distribution destination of the distribution data. As shown in FIG. 6, the address can be expressed by a combination of a postal code representing a rough area and other detailed information (such as a letter, address, and number).

  FIG. 7 is an example of the distribution information table 153 held by the communication control device 120. In the distribution information table 153, the communication control device 120 manages a service ID for managing a service requested from the wireless terminal 100, ID information (terminal ID) for identifying the wireless terminal 100 that has issued the request, and the wireless terminal 100. The address of the delivery destination designated from, and the latitude, longitude and altitude corresponding to the delivery destination address are associated and managed.

  FIG. 8 is an example of the base station information table 240 held by the base stations 110, 111, 112, and 113. Each of the base stations 110, 111, 112, and 113 manages its own ID information, its own latitude, longitude, and altitude in association with each other in the base station information table 240.

  FIG. 9 is an example of the distribution information table 241 held by the base stations 110, 111, 112, and 113. Each of the base stations 110, 111, 112, and 113 associates the distribution data service ID specified by the communication control device 120 with the latitude, longitude, and altitude information of the distribution destination of the distribution data in the distribution information table 241. Manage.

  FIG. 10 is a processing sequence diagram illustrating a method in which the communication control apparatus 120 registers information on each base station.

  In step S10, each base station 110, 111, 112, 113 is activated. Next, in step S <b> 11, each base station 110, 111, 112, 113 transmits a registration request 910 for requesting registration of information on each base station to the communication control apparatus 120. The base station information registration request 910 includes the ID information of the base station, and the latitude, longitude, and altitude information of the base station. The latitude, longitude, and altitude information of the base station may be stored in advance in the base station memory 236 or the like, or may be obtained from the GPS receiver unit 202.

  In step S12, the communication control apparatus 120 receives the base station information registration request 910. In step S <b> 13, the communication control apparatus 120 registers the received base station ID information and the base station latitude, longitude, and altitude information in the base station information table 151. In step S14, after registration, the communication control apparatus 120 transmits a registration completion response 930 indicating that the registration of the base station information is completed to each base station. The registration completion response includes the ID information of the base station that sent the registration request 910. In step S <b> 15, each base station 110, 111, 112, 113 receives a registration completion response from the communication control device 120.

  FIG. 11 is a processing sequence diagram illustrating a data distribution method.

  In step S20, the requesting wireless terminal 100 that requests data distribution designates a distribution address to which distribution data is to be distributed based on a user operation or the like. In step S21, the radio terminal 100 transmits a data distribution request 1010 to the base station 110 in which it is located. The data delivery request 1010 includes ID information of the wireless terminal 100 itself and delivery destination address information.

  In step S <b> 22, the base station 110 receives the data distribution request 1010 from the wireless terminal 100. In step S <b> 23, the base station 110 transfers the received data distribution request 1011 to the communication control device 120. The data distribution request 1011 includes ID information of the wireless terminal 100 that requests data distribution and information on a distribution destination address.

  In step S24, the communication control apparatus 120 receives the data distribution request 1011. In step S25, the communication control device 120 refers to the address information database 152, and acquires information on the latitude, longitude, and altitude (a point or region corresponding to the delivery destination address) of the delivery destination corresponding to the received delivery destination address. .

  In step S26, the communication control apparatus 120 refers to the base station information table 151, and a base station that is close to the latitude, longitude, and altitude of the distribution destination and includes the point in the cell is a data transfer destination (or distribution destination). Select as the base station. In the case where the wireless terminal 101 receives data by soft combining, a plurality of base stations may be selected in the order closer to the distribution destination latitude, longitude and altitude. Note that the communication control device 120 may select only the base station closest to the latitude, longitude, and altitude point of the delivery destination, or a predetermined distance (eg, cell radius) from the latitude, longitude, and altitude points of the delivery destination. You may select all the base stations in the parenthesis. Further, the communication control apparatus 120 may select a base station based only on the latitude and longitude of the delivery destination, and the base station information table 151 may not have information on the altitude of the delivery destination.

  In step S27, the communication control device 120 identifies the ID information of the wireless terminal 100 that requested the data distribution, the distribution destination address information, the distribution destination latitude, longitude, and altitude information acquired in step S25, Information on the base station of the distribution destination selected in S26 is registered in the distribution information table 153 as distribution information. Further, when registering, in order to manage the distribution information, the communication control device 120 assigns a service ID (service identifier) to the distribution information and associates the distribution information with the service ID. The service ID is assigned to the data transfer destination (distribution destination) base station so as to be unique (unique) in the communication control device 120. In step S28, the communication control apparatus 120 transmits a data distribution request 1030 to the base stations 111 and 112 selected in step S26. The data distribution request 1030 includes a corresponding service ID and information on the latitude, longitude, and altitude of the distribution destination.

  In step S29, the base stations 111 and 112 selected in step S26 receive the data distribution request 1030. In step S <b> 30, the base stations 111 and 112 register the received service ID information and distribution destination latitude, longitude, and altitude information in the distribution information table 241. Thereafter, in step S31, the base stations 111 and 112 return a data distribution request response (response to the data distribution request) 1031 to the communication control apparatus 120. The data distribution request response 1031 includes information on the service ID received by the data distribution request 1030.

  In step S32, the communication control device 120 receives the data distribution request response 1031 from the data transfer destination base stations 111 and 112. In step S <b> 33, the communication control apparatus 120 transmits a data distribution request response 1050 to the base station 110 that transmitted the data distribution request 1011. The data distribution request response 1050 includes the corresponding service ID and ID information of the wireless terminal 100 that is the distribution request source.

  In step S34, the base station 110 receives the data distribution request response 1050. In step S35, the base station 110 transmits a data distribution request response 1051 to the wireless terminal 100 that has transmitted the data distribution request 1010. The data distribution request response 1051 includes the service ID information received by the data distribution request response 1050.

  In step S36, the wireless terminal 100 receives the data distribution request response 1051. In step S37, the wireless terminal 100 transmits the distribution data 1060 in which the service ID information received by the data distribution request response 1051 is set in the header part to the base station 110 in the area.

  In step S38, the base station 110 receives the distribution data 1060. In step S39, the base station 110 transfers the received distribution data 1061 to the communication control device 120.

  In step S40, the communication control apparatus 120 receives the distribution data 1061. In step S41, the communication control apparatus 120 transfers the received distribution data 1070 to the base stations 111 and 112 that are data transfer destinations (distribution destinations).

  In step S42, the base stations 111 and 112 receive the distribution data 1070. In step S43, the base stations 111 and 112 set information such as the latitude, longitude, and altitude of the distribution destination received by the data distribution request 1030 in the header portion of the distribution data. In step S44, the base stations 111 and 112 distribute the distribution data 1090 associated with the latitude, longitude, and altitude of the distribution destination toward the latitude (longitude) and altitude (or region) of the distribution destination. When the base station 111, 112 distributes the distribution data 1090, the base station 111, 112 selects a sector (or sector cell) and a corresponding wireless analog unit based on the latitude, longitude, and altitude of the distribution destination, and the radio wave transmission direction of the antenna The transmission power is controlled and data is transmitted. When the number of sectors is large, it is not always necessary to control the radio wave transmission direction and transmission power of the antenna.

  In step S45, the wireless terminal 101 located in the cell of the base station to which the distribution data is transferred transmits the distribution destination latitude X1, longitude Y1, and altitude Z1 set in the received distribution data, respectively. Compare with the latitude X0, longitude Y0, and altitude Z0 of the terminal 101. The wireless terminal 101 acquires its own latitude, longitude, and altitude by the GPS receiver unit 411. When the point specified by the latitude, longitude, and altitude of the wireless terminal 101 is included in the reception target area (reception target point) corresponding to the distribution destination address, the wireless terminal 101 receives the distribution data. Assuming that the reception target area is X1 ± α, Y1 ± β, Z1 ± γ (α, β, and γ are predetermined values), the wireless terminal 101 has | X1-X0 | ≦ α and | Y1-Y0 | ≦ β If the condition of | Z1-Z0 | ≦ γ is satisfied, the wireless terminal 101 may be determined to be included in the reception target area. Note that, when α, β, and γ are not set and the latitude X0, longitude Y0, and altitude Z0 of the wireless terminal 101 match the destination latitude X1, longitude Y1, and altitude Z1, respectively, the wireless terminal 101 receives It may be determined that it is included in the target area.

  A wireless terminal 101 that has received data transmitted from a plurality of base stations 111 and 112 may receive the received data by combining (soft combine) the received data, or a cell (base station) having a better radio wave reception state You may select and receive data.

  The wireless terminal 100 that is the distribution data distribution source specifies α, β, and γ values that define the reception target area by user input and the like, and the data distribution request 1010 includes the distribution destination address information and α, β. , Γ may be included and transmitted. In this case, the values of α, β, and γ are transmitted to the wireless terminal 101 together with the latitude, longitude, and altitude of the delivery destination via the base station 110, the communication control device 120, and the base stations 111 and 112. In this way, it is possible to set the size of the distribution data reception target area from the wireless terminal 100 side.

  Hereinafter, application examples of the present embodiment will be described. For example, an administrator in a condominium can input a specific floor as a delivery destination address to the wireless terminal 100 and distribute maintenance guidance or the like as audio data from the wireless terminal 100. In this case, the wireless terminal 100 located on the specific floor can receive the audio data. For example, an employee of a department store inputs the address of a floor where a specific store exists as a delivery destination address to the wireless terminal 100, and transmits the sales information of the store as data along with the address information from the wireless terminal 100. Can do. In this case, the wireless terminal 100 located on the floor can receive the sales information.

<Modification 1>
In the above-described embodiment, the wireless terminal 100 that is a request source for requesting data distribution owns or generates content data (distributed data), and the wireless terminal 100 becomes the distribution source. However, the present invention is not limited to this. In other words, the request source that requests the data distribution and designates the address of the distribution destination may be different from the distribution source that stores the distribution data.

  For example, the communication control device 120 may serve as a distribution source by storing content data in a database or the like. In addition, the communication control device 120 may receive content data from a place other than the wireless terminal 100 (for example, a content distribution server). In this case, the wireless terminal 100 includes information (for example, content ID) for specifying content data in the data distribution request 1010 and transmits the information to the communication control device 120. The communication control device 120 distributes the content data to the wireless terminal 101 based on the information specifying the content data via the base stations 111 and 112.

<Modification 2>
A wired terminal can be used instead of the wireless terminal 100. In this case, the wired terminal may transmit the address of the data distribution destination to the communication control device 120 via the Internet or the like. The communication control device 120 selects a base station to which data is transferred based on the information of the delivery destination address, and transfers the data to the selected base station.

<Modification 3>
In the above-described embodiment, the base stations 110, 111, 112, and 113 include a plurality of wireless analog units corresponding to sectors. However, a configuration in which the base station has one antenna that changes the transmission direction over a wide range and includes a single wireless analog unit may be employed. In this case, the base station selects a radio wave transmission direction without selecting a sector (wireless analog unit).

<Modification 4>
In the above-described embodiment, the communication control device 120 has an address information database (association information) that associates addresses with latitude, longitude, and altitude. However, each base station may have an address information database that associates addresses with latitude, longitude, and altitude in the corresponding cell.

  In this case, the communication control device 120 has a table (association information) for associating the base station with its address, and the communication control device 120 selects the base station from the distribution destination address. The communication control apparatus 120 transmits information on the delivery destination address to the selected base station. The selected base station may determine the latitude, longitude and altitude of the delivery address based on the delivery address with reference to the address information database and register them in the delivery information table.

-Effect-
According to the above-described embodiment, the wireless terminal 100 (first terminal) designates and transmits information on a delivery address to which data is to be distributed. The communication control device 120 selects a data transfer destination base station (for example, the base station 111) from a plurality of base stations based on the information of the delivery destination address, and transfers the data to the selected base station. In the cell of the selected base station, the wireless terminal 101 (second wireless terminal) is determined based on the information of the delivery destination address and selected at the point corresponding to the delivery destination address (for example, the base station) 111, etc.) can be received.

  Thereby, in addition to limiting the base station which distributes data, the area which distributes data can be limited to the specific address in the cell of a base station. Further, it is not necessary to specify information of terminals existing in an area or a point where data is transmitted. Since data is distributed only to a specific address, a terminal having a poor radio wave reception environment is less likely to be included in an area where data is distributed, and the data distribution rate is increased. In addition, radio resources are saved because the radio channel of the area corresponding to the specific address is used and the radio channel is not used in other areas.

  The communication control device 120 stores an address information database 152 (association information) that associates addresses with at least latitude and longitude, and determines latitude and longitude corresponding to information on the delivery destination address. The communication control device 120 compares the latitude and longitude corresponding to the information of the delivery destination address with the latitude and longitude of the plurality of base stations 110, 111, 112, and 113, respectively, so that the transfer destination base station 111, 112 is selected from a plurality of base stations. Thereby, for example, a base station having a cell close to and covering the delivery address can be selected.

  The selected base station (for example, the base station 111) determines the direction in which the radio wave is transmitted based on the latitude, longitude, and altitude of the base station and the latitude, longitude, and altitude of the point corresponding to the delivery address. , Wirelessly transmit data in the determined direction. Thereby, the area which distributes data can be limited to the specific address in the cell of a base station simply. Considering the height (altitude), data distribution limited to a specific floor in the building can be performed, and the limited wireless band can be used more efficiently. In addition, the selected base station determines the transmission power for wireless transmission of data based on the latitude, longitude, altitude of the base station, and the latitude, longitude, and altitude of the point corresponding to the delivery address. Thereby, the transmission power of the base station can be minimized.

  The wireless terminal 101 (second wireless terminal) receives the data by comparing the latitude, longitude, and altitude of the wireless terminal 101 obtained by GPS with the latitude, longitude, and altitude of the point corresponding to the delivery address. The wireless terminal 101 determines whether it is included in the reception target area and receives data when included in the reception target area. As a result, data cannot be received outside the reception target area, and the area where the data is distributed can be accurately limited to a specific address. Considering the height (altitude), data distribution limited to a specific floor in the building can be performed, and the limited wireless band can be used more efficiently.

  When the selected base station (for example, the base station 111) has a plurality of sectors or a plurality of sector cells, the base station selects one sector or sector cell and receives data from an antenna corresponding to the selected sector or sector cell. Is transmitted wirelessly. Thereby, the area where data is distributed more accurately can be limited.

  The wireless terminal 100 (first terminal) generates or stores data and transmits the data to the communication control device 120. As a result, when the user of the wireless terminal 100 using the wireless terminal 100 as the distribution source desires distribution (without storing the data in advance elsewhere), the data can be distributed in a timely manner.

  It is obvious that the present invention is not limited to the above-described embodiments and modifications thereof, and various modifications can be made within the scope of the technical idea.

100, 101 Wireless terminal 110, 111, 112, 113 Base station 120 Communication control device 151 Base station information table 152 Address information database 201 Control unit 202 GPS receiver unit 220, 221, 222 Wireless analog unit 240 Base station information table 241 Distribution information Table 402 Wireless communication unit 406 Input unit 409 Memory 411 GPS receiver unit

Claims (9)

A communication system for distributing data by multicast,
Multiple base stations,
A first terminal that specifies and transmits information of a delivery address to which the data is to be distributed;
A communication control device that selects a base station to which the data is transferred from the plurality of base stations based on the information of the delivery destination address, and transfers the data to the selected base station;
Second data that can be received at a point corresponding to the delivery destination address determined based on the delivery address information in the cell of the selected base station, in the data transmitted from the selected base station equipped of a wireless terminal, the,
The selected base station determines a direction in which radio waves are transmitted based on the latitude, longitude, and altitude of the base station, and the latitude, longitude, and altitude of the point corresponding to the delivery address, and the determined communication system comprising the features and to Rukoto to send wirelessly the data direction. A communication system for distributing data by multicast,
Multiple base stations,
A communication control device that selects a base station to which the data is to be transferred from the plurality of base stations based on information of a delivery address to which the data is to be distributed, and transfers the data to the selected base station; With
The selected base station determines a direction in which radio waves are transmitted in the cell based on the latitude, longitude, and altitude of the base station and the latitude, longitude, and altitude of the point corresponding to the delivery address. A communication system characterized by wirelessly transmitting the transferred data in the determined direction . The communication according to claim 1 or 2 , wherein the selected base station determines power for transmitting the data based on the latitude, longitude, and altitude of the base station and the latitude, longitude, and altitude of the point. system. The communication control device includes:
Stores correspondence information that associates addresses with at least latitude and longitude,
Determine the latitude and longitude corresponding to the information of the delivery address,
The transfer destination base station is selected from the plurality of base stations by comparing the latitude and longitude corresponding to the information of the delivery destination address with the latitude and longitude of the plurality of base stations, respectively. The communication system according to claim 1 or 2. The second wireless terminal compares the latitude, longitude, and altitude of the second wireless terminal obtained by GPS with respect to the latitude, longitude, and altitude of the point corresponding to the delivery address, respectively. The second wireless terminal determines whether the data is included in a reception target area to receive the data, and the second wireless terminal receives the data when included in the reception target area. The communication system according to 1. When the selected base station has a plurality of sectors or a plurality of sector cells, the base station selects one sector or sector cell, and wirelessly transmits the data from an antenna corresponding to the selected sector or sector cell. The communication system according to claim 1 or 2. A communication method for distributing data by multicast,
A first terminal specifying and transmitting information of a delivery address to which the data is to be distributed;
The communication control device selects a base station to which the data is transferred from a plurality of base stations based on the information of the delivery destination address, and transfers the data to the selected base station;
The selected base station determines a direction for transmitting radio waves based on the latitude, longitude and altitude of the base station, and the latitude, longitude and altitude of the point corresponding to the delivery address, and the determined Wirelessly transmitting the data in a direction;
The second wireless terminal determines the data wirelessly transmitted from the selected base station based on the information of the delivery destination address in the cell of the selected base station, and corresponds to the delivery destination address. Receiving at a point to perform,
A communication method comprising: A communication method for distributing data by multicast,
The communication control device selects a base station to which the data is to be transferred from the plurality of base stations based on information of a delivery destination address to which the data is to be distributed, and transfers the data to the selected base station Steps,
In the cell, the selected base station determines a direction in which radio waves are transmitted based on the latitude, longitude, and altitude of the base station and the latitude, longitude, and altitude of the point corresponding to the delivery address. Wirelessly transmitting the transferred data in the determined direction;
A communication method comprising: The communication according to claim 7 or 8, wherein the selected base station determines the power for transmitting the data based on the latitude, longitude, and altitude of the base station, and the latitude, longitude, and altitude of the point. Method.

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