JPWO2018131437A1 - Transmitting apparatus, transmitting apparatus control method, and control program - Google Patents

Abstract

Reduce the waiting time for content reception. The transmission device (100) includes a use determination unit (12) that determines whether or not the transmission device (100) is in use, and is portable within the first communication range when it is determined that the transmission device (100) is not in use. A transmission control unit that transmits content to the terminal (200) and transmits the content to the portable terminal (200) within a second communication range extending to a further distant position when it is determined that the content is being used. 11).

Description

  One embodiment of the present invention relates to a transmission device or the like that transmits content to surrounding mobile terminals.

  Techniques for distributing content to mobile terminals are conventionally known. For example, Patent Document 1 below discloses a technology for distributing content from a content distribution server to a mobile terminal via the Internet.

Japanese Patent Publication “Japanese Patent Laid-Open No. 2010-205185 (published on September 16, 2010)”

  In addition to the content distribution service via the Internet as described above, a service for distributing content from an information terminal installed in a public space such as a station or a store such as a convenience store to a mobile terminal is also being studied. In such a service, a user who receives content distribution needs to go to an information terminal.

  When receiving content from such an information terminal, a waiting time may occur from the start of reception to the completion of reception depending on the file size and communication speed of the received content. Furthermore, when a plurality of users try to receive content, there is a problem that waiting for an order occurs and a waiting time may occur before reception starts.

  An object of one embodiment of the present invention is to realize a transmission device or the like that can shorten the waiting time of a user when content is transmitted to portable terminals around the transmission device.

  In order to solve the above-described problem, a transmission device according to the present invention has a function of transmitting content to surrounding portable terminals, and is a transmission device that sequentially corresponds to a plurality of users. When the use determination unit determines whether or not the device is in use and the use determination unit determines that the device is not in use, the content is transmitted to the portable terminal within the first communication range, and the use Transmission control for transmitting content to the portable terminal within a second communication range that extends to a position farther from the transmission device than the first communication range when the determination unit determines that it is in use And a section.

  In order to solve the above problem, a control method for a transmission device according to the present invention is a control method for a transmission device that has a function of transmitting content to surrounding mobile terminals and sequentially corresponds to a plurality of users. A user determination step for determining whether or not the user is using the transmission device, and the use determination step for determining whether the user is not using the content in the mobile terminal within the first communication range Is transmitted to the portable terminal within a second communication range extending to a position further away from the transmission device than the first communication range. A transmission control step of transmitting content.

  According to one aspect of the present invention, there is an effect that the waiting time of the user in content reception can be shortened.

It is a block diagram which shows an example of the principal part structure of the transmitter which concerns on Embodiment 1 of this invention. It is a figure which shows an example of the communication range of an omnidirectional communication part and a directional communication part. It is a figure which shows the relationship between the on-off state of each antenna element with which a directional antenna is provided, and the shape of the beam of a directional antenna. It is a flowchart which shows an example of the process which the said transmission apparatus performs before transmission of a content starts. It is a flowchart which shows an example of the process which the said transmitter performs at the time of the transmission of content.

[Embodiment 1]
A configuration of a transmission apparatus according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a block diagram illustrating an example of a main configuration of the transmission device 100. In FIG. 1, the portable terminal 200 that receives content from the transmission device 100 is also illustrated. The type of content is not particularly limited as long as it is digital content, and may be audio content such as music, moving image content such as a movie, text (or still image) content such as an electronic book, and the like. This content may be received from the service server by a known means such as a wired dedicated line or a Web line. In addition, a plurality of contents may be stored in advance in a storage unit (described later) included in the transmission device 100, or may be received from the service server every time a request from the mobile terminal 200 is received.

  The mobile terminal 200 is a mobile terminal device having at least a function of communicating with the transmission device 100, and may be a mobile phone such as a smartphone, a tablet terminal, a notebook computer, or a mobile game machine, for example. Although only one mobile terminal 200 is illustrated in FIG. 1, the transmission apparatus 100 can transmit content and a sample thereof to a plurality of mobile terminals 200 at the same time. The content sample is a sample to be transmitted as one of judgment materials for the user to consider whether or not the content can be purchased. For example, a part of the content, or the entire content in which the data amount is compressed or the sound quality or image quality is reduced may be used as the content sample.

  The transmission device 100 is a device having a function of transmitting content to the mobile terminal 200 around the transmission device 100. That is, a user who wants to receive content from the transmission device 100 travels to the periphery of the transmission device 100 and receives the content with his / her mobile terminal 200. The transmission device 100 may be, for example, a public space such as a station, a street, an airport, or a kiosk (registered trademark) terminal installed in a store such as a convenience store. The transmission device 100 may have functions such as product search and acceptance of various procedures in addition to the content transmission function.

  The transmission device 100 includes a control unit 101, a storage unit 102, a communication unit 103, a display unit 104, a proximity detection unit 105, and a touch unit 107. The control unit 101 performs overall control of each unit of the transmission apparatus 100, and includes a transmission control unit (sample transmission unit) 11, a use determination unit 12, a reception quality monitoring unit 13, a beam width determination unit 14, and antenna control. Part 15 is included. The storage unit 102 stores various data used by the transmission apparatus 100, and stores a beam width control table 21 and reception quality data 22. The communication unit 103 is for the transmission device 100 to communicate with another device (in this example, the portable terminal 200), and the omnidirectional communication unit 31, the omnidirectional antenna 32, the directional communication unit 33, and the directional communication unit 103 are used. The antenna 34. Directional communication may be, for example, communication via millimeter waves. Further, the omnidirectional communication may be, for example, communication by a wireless LAN (Local Area Network). The display unit 104 displays an image, and the proximity detection unit 105 detects that the mobile terminal 200 is close to the touch unit 107. The touch unit 107 is a part where the portable terminal 200 should be brought close to or in contact with the directional communication, and is exposed on the surface of the casing of the transmission device 100.

  The transmission control unit 11 controls content transmission to the mobile terminal 200. Specifically, when the transmission control unit 11 receives a content transmission request from a portable terminal 200 of a certain user, and the other user is not using the transmission device 100, the transmission control unit 11 is portable within the first communication range. The content is transmitted to the terminal 200. On the other hand, if another user uses the transmission device 100, the content is transmitted to the mobile terminal 200 within the second communication range extending to a position farther from the transmission device 100 than the first communication range. . The transmission control unit 11 also functions as a sample transmission unit that transmits a sample of content to another mobile terminal within the third communication range that is wider than the first communication range and the second communication range. . The sample transmission unit may be a separate block from the transmission control unit 11. The communication range at the time of content transmission will be described later with reference to FIG.

  The usage determination unit 12 determines whether or not the transmission device 100 is in use. Here, “use” of the transmission device 100 mainly means that the mobile terminal 200 is brought close to the touch unit 107 to perform communication or the like. Further, the occupation of the transmission apparatus 100 for the operation of the transmission apparatus 100, the browsing of information presented by the transmission apparatus 100, etc. is also included in the category of “use”. In the following, the use determination unit 12 determines that the transmission device 100 is in use and detects when the proximity detection unit 105 detects that the mobile terminal 200 is close to the touch unit 107. If not, it is determined that it is not in use. Note that the method for determining whether or not the transmission device 100 is in use is not limited to this example. For example, when the transmission device 100 includes an operation key for accepting a user's input operation, the operation key is being operated. You may determine with the transmitter 100 being in use.

  The reception quality monitor unit 13 monitors the reception quality of signals in communication via the directivity communication unit 33. The reception quality monitoring unit 13 determines whether the reception quality is equal to or higher than a predetermined value. The signal reception quality is, for example, at least one of received signal strength detection (RSSI), signal-to-noise ratio (SNR), signal-to-interference / noise ratio (SINR), bit error rate, frame error rate, and packet error rate. It may be represented by the value of. The reception quality monitor unit 13 calculates such a numerical value indicating the reception quality and stores it as reception quality data 22. The reception quality monitoring unit 13 may constantly monitor the reception quality during communication via the directivity communication unit 33. In addition, when signals are received from a plurality of portable terminals 200, the reception quality may be monitored in parallel or in time division for each of the signals received from each device.

  The beam width determination unit 14 determines the beam width or the like (hereinafter referred to as a beam pattern) of the directional antenna 34 according to the signal reception quality in communication via the directional communication unit 33. Then, the beam width determination unit 14 transmits antenna element control information for setting the beam pattern of the directional antenna 34 to the determined beam pattern to the antenna control unit 15. The relationship between the beam pattern and the antenna element control will be described later with reference to FIG.

  The antenna control unit 15 controls the operation of the directional antenna 34. For example, the antenna control unit 15 controls the operation of each antenna element of the directional antenna 34 so that the beam pattern of the directional antenna 34 becomes the beam pattern determined by the beam width determination unit 14. By such control, the antenna control unit 15 switches the beam pattern of the directional antenna 34 according to the reception quality of the signal in communication via the directional communication unit 33. However, a plurality of directional antennas may be provided and controlled to have characteristics similar to those of the omnidirectional antenna.

  The beam width control table 21 is information used by the beam width determination unit 14 to determine a beam pattern, and indicates a beam pattern according to reception quality and control information of an antenna element for obtaining the beam pattern. Yes. For example, the beam width control table 21 may prescribe reception quality in stages and indicate control information of antenna elements corresponding to each stage. Further, the beam width control table 21 may be associated with a beam pattern having a wider beam width for higher reception quality. If the reception quality is low, the beam width must be narrowed to ensure the minimum reception quality necessary for content transmission. If the reception quality is high, the content can be This is because the reception quality necessary for transmission is ensured. Further, when the reception quality is high, the beam width may be narrowed to increase the data transmission capacity.

  The reception quality data 22 is data in which the monitoring result of the reception quality monitoring unit 13 is recorded, and is data indicating the reception quality of a signal in communication via the directional communication unit 33. Therefore, the beam width determination unit 14 can specify the reception quality from the reception quality data 22. As described above, the beam pattern corresponding to the specified reception quality can be specified from the beam width control table 21.

[About communication range]
The communication range of the omnidirectional communication unit 31 and the directional communication unit 33 will be described with reference to FIG. FIG. 2 is a diagram illustrating an example of a communication range between the omnidirectional communication unit 31 and the directional communication unit 33. As illustrated, the transmission device 100 can communicate with the mobile terminal 200 in three types of communication ranges W1 to W3. The communication ranges W1 and W2 indicate the communication range of the directional communication unit 33, and the communication range W3 indicates the communication range of the omnidirectional communication unit 31.

  The communication range W1 (first communication range) is a communication range when the mobile terminal 200 brought into contact with or close to the touch unit 107 communicates with the transmission device 100. Therefore, the communication range W1 may be a range including at least the periphery of the touch unit 107, and is the narrowest range among the communication ranges W1 to W3. The communication range W <b> 1 may be a range in which a user who directly operates the transmission device 100 can bring the mobile terminal 200 closer, but a user away from the transmission device 100 cannot bring the mobile terminal 200 closer. For example, the communication range W1 may be a range where the distance from the touch unit 107 is within 10 cm.

  The communication range W2 (second communication range) is a communication range when the mobile terminal 200 at a position away from the transmission device 100 communicates with the transmission device 100. For this reason, the communication range W2 extends to a position farther from the transmission device 100 than the communication range W1. The communication range W2 changes according to the beam pattern formed by the directional antenna 34 of the directional communication unit 33. The communication range W2 may be a range in which the display content of the display unit 104 of the transmission device 100 can be visually recognized. For example, the communication range W2 may be a range in which the distance from the directional communication unit 33 is within 5 m.

  Similarly to the communication range W2, the communication range W3 (third communication range) is a communication range when the mobile terminal 200 at a position away from the transmission device 100 communicates with the transmission device 100. The communication range W3 is preferably wider than the communication range W1 and the communication range W2. The communication range W3 may be a range that allows the user to visually recognize the presence of the transmission device 100 (recognizes that the transmission source of the content sample is the transmission device 100). For example, the communication range W3 may be a range in which the distance from the omnidirectional communication unit 31 is within 20 m.

[Beam pattern of directional antenna]
Next, the beam pattern of the directional antenna 34 will be described with reference to FIG. FIG. 3 is a diagram showing the relationship between the on / off state of each antenna element 341 included in the directional antenna 34 and the beam pattern of the directional antenna 34. As shown in FIG. 3, the directional antenna 34 includes a plurality of antenna elements 341 arranged in a lattice pattern. The black-colored antenna element 341 is supplied with power and shows the antenna element 341 in an on state. A white antenna element 341 indicates an off-state antenna element 341 that is not supplied with power. Signals are transmitted to or received from the portable terminal 200 in the transmission / reception area formed by the antenna element 341 in the on state.

  As shown in FIG. 3A, when all the antenna elements 341 are on, the directional antenna 34 forms a pencil beam F1 having a high directivity and a narrow beam width. The pencil beam has a circular beam shape with a narrow cross section with respect to the radio wave radiation direction, and has a beam width narrower than a fan beam described later. The scanning angle θ of the pencil beam is, for example, within 30 °. When the transmission beam pattern of the directional antenna 34 is a pencil beam, a signal transmitted by the directional antenna 34 is received in a narrow range in the front direction of the transmission device 100 as in the communication range W2 illustrated in FIG.

  On the other hand, as shown in FIG. 3B, when only the antenna elements 341a in the central horizontal row (one row in the horizontal direction) are turned on, the directional antenna 34 receives the fan beam F2 spreading in the elevation angle direction. Mold. As shown in FIG. 3C, when only the antenna elements 341b in the central vertical row (one row in the vertical direction) are turned on, the directional antenna 34 receives the fan beam F3 spreading in the azimuth direction. Mold. The fan beam is a fan-shaped beam and has a wider scanning angle than the pencil beam. Therefore, when the transmission beam pattern of the directional antenna 34 is a fan beam, the signal transmitted by the directional antenna 34 is received in a range wider than the communication range W2 in the front direction of the transmission device 100 in FIG. As described above, the fan beam has an advantage that the transmission range is wider than that of the pencil beam, but the data transmission capacity is inferior to that of the pencil beam.

  Information indicating such an on / off pattern of the antenna element 341 is recorded in the beam width control table 21 as control information of the antenna element 341, so that the beam pattern is set according to the reception quality. can do.

[Processing flow (before starting content transmission)]
A flow of processing executed by the transmission device 100 (a method for controlling the transmission device) will be described with reference to FIG. FIG. 4 is a flowchart illustrating an example of processing executed by the transmission device 100. Here, for the sake of simplicity, it is assumed that there is only one type of content to be purchased, and the content sample is only one type of content sample. Of course, the user may select content to be purchased from a plurality of types of content, or the user may select a sample to be acquired from a plurality of types of samples.

  In S <b> 1, the transmission control unit 11 detects the mobile terminal 200 that has entered the communication range W <b> 3 of the omnidirectional communication unit 31. In subsequent S <b> 2, the transmission control unit 11 starts communication via the portable terminal 200 and the omnidirectional communication unit 31.

  In S <b> 3, the transmission control unit 11 determines whether or not the mobile terminal 200 requests purchase of content. If it is determined that content purchase is not requested (NO in S3), the process proceeds to S4. If it is determined that content purchase is requested (YES in S3), the process proceeds to S6. Proceed to

  In S4, the transmission control unit 11 determines whether or not the mobile terminal 200 requests transmission of a content sample. If it is determined that the transmission of the content sample is requested (YES in S4), the transmission control unit 11 transmits the sample to the portable terminal 200 via the omnidirectional communication unit 31 (S5). , The process returns to S3. The sample to be transmitted is preferably reproducible only within the communication range W3. Note that the sample transmission can be performed in parallel with the content transmission via the directional communication unit 33, and the samples can be transmitted to a plurality of portable terminals 200 simultaneously. When transmitting simultaneously, you may transmit by a time division. In addition, a plurality of omnidirectional communication units 31 may be provided to transmit samples to a plurality of mobile terminals 200 simultaneously. On the other hand, if it is determined that sample transmission is not requested (NO in S4), the illustrated process ends.

  In S6 (use determination step), the use determination unit 12 determines whether or not there are people in front of the transmission apparatus 100, that is, another user different from the user who requests the purchase of content is using the transmission apparatus 100. It is determined whether or not there is. Specifically, if the proximity detection unit 105 detects that an object (such as another portable terminal) is present on the touch unit 107, the use determination unit 12 determines that a person is lined up and detects it. If not, it is determined that no people are lined up. If it is determined that people are lined up (YES in S6), the process proceeds to S7, and if it is determined that no persons are lined up (NO in S6), the process proceeds to S11.

  In S <b> 7, the transmission control unit 11 guides the user of the mobile terminal 200 to move inside the communication range W <b> 2. For example, the transmission control unit 11 may guide the user by causing the portable terminal 200 or the display unit 104 to display a message that prompts the user to move inside the communication range W2. Here, since the transmission apparatus 100 is being used by another user, when displaying on the display unit 104, the transmission apparatus 100 is displayed at a position where it can be seen even from behind the user in use. Further, another display unit 104 may be provided in addition to the display unit 104 for the user who directly operates the transmission apparatus 100, and this may be arranged and displayed at a position where it can be viewed from behind the user. And the transmission control part 11 starts the communication via the portable terminal 200 and the directional communication part 33. FIG.

  In S <b> 8, the reception quality monitoring unit 13 determines whether or not the reception quality of the signal received from the mobile terminal 200 in the communication via the directional communication unit 33 is equal to or higher than a predetermined value. The predetermined value is set to a value that can ensure a minimum reception quality that allows content to be transmitted via the directional communication unit 33. The process of S8 is repeatedly performed until the reception quality becomes equal to or higher than the predetermined value. If it is determined that the reception quality is equal to or higher than the predetermined value (YES in S8), the process proceeds to S9. When it is determined that the value is equal to or less than the predetermined value (NO in S8), the transmission control unit 11 may guide the user of the mobile terminal 200 to move closer to the transmission device 100.

  In S9, the beam width determination unit 14 determines a beam pattern according to the current reception quality, and the antenna control unit 15 sets the beam pattern of the directional antenna 34 to the beam pattern determined by the beam width determination unit 14. To do. This beam pattern is a beam pattern corresponding to the reception quality read from the reception quality data 22 in the beam width control table 21.

  In S9, the beam pattern may be a fan beam regardless of the reception quality. As a result, the range in which content can be received in the initial stage of content transmission can be widened, so that it is possible to avoid a situation where it becomes difficult to start transmission of the content due to the movement of the position of the mobile terminal 200 or the like. .

  In S10, the transmission control unit 11 notifies the mobile terminal 200 of the beam pattern set in S9 by communication via the directional communication unit 33, and the process proceeds to S21 described later. The mobile terminal 200 notified of the beam pattern has a beam pattern that optimizes the reception quality of content when the beam pattern of the antenna for the mobile terminal 200 to perform directional communication is combined with the notified beam pattern. Set.

  However, S10 is not essential, and this step is not applied when the mobile terminal 200 cannot adjust the directivity or when the mobile terminal 200 includes an omnidirectional antenna. In this case, there is a possibility that the data communication efficiency is somewhat lowered as compared with the case where the communication is optimized by adjusting the directivity as described above. However, if the beam pattern from the transmission apparatus 100 is a narrow beam width pattern such as a pencil beam, the power density is high in the space where the mobile terminal 200 on the receiving side is present, so that reception is higher than in the conventional communication method. Efficiency is obtained.

  Note that the beam width determination unit 14 may determine a beam pattern to be applied by the mobile terminal 200 corresponding to the beam pattern applied by the transmission apparatus 100 and notify the mobile terminal 200 of the beam pattern. In this case, in the beam width control table 21, the beam pattern to be applied by the transmission apparatus 100 and the beam pattern to be applied by the mobile terminal 200 may be associated with the reception quality.

  In S <b> 11, the transmission control unit 11 guides the user of the mobile terminal 200 to hold the mobile terminal 200 over the touch unit 107. For example, the transmission control unit 11 may guide the user by causing the mobile terminal 200 or the display unit 104 to display a message that prompts the user to hold the mobile terminal 200 over the touch unit 107.

  In S <b> 12, the proximity detection unit 105 detects the mobile terminal 200 on the touch unit 107. In S13, the transmission control unit 11 determines that the beam pattern is a pencil beam, and instructs the antenna control unit 15 to set the beam pattern of the directional antenna 34 to the pencil beam. When content is transmitted to the mobile terminal 200 on the touch unit 107, communication may be performed within the communication range W1 (see FIG. 2). In this case, since the mobile terminal 200 basically does not move from the touch unit 107 during communication, content transmission can be completed in a short time by using a pencil beam with a narrow communication range but a large data transmission capacity. it can. Thereafter, the process proceeds to S21.

  The determinations in S3 and S4 are performed by displaying a predetermined UI (UserInterface) screen on the mobile terminal 200 and specifying the content of the user operation of the mobile terminal 200 on the UI screen through communication with the mobile terminal 200. May be. For example, the transmission control unit 11 may display on the mobile terminal 200 a UI screen that allows the user to select whether to purchase content, acquire a sample, or perform neither purchase nor sample acquisition.

[Processing flow (when sending content)]
After setting the beam pattern as described above, content transmission is performed. The flow of processing at the time of content transmission (method for controlling the transmission device) will be described with reference to FIG. FIG. 5 is a flowchart illustrating an example of processing executed by the transmission device 100 when content is transmitted. When the beam pattern is set to a pencil beam, among the processes from S21 to S24 described below, the processes of S21 and S24 are performed, and the processes of S22 and S23 are not executed.

  In S <b> 21 (transmission control step), the transmission control unit 11 starts transmission of content via the directional communication unit 33. Specifically, if YES is determined in S6 of FIG. 4, transmission of content to the portable terminal 200 is started within the communication range W2, and if NO is determined in S6 of FIG. 4, the communication range is started. Transmission of content to the mobile terminal 200 is started within W1. As described above, since the transmission of the content is started regardless of whether or not the transmission device 100 is in use, it is possible to minimize the waiting time of the user regarding the reception of the content. When there is another user who is receiving content from the transmission device 100, the processing of S21 may be started after the transmission of the content to the user is completed, or may be started before the transmission is completed. When transmission is started before transmission is completed, transmission may be performed in time division. In addition, a plurality of directional communication units 33 may be provided and content may be simultaneously transmitted to a plurality of mobile terminals 200. In this case, there is an advantage that an optimum beam pattern can be set for each of the mobile terminal 200 located in the communication range W1 and the mobile terminal 200 located in the communication range W2.

  In S <b> 22, the reception quality monitor unit 13 determines whether or not the reception quality of the signal received from the mobile terminal 200 is greater than or equal to a predetermined value in communication via the directional communication unit 33. Note that the determination can be made by transmitting arbitrary data for measuring the reception quality from the portable terminal 200 to the transmission device 100. This predetermined value is set to a value at which content can be stably transmitted even when switching to the pencil beam. That is, the predetermined value of S22 is larger than the predetermined value of S8 described above. If it is determined in S22 that the reception quality is less than the predetermined value (NO in S22), the process proceeds to S24. If it is determined that the reception quality is equal to or higher than the predetermined value (YES in S22), the process proceeds to S23. move on. In S <b> 22, the determination may be performed by causing the mobile terminal 200 to measure the reception quality of the content and receiving the measurement result from the mobile terminal 200.

  In S23, the transmission control unit 11 instructs the antenna control unit 15 to switch the beam pattern of the directional antenna 34 to the pencil beam. As described above, when the reception quality of the fan beam is sufficiently ensured (YES in S22), the time until the content transmission is completed is shortened by increasing the data transmission capacity by switching the beam pattern to the pencil beam. can do. Thereafter, the process proceeds to S24.

  In S <b> 24, the transmission control unit 11 determines whether or not the transmission of the content requested for purchase from the mobile terminal 200 has been completed. If it is determined that the process has ended (YES in S24), the illustrated process ends. On the other hand, if it is determined that the process has not been completed (NO in S24), the process returns to S22.

  It should be noted that switching to the fan beam may be performed when the reception quality deteriorates during the transmission of the content by the pencil beam. Thereby, even when the position of the mobile terminal 200 moves during content transmission, the content transmission speed decreases, but stable content transmission can be continued.

[Embodiment 2]
In the above embodiment, the reception quality is monitored on the transmission device 100 side, but may be monitored on the portable terminal 200 side. In this case, the control unit of the mobile terminal 200 includes a reception quality monitor unit 13, a beam width determination unit 14, and an antenna control unit 15. Then, according to the reception quality monitored by the reception quality monitor unit 13, the beam width determination unit 14 selects the beam pattern of the directional antenna included in the mobile terminal 200. For example, if the reception quality is less than the first threshold, the pencil beam is selected, if the reception quality is less than the first threshold, if less than the second threshold, the fan beam (in the scanning angle) is selected, and if the reception quality is greater than the second threshold, If present, a fan beam (large scanning angle) may be selected. And the antenna control part 15 controls a directional antenna so that it may become the beam pattern which the beam width determination part 14 selected. Further, the beam width determination unit 14 may notify the transmission apparatus 100 of the selected beam pattern, or may notify the transmission apparatus 100 of the beam pattern to be applied by the transmission apparatus 100 corresponding to the selected beam pattern. Good.

[Modification]
In one aspect of the present invention, the mobile terminal 200 (1) determines whether or not the transmission device 100 is used, (2-1) receives content in the communication range W1 when not used, and (2- 2) When used, control may be performed to receive content within the communication range W2. That is, when the mobile terminal 200 determines that another user is using the transmission device 100 and determines that the use determination unit is not in use, the first communication is performed. If the content is received within the range and the use determination unit determines that the content is in use, the content is within the second communication range extending to a position farther from the transmission device than the first communication range. A reception control unit that receives the content. Whether or not another user is using the transmission device 100 may be determined by communicating with the transmission device 100, or the user of the mobile terminal 200 may select whether or not the transmission device 100 is being used. Good. The reception control unit can transmit the content to the communication range by notifying the transmission device 100 of the communication range in which the content is received.

[Example of software implementation]
The control blocks (particularly, the transmission control unit 11, the use determination unit 12, the reception quality monitoring unit 13, the beam width determination unit 14, and the antenna control unit 15) of the transmission device 100 are logic circuits formed in an integrated circuit (IC chip) or the like. It may be realized by a circuit (hardware) or may be realized by software using a CPU (Central Processing Unit).

  In the latter case, the transmitting apparatus 100 includes a CPU that executes instructions of a program that is software that realizes each function, a ROM (Read Only Memory) in which the above-described program and various data are recorded so as to be readable by a computer (or CPU), or A storage device (these are referred to as “recording media”), a RAM (Random Access Memory) that expands the program, and the like are provided. And the objective of this invention is achieved when a computer (or CPU) reads the said program from the said recording medium and runs it. As the recording medium, a “non-temporary tangible medium” such as a tape, a disk, a card, a semiconductor memory, a programmable logic circuit, or the like can be used. The program may be supplied to the computer via an arbitrary transmission medium (such as a communication network or a broadcast wave) that can transmit the program. Note that one embodiment of the present invention can also be realized in the form of a data signal embedded in a carrier wave, in which the program is embodied by electronic transmission.

[Summary]
A transmission apparatus according to aspect 1 of the present invention is a transmission apparatus (100) that has a function of transmitting content to surrounding portable terminals (200) and that sequentially corresponds to a plurality of users, and the previous user transmits the transmission apparatus. The mobile terminal in the first communication range (communication range W1) when the use determination unit (12) that determines whether or not the device is in use and the use determination unit determines that the device is not in use When the content is transmitted and the use determination unit determines that the content is being used, the second communication range (communication range W2) extends to a position farther from the transmission device than the first communication range. ), A transmission control unit (11) for transmitting content to the portable terminal.

  The user of the portable terminal can receive the content within the first communication range unless the previous user uses the transmission device. In this case, since the previous user does not use the transmission device, the mobile terminal can be as close as possible to the transmission device and the content can be received promptly. Further, even when the previous user is using the transmission device, the content can be received from a position away from the transmission device in the second communication range without waiting for the user to finish using the transmission device. Therefore, there is an effect that the waiting time of the user in content reception can be shortened.

  The transmitting device according to aspect 2 of the present invention is the transmitting apparatus according to aspect 1, in which the antenna that transmits the content according to the reception quality of the signal from the mobile terminal during the transmission of the content within the second communication range. It is good also as a structure further provided with the antenna control part (15) which switches beam width.

  According to said structure, the beam width of an antenna is switched according to the reception quality of the signal from the portable terminal during the transmission of the content within the 2nd communication range. Therefore, even when the position of the mobile terminal changes during content transmission, the content can be transmitted with an appropriate beam width according to the reception quality.

  The transmission device according to aspect 3 of the present invention is the transmission device according to aspect 1 or 2, in which the third communication range (communication range W3) is larger than the first communication range and the second communication range around the transmission device. It is good also as a structure further equipped with the sample transmission part (transmission control part 11) which transmits the sample of the said content to the other portable terminal in ().

  According to said structure, the sample of a content is transmitted to the other portable terminal in the 3rd communication range wider than the 1st communication range and the 2nd communication range. Therefore, the user who wants the sample can receive the sample outside the first communication range and the second communication range without disturbing the user who wants to receive the content. In addition, by allowing the sample to be received around the transmission device, it is possible to attract customers around the transmission device and increase the degree of attention to the transmission device.

  In the transmission device according to aspect 4 of the present invention, in the aspect 3, the sample transmission unit may transmit the sample that can be reproduced only within the third communication range. According to this configuration, since the sample can be reproduced only within the third communication range, the user who wants to reproduce the sample remains within the third communication range. Therefore, it is possible to further enhance the customer attracting effect around the transmission device.

  A control method for a transmission device according to aspect 5 of the present invention is a control method for a transmission device (100) that has a function of transmitting content to surrounding portable terminals (200) and sequentially corresponds to a plurality of users. When the use determination step (S6) for determining whether or not the user is using the transmission device and the use determination step determines that the user is not in use, the mobile phone is used within the first communication range. When the content is transmitted to the terminal and it is determined that the content is being used in the use determination step, the content is within the second communication range extending to a position farther from the transmission device than the first communication range. And a transmission control step (S21) for transmitting content to the portable terminal. According to this aspect, there exists an effect similar to the said aspect 1. FIG.

  The transmission apparatus according to each aspect of the present invention may be realized by a computer. In this case, the transmission apparatus is realized by a computer by operating the computer as each unit (software element) included in the transmission apparatus. A control program for the transmission apparatus and a computer-readable recording medium on which the control program is recorded also fall within the scope of the present invention.

  The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is also included in the technical scope of the present invention. Furthermore, a new technical feature can be formed by combining the technical means disclosed in each embodiment.

100 Transmission Device 11 Transmission Control Unit (Sample Transmission Unit)
12 Use determination part 15 Antenna control part 200 Portable terminal W1 Communication range (1st communication range)
W2 communication range (second communication range)
W3 communication range (third communication range)

Claims (6)

A transmission device having a function of transmitting content to surrounding mobile terminals and sequentially supporting a plurality of users,
A use determination unit that determines whether or not the previous user is using the transmission device;
When the use determining unit determines that the content is not in use, the content is transmitted to the portable terminal within the first communication range, and when the use determining unit determines that the content is in use, the first A transmission device comprising: a transmission control unit configured to transmit content to the portable terminal within a second communication range extending to a position farther from the transmission device than the first communication range.   An antenna control unit that switches the beam width of the antenna that transmits the content according to the reception quality of the signal from the portable terminal during the transmission of the content within the second communication range, The transmission device according to claim 1.   A sample transmission unit configured to transmit a sample of the content to another portable terminal in the third communication range wider than the first communication range and the second communication range around the transmission device; The transmission device according to claim 1, wherein the transmission device is a transmission device.   4. The transmission apparatus according to claim 3, wherein the sample transmission unit transmits the sample that can be reproduced only within the third communication range. A method of controlling a transmitting device that transmits content to surrounding mobile terminals,
A use determination step of determining whether another user different from the user of the mobile terminal is using the transmission device;
If it is determined that the use determination step is not in use, content is transmitted to the mobile terminal within the first communication range, and if it is determined that the use determination step is in use, the first A transmission control step of transmitting content to the portable terminal within a second communication range extending to a position farther from the transmission device than the first communication range.   A control program for causing a computer to function as the transmission device according to claim 1, wherein the control program causes the computer to function as the use determination unit and the transmission control unit.

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