JP2021158577A - Communication device, control method of communication device, and program - Google Patents

Abstract

To efficiently determine a base station to be connected.SOLUTION: A communication device acquires a TDD configuration ratio, which is a ratio between an UL (uplink) communication time and a DL (downlink) communication time in each base station or sub-carrier intervals in OFDM communication in each base station as communication characteristics of each of a plurality of base stations from notification information received from each of the base stations, determines a base station to be connected from among the base stations based on the communication characteristics of each base station, and performs connection processing with the determined base station.SELECTED DRAWING: Figure 1

Description

The present invention relates to a communication device, a control method of the communication device, and a program.

Conventionally, in a communication device, various methods for determining a base station to be connected and communicate with have been proposed. For example, a technique has been proposed in which a communication device determines a base station to be connected based on historical information regarding the position of the communication device (Patent Document 1). Further, a technique has been proposed in which a communication device connects to a base station by a plurality of communication carriers to acquire communication quality, and switches the connection to a base station having high communication quality (Patent Document 2).

Japanese Unexamined Patent Publication No. 2018-011326 Japanese Unexamined Patent Publication No. 2016-140081

In the prior art as described above, when a communication device can connect to a base station in a plurality of networks providing different communication services, the communication device connects to all the base stations and then provides the intended communication service. Had to decide. As a result, it takes time and effort to determine an appropriate base station, and communication resources are wasted.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a technique for efficiently determining a base station to be connected.

As one means for achieving the above object, the communication device according to one aspect of the present invention has the following configuration. That is, the communication characteristics of each base station of the plurality of base stations are obtained from the broadcast information received from each of the plurality of base stations capable of communicating by the TDD (time division duplex) method in the communication device. As the above-mentioned plurality of acquisition means for acquiring the TDD composition ratio which is the ratio of the UL (uplink) communication time and the DL (downlink) communication time in each of the base stations, and the communication characteristics of each of the base stations. It has a determination means for determining a base station to be connected from among the base stations of the above, and a connection processing means for performing connection processing with the determined base station.
Further, the communication device according to another aspect of the present invention has the following configuration. That is, from the broadcast information received from each of a plurality of base stations capable of communicating by the OFDM (Orthogonal Frequency Division Multiplexing) method in the communication device, the communication characteristics of each base station of the plurality of base stations. As a determination, a base station to be connected is determined from the plurality of base stations based on the acquisition means for acquiring the subcarrier interval in the communication in the OFDM system in each base station and the communication characteristics of each base station. It has means and connection processing means for performing connection processing with the determined base station.

According to the present invention, a technique for efficiently determining a base station to be connected is provided.

It is a flowchart of the process executed by a communication device. An example of a network configuration in the embodiment is shown. A configuration example of a communication system is shown. An example of the hardware configuration of the base station is shown. (A) shows a hardware configuration example of the communication device, and (b) shows a functional configuration example of the communication device. It is a flowchart of the determination process of a communication direction characteristic. An example of the relationship between the UL / DL value and the communication direction characteristic is shown. It is a flowchart of the determination process of a delay characteristic. An example of the relationship between the subcarrier interval and the delay characteristic is shown. The communication sequence between the communication device and each base station is shown. An example of the relationship between the base station and the communication characteristics is shown. An example of communication requirements in a communication device is shown. An example of the connection priority table is shown (video viewing function). An example of the connection priority table is shown (live shooting simultaneous distribution function) An example of the connection priority table is shown (remote shooting (camera) function)

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. The following embodiments do not limit the invention according to the claims. Although a plurality of features are described in the embodiment, not all of the plurality of features are essential to the invention, and the plurality of features may be arbitrarily combined. Further, in the attached drawings, the same or similar configurations are given the same reference numbers, and duplicate explanations are omitted.

<Network configuration>
FIG. 2 is a diagram showing a network configuration 200 which is an example of a network configuration in this embodiment. The network configuration 200 includes a communication device 201, four communication systems 202 to 205, a video server 211, and a distribution server 212. The communication system 202 has a base station A1 206 and a base station A2 207, and provides a communication service A. The communication system 203 has a base station B1 208 and provides a communication service B. The communication system 204 has a base station C1 209 and provides a communication service C. The communication system 205 has a base station D1 210 and provides a communication service D. Further, the businesses that provide the communication systems 202 to 205 (communication services A to D) are the businesses A, B, C, and D, respectively. The video server 211 is a transmission source server that transmits image (still image / moving image) data to be viewed by the communication device 201, and is connected to the communication systems 202 to 205 via the Internet. The distribution server 212 is a server capable of providing the data uploaded by the communication device 201 to other devices (for example, simultaneous distribution), and is connected to the communication systems 202 to 205 via the Internet.

The communication device 201 is arranged so as to be able to communicate with the base station A1 206, the base station B1 208, the base station C1 209, and the base station D1 210. The communication device 201 can communicate with the video server 211 and the distribution server 212 by connecting to the base station in any of the communication systems 202 to 205. Examples of the communication device 201 are smartphones, laptops, mobile phones, mobile tablets and the like.

Each of the base stations in FIG. 2 may communicate in a predetermined frequency band by a TDD (Time Division Duplex) method in which uplink and downlink (communication directions from each base station to the communication device 201) communication are switched by time. It is possible. The uplink is a communication link from the communication device 201 to each base station, and the downlink is a communication link from each base station to the communication device 201. Further, the base station can communicate with the communication device 201 by the OFDM (Orthogonal Frequency Division Multiplexing) method. The base station notifies the communication device 201 of TDD switching information including switching timing and switching pattern between the uplink and downlink and information on the subcarrier interval (corresponding to the OFDM symbol length). The communication device 201 can communicate in a TDD manner, and can receive TDD switching information and subcarrier interval information notified from the base station in FIG.

FIG. 3 shows a configuration example of the communication system 202 that provides the communication service A. The communication service control unit 301 controls the entire service of the communication service A. The communication service storage unit 302 stores control information, set values, and communication characteristic information of the communication service A. The gateway 303 is a gateway that connects the communication system 202 to the video server 211 and the distribution server 212 via the Internet. Communication systems 203 to 205 can have the same configuration as in FIG. 3, except that the number of base stations is different.

FIG. 4 shows an example of the hardware configuration of the base station A1 206. The control unit 401 is composed of, for example, one or more CPUs (Central Processing Units), and controls the entire base station A1 206 by executing a program stored in the storage unit 402. The control unit 401 may control the entire base station A1 206 in cooperation with the program stored in the storage unit 402 and the OS (Operating System). The storage unit 402 is composed of ROM, RAM, or one of them, and stores various information such as a program for performing various operations described later and communication parameters for communication. As the storage unit 402, in addition to memories such as ROM and RAM, storage media such as flexible disks, hard disks, optical disks, magneto-optical disks, CD-ROMs, CD-Rs, magnetic tapes, non-volatile memory cards, and DVDs. May be used. The transmission / reception unit 403 performs wireless transmission / reception processing via the antenna 404. The interface unit 405 communicates with the communication service control unit 301 and the gateway 303 in FIG. The base station A2 207, the base station B1 208, the base station C1 209, and the base station D1 210 can also have the same hardware configuration as in FIG.

FIG. 5 shows a configuration example of the communication device 201. FIG. 5A shows a hardware configuration example of the communication device 201. In FIG. 5A, the control unit 501 is composed of, for example, one or more CPUs, and controls the entire communication device 201 by executing a program stored in the storage unit 502. The control unit 501 may control the entire communication device 201 by the cooperation between the program stored in the storage unit 502 and the OS. The storage unit 502 is composed of ROM, RAM, or one of them, and includes various programs for performing various operations described later, communication parameters for communication, functions of the communication device 201, information on applications, and the like. Memorize information. Information on the functions and applications of the communication device 201 includes communication requirements for the functions and applications. As the storage unit 502, in addition to memories such as ROM and RAM, storage media such as flexible disks, hard disks, optical disks, magneto-optical disks, CD-ROMs, CD-Rs, magnetic tapes, non-volatile memory cards, and DVDs. May be used. The transmission / reception unit 503 performs wireless transmission / reception processing via the antenna 504. The display unit 505 performs various displays. The display unit 505 displays, for example, information on the functions and applications of the communication device 201 and displays the settings of the communication device 201. The input unit 506 accepts the input of the function and application information of the communication device 201 and the setting of the communication device 201 by the user. The display unit 505 and the input unit 506 may be configured as one module and function as a GUI (Graphic User Interface).

FIG. 5B shows an example of a functional configuration executed by the control unit 501. The analysis unit 511 analyzes the signal received by the transmission / reception unit 503 and acquires (extracts) information necessary for subsequent processing. The creation unit 512 creates a prioritized list of base stations to be connected (hereinafter referred to as a connection priority table) based on the analysis result by the analysis unit 511 and the information stored in the storage unit 502. The connection processing unit 513 determines (selects) a base station to be connected from the connection priority table created by the creation unit 512, and performs connection processing via communication by the transmission / reception unit 503. The communication characteristic confirmation unit 514 confirms the communication characteristics of the communication service provided by the system in which the base station is located after the connection processing with the base station is completed. The position / attitude acquisition unit 515 acquires the position / attitude information of the communication device 201 based on the data obtained from a GPS sensor (position sensor) or a geomagnetic sensor (orientation sensor) (not shown). The position / attitude information of the communication device 201 can be reflected by the control unit 501 in the communication requirements of the function or application to be executed by the communication device 201. The function execution unit 516 executes a function or an application, and transmits / receives data via the transmission / reception unit 503. In this embodiment, the function and the application are objects to be executed by the communication device 201, and are used as words having the same meaning.

<Processing flow by communication device>
Next, the flow of processing by the communication device 201 will be described. FIG. 1 shows a flowchart of processing executed by the communication device 201. The processing of the flowchart can be executed when the communication device 201 attempts to execute a function or an application by using any of the communication services provided in the communication systems 202 to 205. The flowchart shown in FIG. 1 can be realized by the control unit 501 of the communication device 201 executing the control program stored in the storage unit 502, calculating and processing the information, and controlling each hardware.

In S101, the transmission / reception unit 503 transmits notification information (notification signal) from a base station (either base station A1 206, base station B1 208, base station C1 209, or base station D1 210) with which the communication device 201 can communicate. Receive. The broadcast information includes the above-mentioned TDD switching information (switching timing and switching pattern between uplink and downlink) and subcarrier interval (corresponding to OFDM symbol length).

S102 and S103 are processes for determining the communication characteristics of the base station. In S102, the analysis unit 511 acquires the switching information from the received notification information, and determines the communication direction characteristic of the base station based on the switching information. The processing of S102 will be described later with reference to FIGS. 6 and 7. In S103, the analysis unit 511 acquires the information of the subcarrier interval from the received broadcast information, and determines the delay characteristic of the base station based on the information of the subcarrier interval. The processing of S103 will be described later with reference to FIGS. 8 and 9. The order of processing of S102 and S103 may be reversed or may be performed at the same time.

In S104, the control unit 501 determines whether or not the analysis processing (S102, S103) for the broadcast information received from all the base stations that the communication device 201 can communicate with has been completed. When the analysis processing for the broadcast information received from all the base stations is completed (Yes in S104), the processing proceeds to S105, and if not (No in S104), the processing returns to S101.

In S105, the analysis unit 511 compares the communication characteristics of the base station obtained by the processing of S102 and S103 with the communication requirements of the function or application to be executed by the communication device 201. Subsequently, in S106, the creation unit 512 creates a connection priority table for a plurality of base stations capable of communicating based on the comparison result in S105 and the communication requirements of the function or application to be executed by the communication device 201. .. In S107, the connection processing unit 513 selects the highest base station in the connection priority table created by the creation unit 512, and attempts to establish a connection with the selected base station. Details of the connection establishment process will be omitted. After the connection trial, in S108, the connection processing unit 513 determines whether or not the connection with the selected base station is successful (whether or not the connection is established).

If the connection with the selected base station is successful (Yes in S108), the process proceeds to S109, and the communication characteristic confirmation unit 514 communicates from the connected base station to the communication service provided by the communication system to which the base station belongs. Get the characteristics. For example, the communication characteristic confirmation unit 514 requests the base station connected via the transmission / reception unit 503, and acquires the communication characteristic of the communication service as a response. The communication characteristic information of the communication service is stored in the communication service storage unit 302 in the communication system to which the base station belongs, and the base station acquires the communication characteristic information via the communication service control unit 301 and communicates with the communication device. Send to 201. Subsequently, in S110, the communication characteristic confirmation unit 514 determines whether the communication characteristics of the acquired communication service match the communication requirements of the function or application to be executed by the communication device 201. If the communication characteristics match the communication requirements (Yes in S110), the connection process shown in FIG. 1 ends, and if not (No in S110), the process returns to S107. After the connection process is completed, the function execution unit 516 may transmit / receive data via the transmission / reception unit 503.

If the connection with the selected base station is not successful (No in S108), or if the communication characteristics of the communication service do not match the communication requirements of the function or application to be executed (No in SS110), the processing is performed. Return to S107. In this case, the connection processing unit 513 selects the next base station (the base station listed next to the base station for which the connection was not successful) in the connection priority table created by the creation unit 512, and selects the next base station. Attempts to establish a connection with the base station. After that, the processes of S108 to S110 are performed. In S110, if the communication characteristics of the lowest base station in the connection priority table do not match the communication requirements of the function or application to be executed, the connection processing unit 513 connects to the highest base station in the table. It may be configured to do so. Further, in such a case, the connection processing unit 513 may be configured to connect to a base station having communication characteristics closest to the communication requirements of the function to be executed or the application among the base stations that can communicate. good.

In S104, instead of the analysis end determination for all the base stations that the communication device 201 can communicate with, the analysis end determination for one or more base stations satisfying other conditions may be performed. For example, the analysis end determination may be made for a predetermined number of base stations, one or more base stations having a received signal strength of a certain value or more, and one or more base stations capable of receiving broadcast information.

Next, the process of S102 (communication direction characteristic determination process) of FIG. 1 will be described with reference to FIGS. 6 and 7. FIG. 6 is a flowchart of the communication direction characteristic determination process. In S601, the analysis unit 511 acquires TDD switching information (information including switching timing and switching pattern between uplink and downlink) from the notification information received by the transmission / reception unit 503. In S602, the analysis unit 511 uses the TDD switching information to obtain the uplink (UL) communication time (the number of (sub) frames used for the uplink) and the downlink (DL) communication time (used for the downlink (sub)). ) Number of frames) (TDD composition ratio) is acquired. Specifically, the analysis unit 511 calculates and acquires the value of the UL communication time (referred to as “UL / DL”) with respect to the DL communication time as the TDD composition ratio. Subsequently, in S603, the analysis unit 511 determines whether or not the UL / DL value is equal to or greater than a predetermined first threshold value. In the present embodiment, the predetermined first threshold value is set to 2.

If the UL / DL value is equal to or greater than or equal to the predetermined first threshold value (that is, 2 or more) (Yes in S603), the process proceeds to S604, and if not (No in S603), the process proceeds to S605. In S604, the analysis unit 511 determines that the communication characteristic is suitable for uploading, and stores the result of the determination in the storage unit 502. In S605, the analysis unit 511 determines whether or not the UL / DL value is equal to or less than a predetermined second threshold value. In the present embodiment, the predetermined second threshold value is halved.

If the UL / DL value is equal to or less than the predetermined second threshold value (that is, 1/2 or less) (Yes in S605), the process proceeds to S606, otherwise (No in S605), the process proceeds to S607. move on. In S606, the analysis unit 511 determines that the communication characteristic is suitable for download, and stores the result of the determination in the storage unit 502. In S607, the analysis unit 511 determines that the communication characteristics are for both directions (uplink and downlink), and stores the result of the determination in the storage unit 502. In the example of FIG. 6, the communication characteristics are classified into three categories: upload direction, download direction, and bidirectional, but the number of classifications may be increased as needed. FIG. 7 is a table showing the relationship between the UL / DL value and the communication direction characteristic in the determination of the communication direction characteristic shown in FIG.

Next, the process of S103 of FIG. 1 (delay characteristic determination process) will be described with reference to FIGS. 8 and 9. FIG. 8 is a flowchart of the delay characteristic determination process. In S801, the analysis unit 511 acquires information on the subcarrier interval of the OFDM system from the broadcast information received by the transmission / reception unit 503. The subcarrier interval corresponds to the OFDM symbol length, and the wider the subcarrier interval, the more the followability of high-speed movement can be ensured, which is effective in reducing the delay. In S602, the analysis unit 511 determines whether or not the subcarrier interval is equal to or greater than the predetermined first interval. In the present embodiment, the predetermined first interval is 240 KHz.

If the subcarrier interval is equal to or greater than the predetermined first interval (that is, 240 KHz or higher) (Yes in S802), the process proceeds to S803, otherwise (No in S802), the process proceeds to S804. In S803, the analysis unit 511 determines that the communication characteristic has an ultra-low delay, and stores the result of the determination in the storage unit 502. In S804, the analysis unit 511 determines whether or not the subcarrier interval is equal to or greater than a predetermined second interval. In the present embodiment, the predetermined second interval is set to 60 KHz.

If the subcarrier interval is equal to or greater than the predetermined second interval (that is, 60 KHz or higher) (Yes in S804), the process proceeds to S805, and if not (No in S804), the process proceeds to S806. In S805, the analysis unit 511 determines that the communication characteristic has low delay, and stores the result of the determination in the storage unit 502. In S806, the analysis unit 511 determines that the communication has a normal delay (not a low delay), and stores the result of the determination in the storage unit 502. In the example of FIG. 8, the delay characteristics are classified into three categories: ultra-low delay, low delay, and normal delay, but the number of classifications may be increased as necessary. FIG. 9 is a table showing the relationship between the subcarrier interval and the delay characteristic in the determination of the delay characteristic shown in FIG.

FIG. 10 is a sequence diagram showing a procedure for the communication device 201 to receive broadcast information from a plurality of communicable base stations and establish a connection with the selected base station. The plurality of base stations with which the communication device 201 can communicate are base station A1 206, base station B1 208, base station C1 209, and base station D1 210.

In the M1001, the communication device 201 receives the broadcast information from the base station A1 206 and analyzes the broadcast information to acquire the communication characteristics (communication direction characteristics, delay characteristics) of the base station A1 206 (FIG. 1). Corresponds to the processing of S102 and S103). Similarly, in M1002 to M1004, the communication device 201 receives broadcast information from base station B1 208, base station C1 209, and base station D1 210, respectively, and acquires the communication characteristics of each base station. The broadcast information can include information of companies A, B, C, and D, which are providers of communication systems 202 to 205 (communication services A to D). FIG. 11 shows an example of the relationship between each base station and the communication characteristics acquired by M1001 to M1004.

In the M1005, the communication device 201 determines the connection priority of the base station based on the communication characteristics of each base station obtained in the processes of the M1001 to M1004 and the communication requirements of the functions and applications to be executed by the communication device 201. .. Then, the communication device 201 creates a connection priority table based on the determined order (corresponding to the process of S106 in FIG. 1). FIG. 12 shows an example of communication requirements of a function or application stored in the storage unit 502 of the communication device 201 to be executed by the communication device 201. The communication requirement may be stored in the storage unit 502 of the communication device 201. Further, the communication requirement can be changed by the control unit 501 according to the operating state of the communication device 201 and the operating state of the function or application. Further, the communication requirement can be changed by the control unit 501 according to the position / attitude information of the communication device 201 acquired by the position / attitude acquisition unit 515.

Here, an example of a connection priority table created by the communication device 201 based on the information shown in FIGS. 11 and 12 will be described with reference to FIGS. 13 to 15. FIG. 13 shows a connection priority table created when the function to be executed by the communication device 201 is video viewing (function ID = 1 in FIG. 12). As shown in FIG. 12, the communication requirements for executing the video viewing function are communication direction characteristic = download priority and delay characteristic = normal. The required communication requirements are delay characteristic = normal, but referring to FIG. 11, since there is a base station D1 having higher characteristics such that communication direction characteristic = download direction and delay characteristic = low delay, there is a base station D1. Base station D1 has the highest priority. The base station D1 is followed by a base station A1 having a communication direction characteristic = download direction, a delay characteristic = a normal base station A1, a communication direction characteristic = a bidirectional communication direction, and a delay characteristic = an ultra-low delay base station C1. At the lowest level, the communication direction characteristic = upload orientation, and the delay characteristic = normal base station B1.

FIG. 14 shows a connection priority table created when the function to be executed by the communication device 201 is live shooting simultaneous distribution (function ID = 2 in FIG. 12). As shown in FIG. 12, the communication requirements for executing the function of simultaneous live shooting distribution are communication direction characteristic = upload priority and delay characteristic = normal. Referring to FIG. 11, since there is a base station B1 in which the communication direction characteristic = upload orientation and the delay characteristic = normal, the base station B1 has the highest priority. The base station B1 is followed by a base station C1 having a communication direction characteristic = bidirectional direction and a delay characteristic = ultra-low delay, a base station D1 having a communication direction characteristic = download direction, and a delay characteristic = low delay. At the lowest level, the communication direction characteristic = download direction, and the delay characteristic = normal base station A1.

FIG. 15 shows a connection priority table created when the function to be executed by the communication device 201 is remote shooting (camera) (function ID = 3 in FIG. 12). The remote shooting (camera) is a function (application) in which the communication device 201 functions as a camera and uploads image data obtained by shooting to a controller (not shown). As shown in FIG. 12, the communication requirements for executing the remote shooting (camera) function are communication direction characteristic = upload priority and delay characteristic = low delay. Referring to FIG. 11, since there is a base station B1 in which the communication direction characteristic = upload orientation and the delay characteristic = normal, the base station B1 has the highest priority. The base station B1 is followed by a base station C1 having a communication direction characteristic = bidirectional direction and a delay characteristic = ultra-low delay, a base station D1 having a communication direction characteristic = download direction, and a delay characteristic = low delay. At the lowest level, the communication direction characteristic = download direction, and the delay characteristic = normal base station A1.

Returning to the description of FIG. 10, it is assumed that the communication device 201 creates the connection priority table shown in FIG. 13 when the function to be executed by the communication device 201 in M1005 is video viewing (function ID = 1 in FIG. 12). In the M1006, the communication device 201 attempts to establish a connection by selecting the base station D1 210 at the top of the connection priority table shown in FIG. 13 and transmitting a connection request message to the base station D1 210 (FIG. 13). Corresponds to the processing of S107 in 1). When the base station D1 210 receives the connection request message from the communication device 201, the base station D1 210 transmits a connection acceptance message as a response to the connection request message in the M1007. When the communication device 201 receives the connection acceptance message from the base station D1 210, it can determine that the connection is successful (corresponding to the case of Yes in the process of S108 in FIG. 1).

Subsequently, in M1008, the communication device 201 transmits the communication characteristic information request message of the communication service D provided by the communication system 205 to which the base station D1 210 belongs to the base station D1 210. When the base station D1 210 receives the communication characteristic information request message of the communication service D from the communication device 201, the base station D1 210 returns the communication characteristic information of the communication service D as a response in the M1009. Specifically, the base station D1 210 acquires the information on the communication characteristics of the communication service D stored in the communication service storage unit 302 in the communication system 205 via the communication service control unit 301, and the communication device 201 receives the information. Send. When the communication device 201 receives the information on the communication characteristics of the communication service D (corresponding to the process of S109 in FIG. 1), the communication characteristics of the communication service D in M1010 meet the communication requirements for video viewing (see FIG. 12). (Corresponding to the processing of S110 in FIG. 1). When it is confirmed that the communication characteristics of the communication service D meet the communication requirements for video viewing, the communication device 201 transmits / receives data to / from the base station D1 210. For example, the communication device 201 can send and receive data to and from the video server 211 via the base station D1 210.

In FIG. 10, the notification information received by the communication device 201 in M1001 to M1004 is described as one by one, but when there is a plurality of notification information from each base station, it can be received a plurality of times. .. Further, FIG. 10 shows an example in which the communication device 201 matches the communication characteristics of the communication service D and the communication requirements for the function to be executed. If these do not match, the communication device 201 is listed in the connection priority table. Transmission / reception and processing of messages from M1006 to M1010 are repeated in the order of base stations.

As described above, according to the present embodiment, it is possible to determine a base station capable of providing a communication service suitable for the function or application to be executed before the communication device connects to each base station. Therefore, it is possible to efficiently use communication resources and determine an appropriate base station for connection.

The invention is not limited to the above embodiments, and various modifications and modifications can be made without departing from the spirit and scope of the invention. Therefore, a claim is attached to make the scope of the invention public.

The present invention supplies a program that realizes one or more functions of the above-described embodiment to a system or device via a network or storage medium, and one or more processors in the computer of the system or device reads and executes the program. It can also be realized by the processing to be performed. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

201 Communication device, 511 Analysis unit, 512 Creation unit, 513 Connection processing unit, 514 Communication characteristic confirmation unit, 515 Position / attitude acquisition unit 516 Function execution unit

Claims (10)

It ’s a communication device,
From the broadcast information received from each of a plurality of base stations capable of communicating by the TDD (time division duplex) method, the communication characteristics of each base station of the plurality of base stations are as follows: An acquisition means for acquiring the TDD composition ratio, which is the ratio between the (uplink) communication time and the DL (downlink) communication time,
A determination means for determining a base station to be connected from among the plurality of base stations based on the communication characteristics of each base station, and
A connection processing means for performing connection processing with the determined base station, and
A communication device characterized by having. When the communication requirement required for the function to be executed by the communication device includes that the priority communication direction is UL, the determination means has a UL communication time longer than the DL communication time. When the base station having the above is determined as the base station to be connected and the communication requirement includes that the priority communication direction is DL, the base having the TDD composition ratio whose DL communication time is longer than the UL communication time. The communication device according to claim 1, wherein the station is determined as a base station to be connected. It ’s a communication device,
From the broadcast information received from each of a plurality of base stations capable of communicating by the OFDM (Orthogonal Frequency Division Multiplexing) method, the communication characteristics of each base station of the plurality of base stations are the OFDM in each of the base stations. An acquisition method for acquiring the subcarrier interval in communication by the method,
A determination means for determining a base station to be connected from among the plurality of base stations based on the communication characteristics of each base station, and
A connection processing means for performing connection processing with the determined base station, and
A communication device characterized by having. The determining means is a base station capable of communicating using OFDM with a subcarrier interval wider than a predetermined interval when the communication requirements required by the function to be executed by the communication device include low-delay communication. The communication device according to claim 3, wherein the base station to be connected is determined. Further, it has a means for creating a priority table showing the priority of the base stations to be connected to the plurality of base stations based on the communication characteristics of each base station and the communication requirements.
The determination means determines the base station listed at the top of the priority table as the base station to be connected.
The communication device according to claim 2 or 4, wherein the connection processing means performs connection processing with the determined base station. If the connection processing means does not succeed in connecting to the determined base station, the determining means is listed next to the base station in which the connection was not successful in the priority table. The station is determined as the base station to be connected,
The communication device according to claim 5, wherein the connection processing means performs connection processing with the determined base station. The communication device according to claim 5 or 6, wherein the creating means is listed in the priority table in order from a base station having the communication characteristics that more closely matches the communication requirements. It is a control method for communication devices.
From the broadcast information received from each of a plurality of base stations capable of communicating by the TDD (time division duplex) method, the communication characteristics of each base station of the plurality of base stations are as follows: The acquisition process for acquiring the TDD composition ratio, which is the ratio between the (uplink) communication time and the DL (downlink) communication time,
A determination step of determining a base station to be connected from among the plurality of base stations based on the communication characteristics of each base station, and
A connection processing step for performing connection processing with the determined base station, and
A method for controlling a communication device, which comprises. It is a control method for communication devices.
From the broadcast information received from each of a plurality of base stations capable of communicating by the OFDM (Orthogonal Frequency Division Multiplexing) method, the communication characteristics of each base station of the plurality of base stations are the OFDM in each of the base stations. The acquisition process to acquire the subcarrier interval in communication by the method,
A determination step of determining a base station to be connected from among the plurality of base stations based on the communication characteristics of each base station, and
A connection processing step for performing connection processing with the determined base station, and
A method for controlling a communication device, which comprises. A program for causing a computer to function as the communication device according to any one of claims 1 to 7.

Images