Patent Publication Number: US-2021167638-A1

Title: Wireless terminal apparatus and wireless power transmitter

Description:
TECHNICAL FIELD 
     The present invention relates to a technique such as a wireless power transfer system, a wireless communication system, a wireless terminal apparatus, and a wireless power transmitter. Further, the present invention relates to a technique of a wireless power transfer and wireless communication capable of utilizing electromagnetic waves such as microwaves or millimeter waves. 
     BACKGROUND ART 
     As a wireless power transfer technique, a system for executing wireless power transfer from a wireless power transmitter to a wireless terminal apparatus has been developed. A system that executes wireless power transfer over an access distance has already been realized. In recent years, a system that executes wireless power transfer over a medium distance (for example, about several meters) has also been developed. As a method of the wireless power transfer, there are several methods such as a radio wave transmitting method, an electromagnetic induction method, a magnetic resonance method, or an electric field coupling method, for example. In case of the radio wave transmitting method, wireless power transfer is executed by transmission of electromagnetic waves (for example, microwaves or millimeter waves) from a wireless power transmitter to a wireless terminal apparatus within a medium distance area. 
     As examples of a conventional technique regarding wireless power transfer, Japanese Patent No. 5456380 (Patent document 1), Japanese Patent Application Publication No. 2017-139954 (Patent document 2), and Japanese Patent Application Publication No. 2015-231252 (Patent document 3) are cited. Patent document 1 describes a system for executing wireless power transfer with low output from a wireless power transfer terminal to a wireless terminal apparatus in a wireless communication network. Patent document 2 describes a wireless electric power transmitting system for supplying wireless charging to a device via microwave energy. Patent document 3 describes an electromagnetic induction type wireless power transmitting apparatus. 
     RELATED ART DOCUMENTS 
     Patent Documents 
     Patent document 1: Japanese Patent No. 5456380 
     Patent document 2: Japanese Patent Application Publication No. 2017-139954 
     Patent document 3: Japanese Patent Application Publication No. 2015-231252 
     SUMMARY OF THE INVENTION 
     Problems to be Solved by the Invention 
     In wireless power transfer system that executes wireless power transfer by using electromagnetic waves or a wireless communication system that executes wireless communication (referred to also as “wireless data communication” in order to distinguish it from wireless communication for control) by using electromagnetic waves, both the wireless power transfer and the wireless data communication may be executed. For example, both a wireless power transfer request from a wireless terminal apparatus and a wireless data communication request from the wireless terminal apparatus or a wireless base station may be generated at close ng. In that case, undesired interference may occur between the wireless power transfer and the wireless data communication. As the interference, interference of frequencies of electromagnetic waves and a processing load when the both are processed at the same time are cited, for example. For this reason, there are problems in view of efficiency, reliability, or convenience of a user with respect to the wireless power transfer and the wireless data communication. Further, in a case where a plurality of wireless terminal apparatuses and a plurality of wireless power transmitters exist in an area that accepts a LAN (Local Area Network) or the like, the plurality of wireless power transfers and the plurality of wireless data communications may be mixed (or coexist). Even in that case, there is a problem related to interference. 
     It is an object of the present invention to provide a technique capable of preventing or reducing interference between wireless power transfer and wireless data communication with respect to a technique of the wireless power transfer and the wireless data communication, whereby it is possible to improve efficiency, reliability, and convenience of a user 
     Means for Solving the Problem 
     A representative embodiment of the present invention is a wireless terminal apparatus and a wireless power transmitter that constitute a wireless power transfer system, and is characterized by including a configuration described below. 
     A wireless terminal apparatus according to one embodiment is a wireless terminal apparatus constituting a wireless power transfer system. The wireless power transfer system includes: the wireless terminal apparatus as a target of wireless power transfer; a wireless power transmitter configured to execute the wireless power transfer to the wireless terminal apparatus; and a wireless base station configured to relay wireless data communication of the wireless terminal apparatus. In this case, the wireless base station creates schedule information for preventing or reducing interference regarding the wireless data communication and the wireless power transfer on a basis of grasp of a request of the wireless data communication and a request of the wireless power transfer of the wireless terminal apparatus, and transmits the schedule information to the wireless power transmitter and the wireless terminal apparatus, the schedule information containing allocation of wireless resources to the wireless data communication and the wireless power transfer. The wireless power transmitter executes the wireless power transfer to the wireless terminal apparatus in accordance with the schedule information. The wireless terminal apparatus receives the wireless power transfer from the wireless power transmitter in accordance with the schedule information, and executes the wireless data communication via the wireless base station. 
     A wireless power transmitter according to one embodiment is a wireless power transmitter constituting a wireless power transfer system. The wireless power transfer system includes: a wireless terminal apparatus as a target of wireless power transfer; the wireless power transmitter configured to execute wireless power transfer to the wireless terminal apparatus; and a wireless base station configured to relay wireless data communication of the wireless terminal apparatus. In this case, the wireless base station creates schedule information for preventing or reducing interference regarding the wireless data communication and the wireless power transfer on a basis of grasp of a request of the wireless data communication and a request of the wireless power transfer of the wireless terminal apparatus, and transmits the schedule information to the wireless power transmitter and the wireless terminal apparatus, the schedule information containing al location of wireless resources to the wireless data communication and the wireless power transfer. The wireless power transmitter executes the wireless power transfer to the wireless terminal apparatus in accordance with the schedule information. The wireless terminal apparatus receives the wireless power transfer from the wire less power transmitter in accordance with the schedule information, and executes the wireless data communication via the wireless base station. 
     Effects of the Invention 
     According to the representative embodiment of the present invention, with respect to the technique of wireless power transfer and wireless data communication, it is possible to prevent or reduce interference between the wireless power transfer and the wireless data communication, and this makes it possible to improve efficiency, reliability, and convenience of a user. 
    
    
     
       BRIEF DESCRIPTIONS OF THE DRAWINGS 
         FIG. 1  is a view illustrating a configuration of a wireless power transfer system including a wireless terminal apparatus and a wireless power transmitter according to a first embodiment of the present invention; 
         FIG. 2  is a view illustrating another configuration example of the wireless power transfer system; 
         FIG. 3  is a view illustrating still another configuration example of the wireless power transfer system; 
         FIG. 4  is a view illustrating a configuration example of an area of the wireless power transfer system and a usage scene thereof; 
         FIG. 5  is a view illustrating a first communication system according to the first embodiment; 
         FIG. 6  is a view illustrating a configuration of the wireless terminal apparatus according to the first embodiment; 
         FIG. 7  is a view illustrating a configuration of an antenna switch and the like of the wireless terminal apparatus according to the first embodiment; 
         FIG. 8  is a view illustrating a configuration of the wireless terminal apparatus according to a modification example of the first embodiment; 
         FIG. 9  is a view illustrating a configuration example of appearance of the wireless terminal apparatus according to the first embodiment; 
         FIG. 10  is a view illustrating a configuration example of a cross section of the wireless terminal apparatus illustrated in  FIG. 9 ; 
         FIG. 11  is a view illustrating a configuration of the wireless power transmitter according to the first embodiment; 
         FIG. 12  is a view illustrating a configuration example of appearance of the wireless power transmitter according to the first embodiment; 
         FIG. 13  is an explanatory drawing illustrating a relationship of Line of Sight between the wireless power transmitter and the wireless terminal apparatus according to the first embodiment; 
         FIG. 14  is a view illustrating an example of a state where a user holds the wireless terminal apparatus according to the first embodiment; 
         FIG. 15  is a view illustrating a processing flow of wireless terminal apparatus according to the first embodiment; 
         FIG. 16  is a view illustrating a processing flow of the wireless power transmitter according to the first embodiment; 
         FIG. 17  is a view illustrating a configuration example of a schedule according to the first embodiment; 
         FIG. 18  is a view illustrating a sequence among apparatuses during wireless data communication according to the first embodiment; 
         FIG. 19  is a view illustrating a first sequence among the apparatuses according to the first embodiment; 
         FIG. 20  is a view illustrating a second sequence among the apparatuses according to the first embodiment; 
         FIG. 21  is a view illustrating a third sequence among the apparatuses according to the first embodiment; 
         FIG. 22  is a view illustrating a configuration example of a schedule corresponding to a case of  FIG. 21 ; 
         FIG. 23  is a view illustrating a location managing function according to the first embodiment; 
         FIG. 24  is a view illustrating a second communication system according to a modification example of the first embodiment; 
         FIG. 25  is a view illustrating an example of interference in a wireless power transfer system according to a comparative example; 
         FIG. 26  is a view illustrating a configuration of a wireless power transfer system including a wireless terminal apparatus and a wireless power transmitter according to a second embodiment of the present invention; 
         FIG. 27  is a view illustrating a sequence among apparatuses according to the second embodiment; 
         FIG. 28  is a view illustrating a configuration of a wireless terminal apparatus according to a third embodiment of the present invention; 
         FIG. 29  is a view illustrating a first example of scheduling in a wireless power transfer system including a wireless terminal apparatus and a wireless power transmitter according to a fourth embodiment of the present invention; and 
         FIG. 30  is a view illustrating a second example of the scheduling in the wireless power transfer system including the wireless terminal apparatus and the wireless power transmitter according to the fourth embodiment of the present invention. 
     
    
    
     DETAILED DESCRIPTION OF EMBODIMENTS 
     Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Note that in each of the embodiments, “wireless data communication” indicates wireless communication that is a control target related to interference prevention in a wireless power transfer system. 
     [Problems and The Like] 
     Prerequisite techniques, problems, and the like will be described supplementary. In the wireless power transfer system according to the conventional technique example, for example, as described in Patent document 1, electromagnetic waves having at least one frequency are used at the time of wireless power transfer from a wireless power transmitter to a wireless terminal apparatus. Further, the wireless terminal apparatus executes wireless data communication with a wireless base station by using the electromagnetic waves having the at least one frequency in a case where timing or frequency between these wireless power transfer and wireless data communication match, interference or inefficiency may occur. Interference may cause one to interfere with the other such as a situation that wireless data communication for executing wireless power transfer cannot be executed or a situation that wireless power transfer for executing wireless data communication cannot be executed, for example. Alternatively, interference may cause a situation that efficiency of wireless power transfer is reduced or a situation that efficiency of wireless data communication is reduced. Further, in a case where an apparatus has to process a plurality of wireless power transfers or a plurality of wireless data communications at the same time, there is a possibility to become a situation that a processing load becomes too high. Each of the conventional technique examples does not describe a method of avoiding such a situation or a method of processing the both efficiently. 
     Further, for example, Patent document 3 describes an electromagnetic induction method. In case of such a method, effective electric power cannot be supplied unless a wireless power transmitter and a wireless terminal apparatus are brought close to each other within an area of a predetermined near distance (for example, several centimeters). In a wireless power transfer system using a radio wave transmitting method or the like, a user can carry out wireless power transfer in a state where the wireless terminal apparatus is separated from a location of the wireless power transmitter by a medium distance (for example, several meters), which is worth in view of convenience and the like. In this case, at the time of the wireless power transfer from the wireless power transmitter to the wireless terminal apparatus as a target, there is a possibility of interference with wireless power transfer or wireless data communication executed by another apparatus existing around there. 
     Further, in particular, in a case where wireless power transfer using a millimeter wave band is to be executed, high accuracy is required for a location relationship between a wireless power transmitter and a wireless terminal apparatus due to characteristics of millimeter waves. In a case where there is a shielding object on a straight line connecting the wireless power transmitter to the wireless terminal apparatus, or in a case where a location or a direction of an antenna is not suitable, there is a possibility that the wireless power transfer cannot be realized efficiently. In the conventional technique examples, interference and efficiency related to the wireless power transfer of the millimeter waves have not been considered sufficiently. Note that the millimeter waves (EHF) are electromagnetic waves having a wavelength of 1 to 10 mm and frequency of 30 to 300 GHz, 
     Further, a case where a wireless terminal apparatus includes a communication interface (or a wireless communication interface device) that handles plural types of electromagnetic waves and a case where a wireless power transmitter includes a power transmitter that handles plural types of electromagnetic waves are assumed. As the plural types of electromagnetic waves, microwaves and millimeter waves are assumed, for example. In the conventional technique examples, interference and efficiency when plural types of electromagnetic waves are handled also have not been considered sufficiently. 
     COMPARATIVE EXAMPLE 
       FIG. 25  illustrates a case of interference in a wireless power transfer system according to a comparative example. A narrow-area base station  92 , a wireless power transmitter  93 , and a wireless terminal apparatus  94  are arranged in an area  901 . The narrow-area base station  92  is connected to a wide-area base station  91 . The wireless terminal apparatus  94  includes wireless terminal apparatuses  941  to  943  as an example of a plurality of wireless terminal apparatuses. The wireless terminal apparatus  941  executes wireless data communication C 1 , and receives a wireless power transfer W 1 . The wireless terminal apparatus  942  executes wireless data communication C 2 , and receives a wireless power transfer W 2 . The wireless terminal apparatus  943  executes wireless data communication C 3 , and receives a wireless power transfer W 3 . For example, there is a possibility that interference occurs among these six operations. 
     Note that with respect to a portion of the plurality of wireless data communications (the wireless data communications C 1  to C 3 ), conventionally, scheduling, for example, allocation of different frequencies (also called as “channels”) is generally executed by a wireless base station so that interference does not occur. However, with respect to a portion of the plurality of wireless power transfers (the wireless power transfers W 1  to W 3 ), conventionally, interference including a relationship of the wireless data communications C 1  to C 3  is not fully considered, and scheduling for preventing interference is not executed. 
     Moreover, in the configuration illustrated in  FIG. 25 , it is assumed that two types of electromagnetic waves including microwaves and millimeter wave can be used as electromagnetic waves related to radio waves. In this case, four types of operations including (1) wireless data communication of microwaves, (2) wireless data communication of millimeter waves, (3) wireless power transfer of microwaves, and (4) wireless power transfer of millimeter waves may be generated. There is also a problem such as interference with respect to these operations 
     First Embodiment 
     A wireless power transfer system including a wireless terminal apparatus and a wireless power transmitter according to a first embodiment of the present invention will be described with reference to  FIG. 1  to  FIG. 24 . An outline and basic functions according to the first embodiment are as follows. 
     (1) This wireless power transfer system has a mechanism to execute scheduling in view of interference between wireless power transfer and wireless data communication and the whole efficiency thereof. For example, the wireless base station has a function to execute scheduling. The wireless base station allocates wireless resources (each including a time and a frequency) to the wireless data communication and the wireless power transfer thus requested so that interference is prevented or reduced, and creates a schedule. The wireless terminal apparatus and the wireless power transmitter according to the first embodiment have a function to request scheduling to the wireless base station. Each of the wireless terminal apparatus and the wireless power transmitter transmits information on a state on its own apparatus and a request, and obtains schedule information from the wireless base station. Each of the wireless terminal apparatus and the wireless power transmitter controls execution of the wireless power transfer and the wireless data communication in accordance with the schedule information. 
     (2) In this wireless power transfer system, at the time of scheduling, for example, various kinds of methods such as a method of dividing a time by the wireless power transfer and the wireless data communication, a method of dividing a frequency, a method of separating antennas, or a method of separating types of electromagnetic waves are used. 
     (3) The wireless terminal apparatus according to the first embodiment includes a communication interface that deals with plural types of electromagnetic waves, in particular, millimeter waves and microwaves. The wireless power transmitter according to the first embodiment includes a power transmitter that deals with plural types of electromagnetic waves, in particular, mill meter waves and microwaves. The wireless terminal apparatus according to the first embodiment switches states of an antenna of the communication interface so as to execute power reception of wireless power transfer or wireless data communication in accordance with schedule information. The wireless power transmitter according to the first embodiment switches states of an antenna of the power transmitter so as to execute wireless power transfer in accordance with the schedule information. 
     [Wireless Power Transfer System ( 1 )] 
       FIG. 1  illustrates a configuration outline of a wireless power transfer system according to the first embodiment. In other words, this wireless power transfer system is a wireless communication system. This wireless power transfer system includes a global base station (wide-area base station)  1 , a local base station (narrow-area base station)  2 , a wireless power transmitter  3 , and a wireless terminal apparatus  4 . One or more narrow-area base stations  2 , one or more wireless power transmitters  3 , and one or more wireless terminal apparatuses  4  are provided within a predetermined area  101 . The area  101  is an area dealing with a wireless LAN, such as a home or an office. One or more users respectively uses the wireless terminal apparatus  4  and the like in the area  101 . The wide-area base station  1  and the narrow-area base station  2  are connected by an optical fiber or wirelessly. The narrow-area base station  2 , the wireless power transmitter  3 , and the wireless terminal apparatus  4  are wirelessly connected to each other (illustrated by broken lines). The narrow-area base station  2  may be connected to the wireless power transmitter  3  via optical fibers. The wireless power transmitter  3  is wirelessly connected to the wireless terminal apparatus  4 . The wireless terminal apparatus  4  is a portable information terminal apparatus such as a smartphone or a tablet terminal, for example, and is possessed by a user. 
     This wireless power transfer system includes the wide-area base station  1  and the narrow-area base station  2  as wireless base stations. Each of the wireless base stations is an apparatus that communicates with the wireless terminal apparatus  4  and the wireless power transmitter  3 , and relays wireless data communication of the wireless terminal apparatus  4 . The wide-area base station  1  constitutes a core network of a wireless communication network (or a mobile network), and may be called a macro base station or the like. The wide-area base station  1  is a base station that covers a distance range from several hundred meters to tens of kilometers, for example. The Internet and the like are connected to the wireless communication network. The wireless terminal apparatus  4  and the like are also allowed to execute wire less data communication with a server apparatus on the Internet. 
     The narrow-area base station  2  is connected to the wide-area base station  1  for communication, for example, and corresponds to an apparatus such as an access point or a router, which constitutes a wireless LAN. The narrow-area base station  2  is a base station that covers a distance range from several meters to several tens of meters, for example. The narrow-area base station  2  may be called a small base station, a spot base station, a femto base station, an ultra small base station, or the like in accordance with the radius of an area that can cover wireless communication, and is a generic term including all of them. 
     In the configuration example of  FIG. 1 , the wireless power transmitter  3  and the narrow-area base station  2  are independent from each other, and are installed at locations separated from each other. The wireless power transmitter  3  and the narrow-area base station  2  cooperate with each other by communication. Note that the wireless power transmitter  3  and the narrow-area base station  2  may be arranged at substantially the same location. 
     The wireless power transmitter  3  has a wireless power transfer function for executing wireless power transfer for the wireless terminal apparatus  4 . The wireless power transmitter  3  executes a wireless power transfer W 1  to the wireless terminal apparatus  4 . The wireless power transmitter  3  also has a wireless communication function with the narrow-area base station  2  and a wireless communication function with the wireless terminal apparatus  4 , and executes control communication and the like by using the wireless communication function. 
     The wireless terminal apparatus  4  has a wireless data communication function and a function for receiving wireless power transfer from the wireless power transmitter  3 . The wireless terminal apparatus  4  executes wireless data communication C 1  with another wireless terminal apparatus or the other apparatus via wireless communication with the narrow-area base station  2 . Wireless data communication Ca in a receiving direction and wireless data communication Cb in a transmitting direction are included as the wireless data communication C 1 . The wireless data communication Ca is wireless data communication in the receiving direction to the wireless terminal apparatus  4  via a wireless base station from the outside of the area  101 , for example, another remote wireless terminal apparatus. The wireless data communication Cb is wireless data communication in the transmitting direction to the outside of the area  101 , for example, another remote wireless terminal apparatus from the wireless terminal apparatus  4 . The wireless data communication C 1  is realized by known procedures of establishing a connection, transmitting or receiving data in a connection state, and disconnecting the connection. 
     In this wireless power transfer system, the wireless base station, in particular, the wide-area base station  1  has a scheduling function  102 . In corresponding thereto, the wireless power transmitter  3  has a scheduling request function  103 , and the wireless terminal apparatus  4  has a scheduling request function  104 . The scheduling function  102  is a function to create a schedule including allocation of wireless resources with respect to both wireless power transfer and wireless data communication related to the wireless power transmitter  3  and the wireless terminal apparatus  4 . Each of the scheduling request functions  103  and  104  is a function to transmit information or a request to the scheduling function  102 ; obtain schedule information; manage execution of wireless power transfer and wireless data communication in accordance with the schedule information. This scheduling determines allocation of a time, a frequency, and antennas so that interference of both the wireless power transfer and the wireless data communication is prevented or reduced. 
     [Wireless Power Transfer System ( 2 )] 
       FIG. 2  illustrates another configuration example of the wireless power transfer system. In the wireless power transfer system illustrated in  FIG. 2 , a wireless power transmitter  3  is established at the same location as an integrated type with a narrow-area base station  2 , which cooperates with each other. In other words, functions of the wireless power transmitter  3  and functions of the narrow-area base station  2  are implemented as one device. This device is a wireless base station device with a wireless power transfer function or a wireless power transmitter with a wireless base station function. This one apparatus is described as a wireless base station power transmitter  5 . 
     Further, in the configuration example of  FIG. 2 , a case where a plurality of wireless terminal apparatuses  4 , for example, three wireless terminal apparatuses  41 ,  42 , and  43  exists within the area  101  with respect to one wireless base station power transmitter  5  and they are respectively connected to each other wirelessly is illustrated. Each of the plurality of wireless terminal apparatuses  4  ( 41  to  43 ) is capable of wireless data communication and wireless power transfer with the narrow-area base station  2  (the wireless base station power transmitter  5 ). Each of the plurality of wireless terminal apparatuses  4  ( 41  to  43 ) may mutually execute wireless communication via the narrower-area base station  2  (the wireless base station power transmitter  5 ). The wireless communication is also included in the wireless data communication as a scheduling target. 
     Further, in the configuration example of  FIG. 2 , as wireless data communication, a case where the plurality of wireless terminal apparatuses  4  ( 41  to  43 ) mutually and directly communicates with the other apparatus in the vicinity without going through the wireless base station (the narrow-area base station  2 ) (multiple-apparatus connection data communication, will be described later) is also illustrated. Examples of this communication are illustrated as communications MM 1 , MM 2 , MM 3 . This communication may be realized by short-range wireless communication using an interface such as Bluetooth (registered trademark), for example This type of wireless communication is also included in the wireless data communication as the scheduling target. 
     Further, in the wireless power transfer system in the configuration example of  FIG. 2 , a PC is wirelessly connected to the narrow-area base station  2  and the wireless terminal apparatus  4  within the area  101  as the other device  6 , for example. In this case, the wireless terminal apparatus  4  is capable of wireless data communication CX with the other device  6  (PC). This wireless data communication CX can be included n the wireless data communication as the scheduling target. 
     [Wireless Power Transfer System ( 3 )] 
       FIG. 3  illustrates still another configuration example of the wireless power transfer system as a modification example. In this wireless power transfer system, a plurality (for example, two) of wireless power transmitters  3  ( 31 ,  32 ) is wirelessly connected to one narrow-area base station.  2  within the area  101 . Further, one wireless terminal apparatus  4  is wirelessly connected to the plurality (for example, two) of wireless power transmitters  3  ( 31 ,  32 ). In this case, the wireless terminal apparatus  4  can receive wireless power transfer with any of the wireless power transmitters  3 . Moreover, in still another configuration example, the plurality of wireless terminal apparatuses  4  may be wirelessly connected to each of the wireless power transmitters  3 . 
     [Usage Scene] 
       FIG. 4  shows a configuration example of an area  101  in the wireless power transfer system illustrated in  FIG. 1  and the like and an example of a usage scene. The area  101  is associated with a floor of a company, for example. One or more narrow-area base stations  2  and one or more wireless power transmitters  3  are installed in the area  101 . In the example illustrated in  FIG. 4 , each of five wireless power transmitters  3  is wirelessly connected to one narrow-area base station  2 . Power transfer areas  501  and  502  are provided within the area  101  as power transfer areas. One or more wireless power transmitters  3  are installed in each power transfer area, which is an area or a spot where wireless power transfer is allowed. The required number of wireless power transmitters  3  is installed so that power transfer areas are constituted in all area or a part area of the area  101  in accordance with needs. The wireless power transmitters  3  can be added, removed, or moved in accordance with the needs. A power transferable range of each of the wireless power transmitters  3  is indicated by a circle. This range indicates a range corresponding to a medium distance (about several meters) in a case where wireless power transfer by millimeter waves is executed in a radio wave transmitting method, for example. The user in the area  101  can receive wireless power transfer by appropriately bringing his or her wireless terminal apparatus  4  in a power transfer area as needed. 
     In the present embodiment, one wireless power transmitter  3  ( 3   e ) is installed in the power transfer area  501 . Four wireless power transmitters  3  ( 3   a  to  3   d ) are installed in the power transfer area  502 . In particular, power transferable ranges of the respective wireless power transmitters  3  may be configured so as to overlap with each other like the power transfer area  502 . In case of the power transfer area  502 , the wireless terminal apparatus  4  of the user can receive wireless power transfer so long as the wireless terminal apparatus  4  is within the range of any of the wireless power transmitters  3  ( 3   a  to  3   d ). 
     The user may change an installation location of the wireless power transmitter  3  within the area  101  in accordance with needs. Locations of the narrow-area base station  2  and the wireless power transmitter  3  are set in advance at the time of system installation, and information thereof is manage. In a case where the location of the wireless power transmitter  3  is changed, a location on setting is also updated. For example, the setting of a relative location of the wireless power transmitter  3  with respect to the narrow-area base station  2  is updated. Note that at that time, the narrow-area base station  2  may detect the location of the wireless power transmitter  3  and update the setting, or the wireless power transmitter  3  may detect the location thereof and notify the narrow-area base station  2  of it, thereby updating the setting. 
     As another configuration example, a plurality of wireless power transmitters  3  may be installed at an adjacent and dense location in the power transfer area. Further, a wireless power transmitter capable of a conventional adjacent type wireless power transfer and a corresponding wireless terminal apparatus may be mixed within the area  101 . 
     [Wireless Power Transfer Method] 
     The wireless power transfer system between the wireless power transmitter  3  and the wireless terminal apparatus  4  is not limited. basically. However, the radio wave transmitting method is used particularly in the first embodiment. In the radio wave transmitting method, a medium distance (about several meters) is set as a power-transmittable distance where the wireless power transmitter  3  covers, and wireless power transfer is possible within a range of the distance. In a case where the wireless terminal apparatus  4  exists within this range, it is possible to receive the wireless power transfer. In the radio wave transmitting method, the wireless power transmitter  3  (in other words, a power transmitter) converts electric power into electromagnetic waves, and transmits the electromagnetic waves from an antenna. The wireless terminal apparatus  4  (in other words, a power receiving apparatus) receives the electromagnetic waves by the antenna, converts them into electric power, and uses the electric power, for example, charges a battery. 
     Further, in the first embodiment, microwaves or millimeter waves can be used as the electromagnetic waves in the radio wave transmitting method. The wireless terminal apparatus  4  includes a communication interface that deals with these plural types of electromagnetic waves. The wireless power transmitter  3  includes a power transmitter that deals with the plural types of electromagnetic waves. 
     [Scheduling Function and Scheduling Request Function] 
     Generally, a wireless base station manages and grasps a wireless communication status of a predetermined area (the area  101  in  FIG. 1 ). For this reason, in this wireless power transfer system, the wireless base station executes scheduling related to wireless data communication and wireless power transfer. In the first embodiment, the wide-area base station  1  includes the scheduling function  102  that is a function to execute the scheduling. In another embodiment, the narrow-area base station  2  may include the scheduling function  102 . The wireless terminal apparatus  4  and the wireless power transmitter  3  includes a function (the scheduling request functions  103  and  104 ) to transmit information for reflecting the scheduling and a request thereof to the narrow-area base station  2  and the wide-area base station  1 . 
     In a case where two types of requests of wireless power transfer and wireless data communication are generated in the area  101 , in a case where a wireless power transfer request is generated during execution of wireless data communication, or in a case where a wireless data communication request is generated during execution of wireless power transfer, the wide-area base station  1  executes scheduling by means of the scheduling function  102 . Specifically, as a method of the scheduling, between one or more wireless power transfer and one or more wireless data communication, there is a method of dividing a time, a method of dividing frequency, a method of separating antennas, and the like. A method of combining the respective methods can be executed. 
     The wireless terminal apparatus  4  and the wireless power transmitter  3  according to the first embodiment cause the wireless base station (the narrow-area base station  2  and the wide-area base station to execute scheduling and create a suitable schedule in cooperation with them. This makes it possible to efficiently execute wireless power transfer and wireless data communication as a whole in accordance with the schedule without interference of the wireless power transfer and the wireless data communication. 
     [Scheduling Method ( 1 )—Time Division Separation Method] 
     As a scheduling method, a time division separation method is as follows. 
     ( 1 - 1 ) For example, in  FIG. 1 , in a case where two requests of a request of the wireless power transfer  1  and a request of the wireless data communication C 1  are generated in substantially the same time zone with respect to the wireless terminal apparatus  4 , scheduling is executed as follows. As a first example of a schedule, the wireless terminal apparatus  4  is first caused to execute the wireless power transfer W 1  in a first time, and is next caused to execute the wireless data communication C 1  in a second time. Alternatively, as a second example of the schedule, the wireless terminal apparatus  4  is first caused to execute the wireless data communication C 1  in the first time, and is next caused to execute the wireless power transfer W 1  in the second time. 
     Whether any of the wireless power transfer and the wireless data communication is first to be executed is determined in accordance with types of the wireless power transfer and the wireless data communication at that time, priority or urgency, a state of the wireless terminal apparatus  4  and the like. For example, in a case where a charging state value (a charging rate or the like) of the battery of the wireless terminal apparatus  4  is equal to or less than a threshold value, it is determined that priority is high, and the wireless power transfer is first executed. In a case where the charging state value of the battery of the wireless terminal apparatus  4  is larger than the threshold value, it is determined that priority is low, and the wireless power transfer is executed later. 
     ( 1 - 2 ) Further, for example, in  FIG. 2 , in a case where there are requests of a plurality of wireless power transfers regarding the plurality of wireless terminal apparatuses  4  in substantially the same time zone, scheduling is executed so that a time is divided in the plurality of wireless power transfers. For example, there are the wireless power transfer W 1  to the wireless terminal apparatus  41  and the wireless power transfer W 2  to the wireless terminal apparatus  42 . In that case, as a first example of a schedule, the wireless terminal apparatus  41  is first caused to execute the wireless power transfer W 1  in a first time, and the wireless terminal apparatus  42  is next caused to execute the wireless power transfer W 2  in a second. time. Alternatively, as a second example of the schedule, the wireless terminal apparatus  42  is first caused to execute the wireless power transfer W 2  in the first time, and the wireless terminal apparatus  41  is next caused to execute the wireless power transfer W 1  in the second time. 
     ( 1 - 3 ) Further, in a case where an antenna provided in the communication interface of the wireless terminal apparatus  4  is an antenna that can be shared by wireless power transfer and wireless data communication (referred to as a “shared antenna”), the shared antenna is shared by the wireless power transfer and the wireless data communication, and scheduling can be executed so that a time is divided. The wireless terminal apparatus  4  switches the shared antenna between at the time of the wireless power transfer and at the time of the wireless data communication in accordance with the schedule. The wireless terminal apparatus  4  has a configuration of hardware and software including an antenna switch capable of such switching (will be described later). 
     [Scheduling Method ( 2 )—Frequency Division Separation Method] 
     As the scheduling method, a frequency division separation method is as follows. 
     ( 2 - 1 ) For example, in  FIG. 1 , in a case where two requests of a request of the wireless power transfer and a request of the wireless data communication are generated in substantially the same time zone with respect to a certain wireless terminal apparatus  4 , scheduling is executed so as to use different frequencies as follows. As a first example of a schedule, a first frequency is allocated to the wireless power transfer W 1 , and a different second frequency is allocated to the wireless data communication C 1 . A frequency to be used is selected among available frequencies at that time and allocated. Note that in case of this method, in a case where there is no problem in interference between electromagnetic waves with the frequencies to be used, the wireless power transfer and the wireless data communication using these frequencies may be executed in the same time zone. 
     ( 2 - 2 ) Further, in  FIG. 2 , in a case where there are requests of a plurality of wireless power transfers regarding the plurality of wireless terminal apparatuses  4  in substantially the same time zone, scheduling is executed so that frequencies are divided in the plurality of wireless power transfers. As a first example of a schedule, a first frequency is allocated to the wireless power transfer W 1  of the wireless terminal apparatus  41 , and different second frequency is allocated to the wireless power transfer W 2  of the wireless terminal apparatus  42 . For example, in a case where a plurality of frequencies can be switched in the communication interface of the wireless terminal apparatus  4 , it can be addressed. by switching of frequencies in the communication interface. Alternatively, in a case where a plurality of communication interfaces according to frequencies is provided as the communication interface of the wireless terminal apparatus  4 , it can be addressed by switching of the communication interfaces to be used. 
     [Scheduling Method ( 3 )—Antenna Separating Method] 
     As the scheduling method, an antenna separating method is as follows. The communication interface of the wireless terminal apparatus  4  includes a plurality of available antennas. For example, in  FIG. 1 , in a case where two requests of a request of the wireless power transfer W 1  and a request of the wireless data communication C 1  are generated in substantially the same time zone with respect to a certain wireless terminal apparatus  4 , scheduling is executed so as to use different antennas as follows. As an example of a schedule, a first antenna is allocated to the wireless power transfer W 1 , and a second antenna is allocated to the wireless data communication C 1 . Note that in case of this method, in a case where there is no problem in interference between the antennas to be used, the wireless power transfer and the wireless data communication using the plurality of antennas may be in the same time zone. The wireless terminal apparatus  4  uses an antenna switch and the like to switch the antennas to be used. 
     [Scheduling Method ( 4 )—Millimeter Waves/Microwaves Separating Method] 
     As the scheduling method, a millimeter wave/microwave separating method, that is, a method of separating types of electromagnetic waves (millimeter waves and microwaves) and corresponding communication interfaces between wireless power transfer and wireless data communication is as follows. The communication interface of the wireless terminal apparatus  4  includes a plurality of communication interfaces for which the types of electromagnetic waves to be used (for example, millimeter waves, microwaves) are different from, each other. For example, in  FIG. 1 , in a case where two requests of a request of the wireless power transfer W 1  and a request of the wireless data communication C 1  are generated in substantially the same time zone with respect to a certain the wireless terminal apparatus  4 , scheduling is executed so as to use different types of electromagnetic waves as follows. As an example of a schedule, a communication interface for millimeter waves is allocated to the wireless power transfer W 1 , and a communication interface for microwaves is allocated to the wireless data communication C 1 . 
     [Communication System ( 1 )] 
     Hereinafter, detail s of the first embodiment will further be described.  FIG. 5  illustrates a first communication system according to the first embodiment. The first communication system illustrates an example of a detailed communication system when wireless power transfer and wireless data communication are processed on the basis of scheduling among a wide-area base station  1 , a narrow-area base station  2 , a wireless power transmitter  3 , and a wireless terminal apparatus  4 . In the first communication system, the wide-area base station executes the scheduling. Further, in the first communication system, a wireless power transfer request from the wireless terminal apparatus  4  is transmitted to a wireless base station (the narrow-area base station  2 ). 
     There are one wireless terminal apparatus  4  (whose ID=MT 1 ), one wireless power transmitter  3  (whose ID=SP 1 ), and one narrow-area base station  2  (whose ID=ST 1 ) in an area  101 . Wireless data communication C 1  and wireless power transfer W 1  regarding the wireless terminal apparatus  4  (MT 1 ), which is a target of scheduling, are illustrated. The wireless data communication C 1  is communication from the wireless terminal apparatus  4  (MT 1 ) to another wireless terminal apparatus of the outside or communication from another wireless terminal apparatus of the outside to the wireless terminal apparatus  4  (MT 1 ), for example. The wireless power transfer W 1  is a wireless power transfer from the wireless power transmitter  3  (SP 1 ) to the wireless terminal apparatus  4  (MT 1 ). 
       FIG. 5  illustrates procedures WR 1  to WR 5  as communication procedures regarding a request of the wireless power transfer W 1 . In the procedure WR 1 , the wireless terminal apparatus  4  transmits a wireless power transfer request to the narrow-area base station  2 . In the procedure WR 2 , the narrow-area base station  2  transmits the wireless power transfer request from the wireless terminal apparatus  4  to the wide-area base station  1 . In the procedure WR 3 , the wide-area base station  1  transmits schedule information and the like to the narrow-area base station  2  after scheduling is executed. In the procedure WR 4 , the narrow-area base station  2  transmits the schedule information and the like to the wireless power transmitter  3 . Further, in the procedure WR 5 , the narrow-area base station  2  transmits the schedule information and the like to the wireless terminal apparatus  4 . 
     Procedures CR 1  to CR 5  are illustrated as communication procedures regarding a request of the wireless data communication C 1 . In the procedure CR 1 , the wireless terminal apparatus  4  transmits a request of connection of wireless data communication to the narrow-area base station  2 . In the procedure CR 2 , the narrow-area base station  2  transmits the request from the wireless terminal apparatus  4  to the wide-area base station  1 . In the procedure CR 3 , the wide-area base station  1  transmits schedule information and the like to the narrow-area base station  2  after scheduling is executed. In the procedure CR 4 , the narrow-area base station  2  transmits the schedule information and the like to the wireless power transmitter  3 . Further, in the procedure CR 5 , the narrow-area base station  2  transmits the schedule information and the like to the wireless terminal apparatus  4 . 
     An example of the scheduling is as follows. The wide-area base station  1  executes the latest scheduling according to a situation at that time when the request is received in the procedure WR 2  and when the request is received in the procedure CR 2 . Further, in a case where there are both the request of the wireless power transfer W 1  and the request of the wireless data communication C 1 , the wide-area base station  1  determines a schedule by the time division separation method described above. For example, a first time T 1  and a first frequency F 1  are allocated to the wireless power transfer W 1 . A second time T 2  and a second frequency F 2  are allocated to the wireless data communication C 1 . The wide-area base station  1  transmits schedule information containing such information on allocation (schedule information J 3  and schedule information J 4 ) to the wireless power transmitter  3  and the wireless terminal apparatus  4 . Note that the content of the schedule information J 3  corresponds to the content of the schedule information J 4 . 
     The wireless power transmitter  3  executes the wireless power transfer W 1  for the wireless terminal apparatus  4  with the first time T 1  and the first frequency F 1  in accordance with the obtained schedule information J 3 . In corresponding thereto, the wireless terminal apparatus  4  receives the wireless power transfer W 1  from the wireless power transmitter  3  in accordance with the obtained schedule information J 4 . Further, the wireless terminal apparatus  4  executes the wireless data communication C 1  with the second time T 2  and the second frequency F 2  in accordance with the schedule information J 4 . 
     As described above, in the first communication system, each of the wide-area base station  1 , the narrow-area base station  2 , and the wireless power transmitter  3  grasps states of the wireless power transfer W 1  and the wireless data communication C 1  regarding the wireless terminal apparatus  4  as a target though the scheduling. Then, each apparatus processes the wireless power transfer W 1  and the wireless data communication C 1  in accordance with a schedule. 
     [Wireless Terminal Apparatus ( 1 - 1 )] 
       FIG. 6  illustrates a block configuration of the wireless terminal apparatus  4 . It illustrates a case where this wireless terminal apparatus  4  is a portable information terminal apparatus such as a smartphone. The wireless terminal apparatus  4  includes a processor  401 , a memory  402 , a sensor  403 , a camera  404 , a microphone  405 , a speaker  406 , a display  407 , an LED  408 , a communication interface  410 , an AC-DC converter  421 , a charging control circuit  422 , a battery  423 , an AC adapter  424 , and the like, and they are connected to each other via a bus or the like. The communication interface  410  includes a first communication interface  411 , a second communication interface  412 , and a third communication interface  413 . The communication interface  410  is a wireless communication interface apparatus 
     The battery  423  is fitted to the charging control circuit  422 . The AC-DC converter  421  is connected to the charging control circuit  422 . An antenna switch  71  of the first communication interface  411  is connected to the AC-DC converter  421 . The AC adapter  424  can be connected to the charging control circuit  422  in a case where a remaining amount of the battery  423  (charged electric power) is not sufficient to operate the wireless terminal apparatus  4 . In a state where the AC adapter  424  is connected thereto, electric power supplied from commercial power source can be charged to the battery  423  from the AC adapter  424  via the charging control circuit  422 . 
     Each of antenna switches  71  to  73  is an element for switching an antenna and a circuit to be used in accordance with a schedule and a purpose. Each of the antenna switches  71  to  73  is provided between the corresponding antenna and the corresponding circuit. In the configuration example illustrated in  FIG. 6 , only the antenna switch  71  of the first communication interface  411  among the antenna switches  71  to  73  is connected to the AC-DC converter  421 . Namely, in this configuration, a wireless power transfer when charging to the battery  423  is possible from only the first communication interface  411  (an antenna  61 ). In accordance with a connection state of the antenna switch  71 , AC electric power from the antenna  61  is converted into DC electric power by the AC-DC converter  421 , and is supplied to the charging control circuit  422 . 
     The processor  401  is configured by a CPU, a ROM, a RAM and the like, and executes a control of the whole wireless terminal apparatus  4 . The processor  401  controls each communication interface of the communication interface  410  (antenna switches  71  to  73  and circuit  81  to  83 ). The processor  401  includes a communication controller  401 A, an electric power manager  401 B, an antenna controller  401 C, and a schedule manager  401 D as processing units configured by software program processing or hardware circuit. Programs, various kinds of data, setting information, and the like are stored in the memory  402 . Data obtained by wireless communication (containing schedule information J 4 ) and image data photographed by the camera  404  are stored in the memory  402 , for example. 
     The sensor  403  is known sensor devices including a GPS sensor, a gyro sensor, an acceleration sensor, an electromagnetic compass, an illuminance sensor, and a proximity sensor. The GPS sensor obtains location information of the wireless terminal apparatus  4 . The gyro sensor obtains information regarding inclination, rotation, and a direction of the wireless terminal apparatus  4 . The acceleration sensor obtains information regarding acceleration. The illuminance sensor obtains information regarding brightness. The proximity sensor obtains information regarding a proximity state of objects. The microphone  405  and the speaker  406  are used to input and output audio. The display  407  is a touch panel, for example, and also receives a touch input operation The LED  408  is used for illumination of the camera  404 . Further, although it will be described later, the LED  408  includes an LED used to let the user know a location of the antenna  61  of millimeter waves by means of light emission. 
     The first communication interface  411  is a communication interface that executes wireless communication with the narrow-area base station  2  or the other terminal by using millimeter waves. The second communication interface  412  is a communication interface that executes wireless communication with the narrow-area base station  2  or the other terminal by using microwaves. The third communication interface  413  is a communication interface that executes wireless communication among adjacent apparatuses by Bluetooth in the present embodiment. 
     The first communication interface  411  includes an antenna  61 , an antenna switch  71 , and a circuit  81 . The antenna  61  is an antenna that can transmit and receive by using millimeter waves as electromagnetic wave. The antenna  61  of the first communication interface  411  is basically an array antenna. The antenna  61  can be used as an antenna combined with a lens. The circuit  81  is a circuit such as a wireless IC in which wireless communication interface processing is implemented, and executes processing of transmission and reception regarding wireless communication using millimeter waves on the basis of a control of the processor  401 . The antenna switch  71  is connected between the antenna  61  and the circuit  81 , and is also connected to the AC-DC converter  421 . The processor  401  controls a connection state between the antenna  61  and the circuit  81  by controlling a state of the antenna switch  71 . 
     The second communication  412  includes an antenna  62 , an antenna switch  72 , and a circuit  82 . The antenna  62  is an antenna that can transmit and receive by using microwaves as electromagnetic waves. The circuit  82  executes processing of transmission and reception regarding wireless communication using microwaves on the basis of a control of the processor  401 . The antenna switch  72  is connected between the antenna  62  and the circuit  82 . The processor  401  controls states of the antenna  62  and the circuit  82  by controlling a state of the antenna switch  72 . 
     The third communication interface  413  includes an antenna  63 , an antenna switch  73 , and a circuit  83 . The antenna  63  is an antenna that can transmit and receive by using electromagnetic waves corresponding to Bluetooth. The circuit  83  executes processing of transmission and reception regarding wireless communication of Bluetooth on the basis of a control of the processor  401 . The antenna switch  73  is connected between the antenna  63  and the circuit  83 . The processor  401  controls states of the antenna  63  and the circuit  83  by controlling a state of the antenna switch  73 . 
     In the first embodiment, the antenna  61  of the first communication interface  411  is a shared antenna that can address both wireless data communication and wireless power transfer. With respect to this shared antenna, wireless data communication and wireless power transfer can be switched in accordance with the state of the antenna switch  71 . For example, when the wireless data communication is executed with respect to the first communication interface  411 , it is set to a state where the antenna  61  and the circuit  81  are connected to each other by the antenna switch  71 . For example, the circuit  81  processes information from, the processor  401  to send a transmitting signal to the antenna  61 , and processes a receiving signal from the antenna  61  to send information to the processor  401 . When the wireless power transfer is executed, it is set to a state where the antenna  61  and the AC-DC converter  421  are connected to each other by the antenna switch  71 . In case of wireless power transfer, AC electric power received by the antenna  61  is converted into DC electric power by the AC-DC converter  421 , and is charged to the battery  423  via the charging control circuit  422 . 
     The communication controller  401 A controls protocol processing of a wireless communication interface. The communication controller  401 A determines necessity of wireless data communication to generate a wireless data communication request (=a connection request). 
     The electric power manager  401 B monitors and manages a state such as a remaining amount of the battery  423  and a state of electric power; determines necessity of wireless power transfer on the basis of the state; and generates a request of the wireless power transfer if needed. 
     The antenna controller  401 C controls switching of the antenna switches  71  to  73  in accordance with schedule information J 4  so as to select and use the antenna and the circuit of the communication interface  410 . 
     The schedule manager  401 D stores, in the memory  402 , the schedule information J 4  containing wireless resource allocation obtained from, the narrow-area base station  2  or the wireless power transmitter  3 , and manages it. The schedule manager  401 D controls execution of the wireless data communication and the wireless power transfer in accordance with the schedule information J 4 . 
     [Wireless Terminal Apparatus ( 1 - 2 ) Wireless Communication Method] 
     An example of a wireless communication method and a wireless communication interface corresponding to implementation in the communication controller  401 A and the communication interface  410  of the wireless terminal apparatus  4  is as follows. (1) Wi-Fi (registered trademark), (2) LTE (registered trademark), (3) WiGig (registered trademark), (4) WiMAX (registered trademark), (5) Bluetooth, and (6) 5G NR (New Radio) of 3GPP (3rd Generation Partnership Project). In particular, the WiGig and the New Radio are a communication system corresponding to electromagnetic waves in a millimeter wave band. The first communication interface  411  has implementation that accepts the WiGig or the New Radio. The second communication interface  412  has implementation that accepts the Wi-Fi, the LTE, and the WiMAX. The third communication interface  413  has implementation that accepts the Bluetooth. The third communication interface  413  accepts other wireless communication interface than a mobile network. 
     [Wireless Terminal Apparatus ( 1 - 3 )—Antenna Switch] 
       FIG. 7  illustrates a configuration example regarding an antenna  61 , an antenna switch  71 , and a circuit  81  of a first communication interface  411  in a wireless terminal apparatus  4 . In the present embodiment, an antenna  61 - 1  and an antenna  61 - 2  are provided as two antennas  61  that accepts the millimeter wave band. The circuit (wireless IC)  81  includes an RF IC  81 - 1  (RE: Radio Frequency) and a base band IC  81 - 2 . 
     The antenna switch  71  has eight terminals indicated by numbers # 1  to # 8 . The two terminals # 5  and # 6  are respectively connected to the antennas  61  ( 61 - 1 ,  61 - 2 ). The AC-DC converter  421  (that is, wireless power transfer side) is connected to the two terminals # 1  and # 3 . The RF IC  81 - 1  (that is, wireless data communication side) is connected to the two terminal # 2  and # 4 . The processor  401  (in particular, the antenna controller  401 C) is connected to control terminals that are the two terminals # 7  and # 8 . 
     Connection destinations (# 1 , # 2 , # 3 , and # 4 ) of the switch in the antenna switch  71  are selected by an input of a control signal from, the antenna controller  401 C to the control terminals (# 7 , # 8 ). A table  701  indicates a truth table of the antenna switch  71 . Depending upon whether an input of each of the control terminals (# 7  and # 8 ) is “H” (High) or “L” (Low) in the cable  701 , a wireless power transfer side or a wireless data communication side is selected as the connection destination of the switch, that is the connection destination of the antenna  61 . The input of # 7  is used for switching regarding the antenna  61 - 1  (# 5 ), and the input of # 8  is used for switching regarding the antenna  61 - 2  (# 6 ). For example, in a case where the inputs of (# 7 , # 8 ) are (H, H), (# 1 , # 3 ) are selected as the connection destinations of the antenna  61 - 1 ,  61 - 2 . Namely, both the two antennas are connected to the AC-DC converter  421  (the wireless power transfer side). In case of (L, L), (# 2 , # 4 ) are selected as the connection destinations of the antenna  61 - 1 ,  61 - 2 . Namely, both the two antennas are connected to the RF IC  81 -I (the wireless data communication side). In case of (H, L), the antenna  61 - 1  is connected to the wireless power transfer side, and the antenna  61 - 2  is connected to the wireless data communication side. In case of (L, H), the antenna  61 - 1  is connected to the wireless data communication, and the antenna  61 - 2  is connected to the wireless power transfer. Note that the switch. in the antenna switch can take an off state in accordance with a control. For example, in a case where the switch to which the antenna  61 - 1  is connected is in the off state, it becomes a state where any of the terminals # 1  and # 2  is not connected to the terminal # 5 . In this off state, both the wireless power transfer and the wireless data communication are not executed. 
     The processor  401  (in particular, the schedule manager  401 D) obtains the schedule information J 4  from the narrow-area base station  2  or the wireless power transmitter  3 , and stores it in the memory  402 . The schedule manager  401 D controls execution of the wireless data communication and the wireless power transfer in accordance with the schedule information J 4  of the memory  402  in cooperation with the antenna controller  401 C and the like. In accordance with a control, the antenna controller  401 C gives a control signal to the antenna switch  71 . In accordance with the control, the communication controller  401 A controls an operation of the circuit  81 . In accordance with the control, the electric power manager  401 B controls an operation of the charging control circuit  422 . 
     [Wireless Terminal Apparatus ( 1 - 4 )—Modification Example] 
       FIG. 8  illustrates a configuration of a wireless terminal apparatus  4  according to a modification example with respect to  FIG. 6 . A modification example illustrated in  FIG. 8  has a difference with the configuration illustrated in  FIG. 6  as follows. In this wireless terminal apparatus  4 , two of a first AC-DC converter  421 - 1  and a second AC-DC converter  421 - 2  are provided in parallel as AC-DC converters. In the communication interface  410 , the antenna switch  71  of the first communication interface  411  is connected to the first AC-DC converter  421 - 1 , and the antenna switch  72  of the second communication interface  412  is connected to the second AC-DC converter  421 - 2 . Namely, this configuration allows charging to the battery  423  from either the first communication interface  411  for a millimeter wave band or the second communication interface  412  for a microwave band. 
     In this modification example, each of the antenna  61  of the first communication interface  411  and the antenna  62  of the second communication interface  412  is a shared antenna that can accept both. wireless data communication and wireless power transfer. With respect to this shared antenna, the wireless data communication and the wireless power transfer can be switched in accordance with states of the antenna switches  71 ,  72 . 
     The configuration of the AC-DC converter is not limited to this, and any is possible. These two AC-DC converters can be configured so as to be integrated into and shared one AC-DC converter. However, in case of the shared configuration, the first communication interface  411  accepts he millimeter wave band and the second communication interface  412  accepts a microwave band. For this reason, it is necessary to use a wide band AC-DC converter. 
     [Wireless Terminal Apparatus ( 1 - 5 )—Appearance] 
       FIG. 9  illustrates a configuration example regarding appearance of the wireless terminal apparatus  4 , in particular, a configuration example regarding an antenna in case of a smartphone. (A) of  FIG. 9  i illustrates a configuration of a plane (referred to as an “x-y plane”) of a front face s 1  side, which is a side that has a display screen, of a housing of the wireless terminal apparatus  4 , and (B) illustrates a configuration of the plane of a back face s 2  side. An x direction corresponds to a short side, and a y direction corresponds to a long side. A display screen  900  of the touch panel that is the display  407  is provided on the front face s 1  as a main rectangular area. A home button  903 , an in camera  404 - 1  (in particular, a lens unit) of the camera  404 , the speaker  406 , and the like are provided in a frame area that is provided outside the display screen  900  on the front face s 1 . The microphone  405  and the like (not illustrated in the drawing) is provided in the vicinity of a side face of the housing. An out camera  404 - 2  (in particular, a lens unit) of the camera  404 , and the like are provided on the back face s 2 . 
     Further, although they are illustrated by a broken line, the antennas  62  ( 62 - 1 ,  62 - 2 ) of the second communication interface  412  for a microwave band are provided in the housing of the wireless terminal apparatus  4 . In the present embodiment, the two antennas  62 - 1 ,  62 - 2  are provided at upper and lower locations of the long side (the y direction) in the frame area in a plane view of the front face s 1  and the back face s 2  of the housing. In particular, the antenna  62 - 1  at the upper side is an antenna that accepts the Wi-Fi, and the antenna  62 - 2  at the lower side is an antenna that accepts the LTE and the New Radio. 
     Further, the antennas  61  ( 61 - 1  to  61 - 4 ) of the first communication interface  411  for the millimeter wave band are provided within the housing of the wireless terminal apparatus  4  in a state where a part thereof is exposed to the front face s 1  and the back face s 2 . In the present embodiment, total four antennas  61 - 1  to  61 - 4  are particularly provided as an exposed antenna unit at right and left locations of upper and lower sides in the long side (the y direction) of the frame area. Specifically, the antenna  61 - 1  is provided at an upper right location of the front face s 1 ; the antenna  61 - 2  is provided at a lower left location of the front face s 1 ; the antenna  61 - 3  is provided at an upper right location of the back face s 2 ; and the antenna  61 - 4  is provided at a lower left location of the back face s 2 . 
       FIG. 10  illustrates a part of a cross section (referred to as an “x-z plane”) of an A-A line at the lower side of the front face s 1  illustrated in (A) of  FIG. 9 . The antennas  61  ( 61 - 2 ,  62 - 4 ) for the millimeter wave band are respectively implemented at the front face s 1  side and the back face s 2  side on a substrate  1001  within the housing of the wireless terminal apparatus  4 . Each of the antennas  61  is configured by components such as an antenna element  611 , an LED element  612  (a part of the LED  408 ), or an optical guiding part  613 . For example, the antenna  61 - 2  of the front face s 1  includes an antenna element  611 - 2 , an LED element  612 - 2 , and an optical guiding part  613 - 2 . The antenna  61 - 4  of the back face s 2  includes an antenna element  611 - 4 , an LED element  612 - 4 , and an optical guiding part  613 - 4 . 
     The optical guiding part  613  is transparent, and guides light emission of the LED element  612  to emit the light to the outside from a region where a part is exposed from the front face s 1  or the back face s 2  (that is, the location of the antenna unit illustrated in  FIG. 9 ). The respective components are arranged so that the optical guiding part  613  overlaps the upper side of the antenna element  611  in a thickness direction (a z direction) of the housing. A surface of the optical guiding part  613  exposes so as to become substantially the same surface as the front face s 1  or the back face s 2 . 
     When the antenna  61  for the millimeter wave band is used, for example, the processor  401  controls the LED element  612  so as to emit light during wireless power transfer. This causes the optical guiding part  613  of the antenna  61  on the front face s 1  or the back face s 2  to emit light. A location of the optical guiding part  613  corresponds to a location of the antenna element  611 . This makes it possible to easily let the user know the location of the antenna  61  for millimeter waves (the antenna unit) by means of light. The antennas  61  ( 61 - 1 ,  61 - 3 ) of the upper side portion are also configured in the similar manner. 
     [Wireless Power Transmitter ( 1 - 1 )] 
       FIG. 11  illustrates a block configuration of the wireless power transmitter  3 . The wireless power transmitter  3  includes a processor  301 , a memory  302 , a sensor  303 , a camera  304 , a display  307 , an LED  308 , a communication interface  310 , a first power transmitter  311 , a second power transmitter  312 , a power source control circuit  321 , a power source  322 , and the like. 
     The processor  301  is configured by a CPU or the like, and executes a control of the whole wireless power transmitter  3  to control power transmission (that is, transmission of electromagnetic waves during wireless power transfer. During the wireless power transfer, the processor  301  controls to supply electric power to the power transmitters (the first power transmitter  311 , the second power transmitter  312 ) from the power source  322  via the power source control circuit  321 . The processor  301  includes, as processing units performed by program processing or the like, a communication controller  301 A, a power transmission controller  301 B, a schedule manager  301 C, and a terminal information manager  301 D. 
     The communication interface  310  corresponds to a wireless communication interface device for executing wireless communication with the narrow-area base station  2  or the wireless terminal apparatus  4 . The communication interface  310  includes an antenna  311 A, an antenna switch  311 B, and a circuit (wireless IC)  311 . The first power transmitter  311  executes wireless power transfer by a millimeter wave band. The second power transmitter  312  executes wireless power transfer by a microwave band. Each of the power transmitters includes an antenna, an antenna switch, a circuit, and the like. The first power transmitter  311  includes an antenna  311   a , an antenna switch  311   b , and a circuit  311   c . The second power transmitter  312  includes an antenna  312   a , an antenna switch  312   b , and a circuit  312   c.    
     The communication controller  301 A controls wireless communication of the communication interface  310 . The power transmission controller  301 B controls wireless power transfer by the power transmitters (the first power transmitter  311 , the second power transmitter  312 ). The schedule manager  301 C stores, in the memory  302 , the schedule information J 3  obtained from the narrow-area base station  2 , and manages it. The schedule manager  301 C controls execution of the wireless power transfer in accordance with the schedule information J 3  in cooperation with the respective units. The terminal information manager  301 D obtains terminal information JT from the wireless terminal apparatus  4  to store it in the memory  302 , and grasps and manages a state of the wireless terminal apparatus  4  on the basis of the terminal information CT and the like. 
     [Wireless Power Transmitter ( 1 - 2 )] 
       FIG. 12  illustrates a configuration example of appearance of the wireless power transmitter  3 . (A) of  FIG. 12  illustrates the configuration in a perspective view, (B) thereof illustrates the configuration in a plane view from a vertically upper side. A schematically triangular prism-shaped antenna unit  331  is provided in the wireless power transmitter  3  with respect to a column  330  that is a body thereof. An antenna  362  that is a microwave antenna that accepts a microwave band is provided on vertex faces of the column  330  and the antenna unit  331 . The antenna  362  has a disk shape, for example. This antenna  362  corresponds to the antenna  312   a  of the second power transmitter  312  illustrated in  FIG. 11 . 
     Further, antennas A 1 , A 2 , and A 3  are provided on three side surfaces of the triangular prism of the antenna unit  331  as three antennas  361  each of which is a millimeter wave antenna that accepts a millimeter wave band. These antennas  361  (A 1  to A 3 ) correspond to the antenna  311 A of the first power transmitter  311  illustrated in  FIG. 11 , and each of the antennas  361  (A 1  to A 3 ) is configured by an array antenna. Namely, although it is not illustrated, a plurality of small antennas (array antenna elements) is arranged on a surface of the antenna A 1 , for example. 
     In (B), the respective antennas A 1  to A 3  of the antennas  361  are respectively directed to directions, in the present embodiment, directions d 1  to d 3  obtained by dividing 360 degrees in a horizontal direction into three. A direction of the antenna  361  and a direction of each of the side surfaces mean a direction perpendicular to the face. Further, by configuring the antenna unit  331  so as to be capable of rotating with respect to the column  330 , it becomes possible for the user to adjust the directions of the three side surfaces of the antenna  361 . 
     Further, in the present embodiment, as illustrated in (A) of  FIG. 12 , cameras  304  ( 304 - 1  to  304 - 3 ) are provided on the surfaces of the antennas  361  (A 1  toA 3 ). For example, each of the cameras  304  (in particular, lens units) is provided at a position near an upper side of each of the side surfaces, the position avoiding the corresponding array antenna element. A photographing direction of each of the cameras  304  (that is, an optical axis of each of the lens units) is the same as the direction d 1  to d 3  of the corresponding antenna A 1  to A 3  and the corresponding side surface. The wireless power transmitter  3  can grasp, on the basis of an image of the camera  304 , existence and the location (in particular, the positions of the antenna  61  described above) of the wireless terminal apparatus  4  that is a target of the wireless power transfer. In particular, the wireless power transmitter  3  can grasp whether there is the antenna  61  of the wireless terminal apparatus  4  within a predetermined range centered on any of the directions (the directions d 1  to d 3 ) of the antenna  361  (A 1  to A 3 ) or not and whether there is no shielding object in the direction or not. 
     The configuration of the wireless power transmitter  3  is not limited to the configuration example described above, and any configuration example is possible. For example, the wireless power transmitter  3  may be configured so as not to include the cameras  304 . Further, for example, the antennas  361  and the antenna unit  331  may be configured so as to have four or more side surfaces and four or more directions, or may be configured so as to have two or less side surface(s) and two or less direction (s). Further, for example, the position of each of the cameras  304  may be a central position of the surface of each of the antennas  361 , or may be the other position of the surface of each of the antennas  361 . 
     [Millimeter Wave Wireless Power Transfer and Relationship of Line of Sight ( 1 )] 
       FIG. 13  illustrates an example of a location relationship between the wireless power transmitter  3  and the wireless terminal apparatus  4  in a case where wireless power transfer using millimeter waves is executed. (A) of  FIG. 13  illustrates an outline in a perspective view, in particular, illustrates a “relationship of Line of Sight (LOS)” between the antenna  361  for a millimeter wave band (for example, the antenna A 1 ) of the wireless power transmitter  3  and the antenna  61  for the millimeter wave band of the wireless terminal apparatus  4 . In a space, a rough location of the wireless power transmitter  3  is set to a location P 3 , and a rough location of the wireless terminal apparatus  4  is set to a location P 4 . A distance between the location P 3  and the location P 4  is several meters or shorter. 
     In the present embodiment, the antenna A 1  of the wireless power transmitter  3  and the antennas  61  ( 61 - 1 ,  61 - 2 ) on the front face s 1  of the wireless terminal apparatus  4  are disposed so as to roughly face each other. A line E 1  is a line connecting the antenna A 1  to the antenna  61 - 1 , and a line E 2  is a line connecting the antenna A 1  to the antenna  61 - 2 . In a case where such a direction of the line between the antennas is within a predetermined range sufficiently close to the direction d 1  of the antenna A 1 -, it is possible to execute the wireless power transfer using the millimeter wave efficiently. In a case where such a direction of the line between the antennas is outside the predetermined range centered on the direction d 1  of the antenna A 1 , the wireless power transfer cannot be executed efficiently. Further, in a case where there is a shielding object OB on the line between the antennas, the millimeter waves are shielded, whereby the wireless power transfer cannot be executed efficiently or it becomes impossible to execute the wireless power transfer. 
     (B) of  FIG. 13  illustrates an arrangement example when viewed from a vertically upper side by overlooking. In particular, a case where the line E 1  between the antennas substantially coincides with the direction d 1  of the antenna A 1  is illustrated. In this case, in particular, the most efficient wireless power transfer is possible by using the antenna  61 - 1  corresponding to the line E 1 . Even in a case where the antenna  61 - 2  corresponding to the line E 2  is used, sufficiently efficient wireless power transfer is possible. 
     Further, in an arrangement example illustrated in (C) of  FIG. 13 , in particular, a case where there is no line that forms a “relationship of Line of Sight” by which efficient wireless power transfer is possible with respect to the direction d 1  of the antenna A 1  is illustrated. A direction perpendicular to the front face s 1  of the wireless terminal apparatus  4  is indicated by a direction Ds 1 , and a direction perpendicular to the back face s 2  thereof is indicated by a direction Ds 2 . A direction of the antennas  61 - 1 ,  61 - 2  on the front face s 1  is the same as the direction Ds 1 . A direction of the antennas  61 - 3 ,  61 - 4  of the back face s 2  is the same as the direction Ds 2 . In accordance with a state of the direction (or posture) of the wireless terminal apparatus  4 , it becomes a state where a difference between the direction d 1  of the antenna A 1  and any of the directions Ds 1 , Ds 2  of the wireless terminal apparatus  4  is large. For that reason, a good “relationship of Line of Sight” cannot be formed. 
     As described above, in particular, in a case where wireless data communication or wireless power transfer is executed by using electromagnetic waves in the millimeter wave band, it is important that the wireless base station or the wireless power transmitter  3  and the wireless terminal apparatus  4  has a “relationship of Line of Sight”. Namely, in a case where transmission and reception of millimeter waves on a line connecting the wireless power transmitter  3  to the wireless terminal apparatus  4  is considered, for example, the “relationship of Line of Sight” indicates a state where no object that shields the millimeter waves intervenes on the straight line. Further, the “relationship of Line of Sight” indicates a state where a difference between the direction of the antenna of the wireless power transmitter  3  and the direction of the antenna of the wireless terminal apparatus  4  is sufficiently small. Further, the “relationship of Line of Sight” indicates a state where the antenna of the wireless power transmitter  3  and the antenna of the wireless terminal apparatus  4  ideally face each other in a state where there is no shielding object. 
     [Millimeter Wave Wireless Power Transfer and Relationship of Line of Sight ( 2 )] 
       FIG. 14  illustrates an example of a state when the user holds and operates the wireless terminal apparatus  4  illustrated in FIG.  9  by his or her hand. Electromagnetic waves in the millimeter wave band are significantly attenuated compared with electromagnetic waves of the microwaves. For that reason, when the wireless power transfer in the millimeter wave band is executed, it is desirable that the antenna  61  for the millimeter wave band is disposed so as not to be hidden by the hand or body of the user when viewed from the antenna  361  of the wireless power transmitter  3 . Further, the electromagnetic waves in the millimeter wave band has higher straightness compared with the electromagnetic waves of the microwaves. In other words, a directional characteristic in the direction is stronger. For that reason, in order to execute efficient wireless power transfer, high accuracy is requested with respect to a location relationship for the wireless power transfer by the millimeter waves, that is, the location of each of the antennas  61 ,  361 . 
     In the example of the state illustrated in  FIG. 14 , when the user holds the wireless terminal apparatus  4  by his or her left hand, the antennas  61  ( 61 - 3 ,  61 - 4 ) for the millimeter waves on the back face s 2  become a state where they are exposed without being hidden by his or her hand. In other words, the locations of the antennas  61  are designed so that the corresponding antenna is hardly hidden in such a handheld state. In this handheld state, the antenna  61  can form the relationship of Line of Sight with the antenna  361  ( FIG. 13 ) of the wireless power transmitter  3 . 
     Further, as in the present embodiment, in a case where a plurality of antennas, in particular, the antennas  61  for the millimeter waves are configured so as to be provided at a plurality of different positions in a housing of the wireless terminal apparatus  4 , a method of separating the antennas to be used can be applied at the time of scheduling. In other words, the electromagnetic waves to be used are spatially separated by separation of the antennas in this method. This makes it possible to prevent or reduce interference between the electromagnetic waves. For example, in a case where a certain wireless terminal apparatus  4  requires to execute both wireless data communication using millimeter waves and wireless power transfer using millimeter waves, the following can be executed as an example of scheduling. Namely, one antenna (for example, the antenna  61 - 3 ) is allocated for the wireless data communication, and another antenna (for example, the antenna  61 - 4 ) is allocated for the wireless power transfer. In this case, it is also possible to execute the wireless data communication and the wireless power transfer in parallel at the same time by using these antennas. 
     [Wireless Terminal Apparatus—Processing Flow] 
       FIG. 15  illustrates a processing flow related to a control of charging of the battery  423  in the wireless tel apparatus  4 . The flow illustrated in  FIG. 15  includes Steps S 401  to S 414 . Hereinafter, the processing flow will be described in the order of Steps. The present processing flow corresponds to a function that automatic charging can be executed by using wireless power transfer when the remaining amount of the battery  423  becomes low. As a result, even in a case where the user forgets to charge the battery  423  via the AC adapter  424 , the battery  423  can be charged automatically if the wireless terminal apparatus  4  exists within the area of the wireless power transmitter  3 . 
     At S 401 , the electric power manager  401 B ( FIG. 6 ) of the wireless terminal apparatus  4  monitors a terminal voltage of the battery  423  via the charging control circuit  422 , and reads out its terminal voltage value (hereinafter, referred to as “VB”). At S 402 , the electric power manager  401 B uses a threshold value Vth 1  and a threshold value Vth 2  (Vth 1 &gt;Vth 2 ), which are set in advance, regarding the terminal voltage value VP to determine the magnitude of the terminal voltage value VP at that time with respect to each of their threshold values. In a case where it is determined that the terminal voltage value VP is smaller than the threshold value Vth 1 (Y) (VP&lt;Vth 1 , the processing flow proceeds to S 403 . At S 403 , the electric power manager  401 B executes warning display on the display  407 . The warning display is display of information for prompting the user to carry out charging, such as “Please charge the battery”, for example. Note that an audio output may be used similarly. In a case where the electric power manager  401 B determines at S 404  that the AC adapter  424  is connected to the battery  423  within a predetermined time from, the warning display (Y), the processing flow proceeds to S 405 . In a case where the electric power manager  401 P determines at S 404  that the AC adapter  424  is not connected to the battery  423  therewithin (N), the processing flow proceeds to S 406 . At S 405 , the electric power manager  401 B starts to charge the battery  423  via the AC adapter  424  and the charging control circuit  422 . 
     At S 406 , the electric power manager  401 B reads out the terminal voltage value VB of the battery  423  again. In a case where the electric power manager  401 B determines at S 407  that the terminal voltage value VB is smaller the threshold value Vth 2  (Y) (VP&lt;Vth 2 ), the processing flow proceeds to S 408 . At S 408 , the electric power manager  401 B executes warning display on the display  407 . The warning display is display of information indicating execution of automatic charging, such as “Charging of battery is carried out”, for example. 
     At S 409 , the electric power manager  401 B transmits a wireless power transfer request, which is a charging request, to the narrow-area base station  2 . At S 410 , the electric power manager  401 B receives authorization of wireless power transfer from the narrow-area base station  2 . At S 411 , the schedule manager  401 D receives the schedule information J 4  from the narrow-area base station  2 . At S 412 , the schedule manager  401 D transmits schedule receipt notification to the narrow-area base station  2 . At S 413 , the antenna controller  401 C switches, in accordance with the schedule information J 4 , the antenna switch  71  so that the antenna  61  of the first communication interface  411  is connected to the AC-DC converter  421  at a charging side (wireless power transfer side), for example. At S 414 , the electric power manager  401 B executes charging of the battery  423  on the basis of electric power received from the antenna  61  via the AC-DC converter  421  and the charging control circuit  422 . 
     [Wireless Power Transmitter—Processing Flow] 
       FIG. 16  illustrates a processing flow related to a control of the wireless power transfer n the wireless power transmitter  3 . The flow illustrated in  FIG. 16  includes Steps S 301  to S 303 . Hereinafter, the processing flow will be described in the order of Steps. At S 301 , the wireless power transmitter  3  confirms whether a wireless power transfer request from the wireless terminal apparatus  4 , the narrow-area base station  2  or the wide-area base station  1  is received or not. In a case where it is confirmed that the wireless power transfer request is received (Y), the processing flow proceeds to S 302 . At S 302 , the wireless power transmitter  3  obtains the terminal information JT regarding the wireless terminal apparatus  4 , which becomes a target by the wireless power transfer request. Alternatively, the wireless power transmitter  3  refers to the terminal information JT that has already been obtained in the memory  302 . At S 303 , the wireless power transmitter  3  determines whether wireless power transfer to the wireless power transmitter  3  as a target can be executed or not on the basis of the wireless power transfer request and the terminal information JT. In a case where the wireless power transfer request is authorized, the wireless power transmitter transmits authorization of wireless power transfer to the narrow-area base station  2  or the wide-area base station  1 . At S 304 , the wireless power transmitter  3  receives schedule notification (the schedule information J 3 ) from the narrow-area base station  2  or the wide-area base station  1 . The wireless power transmitter  3  stores the obtained schedule information J 3  in the memory  302 . At S 305 , the wireless power transmitter  3  transmits the schedule receipt notification to the narrow-area base station  2  or the wide-area base station  1 . At S 306 , the wireless power transmitter  3  controls a state of each of the power transmitters as preparation for wireless power transfer in accordance with the schedule information J 3 , and transmits wireless power transfer start notification to the narrow-area base station  2  or the wide-area base station  1 . At S 307 , the wireless power transmitter  3  starts wireless power transfer for the wireless terminal apparatus  4 . At S 308 , the wireless power transmitter  3  stops the wireless power transfer for the wireless terminal apparatus  4 , and transmits wireless power transfer end notification to the narrow-area base station  2  or the wide-area base station  1 . 
     [Wireless Resource and Schedule] 
       FIG. 17  illustrates an example of wireless resources and schedule. In a table of  FIG. 17 , wireless resources and schedules are represented by a matrix in which a horizontal axis thereof indicates times (time slots) and a vertical axis thereof indicates channels (frequencies). One cell in the table represents a wireless resource unit. In the present embodiment, a case where there are a channel c 1  (frequency f 1 ) to a channel c 12  (frequency f 12 ) in an area  101  as a plurality of available channels (that is, frequencies) is illustrated. In the present embodiment, a portion of times t 1  to t 12  is illustrated. A plurality of wireless terminal apparatuses  4  (whose IDs=MT 1  to MT 5 ) (for example, five) exist within the area  101 . The following is an example of scheduling. 
     The channel c 1  (the frequency f 1 ) and the channel c 2  (the frequency f 2 ) are allocated to a wireless terminal apparatus MT 1  for wireless data communication (indicated by a dot pattern) the times t 1  to t 12 . Further, the channel c 3  (the frequency f 3 ) and the channel c 4  (the frequency f 4 ) are allocated to a wireless terminal apparatus MT 2  for wireless data communication during the times t 1  to t 6 , and the channel c 3  (the frequency f 3 ) and the channel c 4  (the frequency f 4 ) are allocated to the wireless terminal apparatus MT 2  for wireless power transfer (indicated by a diagonal line pattern) during the times t 7  to t 12 . Further, the channel c 5  (the frequency f 5 ) and the channel c 6  (the frequency f 6 ) are allocated to a wireless terminal apparatus MT 3  for wireless power transfer during the times t 1  to t 12 . Further, the channel c 7  (the frequency f 7 ) and the channel c 8  (the frequency f 8 ) are allocated to a wireless terminal apparatus MT 4  for wireless power transfer during the times t 1  to t 6 , and the channel c 7  (the frequency f 7 ) and the channel c 8  (the frequency f 8 ) are allocated to the wireless terminal apparatus MT 4  for wireless data communication during the times t 7  to t 12 . Further, the channel c 9  (the frequency f 9 ) and the channel c 10  (the frequency f 10 ) are allocated to a wireless terminal apparatus MT 5  for wireless data communication during the times t 1  to t 6 , and the channel c 11  (the frequency f 11 ) and the channel c 12  (the frequency f 12 ) are allocated to the wireless terminal apparatus MT 5  for wireless terminal apparatus MT 5  for during the times t 7  to t 12 . 
     [Wireless Communication Sequence ( 1 )] 
       FIG. 18  illustrates an example of a sequence of wireless communication in a case where a request of normal wireless data communication is generated. Note that scheduling regarding only wireless data communication (that is, wireless resource allocation) is executed herein. The flow illustrated in  FIG. 18  includes Steps S 11  to S 20  below. 
     At S 11 , the wireless terminal apparatus  4  transmits a connection request, which is a wireless data communication request, to the wide-area base station  1 . The wide-area base station  1  grasps the wireless data communication request. At S 12 , the wide-area base station  1  transmits information on the corresponding connection request to the narrow-area base station  2 . At S 13 , the narrow-area base station  2  transmits the information on the corresponding connection request to the wireless power transmitter  3 . In a case where connection to wireless data communication is authorized at S 14 , the wide-area base station  1  transmits connection authorization notification to the wireless terminal apparatus  4 . Further, at S 15 , the wide-area base station  1  transmits the corresponding connection authorization notification to the narrow-area base station  2 . At S 16 , the narrow-area base station  2  transmits corresponding connection authorization information to the wireless power transmitter  3 . At S 17 , the wireless terminal apparatus  4  transmits connection completion notification to the wide-area base station  1  on the basis of reception of the connection authorization at S 14 . At S 18 , the wide-area base station  1  transmits the corresponding connection completion notification to the narrow-area base station  2 . At S 19 , the narrow-area base station  2  transmits corresponding: connection completion information to the wireless power transmitter  3 . At S 20 , the wireless terminal apparatus  4  executes wireless data communication through the wide-area base station  1 . 
     As described above, the wireless power transmitter  3  and the narrow-area base station  2  obtain and grasp information regarding a request for wireless data communication from the wireless terminal apparatus  4  and a state thereof through the wide-area base station  1 . Note that as examples of the content of normal wireless data communication, a case where the wireless terminal apparatus  4  makes a call to an external wireless terminal apparatus and a case where the wireless terminal apparatus  4  receives a call from an external wireless terminal apparatus are cited. As another example, a case where transmission and reception of data are executed between the wireless terminal apparatus  4  and an external server apparatus is cited. As still another example, the wireless terminal apparatus  4  executes communication with another wireless terminal apparatus  4  or the other device  6  that exist in the vicinity of the wireless terminal apparatus  4  within the area  101  is cited as illustrated in  FIG. 2 . 
     [Wireless Communication Sequence ( 2 )] 
       FIG. 19  illustrates one example of a sequence of wireless communication (hereinafter, referred to as a “first sequence”). The first sequence illustrates a sequence of wireless communication in which the wireless terminal apparatus  4  (whose ID=MT 1 ) that is in a state where connection of the wireless data communication (that is, connection to the wireless communication network) has already been completed as illustrated in  FIG. 18  further receives wireless power transfer from the wireless power transmitter  3  (whose ID=PS 1 ).  FIG. 19  illustrates operations such as control communication among a wireless base station, the wireless power transmitter  3  (PS 1 ), and the wireless terminal apparatus  4  (MT 1 ). Note that the wide-area base station  1  and the narrow-area base station  2  are combined into one and illustrated as a wireless base station. In the first sequence, a case where the wide-area base station  1  executes scheduling and a time division separation method and the like are used will be described as an example. The first sequence includes Steps S 21  to S 32  below. 
     At S 21 , the wireless terminal apparatus  4  is in a wirelessly connected state as illustrated in  FIG. 18 . Namely, a certain wireless resource (for example, frequency F 1 ) has already been allocated to the wireless terminal apparatus  4  for the wireless data communication. At S 22 , the wireless terminal apparatus  4  determines necessity for charging of the battery  423 . In a case where it is determined that there is necessity, the wireless terminal apparatus  4  transmits a wireless power transfer request to the wide-area base station  1  together with terminal information JT thereof. The terminal information JT contains various kinds of information such as an ID, a type, a position, device configuration information, or a state of the wireless terminal apparatus  4 . The device configuration information contains information on a type of each of antennas and the number of antennas in the communication interface  410 , for example. The state includes an electric power state, for example, a charging state of the battery  423 . At S 22 , the wireless terminal apparatus  4  may transmit the wireless power transfer request to the wide-area base station  1  through the narrow-area base station  2 , or may transmit the wireless power transfer request directly to the wide-area base station  1 . 
     At S 23 , the wide-area base station  1  receives and grasps the wireless power transfer request with the terminal information JT, and also transmits the corresponding wireless power transfer request to the wireless power transmitter  3  through the narrow-area base station  2 . At S 24 , in a case where execution of wireless power transfer regarding the received wireless power transfer request is to be authorized, the wireless power transmitter  3  transmits authorization of wireless power transfer to the wide-area base station I through the narrow-area base station  2 . Information on wireless resources available for wireless power transfer of the wireless power transmitter  3  (such as time, frequency, or antennas) may be contained in information on authorization of wireless power transfer. 
     At S 25 , the wide-area base station  1  executes scheduling regarding both wireless power transfer and wireless data communication on the basis of reception of the authorization of wireless power transfer. On the basis of wireless resources that can be used at that time, the wide-area base station  1  creates a schedule (corresponding schedule information) so that interference between the wireless power transfer and the wireless data communication is prevented or reduced. In the present embodiment, the wide-area base station  1  executes the latest scheduling on the basis of the frequency F 1  that the wireless terminal apparatus  4  that has already been connected wirelessly allocates for the wireless data communication and wireless resources such as vadant frequencies at that time. The latest scheduling contains reconsideration of an existing schedule. Information on allocation of the wireless resources for both of the wireless data communication and the wireless power transfer is contained in the schedule information. During the scheduling, wireless resources (including time and frequency) regarding the requested wireless power transfer are allocated on the basis of both importance and priority of existing wireless data communication and importance and priority of the requested wireless power transfer. 
     Specifically, in the present embodiment, the wide-area base station  1  switches the wireless terminal apparatus  4  from a state where wireless data communication is executed to a state where wireless power transfer is executed by the time division separation method and a frequency division separation method. For example, the wide-area base station  1  switches from a state where the second communication interface  412  of the wireless terminal apparatus  4  executes wireless data communication by using the antenna  62  for a microwave band and the frequency F 1  to a state where the first communication interface  411  executes wireless power transfer by using the antenna  61  for a millimeter wave band and frequency F 2  (which is frequency different from the frequency F 1 ). In this case, interference can be prevented by separating the time and the frequency between the wireless data communication and the wireless power transfer. 
     At S 26 , the wide-area base station  1  notifies the wireless terminal apparatus  4  of authorization of wireless power transfer after the wireless resource of the requested wireless power transfer is scheduled. Further, at S 27 , the wide-area base station  1  notifies each apparatus of the wireless terminal apparatus  4 , the narrow-area base station  2 , and the wireless power transmitter  3  of the latest schedule information thus created. Namely, each apparatus receives and grasps the schedule information. The wireless terminal apparatus  4  obtains the schedule information J 4  described above, and the wireless power transmitter  3  obtains the schedule information J 3  described above. At S 28 , each apparatus of the wireless terminal apparatus  4 , the narrow-area base station  2 , and the wireless power transmitter  3  transmits schedule receipt notification to the wide-area base station  1 . The schedule receipt notification is notification of confirming that the schedule information is received. 
     At S 29 , the wireless terminal apparatus  4  executes switching of antenna switches so as to switch a state of the communication interface  410  from the wireless data communication side to the wireless power transfer side in accordance with the schedule information J 4 . Namely, the wireless terminal apparatus  4  executes preparation for executing wireless power transfer. At S 30 , the wireless power transmitter  3  transmits wireless power transfer start notification to the wide-area base station  1  through the narrow-area base station  2  in accordance with the schedule information J 3 , and also transmits it to the wireless terminal apparatus  4 . At S 31 , the wireless power transmitter  3  starts the wireless power transfer with the wireless terminal apparatus  4  in accordance with the schedule information J 3 . The wireless terminal apparatus  4  receives the wireless power transfer from the wireless power transmitter  3  to charge the received electric power to the battery  423 . At S 32 , in a case where the wireless power transfer is ended in accordance with the schedule information J 3 , the wireless power transmitter  3  transmits wireless power transfer end notification to the wide-area base station  1  through the narrow-area base station  2 . The wide-area base station  1  receives the wireless power transfer end notification to grasp a state of each of the apparatuses. Thus, the wireless power transfer and the wireless data communication are scheduled so that the time and frequency to be used are separated. Therefore, interference between the two is prevented. 
     [Wireless Communication Sequence ( 3 )] 
       FIG. 20  illustrates another example of the sequence of wireless communication (hereinafter, referred to as a “second sequence”). In the second sequence, scheduling in the following case is illustrated. A case where there are two wireless terminal apparatuses  4  ( 41 ,  42 ) within a power transferable range of one wireless power transmitter  3  in an area  101  is illustrated. It is assumed that the other wireless terminal apparatus  42  that has already been connected wirelessly generates a wireless power transfer request in a state where one wireless terminal apparatus  41  receiving wireless power transfer at frequency F 1 . The sequence illustrated  FIG. 20  includes Steps S 41  to S 50  below. 
     At S 41 , the wireless terminal apparatus  41  is executing wireless power transfer with the wireless power transmitter  3  in accordance with an existing schedule by allocating the frequency F 1 . Further, the wireless terminal apparatus  42  is in a state where it has already been connected to wireless data communication by allocating predetermined frequency. At S 42 , the wireless terminal apparatus  42  transmits a wireless power transfer request to a wireless base station (a wide-area base station  1 ) on the basis of determination of necessity of charging, and the wide-area base station  1  transmits the corresponding wireless power transfer request to the wireless power transmitter  3  through a narrow-area base station  2 . At S 43 , the wireless power transmitter  3  transmits authorization of wireless power transfer to the wide-area base station  1  through the narrow-area base station  2 . 
     At S 44 , the wide-area base station  1  executes scheduling on the basis of grasp of the wireless power transfer request and the authorization or wireless power transfer. At that time, the wide-area base station  1  creates the latest schedule regarding wireless data communication and wireless power transfer on the basis of a state of allocation of wireless resources to the plurality of wireless terminal apparatuses  4  ( 41 ,  42 ) and a state of vacant wireless resources. Specifically, in the present embodiment, the wide-area base station  1  allocates frequency different from the frequency F 1  of the wireless power transfer of the wireless terminal apparatus  41  in the same time zone, for example, frequency F 2  as a wireless resource for the wireless power transfer of the wireless terminal apparatus  42  during scheduling. The present embodiment is similar to the scheduling of the wireless terminal apparatuses MT 2  and MT 3  illustrated in  FIG. 17 . 
     At S 45 , the wide-area base station  1  transmits the authorization of wireless power transfer to the wireless terminal apparatus  42  and the wireless terminal apparatus  41 . Note that in the present embodiment, the wide-area base station  1  transmits information on the corresponding authorization of wireless power transfer not only to the wireless terminal apparatus  42  that executed the wireless power transfer request, but also to the other wireless terminal apparatus  41 . At S 46 , the wide-area base station  1  transmits schedule notification to the narrow-area base station  2 , the wireless power transmitter  3 , the wireless terminal apparatus  41 , and the wireless terminal apparatus  42 . Note that in the present embodiment, the wide-area base station  1  transmits the corresponding schedule notification not only to the wireless terminal apparatus  42 , but also to the wireless terminal apparatus  41 . The wireless power transmitter  3  obtains schedule information J 3 , while the wireless terminal apparatus  41  and the wireless terminal apparatus  42  obtain schedule information J 4 . 
     At S 47 , each apparatus of the narrow-area base station  2 , the wireless power transmitter  3 , the wireless terminal apparatus  41 , and the wireless terminal apparatus  42  transmits schedule receipt notification to the wide area base station  1 . At S 48 , the wireless terminal apparatus  42  switches the antenna switch so that the antenna is connected to the wireless power transfer side to execute preparation of wireless power transfer. At S 49 , the wireless power transmitter  3  transmits wireless power transfer start notification to the wide-area base station  1  through the narrow-area base station  2 . The wide-area base station  1  transmits the corresponding wireless power transfer start notification to the wireless terminal apparatus  41  and the wireless terminal apparatus  42  through the narrow-area base station  2 . The wireless power transfer start notification at this time is notification that the wireless power transmitter  3  starts wireless power transfer for the wireless terminal apparatus  42  by using the frequency F 2 . 
     At S 50 , the wireless power transmitter  3  ongoingly continues the wireless power transfer to the wireless terminal apparatus  41  by using the frequency f 1 . The wireless power transmitter  3  newly starts wireless power transfer for the wireless terminal apparatus  42  by using the frequency F 2 . The wireless terminal apparatus  42  receives the wireless power transfer at the frequency F 2 , rand charges received electric power to the battery  423 . Then, in a case where each wireless power transfer is ended, the wireless resource is released on the basis of the wireless power transfer end notification. The wireless base station can use the released wireless resource at the time of new scheduling. As described above, in the example of the second sequence, it is possible to prevent interference by separating frequencies of the wireless power transfers for the plurality of wireless terminal apparatuses  4  in the same time zone. 
     Note that the sequence in a case where the narrow-area base station  2  and the wireless power transmitter  3  are separate bodies as illustrated in  FIG. 1  is illustrated in the above. Even in a case where the narrow-area base station  2  and the wireless power transmitter  3  are integrated as the wireless base station power transmitter  5  as illustrated in  FIG. 2 , similar control can be realized. In that case, wireless communication between the narrow-area base station  2  and the wireless power transmitter  3  can be reduced. 
     Further, in the above, the sequence in a case where the wide-area base station  1  executes scheduling has been illustrated. However, even in a case where the narrow-area base station  2  or the wireless base station power transmitter  5  executes scheduling, similar control can be realized. Note that there may be a difference in a scheduling target area between a case where the wide-area base station  1  executes the scheduling and a case where the narrow-area base station  2  executes the scheduling. In a case where the narrow-area base station  2  executes the scheduling, the scheduling target area is limited to the area  101 . In a case where the wide-area base station  1  executes the scheduling, the scheduling target area may be a wider area than the area  101 . 
     In the second sequence, assuming cooperation among the plurality of wireless terminal apparatuses  4 , the method of notifying both the wireless terminal apparatus  41  and the wireless terminal apparatus  42  of the schedule notification and the wireless power transfer start notification is adopted. However, the present invention is not limited to this, and any method can be adopted. A method of notifying only the wireless terminal apparatus  42  as a target of the schedule notification or the like may be used. 
     [Wireless Communication Sequence ( 4 )—Highest Priority Data Communication] 
       FIG. 21  illustrates still another example of the sequence of wireless communication (hereinafter, referred to as a “third sequence”). In the present embodiment, a case where a request of a type of wireless data communication with nigher importance and higher priority (referred to as “highest priority data communication”), which is distinguished from normal (in other words, general) wireless data communication is generate as wireless data communication is illustrated. In the present embodiment, one wireless terminal apparatus  41  of a plurality (for example, two) of wireless terminal apparatuses  4  ( 41 ,  42 ) in an area  101  is in a state where it is receiving wireless power transfer from a wireless power transmitter  3  by using frequency F 1 . At that time, a case where a request of the highest priority data communication is generated in a state where the other wireless terminal apparatus  42  has already been connected to the wireless data communication is illustrated. The sequence illustrated in  FIG. 21  includes Steps S 61  to S 80  below. 
     Here, the highest priority data communication is wireless data communication (at least one communication of transmission or reception) has property of Ultra-Reliable and Low Latency Communications (URLLC). The URLLC is communication in which communication in real time is continued and non-disconnection is desirable. The URLLC is applied to remote surgery, automatic vehicle driving, and the like, for example. The URLLC is not limited to a control within a single narrow-area base station  2  (the corresponding area  101 ) to which the wireless terminal apparatus  4  belongs, and may be communication with an apparatus such as another wireless terminal apparatus  4  that exists within an area that another wide-area base station  1  different from, the wide-area base station  1  to which the narrow-area base station  2  belongs has jurisdiction over. The URLLC is supposed to be executed using all channels of a millimeter wave band due to its nature, for example. 
     At S 61 , wireless power transfer for the wireless terminal apparatus  41  is executed from the wireless power transmitter  3  by using the frequency F 1  on the basis of an existing schedule. Further, the wireless terminal apparatus  42  is in a state where it has already been connected by wireless data communication using predetermined frequency. At S 62 , the narrow-area base station  2  receives an URLLC request from the wide-area base station  1  as an interrupt signal. The wide-area base station  1  receives the URLLC request from the other wide-area base station through a core network or the like. A target of the URLLC is the wireless terminal apparatus  42 . At S 63 , the wireless terminal apparatus  42  also receives the URLLC request through the wide-area base station  1  at substantially the same time as the narrow-area base station  2 . 
     At S 64 , the narrow-area base station  2  grasps that wireless data communication to the target wireless terminal apparatus  42  is of a high priority type on the basis of the URLLC request. Further, at that time, the narrow-area base station  2  also grasps that the wireless terminal apparatus  41  is in a state during wireless power transfer. The narrow-area base station  2  determines that the URLLC should be given the highest priority so that the URLLC does not interfere with the other wireless data communication or the other wireless power transfer. For that reason, at S 64 , the narrow-area base station  2  first transmits a wireless power transfer stop request regarding the executing wireless power transfer to the wireless power transmitter  3 . At S 65 , the wireless power transmitter  3  immediately stops the wireless power transfer for the wireless terminal apparatus  41  in accordance with reception of the wireless power transfer stop request. Further, at that time, the wireless power transmitter  3  transmits wireless power transfer stop notification to the narrow-area base station  2  and the wireless terminal apparatus  41 . 
     At S 66 , the wireless terminal apparatus  41  that receives the wireless power transfer stop notification switches the antenna switch so that the antenna is connected from the wireless power transfer side to the wireless data communication side. Note that at the time of a normal state, the wireless terminal apparatus  4  standardizes the wireless data communication, and thus keeps a state where the antenna is connected to the wireless data communication side. 
     At S 67 , the narrow-area base station  2  executes scheduling in view of the URLLC. For example, time and frequency are preferentially secured for the URLLC of the wireless terminal apparatus  42 . Then, at S 68 , the narrow-area base station  2  starts the URLLC for the wireless terminal apparatus  42  together with schedule notification. Along with this, the wireless terminal apparatus  42  executes the wireless data communication of the URLLC with an external device on the other side through the narrow-area base station  2  and the wide-area base station.  1 . 
     On the other hand, at S 69 , after the wireless power transfer is stopped halfway at S 65 , the wireless terminal apparatus  41  transmits a power retransfer request, which is a request for restart of the wireless power transfer, to the narrow-area base station  2  at regular timing, for example. Alternatively, the wireless terminal apparatus  41  may transmit the power retransfer request to the wireless power transmitter  3 , and the wireless power transmitter  3  may transmit the power retransfer request corresponding to the narrow-area base station  2 . 
     At S 70 , when the power retransfer request is received, the narrow-area base station  2  determines whether the wireless power transfer is restarted or not (in other words, authorized or not). In the present embodiment, the narrow-area base station  2  determines that restart or authorization is not executed in a state where the URLLC continues. In the present embodiment, in a case where the URLLC continues or is not ended when the power retransfer request is received, the narrow-area base station  2  does not transmit a response to the wireless terminal apparatus  41 . Alternatively, the narrow-area base station  2  may transmit a response of unauthorization. At S 71 , in a case where the URLLC is ended, the URLLC end notification is transmitted from the wireless terminal apparatus  42  to the narrow-area base station  2 . Alternatively, the narrow-area base station  2  grasps an URLLC end state on the basis of communication with the wide-area base station  1 . 
     At S 72 , in case of a state where the URLLC is ended when the power retransfer request is received, the narrow-area base station  2  executes scheduling again. Since a wireless resource for the URLLC is released in this scheduling, the narrow-area base station  2  can create a new schedule by using the wireless resource. For example, for wireless power transfer of the wireless terminal apparatus  41 , the frequency F 1  is allocated again. Note that at the time of this scheduling, a frequency different from the previous frequency F 1  may be allocated depending upon a situation. 
     At S 73 , the narrow-area base station  2  transmits a wireless power transfer request based on the new schedule to the wireless power transmitter  3 . At S 74 , in case of a state where the wireless power transfer can be restarted, the wireless power transmitter  3  transmits authorization of the wireless power transfer to the narrow-area base station  2 . At S 75 , the narrow-area base station  2  transmits authorization of the wireless power transfer, which is authorization of restart of the wireless power transfer, to the wireless terminal apparatus  41 . At S 76 , the narrow-area base station  2  transmits new schedule notification to the wireless power transmitter  3  and the wireless terminal apparatus  41 . At S 77 , each of the wireless power transmitter  3  and the wireless terminal apparatus  41  transmits schedule receipt notification to the narrow-area base station  2 . At S 78 , in a case where frequency or the like changes, the wireless terminal apparatus  41  addresses the change in accordance with schedule information to switch the antenna switch so that the antenna is connected to the wireless power transfer side. 
     At S 79 , the wireless power transmitter  3  transmits wireless power transfer start notification to the wireless terminal apparatus  41 . This notification is notification that the wireless power transfer to the wireless terminal apparatus  41  is restarted using the frequency F 1  allocated by scheduling. The wireless power transmitter  3  then starts the wireless power transfer with the wireless terminal apparatus  41  by using the frequency F 1 . The wireless terminal apparatus  41  receives the wireless power transfer to charge received electric power into the battery  423 . 
     In the sequence described above, at S 66 , the wireless terminal apparatus  41  switches the antenna from the wireless power transfer side to the wireless data communication side, and at S 78 , switches the antenna from the wireless data communication side to the wireless power transfer side. The following may be a sequence of a modification example. At S 66 , the wireless terminal apparatus  41  does not switch the antenna from the wireless power transfer side to the wireless data communication side, and at S 69 , transmits a power retransfer request to the narrow-area base station  2 . Further, in a case where authorization of wireless power transfer for restart is received at S 75 , the wireless terminal apparatus  41  does not switch the antenna at S 78 , and restarts the wireless power transfer. The present invention is not limited to the example of the URLLC described above. In a case where urgency, the degree of importance, priority and the like can be determined with respect to the type or the content of the wireless data communication, scheduling and control can be executed in accordance with the determination. 
     [Scheduling Example] 
       FIG. 22  illustrates a schedule example that also corresponds to the example of the third sequence illustrated in  FIG. 21 . (A) and (B) of  FIG. 22  illustrates examples of a change in schedule information on wireless resource allocation before and after the URLLC request, In the present embodiment, there are twelve wireless terminal apparatuses  4  (whose ID=MT 1  to MT 12 ) as the plurality of wireless terminal apparatuses  4  in the area  101 , for example. In the schedule of (A), the wireless terminal apparatus MT 1  uses two channels of channels c 12 , c 13  to receive wireless power transfer during time t 1  to t 12 . The wireless terminal apparatus MT 3  uses one channel c 1  to execute general wireless data communication during time t 1  to t 10 . Further, nine wireless terminal apparatuses  4  of the wireless terminal apparatuses MT 4  to MT 12  uses nine channels of channel c 2  to c 10  to execute multiple-apparatus connection data communication (MMTC, indicated by a grid pattern) as illustrated in the example of  FIG. 2 . 
     In a case where a request of the URLLC is generated as the highest priority communication for the wireless terminal apparatus MT 2  as a target, a schedule of (B) is created by scheduling. In the schedule of (B), the wireless terminal apparatus MT 2  uses all the channels c 1  to c 12  to execute the URLLC (indicated by a stripe pattern) at times t 5 , t 6 , t 9 , and t 10 . Due to the generation of the URLLC, the wireless power transfer for the wireless terminal apparatus MTA using the channels c 12 , c 13  is interrupted at the time t 5 . The general wireless data communication for the wireless terminal apparatus MT 3  using the channel c 1  is interrupted at the time of the URLLC. The MMTC for the wireless terminal apparatuses MT 4  to MT 12  using the channels c 2  to c 10  is interrupted at the time of the URLLC. 
     In a case where the URLLC for the wireless terminal apparatus MT 2  via the narrow-area base station  2  is ended, wireless power transfer for the wireless terminal apparatus MT 1  using the channels c 12 , c 13  is restarted at the time t 12  immediately after a time of one cell. This is because data of the wireless terminal apparatus MT 3  and data of the wireless terminal apparatuses MT 4  to MT 12 , which are interrupted by the URLLC and are time-shifted due to the scheduling of the narrow area base station  2 , are restored in the narrow-area base station  2  by an error correction technique such as HARQ (Hybrid Automatic Repeat request). 
     In the example described above, the wireless power transfer of the wireless terminal apparatus MT 1  is restarted again using the wireless resource at the same frequency after the URLLC is ended in the similar manner illustrated in  FIG. 21 . On the other hand, in another example of scheduling, the narrow-area base station  2  manages the schedule together with the states of the wireless terminal apparatus MT 3  and the wireless terminal apparatuses MT 4  to MT 12 , whereby it is also possible to restart the wireless power transfer for the wireless terminal apparatus MT 1  after the URLLC is ended. 
     [Location Managing Function] 
     In the first embodiment, each of the apparatuses of the wireless power transfer system further includes a location managing function that is a function for location grasping or location correction of each of the apparatuses related to wireless power transfer. This location managing function is a function that particularly realizes accuracy improvement of the wireless power transfer using a millimeter wave band. In the present system, before wireless power transfer using millimeter waves, a location of the wireless terminal apparatus  4  when viewed from the wireless power transmitter  3  is obtained by correction using this function on the basis of terminal location information possessed by the narrow-area base station  2 . The wireless power transmitter  3  can execute the wireless power transfer using the millimeter waves with high accuracy by using the location on the basis of a relationship of Line of Sight. 
       FIG. 23  illustrates an explanatory drawing regarding the location managing function. A case where one narrow-area base station  2 , one wireless power transmitter  3 , and one wireless terminal apparatus  4  are connected to each other in an area  101 . An absolute location (a three-dimensional coordinate indicating a location) of each apparatus is as follows. A location of the narrow-area base station  2  is referred to as a location P 2 , a location of the wireless power transmitter  3  is referred to as a location P 3 , and a location of the wireless terminal apparatus  4  is referred to as a location P 4 . Further, a relative position (corresponding to a displacement amount or a vector) of the wireless terminal apparatus  4  when viewed from the narrow-area base station  2  is referred to as a location L 1 . A, relative position of the wireless terminal apparatus  4  when viewed from the wireless power transmitter  3  is referred to as a location L 2 . A relative position of the wireless power transmitter  3  when viewed from the narrow-area base station  2  is referred to as a location L 3 . 
     When the wireless power transmitter  3  executes wireless power transfer to the wireless terminal apparatus  4 , in particular, executes wireless power transfer using millimeter waves, the wireless power transmitter  3  needs to grasp the location of the wireless terminal apparatus  4  as a target with high accuracy. As illustrated in  FIG. 13  described above, due to strength of a directional characteristic of the millimeter waves, a relationship of Line of Sight between the location P 3  of the wireless power transmitter  3  (in particular, the antenna  361 ) and the location P 4  of the wireless terminal apparatus  4  (in particular, the antenna  61 ) is important for efficient wireless power transfer. Namely, it is desirable that the wireless power transmitter  3  grasps the location L 2  with high accuracy. For that reason, the location managing function is used in the present system. The terminal information manager  301 D illustrated in  FIG. 11  also executes processing corresponding to the location managing function. 
     In a case where the wireless power transmitter  3  can obtain information on the location L 2  (or the location P 4  of the wireless terminal apparatus  4  and the location P 3  of the wireless power transmitter  3 ) directly from the wireless terminal apparatus  4  or the narrow-area base station  2  as the terminal information JT, it is not necessary to use this location managing function. For example, the wireless terminal apparatus  4  may provide the wireless power transmitter  3  with the terminal information JT containing its own location P 4  obtained by using a GPS with high accuracy or a sensor. 
     However, for example, in a case where the information obtained as the location of the wireless terminal apparatus  4  is only the location L 1  when viewed from the narrow-area base station  2 , there is a location difference between the wireless power transmitter  3  and the narrow-area base station  2 , and it is different from the location L 2  when viewed from the wireless power transmitter  3 . For that reason, efficiency of the wireless power transfer based on the location L 1  is lower than an ideal value. Therefore, in the present system, the location managing function is used to obtain the information on the location L 2  from the information on the location L 1  and the location L 3  by correction, and wireless power transfer based on the location L 2  is executed. This makes it possible to execute more efficient wireless power transfer. 
     In  FIG. 23 , the location L 3  of the wireless power transmitter  3  when viewed from the narrow-area base station  2  is registered in the present system in advance as a setting when the system is installed. Each of the narrow area base station  2  and the wireless power transmitter  3  has the information on the location L 3 .  FIG. 23  includes Steps S 231  to S 234  as a sequence regarding location correction. 
     At S 231 , when a wireless power transfer request is transmitted to the narrow-area base station  2  or the wireless power transmitter  3 , the wireless terminal apparatus  4  transmits the terminal information JT thereto at the same time, for example. This terminal information JT contains an ID and a type of the wireless terminal apparatus  4 , an electric power state including a state of the battery  423 , location information, device configuration information, and the like. In this sequence, this terminal information JT contains information on the relative location L 1  when viewed from the narrow-area base station  2  as the location information. The narrow-area base station  2  grasps the location L 1  of the wireless terminal apparatus  4  for wireless data communication as a basic function. Alternatively, this location information on the location L 1  may be location information grasped by the wireless terminal apparatus  4  itself by means of the GPS with high accuracy, the sensor or the other means. 
     At S 252 , the narrow-area base station  2  transmits the terminal information JT of the wireless terminal apparatus  4  to the wireless power transmitter  3 . Alternatively, the wireless power transmitter requests and obtains the terminal information JT from the narrow-area base station  2 . At S 253 , the wireless power transmitter  3  grasps the location L 1  from the obtained terminal information JT. Further, the wireless power transmitter  3  grasps the location L 3  of the wireless power transmitter  3  when viewed from the narrow-area base station  2 . The wireless power transmitter  3  then corrects the location L 1  by using the location L 3 , thereby obtaining the location L 2 . A formula when considered as a vector is L 2 =L 1 −L 3 . Further, the wireless power transmitter  3  can grasp the location P 4  of the wireless terminal apparatus  4  from the location L 2  with respect to its own location P 3 . 
     At S 254 , the wireless power transmitter  3  uses the location L 2  and the location P 4  obtained at S 253  to execute wireless power transfer of millimeter waves to the wireless terminal apparatus  4 . At that time, the wireless power transmitter  3  selects the antenna  361  that becomes the best location relationship with respect to the location L 2  and the location P 4 , and executes the wireless power transfer of the millimeter waves. Namely, as described above, for example, one that has a location relationship in which a difference between a direction of the antenna  361  and a direction of the antenna  61  of the wireless terminal apparatus  4  is the smallest is selected. Further, for example, the wireless power transmitter  3  may adjust the direction of the antenna  361  so as to face a direction corresponding to the location L 2  and the location P 4 , and execute the wireless power transfer of the millimeter waves In a case where the antenna  361  has a movable mechanism, such adjustment is possible. Alternatively, the wireless power transmitter  3  may notify the wireless terminal apparatus  4  and cause the user to output a prompt so as to have a suitable location relationship corresponding to the location L 2 . 
     In the example of the location managing function described above, the location correction has been executed by the wireless power transmitter  3 . However, the present invention is not limited to this, and any location correction is possible. In the modification example, the narrow-area base station  2  or the wireless terminal apparatus  4  may execute the location correction. In a case where the narrow-area base station  2  executes the location correction, the narrow-area base station  2  calculates the location L 2  from the location L 1  and the location L 3 , and transmits the information on the location L 2  to the wireless power transmitter  3 . In a case where the wireless terminal apparatus  4  executes the location correction, the wireless terminal apparatus  4  obtains the information on the location L 1  and the location L 3  from the narrow-area base station  2 ; calculates the location L 2  from the location L 1  and the location L 3 ; and transmits the information on the location L 2  to the wireless power transmitter  3 . 
     Further, in case of the integrated wireless base station power transmitter  5  illustrated in  FIG. 2 , the location P 3  is almost the same as the location P 2 , that is, the location L 1  is almost the same as the location L 2 . In this case, the location correction can be omitted. Further, in a case where the location L 3  of the wireless power transmitter  3  is changed in the area  101  due to movement by the user, as described above, it may be grasped by using a location measuring function regarding the location L 3 . For example, the narrow-area base station  2  uses an electromagnetic source of millimeter waves as a radar to grasp the location L 3  of the wireless power transmitter  3  when viewed from the narrow-area base station  2 . Alternatively, the wireless power transmitter  3  uses the electromagnetic source of the millimeter waves as the radar to grasp the location of the narrow-area base station  2  when viewed from the wireless power transmitter  3  and obtain the location L 3  from the location. 
     Further, the narrow-area base station  2  may use the electromagnetic source of the millimeter waves as the radar to measure and grasp the location L 1  of the wireless terminal apparatus  4 . Further, the wireless power transmitter  3  may use the electromagnetic source of the millimeter waves as the radar to measure and grasp the location L 2  of the wireless terminal apparatus  4 . 
     [Effect and The Like ( 1 )] 
     As described above, according to the system including the wireless terminal apparatus  4  and the wireless power transmitter  3  of the first embodiment, it is possible to prevent or reduce interference between the wireless power transfer and the wireless data communication by scheduling, and this makes it possible to improve efficiency, reliability, and convenience of the user. According to the first embodiment, by separating the time or the frequency of the wireless power transfer and the wireless data communication regarding one or more apparatuses, it is possible to prevent or reduce the interference thereof. Further, in particular, the first embodiment is a method of executing the wireless power transfer by using the radio wave transmitting method, and the wireless terminal apparatus  4  can be arranged within an area of a distance of about several meters with respect to the wireless power transmitter  3 , for example. Since it is not limited to adjacent installation, it is highly convenient for the user. Further, in the first embodiment, the wireless power transfer and the wireless data communication using the millimeter wave band and the microwave band are possible. The interference can be reduced for each combination. Further, in case of the wireless power transfer using the millimeter wave band, the relationship of Line of Sight is determined by using the location managing function, whereby it is possible to heighten accuracy thereof. 
     MODIFICATION EXAMPLE 
     The following is applicable as a modification example of the first embodiment. In the first embodiment, the wireless terminal apparatus  4  determines charging necessity to generate a wireless power transfer request. The present invention is not limited to this. In the modification example, the wireless power transmitter  3  may cooperate with and communicate with the wireless terminal apparatus  4 , and determine charging necessity of the wireless terminal apparatus  4  to generate a wireless power transfer request. For example, the wireless power transmitter  3  obtains the terminal information JT from the wireless terminal apparatus  4 , and determines necessity of wireless power transfer in accordance with an electric power state of the wireless terminal apparatus  4 , which is indicated by the terminal information JT. The wireless power transmitter  3  then transmits the wireless power transfer request to a wireless base station for a scheduling request. 
     Further, the communication interface  410  of the wireless terminal apparatus  4  may be a communication interface that accepts one type of wireless communication interface (for example, only a millimeter wave band, or only a microwave band). Further, one communication interface may include a single antenna. 
     Further, as the system according to the modification example, the wireless base station does not execute scheduling, but the wireless power transmitter  3  may be configured so as to execute the scheduling. In this configuration, the wireless power transmitter  3  grasps information on the wireless power transfer request from the wireless terminal apparatus  4 , and obtains and grasps information regarding a request and a state of wireless data communication in cooperation with the narrow area base station  2 . The wireless power transmitter  3  executes scheduling, or at least suitable scheduling of the wireless power transfer on the basis of the information so as to reduce interference between the wireless power transfer and the wireless data communication. The wireless power transmitter  3  notifies the wireless terminal apparatus  4  of created schedule information. The wireless terminal apparatus  4  receives the wireless power transfer in accordance with the schedule information. 
     [Modification Example—Communication System ( 2 )] 
       FIG. 24  illustrates a second communication system in a system according to a modification example of the first embodiment. In the second communication system, a narrow-area base station  2  executes scheduling. Further, in the second communication system, a wireless power transfer request from a wireless terminal apparatus  4  is transmitted to a wireless power transmitter  3 . This modification example also allows to obtain the similar effects. 
     As communication procedures regarding a request of wireless power transfer W 1 , procedures WR 1  to WR 4  are illustrated. In the procedure WR 1 , the wireless terminal apparatus  4  transmits a wireless power transfer request to the wireless power transmitter  3 . In the procedure WR 2 , the wireless power transmitter  3  grasps the wireless power transfer request from, the wireless terminal apparatus  4 , and transmits a corresponding wireless power transfer request to the narrow-area base station  2 . In the procedure WR 3 , the narrow-area base station  2  executes scheduling, and then transmits schedule information and the like to the wireless power transmitter  3 . In the procedure WR 4 , the wireless power transmitter  3  transmits the schedule information and the like to the wireless terminal apparatus  4 . 
     Further, as communication procedures regarding a request for wireless data communication C 1 , procedures CR 1  to CR 3  are illustrated. In the procedure CR 1 , the wireless terminal apparatus  4  transmits a request for connection to wireless data communication to the narrow area base station  2 . In the procedure CR 2 , the narrow-area base station  2  communicates with the wide-area base station  1  to confirm connection to wireless data communication, and executes scheduling. In the procedure CR 3 , the narrow-area base station  2  transmits schedule information and the like to the wireless terminal apparatus  4 . 
     The narrow-area base station  2  executes scheduling when each request is received. The wireless power transmitter  3  executes the wireless power transfer W 1  for the wireless terminal apparatus  4  with a first time T 1  and a first frequency F 1  in accordance with obtained schedule information J 3 . In corresponding thereto, the wireless terminal apparatus  4  receives the wireless power transfer W 1  from the wireless power transmitter  3  in accordance with obtained schedule information J 4 . Further, the wireless terminal apparatus  4  executes, in accordance with the schedule information J 4 , the wireless data communication C 1  with a second time T 2  and a second frequency F 2 . 
     Second Embodiment 
     A wireless power transfer system including a wireless terminal apparatus and a wire less power transmitter according to a second embodiment of the present invention will be described with reference to  FIG. 26  and.  FIG. 27 . Hereinafter, component parts of the second embodiment, which are different from those of the first embodiment, will be described. In the second embodiment, at the time of wireless power transfer, a narrow-area base station  2  and a wireless power transmitter  3  do not actively cooperate with each other (including wireless communication for a control) unlike the first embodiment. In the second embodiment, the narrow-area base station  2  and a wireless terminal apparatus  4  cooperate with each other, and the wireless terminal apparatus  4  and the wireless power transmitter  3  cooperate with each other, thereby executing the wireless power transfer. Further, in the second embodiment, the narrow-area base station  2  executes scheduling. 
     [Wireless Power Transfer System and Wireless Terminal Apparatus] 
       FIG. 26  illustrates a configuration example of the wireless power transfer system according to the second embodiment. The narrow-area base station  2 , the wireless power transmitter  3 , and a plurality (for example, three) of wireless terminal apparatuses  4  ( 41  to  43 ) exist within an area  101 . Unlike the first embodiment, the wireless power transmitter  3  does not actively cooperate with the narrow-area base station  2 . The wireless power transmitter  3  wirelessly communicates with the wireless terminal apparatus  4  to cooperate with each other. A wireless base station (in particular, the narrow-area base station  2 ) includes a scheduling function  102 . The wireless terminal apparatus  4  includes a scheduling request function  104 . 
     A configuration of the wireless terminal apparatus  4  according to the second embodiment is different from the configuration of the wireless terminal apparatus  4  according to the first embodiment in that the processor  401  illustrated in  FIG. 8  further includes a wireless power transfer manager  401 E. The wireless power transfer manager  401 E is a part that manages information (hereinafter, referred to as “wireless power transfer information JP”) necessary for the wireless terminal apparatus  4  to recognize the wireless power transmitter  3  and for the wireless terminal apparatus  4  to receive wireless power transfer from the wireless power transmitter  3 . The wireless power transfer manager  401 E stores the wireless power transfer information JP in a memory  402 . The wireless power transfer information JP contains wireless power transmitter information obtained from the wireless power transmitter  3 . The wireless power transmitter information contains an ID, a type, a location, a state, and device configuration information of the wireless power transmitter  3 . The device configuration information contains information on a type of each antenna and the number of antennas in a power transmitter. The wireless power transfer information JP may contain information on a relative location of the wireless power transmitter  3  when viewed from the wireless terminal apparatus  4 . The wireless terminal apparatus  4  grasped the relative location by using the location determining function described above. 
     [Wireless Communication Sequence] 
       FIG. 27  illustrates a sequence of wireless communication by the system according to the second embodiment. This sequence is a sequence in which a location L 1  of the wireless terminal apparatus  4  grasped by the narrow-area base station  2  is corrected to a location L 2  of the wireless terminal apparatus  4  when viewed from the wireless power transmitter  3 , and wireless power transfer is then executed. This sequence includes Steps S 81  to S 88  below. 
     At S 81 , when a wireless power transfer request is executed for charging the battery  423 , the wireless terminal apparatus  4  first. transmits a location information request, a wireless power transfer frequency securing request, and terminal information JT to the narrow-area base station  2 . The location information request is a request regarding the location L 1  of the wireless terminal apparatus  4  when viewed from the narrow-area base station  2 . The wireless power transfer frequency securing request is a request regarding allocation of wireless resources such as frequencies for the wireless power transfer, in other words, it is a scheduling request. As described above, the terminal information JT is Information that contains an ID and a state of the wireless terminal apparatus  4 , and does not contain location information. 
     At S 82 , in response to the wireless power transfer frequency securing request, the narrow-area base station  2  executes scheduling including the allocation of the wireless resources such as frequencies for the wireless power transfer on the basis of the state of the wireless terminal apparatus  4  indicated by the terminal information JT. Alternatively, in a case where the wide-area base station  1  executes the scheduling, the narrow-area base station  2  requests the wide-area base station  1  for scheduling, and obtains schedule information of a scheduling result by the wide-area base station  1 . This scheduling prevents or reduces interference between wireless data communication and wireless power transfer in the similar manner to the first embodiment. 
     At S 83 , the narrow-area base station  2  responds to the location information request from the wireless terminal apparatus  4  to transmit information on the grasped location L 1  to the wireless terminal apparatus  4 . The narrow-area base station  2  transmits the schedule information (corresponding schedule notification) to the wireless terminal apparatus  4  as a response together with location information on the location L 1 . At S 84 , the wireless terminal apparatus  4  transmits the wireless power transfer request to the wireless power transmitter  3  together with the information on the location L 1  obtained from the narrow-area base station  2  and the schedule information. At S 85 , the wireless power transmitter  3  obtains the location L 2  of the wireless terminal apparatus  4  when viewed from the wireless power transmitter  3  by correction using the location L 1  obtained from the wireless terminal apparatus  4  and the location L 3  that is a setting value. In particular, this location correction is effective at the time of wireless power transfer using millimeter waves. 
     At S 86 , in a case where the wireless power transfer is authorized, the wireless power transmitter  3  transmits authorization of wireless power transfer to the wireless terminal apparatus  4  in accordance with the schedule information obtained at S 83 . At S 87 , in accordance with the schedule information, the wireless terminal apparatus  4  switches the antenna switch so that the antenna to be used of the communication interface  410  is connected to the wireless power transfer side. At S 88 , the wireless bower transmitter  3  executes the wireless power transfer with the wireless terminal apparatus  4  toward the location L 2  obtained at S 85  in accordance with the schedule information. 
     [Effect and The Like ( 2 )] 
     As described above, according to the second embodiment, it is possible to obtain the similar effects to those of the first embodiment. In the system according to the second embodiment, at the time of the wireless power transfer, the narrow-area base station  2  and the wireless power transmitter  3  do not actively cooperate with each other, and the similar functions to those in the first embodiment are realized mainly by the wireless terminal apparatus  4  in a form of intervening between the narrow-area base station  2  and the wireless power transmitter  3 . 
     Third. Embodiment 
     A wireless power transfer system including a wireless terminal apparatus and a wireless power transmitter according to a third embodiment of the present invention will be described with reference to  FIG. 28 . In the third embodiment, each apparatus includes a location determining function using a camera. Further, in the third embodiment, a detailed example of a case where an antenna dividing method is used as a scheduling method will be described. 
     [Location Determining Function Using Camera] 
     With respect to the location managing function described above, the following functions can be used when a location L 2  of a wireless terminal apparatus  4  when viewed from a wireless power transmitter  3  is grasped. Each apparatus of the present system may include a location determining function that is a function to determine a location of each of the other apparatuses by analyzing an image using a camera as described below. 
     In a case where a narrow-area base station  2  includes a camera, a location L 1  of the wireless terminal apparatus  4  and a location L 3  of the wireless power transmitter  3  may be grasped by means of an analysis of an image photographed by the camera. Further, in a case where the wireless power transmitter  3  includes a camera  304 , the location L 2  of the wireless terminal apparatus  4  and a location of the narrow-area base station  2  may be grasped by means of an analysis of an image photographed by the camera  304 . In a case where the wireless terminal apparatus  4  includes a camera  404 , the location of the wireless power transmitter  3  and the location of the narrow-area base station  2  may be grasped by means of an analysis of an image photographed by the camera  404 . 
     The location determining function will be described with. reference to  FIG. 13  described above. For example, in (A) of  FIG. 13 , each of the wireless power transmitter  3  and the wireless terminal apparatus  4  may include a location determining function. By determining a relationship of Line of Sight among the apparatuses using the location determining function, it is possible to realize the wireless power transfer more efficiently. 
     In a case where the wireless power transmitter  3  includes a location determining function, the wireless power transmitter  3  photographs an image using the camera  304  at the time of the wireless power transfer The wireless power transmitter  3  determines, from the image, whether the wireless terminal apparatus  4  as a target exists within a predetermined area centered on a direction of the camera  304  or not and whether there is no shielding object OB (including a case where it is a person) in the vicinity of the line in the direction or not. In a case where the wireless terminal apparatus  4  as the target. exists within the area in the direction and there is no shielding object OB, the wireless power transmitter  3  determines that the wireless power transfer can be executed efficiently, that is, it has a relationship of Line of Sight. In a case where the wireless terminal apparatus  4  as the target does not exist within the area in the direction and there is a shielding object OB, the wireless power transmitter  3  determines that the wireless power transfer cannot be executed efficiently, that is, it does not have a relationship of Line of Sight. The wireless power transmitter  3  controls the wireless power transfer on the basis of a determination result. 
     Further, the wireless power transmitter  3  may transmit determination result information of the location determining function to a wireless base station (the narrow-area base station  2  and a wide-area base station  1 ), and notify the wireless base station of it, whereby it may be reflected to scheduling. For example, the wireless power transmitter  3  transmits information containing whether there is a relationship of Line of Sight with the wireless terminal apparatus  4  or not or a location relationship to the wireless base station. The wireless base station takes the information into consideration to create a schedule including suitable wireless resource allocation. Further, the wireless power transmitter  3  may transmit the determination result information and notify the wireless terminal apparatus  4  as the target of it. Further, the wireless power transmitter  3  may cause a user of the wireless terminal apparatus  4  to output a prompt so as to adjust the location and the direction of the wireless terminal apparatus  4 . 
     In a case where the wireless terminal apparatus  4  includes a location determining function, the wireless terminal apparatus  4  photographs an image using a camera  404  when the wireless power transfer is received. The wireless terminal apparatus  4  determines, from the image, whether the wireless power transmitter  3  that becomes the other side or a candidate exists within a predetermined area centered on a direction of the camera  404  or not and whether there is no shielding object OB within an area on a line of the direction or not. In a case where the wireless power transmitter  3  exists within the area in the direction and there is no shielding object OB, the wireless terminal apparatus  4  determines that the wireless power transfer can be received efficiently, that is, it has a relationship of Line of Sight. In a case where the wireless power transmitter  3  does not exist within the area in the direction and there is a shielding object OB, the wireless terminal apparatus  4  determines that the wireless power transfer can be received efficiently, that is, it has a relationship of Line of Sight. The wireless terminal apparatus  4  controls an operation of power reception of the wireless power transfer on the basis of a determination result. 
     Further, the wireless terminal apparatus  4  may transmit determination result information to the wireless base station (the narrow-area base station  2  and the wide-area base station  1 ), and notify the wireless base station of it, it may be reflected to scheduling. For example, the wireless terminal apparatus  4  transmits information containing whether there is a relationship of Line of Sight with the wireless power transmitter  3  or not or the location relationship to the wireless base station. The wireless base station takes the information into consideration to create a schedule including suitable wireless resource allocation. Further, the wireless terminal apparatus  4  may transmit the determination result. information and notify the wireless power transmitter  3  as the other side of it. Further, the wireless terminal apparatus  4  may cause a user to output a prompt so as to adjust the location and the direction of the wireless terminal apparatus  4 . 
     [Antenna Location Determining Function] 
     Moreover, in particular, each apparatus of the present system may include an antenna location determining function as the location determining function described above. The antenna location determining function is a function to determine a location of an antenna of the other apparatus by means of an analysis of an image of a camera. The antenna location determining function will be described with reference to  FIG. 13  described above. For example, in (A) of  FIG. 13 , each of the wireless power transmitter  3  and the wireless terminal apparatus  4  may include the antenna location determining function. By determining a relationship of Line of Sight between antennas using the antenna location determining function, wireless power transfer using millimeter waves can be realized more efficiently. 
     In a case where the wire less power transmitter  3  includes the antenna location determining function, the wireless power transmitter  3  photographs an image using the camera  304  at the time of the wireless power transfer using the millimeter waves. The wireless power transmitter  3  determines, from the image, whether an antenna  61  for millimeter waves of the wireless terminal apparatus  4  as a target exists within a predetermined area centered on a direction (for example, a direction d 1 ) of an antenna  361  or not and whether there is no shielding object OB within the area in the direction or not. In a case where the antenna  61  of the wireless terminal apparatus  4  as the target exists within the area in the direction and there is no shielding object OB, the wireless power transmitter  3  determines that the wireless power transfer using the millimeter waves can be executed efficiently, that is, it has a relationship of Line of Sight between the antennas. In a case where the antenna  61  of the wireless terminal apparatus  4  as the target does not exist within the area in the direction and there is a shielding object OB, the wireless power transmitter  3  determines that the wireless power transfer using the millimeter waves cannot he executed. efficiently, that is, it does not have a relationship of Line of Sight between the antennas. The wireless power transmitter  3  controls the wireless power transfer using the millimeter waves on the basis of a determination result. 
     In a case where the wireless terminal apparatus  4  includes the antenna location determining function, the wireless terminal apparatus  4  photographs an image using the camera  404  when the wireless power transfer using the millimeter waves is received. The wireless terminal apparatus  4  determines, from the image, whether the antenna  361  of the wireless power transmitter  3  as the other side exists within a predetermined area centered on a direction of the antenna  61  or not and whether there is no shielding object OB within an area on a line of the direction or not. In a case where the antenna  361  of the wireless power transmitter  3  exists within the area in the direction and there is no shielding object OB, the wireless terminal apparatus  4  determines that the wireless power transfer using the millimeter waves can be received efficiently, that is, it has a relationship of Line of Sight between the antennas. In a case where the antenna  361  of the wireless power transmitter  3  as the target does not exist within the area in the direction and there is a shielding object OB, the wireless terminal apparatus  4  determines that the wireless power transfer using the millimeter waves cannot be received efficiently, that is, it does not have a relationship of Line of Sight between the antenna The wireless terminal apparatus  4  controls an operation of power reception of the wireless power transfer using the millimeter waves on the basis of a determination result. 
     Similarly, with respect to the antenna location determining function, the wireless power transmitter  3  or the wireless terminal apparatus  4  may transmit determination result information to a wireless base station, and notify the wireless ruse station of it, whereby it may be reflected to scheduling. The wireless base station can execute the scheduling of an antenna dividing method, for example. Further, the wireless power transmitter  3  may transmit the determination result information to the wireless terminal apparatus  4  as the target, and notify the wireless terminal apparatus  4  of it. The wireless terminal apparatus  4  may transmit the determination result information to the wireless power transmitter  3  as the other side, and notify the wireless power transmitter  3  of it. The wireless terminal apparatus  4  may cause the user to output a prompt so as to adjust the location and the direction of the antenna  61 . 
     The camera  404  and the camera  304  described above may be a lensless camera or another sensor that serves as the similar function. Note that a three-dimensional location coordinate or a distance (that is, a distance from the camera) of an object (a corresponding characteristic point) in a camera image can be estimated from a location coordinate of the object on the basis of known calculation. In particular, when electromagnetic waves of a millimeter wave band are used, it is important that the wireless power transmitter  3  and the wireless terminal apparatus  4  have a relationship of Line of Sight and a location relationship between the antennas is accurate. For that reason, it is effective to use the location determining function described above. 
     Further, in a case where the wireless terminal apparatus  4  has the configuration such as the antenna  61  as illustrated in  FIG. 9  and the wireless power transmitter  3  is provided with the camera  304 , the following can particularly be executed as the antenna location determining function. When the wireless terminal apparatus  4  uses the antenna  61 , the wireless terminal apparatus  4  causes the LED element  612  described above ( FIG. 10 ) to emit light, thereby transmitting a location of the antenna  61 . The wireless power transmitter  3  grasps and tracks the location of the antenna  61  of the wireless terminal apparatus  4  from LED light in an image by analyzing the image of the camera  304 . In a case where the camera  304  photographs a moving image, it is possible to track the location from, each image of the moving image. As a result, the wireless power transmitter  3  can grasp the location of the antenna  61  of the wireless terminal apparatus  4  with high accuracy, and this makes it possible to execute the wireless power transfer of the millimeter wave band on the basis of the grasp with higher accuracy. As another configuration example, an optical sensor may be provided in the wireless power transmitter  3  or the narrow-area base station  2  instead of the camera. This optical sensor detects the LED light of an antenna unit of the wireless terminal apparatus  4 . Further, for example, infrared light may be emitted from the antenna unit of the wireless terminal apparatus  4 , and a corresponding infrared sensor or the like may be used. 
     Moreover, the wireless power transmitter  3  determines, on the basis of the image of the camera  304 , a case where a shielding object OB (including a person) is recognized within a predetermined area on a line between the antenna  361  of the wireless power transmitter and the antenna  61  of the wireless terminal apparatus  4 . Alternatively, the wireless power transmitter  3  determines a case where a person is recognized in the vicinity of the area on the line or schematically in the image. In these cases, the wireless power transmitter  3  executes controls such that wireless power transfer is not started, wireless power transfer is stopped, or transmitted electric power is adjusted so as to be weakened. In a case where the wireless power transmitter  3  can confirm a state where any person is not recognized between the antennas, the wireless power transmitter  3  executes controls such that wireless power transfer is started, wireless power transfer is restarted, or transmitted electric power is restored. 
     Further, it is also effective to separate the plurality of antennas  61  of the wireless terminal apparatus  4  between the wireless power transfer and the wireless data communication at the time of scheduling on the basis of a directional characteristic of millimeter waves. For example, in  FIG. 14 , the antenna  61 - 4  for the millimeter waves is selected for the wireless power transfer, and the antenna  61 - 3  is selected for the wireless data communication. As a result, the wireless power transfer and the wireless data communication can be executed in a state of being spatially separated by the antennas, and this makes it possible to prevent or reduce interference therebetween. 
     [Antenna Switch and Antenna Dividing Method] 
       FIG. 28  illustrates a configuration of the antenna switch  71  and the like of the first communication interface  411  in the wireless terminal apparatus  4  according to the third embodiment. The first communication interface  411  includes four antennas  61 - 1 ,  61 - 2 ,  61 - 3 ,  61 - 4  as illustrated in  FIG. 9  as the antennas  61  that accept the millimeter wave band. In corresponding thereto, this configuration has two antenna switches  71  ( 71 - 1  and  71 - 2 ). A configuration of each of the antenna switches  71  is similar to that in case of  FIG. 7 , and. has terminals of numbers # 1  to # 8 , for example. The antennas  61 - 1  and  61 - 2  at a front face s 1  are connected to the antenna switch  71 - 1 . 
     The antennas  61 - 3  and  61 - 4  at a back face s 2  side are connected to the antenna switch  71 - 2 . An AC-DC converter  421  and a circuit  81  are respectively connected to connection destinations (# 1  to # 4 ) of the antenna switch  71 - 1  and the antenna switch  71 - 2 . An antenna controller  401 C controls switching of the antenna switches  71  ( 71 - 1 ,  71 - 2 ). 
     An example of scheduling by the antenna dividing method is as follows. Among the plurality of antennas  61  corresponding to the millimeter wave band, one antenna  61  is allocated for wireless power transfer, and another antenna  61  is allocated for wireless data communication. In an example of a state illustrated in  FIG. 30 , a connection destination of the antenna switch  71 - 2  is selected so that the antenna  61 - 4  is allocated for wireless power transfer and the antenna  61 - 3  is allocated for wireless data communication. Namely, by switches in the antenna switch  71 - 2 , each of the terminals # 2 , # 3  is selected as “H”. As a result, the antenna  61 - 3  is connected to the circuit  81  side, and the antenna  61 - 4  is connected to the AC-DC converter  421  side. 
     At the time of scheduling, as described above, for example, the location determining function using the camera is used to determine the relationship of Line of Sight, and the antenna  61  is selected on the basis of its determination result. In particular, the antenna  61  for wireless power transfer is selected so that the relationship of Line of Sight between the antenna of the wireless power transmitter  3  and the antenna  61  of the wireless terminal apparatus  4  becomes good. 
     [Effects and The Like ( 3 )] 
     As described above, according to the third embodiment, it is possible to obtain the similar effects to those of the first embodiment In the third embodiment, by dividing the antennas to be used, it is possible to prevent or reduce the interference. In the third embodiment, it is possible to heighten location accuracy at the time of the wireless power transfer using the millimeter wave band, and this makes it possible to realize the wireless power transfer more efficiently. 
     Fourth Embodiment 
     A wireless power transfer system including a wireless terminal apparatus and a wireless power transmitter according to a fourth embodiment of the present invention will be described with reference to  FIG. 29  and  FIG. 30 . In the fourth embodiment, in a case where a plurality of wireless terminal apparatuses exists within an area, with respect to a plurality of wireless data communications and a plurality of wireless power transfers, scheduling is executed so as to reduce interference. 
     [Scheduling Method ( 5 )] 
     In the fourth embodiment, the following can be executed as a scheduling method.  FIG. 29  illustrates the scheduling method and a configuration example of the wireless power transfer system. In the wireless power transfer system illustrated in  FIG. 29 , similarly to  FIG. 2 , a plurality of wireless terminal apparatuses  4  exists a power transferable range of one wireless power transmitter  3  (or a wireless base station power transmitter  5 ) within an area  101 . A case where there are wireless terminal apparatuses  41 ,  42 , and  43  is illustrated as examples of the plurality of wireless terminal apparatuses  4 , each of which may become a candidate that receives wireless power transfer. A case where the plurality of wireless terminal apparatuses  4  ( 41  to  43 ) respectively generates wireless power transfer requests (requests RQ 1  to RQ 3 ) in schematically the same time zone is illustrated. A wireless base station (a wide-area base station  1  and a narrow-area base station) and the wireless power transmitter  3  grasp the plurality of wireless power transfer requests (requests RQ 1  to RQ 3 ). In the present embodiment, there are wireless data communications C 1  to C 3  and wireless power transfers W 1  to W 3  as a whole. 
     An electric power manager  401 B of each of the wireless terminal apparatuses  4  grasps an electric power state including a state of a battery  423 . A terminal information manager  301 D of the wireless power transmitter  3  obtains terminal information JT containing the electric power state from the electric power manager  401 B of each of the wireless terminal apparatuses  4  ( 41 ,  42 ,  43 ). For example, the terminal information JT contains information such as battery remaining electric power or an electric power consumed amount rate in addition to information on an ID and a type of the wireless terminal apparatus  4 . The electric power consumed amount rate is an electric power consumed amount rate by a usage application. The wireless power transmitter  3  or the wireless base station grasps the electric power state of each of the wireless terminal apparatuses  4  ( 41  to  43 ) on the basis of the terminal information JT, and determines importance and priority regarding each of the wireless power transfers W 1  to W 3  on the basis of their electric power states. 
     For example, it is assumed that battery remaining electric powers are relatively small to large in the order of the wireless terminal apparatuses  41 ,  42 ,  43  as the electric power states of the wireless terminal apparatuses  4 . The wireless power transmitter  3  determines that the wireless power transfer regarding the wireless terminal apparatus  4  whose battery remaining electric power is smaller is heightened as priority. The wireless base station executes scheduling on the basis of this determination of the priority by the wireless power transmitter  3 . In the present embodiment, a schedule in which wireless resources are allocated is created with the wireless terminal apparatus  41  as first priority, the wireless terminal apparatus  42  as second, priority, and the wireless terminal apparatus  43  as third priority. For example, in case of a time division separation method, the wireless terminal apparatuses  4  are separated into the wireless power transfer W 1  in a first time, the wireless power transfer W 2  in a next second time, and the wireless power transfer W 3  in a next third time, and the wireless terminal apparatus  4  having lower priority is postponed. Further, in a case where available frequencies are limited, the frequency is allocated from the wireless terminal apparatus  4  having high priority. 
     As another method of determining the priority, the priority may be determined on the basis of a type of the wireless terminal apparatus  4 , a type of the application used by the wireless terminal apparatus  4 , or the number of times or frequency of wireless power transfers in a history of the wireless power transfers. Further, as still another method, a method of setting priority regarding the wireless power transfer in advance among the plurality of wireless terminal apparatuses  4  in the area  101  and executing scheduling on the basis of the setting may be adopted. 
     [Scheduling Method ( 6 )] 
     In the fourth embodiment, the following can also be executed as the scheduling method.  FIG. 30  illustrates the scheduling method and a configuration example of the wireless power transfer system. In the configuration example illustrated in  FIG. 30 , similarly to  FIG. 3 , a plurality (for example, three) of wireless power transmitters  3  ( 31 ,  32 ,  33 ) is provided within an area  101 . A plurality of wireless terminal apparatuses  4  (for example, the wireless terminal apparatuses  41 ,  42 ,  43 ) is provided with respect to these wireless power transmitters  3 . A case where the plurality of wireless terminal apparatuses  4  ( 41  to  43 ) respectively generates wireless power transfer requests (requests RQ 1  to RQ 3 ) in schematically the same time zone is illustrated. A wireless base station grasps the plurality of wireless power transfer requests (requests RQ 1  to RQ 3 ) in cooperation with the plurality of wireless terminal apparatuses  4 . In the present embodiment, there are wireless data communications C 1  to C 3  and wireless power transfers W 1  to W 3  as a whole. 
     The wireless base station, for example, the narrow-area base station  2  executes scheduling with respect to the plurality of wireless power transfer requests (requests RQ 1  to RQ 3 ). The narrow-area base station  2  may determine priority in the similar manner to the example of  FIG. 29 , for example. The narrow-area base station  2  respectively allocates different frequencies F 1  to F 3  to the wireless power transfers W 1  to W 3  by different channel numbers (that is, bandwidths) in accordance with the priority, for example. For example, a large number of channels are allocated to the wireless power transfer W 1  having high priority. 
     [Effects and The Like ( 4 )] 
     As described above, according to the fourth embodiment, the effects similar to those of the first embodiment can be obtained. In the fourth embodiment, it becomes possible to execute wireless power transfers efficiently while preventing interference among the plurality of wireless power transmitters  3  or among the plurality of wireless terminal apparatuses  4 . 
     As described above, the present invention has been explained concretely on the basis of the embodiments. However, the present invention is not limited to the embodiments described above, and can be modified into various forms without departing from the substance thereof. 
     REFERENCE SINGS LIST 
       1  . . . wide-area base station,  2  . . . narrow-area base station,  3  . . . wireless power transmitter,  4  . . . wireless terminal apparatus,  101  . . . area,  102  . . . scheduling function,  103  . . . scheduling request function,  104  . . . scheduling request function, W 1  . . . wireless power transfer, C 1  (Ca, Cb) . . . wireless data communication.