JP2014225989A - Communication device, control method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform efficient power transmission with a simple configuration, in wireless power transmission where a power transmission function and a communication function share a part of a circuit.SOLUTION: A communication device has a power reception function for receiving power, a first communication function for performing communication by using an antenna common with the power reception function, and a second communication function for performing communication by using a different antenna. The communication device determines whether switching from communication by the first communication function to communication by the second communication function is possible when performing the communication, for receiving power by the power reception function, by using the first communication function. If switching is possible, the communication for receiving power by the power reception function is switched from communication by the first communication function to communication by the second communication function, and each function is controlled so as to disable the first communication function.

Description

  The present invention relates to wireless power transmission control technology.

  In recent years, mobile terminals often have various communication functions such as a wireless LAN communication function, a Bluetooth (registered trademark) communication function, and an NFC (Near Field Communication) function in addition to a public network communication function. ing. And since these communication functions are used frequently, the frequency which charges a portable terminal is also increasing. For this reason, the request | requirement of making it easy to charge a portable terminal is also strong, and the portable terminal carrying the wireless power transmission function which transmits electric power wirelessly has come to be provided.

  In realizing these multifunctional portable terminals, sharing parts has become an important technical issue for cost reduction. In response to this problem, it has been studied to share an antenna by performing wireless power transmission and NFC communication in the same frequency band (see Patent Document 1 and Patent Document 2).

  In Qi (trademark) proposed by an industry group WPC (Wireless Power Consortium) of a wireless power transmission system, a mechanism is defined in which a power receiving apparatus transmits a control signal to a power feeding apparatus. In general, the control signal is transmitted from the power receiving apparatus to the power feeding apparatus by load modulation that deforms the waveform of the signal radiated by the power feeding apparatus by changing the value of the dedicated capacitor or resistor of the power receiving apparatus. Therefore, in a device in which NFC and power transmission are integrated, it is possible to reduce the cost by removing a capacitor and a resistor by communicating a control signal for power transmission not by load modulation but by NFC.

JP 2011-172299 A JP 2009-253649 A

  However, simply removing capacitors and resistors means that NFC communication and power transmission are operating independently. In this case, since the voltage for power transmission becomes an overvoltage for the input of the NFC circuit, the NFC circuit can be destroyed. On the other hand, in Patent Document 1, an electrical protection circuit is used to perform power transmission independent of the state of the NFC circuit. In Patent Document 1, the applied voltage is changed by a semiconductor switch that operates according to the voltage generated in the coil. However, such a circuit is complicated, and there is a problem that it may be difficult to reduce the cost.

  Further, by coordinating the NFC circuit and the power transmission circuit, it is possible to perform control such that the power transmission voltage is not applied when the NFC circuit is effective. As in the method described in Patent Document 2, this cooperative control can be realized by defining the time on the power feeding side and the power receiving side and dividing the timing for performing power transmission and the timing for performing NFC communication into time divisions. However, in this method, since charging is not performed during NFC communication, there is a problem in that there are many overhead time intervals in which charging is not performed, and quick charging cannot be performed. On the other hand, although the charging period can be increased by shortening the NFC communication period, in that case, the period during which the control signal can be transmitted is shortened, which makes it difficult to perform highly accurate control.

  The present invention has been made in view of the above problems, and in wireless power transmission in which a power transmission function and a communication function share a part of a circuit, a technique that enables efficient power transmission with a simple configuration. The purpose is to provide.

  In order to achieve the above object, a communication apparatus according to the present invention includes a first communication unit having a power reception function for receiving power and a first communication function for performing communication using a common antenna with the power reception function; A communication apparatus having a second communication unit having a second communication function for performing communication using an antenna different from that of the first communication unit, wherein communication for performing power reception by the power reception function is performed by the first communication unit; A determination means for determining whether the communication by the first communication function can be switched to the communication by the second communication function, and the switching is possible. The first communication function is switched from communication by the first communication function to communication by the second communication function to invalidate the first communication function. Communication means And a control means for controlling said second communication means.

  According to the present invention, it is possible to perform efficient power transmission with a simple configuration in wireless power transmission in which the power transmission function and the communication function share some circuits.

FIG. 3 is a block diagram illustrating a configuration example of a power receiving device. The block diagram which shows the structural example of an electric power feeder. The figure which shows operation | movement of an electric power transmission system roughly. The flowchart which shows the process which a power receiving apparatus performs. The sequence diagram which shows the 1st example of a series of processes at the time of performing electric power transmission. The sequence diagram which shows the 2nd example of a series of processes at the time of performing electric power transmission. The sequence diagram which shows the 3rd example of a series of processes at the time of performing electric power transmission.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

(Configuration of power receiving device and power feeding device)
First, configurations of the power receiving device 100 and the power feeding device 200 according to the present embodiment will be described. 1 and 2 show configuration examples of the power receiving device 100 and the power feeding device 200 according to the present embodiment, respectively.

  Both the power receiving apparatus 100 and the power feeding apparatus 200 have a common functional unit (common unit 113). The power receiving apparatus 100 includes a power receiving unit 109 and a power supply unit 111 in addition to the common unit 113. The power supply apparatus 200 includes a power transmission unit 201 and a power supply unit 202 in addition to the common unit 113. The common unit 113 includes, for example, a control unit 101, a storage unit 102, a data processing unit 103, an operation unit 104, an output unit 105, a wireless LAN function unit 106, a Bluetooth function unit 107, an NFC unit 108, and a shared antenna 110. Each functional unit is connected by a bus 112 for transmitting / receiving control information, electrical signals, and the like.

  The control unit 101 has a function of controlling the power receiving device 100 and the power feeding device 200 by executing a control program stored in the storage unit 102, and is configured by a CPU or the like. The storage unit 102 stores, for example, a control program executed by the control unit 101 and data for control. The storage unit 102 is configured by a nonvolatile ROM, a volatile RAM, or the like. Various controls described below are performed, for example, by the control unit 101 executing a control program stored in the storage unit 102.

  The data processing unit 103 executes signal processing, calculation, timekeeping, and the like. The operation unit 104 has a function of accepting user operations and includes, for example, a button, a mouse, and a touch panel. The output unit 105 has a function of notifying the user of various information such as a display and speaker output.

  The wireless LAN function unit 106 is a communication function unit that executes control for communication using a wireless LAN and communication using the wireless LAN. Here, the wireless LAN refers to communication in a wireless local area network that conforms to, for example, the IEEE 802.11 standard. The Bluetooth function unit 107 is a communication function unit for executing control for communication by Bluetooth (hereinafter referred to as BT) and communication using the BT. Each of the wireless LAN function unit 106 and the Bluetooth function unit 107 has a dedicated antenna, for example. Note that the antennas included in the wireless LAN function unit 106 and the Bluetooth function unit 107 may be physically separated for each communication, or may be a single antenna that is shared. The NFC unit 108 is a communication function unit that executes control for communication using NFC and communication using NFC.

  In the power reception device 100, the power reception unit 109 has a power reception function of receiving power supplied from the power supply device 200. In the power receiving apparatus 100, the NFC unit 108 and the power receiving unit 109 execute short-range communication and power reception in wireless power transmission with the power feeding apparatus 200 using a common antenna (shared antenna 110), respectively. . The shared antenna 110 is an antenna different from the antennas of the wireless LAN function unit 106 and the Bluetooth function unit 107. Further, the NFC unit 108 can disable its function, for example, by blocking an electric signal from the shared antenna 110 under the control of the control unit 101. Moreover, the electric power received in the electric power reception part 109 is accumulate | stored in the power supply part 111 which functions as a rechargeable battery, for example.

  In the power supply apparatus 200, the power transmission unit 201 is a power supply function unit that wirelessly supplies power supplied from a commercial power supply (power supply unit 202) to the power reception apparatus 100. Also in the power feeding device 200, the NFC unit 108 and the power transmission unit 201 perform short-range communication and power feeding in wireless power transmission with the power receiving device 100 using a common antenna (shared antenna 110), respectively. . Note that the shared antenna 110 is an antenna different from the antennas of the wireless LAN function unit 106 and the Bluetooth function unit 107, as in the power receiving apparatus 100.

  In the above configuration, the power receiving device 100 and the power feeding device 200 are described as having both the wireless LAN function unit 106 and the Bluetooth function unit 107, but the present invention is not limited thereto. At least one of the power receiving apparatus 100 and the power feeding apparatus 200 may be configured not to include at least one of the wireless LAN function unit 106 and the Bluetooth function unit 107, and may further include other communication function units. You may do it.

(Outline of operation of power transmission system)
Then, the outline | summary of operation | movement of the electric power transmission system which concerns on this embodiment is demonstrated. FIG. 3 shows an operation example of the power transmission system according to the present embodiment. In the present embodiment, as shown in FIG. 3A, first, the NFC communication 301 is established when the power receiving device 100 and the power feeding device 200 come close to each other. Here, if wireless power transmission is performed with the NFC communication 301 established as it is, a common antenna is used for NFC and wireless power transmission, so that the destruction of the NFC circuit and the efficiency of wireless power transmission can be kept low. Such problems may occur. Therefore, in this embodiment, an NFC connection handover from NFC to communication using another communication function is attempted between the power receiving apparatus 100 and the power supply apparatus 200. Here, the NFC connection handover is a procedure defined in the NFC Forum, and refers to a function in which a device that has established NFC communication shifts the communication to communication using BT or wireless LAN. NFC connection handover is also simply referred to as handover (HO).

  When the HO is successful, the power supply apparatus 200 wirelessly supplies power to the power reception unit 109 of the power receiving apparatus 100 by the power transmission unit 201 (302), and wirelessly by communication (303) using BT or wireless LAN. Control power transmission. Further, data communication other than control of wireless power transmission between the power receiving apparatus 100 and the power supply apparatus 200 is also performed by communication (303) using BT or wireless LAN.

  Processing of the power receiving device 100 at this time will be described with reference to FIG. Note that it is assumed that the NFC unit 108 is not invalidated at the start of the processing of FIG. Unless otherwise specified, the following processing is executed by the control unit 101 in accordance with a program stored in the storage unit 102.

  The power receiving apparatus 100 first determines whether NFC communication is established with the power supply apparatus 200 (S401). For example, when the power receiving apparatus 100 and the power supply apparatus 200 are in the proximity state, the power receiving apparatus 100 uses a phenomenon in which a magnetic field generated by the radio wave of the power supply apparatus 200 generates an electric signal in the power receiving apparatus 100. It is determined whether it is close to. The power receiving apparatus 100 determines that NFC communication is available and NFC communication has been established in response to the proximity state.

  When NFC communication is established (YES in S401), the power receiving apparatus 100 starts communication for performing power reception using NFC communication. First, the power receiving apparatus 100 confirms whether a necessary charging service (power transmission service) can be received using NFC communication (S402). In this confirmation, information such as whether the counterpart device (power feeding device 200) has a power feeding function and power feeding voltage is exchanged. Note that the power transmission start processing (S402) after the establishment of NFC communication may be automatically executed by the control unit 101 of the power receiving apparatus 100 or may be executed in accordance with the operation of the operation unit 104 by the user. . At this time, the control unit 101 may determine whether to automatically start the process or wait for a user operation based on setting information held in the storage unit 102. The setting information may be set by operating the operation unit 104 by the user. When the setting information is a setting for automatically starting power transmission, the control unit 101 of the power receiving apparatus 100 checks the voltage of the power supply unit 111 when the NFC communication is established, for example, and the voltage is equal to or lower than a certain value. Sometimes the process of S402 is executed.

  If the power supply apparatus 200 cannot provide the charging service (NO in S402), the power receiving apparatus 100 displays that charging is not possible on the output unit 105 (S413), and ends the process.

  On the other hand, when the power supply apparatus 200 can provide the charging service (YES in S402), the power receiving apparatus 100 subsequently determines whether an NFC connection handover is possible (S403). Currently, the NFC Forum defines a connection switching procedure for Bluetooth and wireless LAN. According to this rule, a device that has received a handover request is to return the availability of the handover in consideration of the state of the communication interface after the handover, the access point function, and the state of the wireless medium such as the presence or absence of an empty channel. . Therefore, the power receiving apparatus 100 inquires of the power supply apparatus 200 whether or not HO is possible through NFC communication, and determines whether switching to BT or wireless LAN is possible based on a response from the power supply apparatus 200.

  When it is determined that HO is not possible (NO in S403), the power receiving apparatus 100 performs communication for subsequent power reception using NFC. In this case, the power receiving apparatus 100 confirms the state of the power supply unit 111, calculates charge request information (at least one of capacity and time) (S410), and notifies the information to the power supply apparatus 200 using NFC. (S411). After that, wireless power transmission is executed according to the charge request information, so NFC communication is unnecessary. For this reason, the control unit 101 of the power receiving apparatus 100 cuts off the supply of power from the shared antenna 110 to the NFC unit 108 and invalidates the NFC unit 108 (S412). Thereafter, wireless power transmission is executed according to the charging request information (not shown), and the process ends.

  On the other hand, when it is determined that HO is possible (YES in S403), the control unit 101 of the power receiving apparatus 100 determines a HO destination (S404). Specifically, when there are a plurality of HO destination candidates, the power receiving apparatus 100 selects a communication switching destination based on the characteristics of each communication from the plurality of candidates (for example, BT and wireless LAN). select. Here, the communication characteristic is, for example, at least one of the data amount transmitted or received between the power receiving apparatus 100 and the power supply apparatus 200 using the BT or the wireless LAN, and the communication speed of each of the BT and the wireless LAN. Including Further, the communication characteristic may be the power consumption of each of the BT and the wireless LAN. Further, the communication characteristic may be whether the power receiving apparatus 100 and the power feeding apparatus 200 have a function of detecting whether they are close to each other. Furthermore, the power receiving apparatus 100 and the power supply apparatus 200 may be compatible with wireless LAN and BT. Note that the switching destination communication method may be selected based on a combination of these characteristics.

  In general, wireless LAN and BT are capable of high-speed and large-capacity communication. Therefore, for example, when the amount of data to be transmitted or received is larger than a predetermined amount, the power receiving apparatus 100 may select the wireless LAN as the switching destination. For example, when the power receiving device 100 is a digital camera and the power feeding device 200 is a data storage device, when the image data is backed up by communication during charging, the power receiving device 100 switches the wireless LAN to the destination communication. You may select as a system. In addition, when the amount of data to be transmitted or received is small, such as when there is only a control signal for wireless power transmission, the power receiving apparatus 100 may select a BT with low power consumption as the switching destination communication method.

  In addition, in the wireless LAN and the BT, the BT has a higher ability to detect whether the power receiving device 100 and the power feeding device 200 are close to each other. In addition, since the Proximity profile is defined as a BT standard, a warning or display function can be used when the power receiving apparatus 100 and the power feeding apparatus 200 are separated during communication. Therefore, when it is desired to ensure that the power receiving apparatus 100 and the power feeding apparatus 200 remain in proximity, the power receiving apparatus 100 may select BT as the switching destination communication method. Note that the proximity state of the power receiving apparatus 100 and the power feeding apparatus 200 can be detected by occurrence or change of resonance (resonance / resonance) in a wireless power transmission circuit. In this case, the proximity state detection by the wireless LAN or BT is positioned as a complementary function of the proximity state detection by wireless power transmission. For this reason, the power receiving apparatus 100 may reduce the importance of the characteristic as to whether or not the wireless LAN or the BT has a proximity state detection function in the switching destination communication method selection process.

  In the above description, the control unit 101 has been described to automatically determine the HO destination based on the characteristics of communication between the BT and the wireless LAN. However, the present invention is not limited to this. For example, the user may set in advance which of BT and wireless LAN is preferentially selected, and the control unit 101 may select a switching destination according to the setting. For example, the wireless LAN may be selected when an image or a moving image is transmitted to the power supply apparatus 200, and the BT may be selected when there is no such data transmission. Good. Similarly, the user may set parameters such as the amount of data, and the control unit 101 may autonomously determine the switching destination communication method based on the parameters. For example, the wireless LAN may be selected as the HO destination when the amount of data transmitted to the power supply apparatus 200 exceeds a predetermined data amount, and BT may be selected as the HO destination when the data amount is equal to or less than the predetermined data amount. . In addition, for example, when the remaining battery level is equal to or less than a predetermined amount according to the remaining battery level, the proximity state can be confirmed with higher accuracy in order to ensure that the wireless power transmission is performed. May be set to select as a connection destination.

  When the HO destination is determined (S404), the power receiving apparatus 100 subsequently performs a connection process to the selected HO destination (S405). Specifically, for example, when the HO destination is BT, the power receiving apparatus 100 establishes Bluetooth communication with the power supply apparatus 200 by performing a Secure Simple Pairing procedure. At this time, the power receiving apparatus 100 may check whether the Proximity profile of Bluetooth Low Energy (BTLE) is operable, and if it is operable, the power receiving apparatus 100 may perform settings related to the Proximity profile operation. In this setting, setting of the roles of Monitor and Reporter and setting of service operations such as link loss (Link Loss), emergency notification (Immediate Alert), and transmission power setting (Tx Power) are performed. A device that performs Bluetooth communication can display a warning and output a warning sound when detecting a broken link of Bluetooth communication according to the setting contents.

  On the other hand, when the HO destination is a wireless LAN, the power receiving apparatus 100 performs parameter setting and handover processing for performing communication using the wireless LAN. This parameter setting is, for example, a setting for connecting to an already activated access point (not shown), or a setting for direct connection between the power receiving apparatus 100 and the power feeding apparatus 200.

  When the connection process to the HO destination (S405) is completed, communication for wireless power transmission is performed by the communication method of the HO destination. Therefore, the control unit 101 of the power receiving apparatus 100 cuts off the supply of power from the shared antenna 110 to the NFC unit 108 and invalidates the NFC unit 108 (S406). After the NFC unit 108 is invalidated (S406), the power receiving apparatus 100 requests the power supply apparatus 200 to start power supply using the HO-destination communication method (S407). Specifically, the power receiving apparatus 100 includes the power supply start request notification in the payload of the BT or the wireless LAN and transmits it to the power supply apparatus 200. Then, the power receiving apparatus 100 monitors whether the charging is completed (S408), and when the charging is completed (YES in S408), the power receiving apparatus 100 is requested to stop the power feeding using the HO destination communication method (S409). . Specifically, the power receiving apparatus 100 includes the power supply stop request notification in the payload of the BT or the wireless LAN and transmits it to the power supply apparatus 200.

  The power receiving apparatus 100 checks whether a BT Proximity event has occurred during power reception. For example, when the power receiving apparatus 100 detects that the power receiving apparatus 100 has left the power supply apparatus 200, the power reception apparatus 100 supplies power to the power supply apparatus 200. A stop request may be transmitted.

  By the series of controls described so far, the power received by the wireless power transmission does not reach the NFC unit 108, so that the NFC unit 108 can be prevented from being destroyed. In addition, since the communication for wireless power transmission is shifted to BT or wireless LAN, it is not necessary to interrupt wireless power transmission in order to transmit and receive control signals by NFC. Can be received.

  Subsequently, processing executed between the power receiving device 100 and the power feeding device 200 according to the present embodiment will be described with three examples.

(Processing example 1)
In FIG. 5, when the power receiving apparatus 100 is an imaging device and the power feeding apparatus 200 is a storage device (network storage), the power receiving apparatus 100 is charged by wireless power transmission while transmitting data such as an image to the power feeding apparatus 200. It is a sequence diagram which shows the process example in the case of performing. In this processing example, when the power receiving device 100 and the power feeding device 200 perform communication for power transmission using NFC communication, the communication is performed to the wireless LAN.

  In this example, the user of the power receiving apparatus 100 operates the operation unit 104 to make a reservation for backup communication with the storage apparatus (power supply apparatus 200). The control unit 101 of the power receiving apparatus 100 treats the operation by the user as a communication reservation setting with the power supply apparatus 200 (F501). When the user brings the power receiving apparatus 100 closer to the power feeding apparatus 200, the control unit 101 of the power receiving apparatus 100 and the power feeding apparatus 200 controls the NFC unit 108 to establish NFC communication (F502).

  The power receiving apparatus 100 requests the power supply apparatus 200 for a charging service, and the power supply apparatus 200 responds with information on capability values such as voltage and current at that time, and whether or not the charging service can be provided. Reply (F503). Here, it is assumed that information indicating that the charging service is possible is returned as a response.

  When receiving the response that the charging service is possible, the power receiving apparatus 100 subsequently confirms whether or not a handover from communication by NFC to communication by another communication method (for example, BT and wireless LAN) is possible (F504). Here, in response to the inquiry from the power receiving apparatus 100, the power supply apparatus 200 returns, as a response, information indicating that both Bluetooth and wireless LAN can be handed over. In this case, the power receiving apparatus 100 determines that the wireless LAN is the handover destination, for example, because the communication reservation is set (F501).

  In response to this determination, the power receiving apparatus 100 executes a handover to the communication using the wireless LAN of the communication using NFC with the power supply apparatus 200. First, the power receiving apparatus 100 and the power supply apparatus 200 set up wireless LAN communication using the HO-destination wireless LAN setting parameters (F505). Then, when the setup is completed, the power receiving apparatus 100 disables the NFC unit 108 so that the received power is not input to the NFC unit 108.

  Subsequently, the power receiving apparatus 100 transmits a power supply start request to the power supply apparatus 200 by wireless LAN communication (F506). In response to receiving the power supply start request, the power supply apparatus 200 starts supplying power (wireless power transmission) to the power reception apparatus 100 (F507, F508). When the power transmission is operating normally, the power supply apparatus 200 continues to supply power until a power supply stop request is received from the power receiving apparatus 100. Note that the power receiving apparatus 100 may determine whether power is normally received during power reception, and may feed back the determination result to the power supply apparatus 200 at regular intervals. In this case, the power supply apparatus 200 may stop supplying power when receiving a notification that an abnormal state has occurred. After the power supply (wireless power transmission) by the power supply apparatus 200 continues for a certain period, when the power reception apparatus 100 detects the completion of charging (F509), the power reception apparatus 100 uses the wireless LAN communication. A power supply stop request is transmitted to (F510). The power supply apparatus 200 stops supplying power to the power receiving apparatus 100 when the power supply stop request is received.

  In this example, the power receiving apparatus 100 can transmit data such as images and moving images to the power supply apparatus 200 during the power transmission period. As a result, the power transmission control can be switched from NFC communication sharing the power transmission and antenna to communication using another communication method that does not share the antenna. It is also possible to effectively use the communication medium.

(Processing example 2)
FIG. 6 is a sequence diagram illustrating a processing example when only NFC is performed between the power receiving apparatus 100 and the power feeding apparatus 200 and handover cannot be performed. In this example, first, similarly to the processing example 1, NFC communication is established when the power receiving device 100 approaches the power feeding device 200 (F601). The power receiving apparatus 100 requests the power supply apparatus 200 for a charging service, and the power supply apparatus 200 responds with information on capability values such as voltage and current at that time, and whether or not the charging service can be provided. Reply (F602). Also in this example, it is assumed that information indicating that the charging service is possible is returned as a response.

  Then, when receiving a response that the charging service is possible, the power receiving apparatus 100 confirms whether or not a handover from NFC communication to communication using another communication method (for example, BT and wireless LAN) is possible (F603). ). In this example, the power receiving apparatus 100 and the power feeding apparatus 200 do not have a communication function that can be handed over. Therefore, the power receiving apparatus 100 determines that HO is not possible.

  In this case, the power receiving apparatus 100 confirms the state of the power supply unit 111, and calculates the amount of power supply or the time of power supply that is a condition for termination of charging (F604). Then, the power receiving apparatus 100 notifies the power supply apparatus 200 of these calculation results as a charge termination condition by NFC communication (F605). After notifying the power supply device 200 of the charging end condition, the power receiving device 100 invalidates the NFC unit 108 so that the received power from the shared antenna 110 does not reach the NFC unit 108. In the power receiving apparatus 100, after the NFC unit 108 is invalidated, power reception (power transmission) is performed (F606, F607). Here, the power supply apparatus 200 periodically checks whether or not the charging end condition is satisfied (F608), and when the charging end condition is satisfied, stops the supply of power (F609).

  Thus, even when handover from NFC communication to communication using another communication method is not possible, according to this example, power can be efficiently transmitted while avoiding destruction of the NFC unit 108. It becomes possible.

(Processing example 3)
FIG. 7 is a sequence diagram illustrating a processing example when a handover from NFC communication to BT communication is performed between the power receiving apparatus 100 and the power supply apparatus 200 when there is no need for large data transfer. In the present processing example, an example in which the detachment from the proximity state of the power receiving device 100 and the power feeding device 200 is displayed to the user by the BT Proximity event is shown. In this example, first, similarly to the processing examples 1 and 2, the NFC communication is established when the power receiving device 100 approaches the power feeding device 200 (F701). The power receiving apparatus 100 requests the power supply apparatus 200 for a charging service, and the power supply apparatus 200 responds with information on capability values such as voltage and current at that time, and whether or not the charging service can be provided. Reply (F702). Also in this example, it is assumed that information indicating that the charging service is possible is returned as a response.

  When receiving the response that the charging service is possible, the power receiving apparatus 100 subsequently confirms whether or not a handover from communication using NFC to communication using another communication method (for example, BT and wireless LAN) is possible (F703). Here, in response to the inquiry from the power receiving apparatus 100, the power supply apparatus 200 returns, as a response, information indicating that both Bluetooth and wireless LAN can be handed over. In this case, the power receiving apparatus 100 does not need to transfer large data to the power supply apparatus 200, and thus determines, for example, that Bluetooth is the handover destination.

  In response to this determination, the power receiving apparatus 100 performs Bluetooth pairing and a proximity profile setting with the power supply apparatus 200 (F704). When the setting is completed, the power receiving apparatus 100 cuts off the power flowing from the shared antenna 110 to the NFC unit 108 and invalidates the NFC unit 108. Thereafter, the power receiving apparatus 100 transmits a power supply start request to the power supply apparatus 200 using communication based on Bluetooth (F705). In response to receiving the power supply start request, the power supply apparatus 200 starts supplying power (wireless power transmission) to the power reception apparatus 100 (F706, F707). As in Processing Example 1, when the power transmission is operating normally, the power supply apparatus 200 continues to supply power until a power supply stop request is received from the power receiving apparatus 100, and stops power supply when a power supply stop request is received. .

  On the other hand, in this example, for example, it is assumed that the power receiving apparatus 100 is separated from the power feeding apparatus 200 by the user moving the power receiving apparatus 100 (F708). In this case, the power receiving apparatus 100 and the power feeding apparatus 200 each detect that a Proximity event has occurred (F709, F710). When the power receiving apparatus 100 and the power feeding apparatus 200 detect the occurrence of the Proximity event, each of the power receiving apparatus 100 and the power feeding apparatus 200 uses the output unit 105 to generate at least one of a warning sound and a display indicating that the power receiving apparatus 100 and the power feeding apparatus 200 are separated Output (F711, F712). Then, the power supply apparatus 200 finally stops power supply (F713).

  In this example, the communication for controlling power transmission is switched from NFC communication that shares the power transmission and antenna to communication by another communication method that does not share the antenna. The proximity state can be monitored by the previous communication method. Furthermore, by selecting BT as a switching destination, it is possible to suppress the power required for communication for controlling power transmission as compared with the case where a wireless LAN is selected.

  As described above, when the NFC unit 108 and the power receiving unit 109 use a common antenna, the power receiving apparatus 100 according to the present embodiment performs efficient power transmission while preventing the NFC unit 108 from being destroyed. Is possible. In addition, this makes it possible to partially share the circuits of the NFC unit 108 and the power receiving unit 109, thereby reducing costs. Furthermore, by performing communication during power transmission using a communication method that uses an antenna different from that for power transmission, the control response performance is kept high and the power transmission is not interrupted, thereby shortening the charging time. Can do.

<< Other Embodiments >>
The present invention can also be realized by executing the following processing. That is, software (program) that realizes the functions of the above-described embodiments is supplied to a system or apparatus via a network or various storage media, and a computer (or CPU, MPU, etc.) of the system or apparatus reads the program. It is a process to be executed.

Claims (8)

A first communication means having a power receiving function for receiving power and a first communication function for performing communication using a common antenna with the power receiving function; and communication using a different antenna from the first communication means. A communication device having a second communication means having a second communication function to perform,
When communication for power reception by the power reception function is performed using the first communication function, it is possible to switch from communication by the first communication function to communication by the second communication function. Determination means for determining whether or not
If the switching is possible, the communication for performing power reception by the power reception function is switched from communication by the first communication function to communication by the second communication function, and the first communication function is invalidated. And control means for controlling the first communication means and the second communication means,
A communication apparatus comprising: The second communication means is configured to start power transmission when the communication for performing power reception by the power reception function is switched from communication by the first communication function to communication by the second communication function. Notify the power supply device that supplies power
The communication apparatus according to claim 1. When the switching is not possible, the first communication function notifies a power supply device that supplies power of a condition for terminating power reception by the power reception function, and the control unit notifies the first after the condition is notified. Disable the communication function of
The communication apparatus according to claim 1. The power receiving function receives power from a power supply device that supplies power after the first communication function is disabled.
The communication device according to any one of claims 1 to 3, wherein The communication device has a plurality of the second communication means,
When the switching is possible, the control means is configured to receive from the communication by the first communication function from the plurality of second communication means based on the communication characteristics of the plurality of second communication means. The first communication unit and the second communication unit are controlled so as to select the switching destination communication unit and switch the communication by the first communication function to the communication by the switching destination communication unit. ,
The communication apparatus according to any one of claims 1 to 4, wherein the communication apparatus is characterized in that: The characteristics of the communication include the amount of data transmitted or received using the second communication unit with a power supply apparatus that supplies power, the communication speed of each of the plurality of second communication units, Each power consumption of the second communication means, whether each of the plurality of second communication means has a function of detecting that the power supply apparatus and the communication apparatus are close to each other, and the power supply Including at least one of a device and the communication device corresponding to any of the plurality of second communication means,
The communication apparatus according to claim 5. A first communication means having a power receiving function for receiving power and a first communication function for performing communication using a common antenna with the power receiving function; and communication using a different antenna from the first communication means. A communication device control method comprising: a second communication unit having a second communication function to perform,
Switching the communication by the first communication function to the communication by the second communication function when the determination unit performs communication for receiving power by the power reception function using the first communication function. A determination step for determining whether or not
When the control unit is capable of switching, the communication for performing power reception by the power reception function is switched from communication by the first communication function to communication by the second communication function, and the first communication function is changed. A control step of controlling the first communication means and the second communication means so as to invalidate;
A control method characterized by comprising: A first communication means having a power receiving function for receiving power and a first communication function for performing communication using a common antenna with the power receiving function; and communication using a different antenna from the first communication means. A computer provided in a communication device having a second communication means having a second communication function to perform;
When communication for power reception by the power reception function is performed using the first communication function, it is possible to switch from communication by the first communication function to communication by the second communication function. A determination step for determining whether or not
If the switching is possible, the communication for performing power reception by the power reception function is switched from communication by the first communication function to communication by the second communication function, and the first communication function is invalidated. A control step for controlling the first communication means and the second communication means;
A program for running

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