JP6496378B1 - Electronic device and control method of electronic device - Google Patents

Abstract

An electronic device and a method for controlling the electronic device that improve the usefulness of a technique for supplying electric power to the electronic device using radio waves. An electronic device includes a storage battery, a power receiving unit that receives a first radio wave radiated from a power transmitter and converts the first radio wave into electric power, and a communication unit that radiates a second radio wave used for wireless communication. A control unit that performs control in a plurality of control modes. In the first control mode, the control unit scans the frequency band of the first radio wave and does not scan at least a predetermined frequency band other than the first radio wave. When the control unit receives the first radio wave from the power transmitter by the power reception unit, the control unit radiates the second radio wave requesting the power transmission from the power transmitter by the communication unit. [Selection] Figure 1

Description

  The present disclosure relates to an electronic device and a method for controlling the electronic device.

  Conventionally, a technique for supplying electric power to an electronic device using radio waves is known. For example, Patent Document 1 discloses an electronic device that is activated by wireless power transmission from an external device in a state where a battery is not attached.

JP 2012-14422 A

  It is desired to improve the usefulness of technology for supplying electric power to electronic devices using radio waves.

  An object of the present disclosure is to provide an electronic device and a method for controlling the electronic device that improve the usefulness of a technique for supplying power to the electronic device using radio waves.

An electronic apparatus according to an embodiment of the present disclosure receives a storage battery, a first radio wave radiated by a power transmitter, a power receiving unit that converts the first radio wave into electric power, and a second radio wave used for wireless communication. A communication unit, and a control unit that performs control in a plurality of control modes. The control unit scans the frequency band of the first radio wave radiated by the power transmitter in the first control mode, and in a mode other than the first control mode among the frequency bands of receivable radio waves The scanning of at least a predetermined frequency band other than the frequency band of the first radio wave that has been performed is stopped . When the control unit receives the first radio wave from the power transmitter by the power reception unit, the control unit radiates the second radio wave requesting the power transmission from the power transmitter by the communication unit.

A control method according to an embodiment of the present disclosure includes a storage battery, a power reception unit that receives a first radio wave radiated from a power transmitter, converts the first radio wave into electric power, and radiates a second radio wave used for wireless communication. An electronic device control method includes a communication unit and a control unit that performs control in a plurality of control modes. In the first control mode, the control method scans the frequency band of the first radio wave radiated by the power transmitter, and in a mode other than the first control mode among the receivable radio frequency bands . A step of stopping scanning of at least a predetermined frequency band other than the frequency band of the first radio wave that has been performed . The control method includes a step of radiating, by the communication unit, the second radio wave that requests the power transmitter to perform wireless power transmission when the power receiving unit receives the first radio wave from the power transmitter.

  According to the electronic device and the control method for the electronic device according to the embodiment of the present disclosure, the usefulness of the technique for supplying power to the electronic device using radio waves is improved.

It is a figure showing a schematic structure of a power transmission system concerning an embodiment of this indication. It is a functional block diagram which shows schematic structure of the power transmission system of FIG. It is an example of the several control mode which the electronic device of FIG. 2 can take. 3 is a flowchart illustrating an example of processing executed by the electronic device of FIG. 2.

  Hereinafter, embodiments of the present disclosure will be described with reference to the drawings.

  FIG. 1 is a diagram illustrating a schematic configuration of a power transmission system 1 according to an embodiment of the present disclosure. The power transmission system 1 includes a power transmitter 10 and one or more electronic devices 20. In the power transmission system 1, the power transmitter 10 performs wireless power transmission that transmits power to the electronic device 20 using radio waves. Wireless power transmission is also called radio wave power supply or wireless power supply. In FIG. 1, as an example, the power transmission system 1 including the three electronic devices 20, that is, the electronic devices 20 </ b> A, 20 </ b> B, and 20 </ b> C is illustrated, but the number of the electronic devices 20 may be arbitrarily determined.

  FIG. 2 is a functional block diagram illustrating a schematic configuration of the power transmission system 1. As described above, the power transmission system 1 includes the power transmitter 10 and the three electronic devices 20A, 20B, and 20C.

  The power transmitter 10 is, for example, a home gateway or a wireless power transmitter. The power transmitter 10 supplies electric power to the power receiver 20 using electromagnetic waves. In the present embodiment, the power transmitter 10 may supply power to the receiver 20 by radiant wireless power transmission using radio waves such as microwaves. Specifically, the power transmitter 10 generates radio waves for supplying power. The power transmitter 10 radiates the generated radio wave to the electronic device 20.

  The power transmission device 10 includes a power transmission unit 11, a communication unit 12, a storage unit 13, a storage battery 14, and a control unit 15.

  The power transmission unit 11 transmits wireless power. Specifically, the power transmission unit 11 transmits wireless power based on the control of the control unit 15 by, for example, radiating power supplied from a power source such as a distribution facility as a radio wave.

  The power transmission unit 11 includes an antenna 11A and an oscillator 11B. The oscillator 11B transmits wireless power by radiating radio waves for wireless power transmission from the antenna 11A to the electronic device 20 based on the power supplied from the power source. There may be a plurality of antennas 11A. By performing beam forming control using the plurality of antennas 11A, the directivity of the radiated radio wave is improved. For example, when receiving a request for wireless power transmission from the electronic device 20A, the power transmission unit 11 can radiate radio waves for wireless power transmission toward the electronic device 20A by beamforming control.

  The communication unit 12 performs wireless communication with an external device based on the control of the control unit 15. In the present embodiment, the communication unit 12 communicates with the electronic device 20. The power transmission device 10 may perform wireless communication using the antenna 11 </ b> A of the power transmission unit 11 instead of the communication unit 12. The communication unit 12 may transmit information related to wireless power transmission such as a beacon and a response to a request for wireless power transmission to the electronic device 20. In addition, the communication unit 12 may receive information related to wireless power transmission such as a request for wireless power transmission and a pilot signal for notifying the position of the electronic device 20 from the electronic device 20.

  In the present specification, a radio wave radiated from the power transmitter 10 to the electronic device 20 and used for the above-described wireless power transmission and wireless communication is referred to as a first radio wave. For example, a radio wave in a frequency band such as a 2.4 GHz band or a 5.6 to 5.8 GHz band may be used as the first radio wave.

  The storage unit 13 stores information used for processing of the power transmitter 10, a program describing processing contents for realizing each function of the power transmitter 10, and the like. The storage unit 13 may function as a work memory.

  The storage battery 14 can store electric power supplied from a power source.

  The control unit 15 is one or more processors that control and manage the entire power transmitter 10 including each function of the power transmitter 10. The control unit 15 may be configured by a processor such as a CPU (Central Processing Unit) that executes a program defining a control procedure, or a dedicated processor specialized for processing of each function.

  The control unit 15 performs processing for wireless power transmission to the electronic device 20. Specifically, the control unit 15 emits a first radio wave including a beacon for identifying the power transmitter 10 from the communication unit 12. In addition, the control unit 15 receives a request for wireless power transmission from the electronic device 20 through the communication unit 12, and determines whether to perform wireless power transmission on the electronic device 20. When it is determined that wireless transmission is to be performed on the electronic device 20, the control unit 15 radiates the first radio wave for wireless transmission from the power transmission unit 11 to the electronic device 20.

  The electronic device 20 is, for example, a mobile phone, a smartphone, a tablet terminal, or a PC (Personal Computer). The electronic device 20 receives wireless power from the power transmitter 10. Specifically, the electronic device 20 receives a radio wave for power supply from the power transmitter 10. The electronic device 20 converts the received radio wave into DC power. In this way, the electronic device 20 receives wireless power from the power transmitter 10.

  The electronic device 20 includes a power reception unit 21, a communication unit 22, a storage unit 23, a storage battery 24, a notification unit 25, an input unit 26, and a control unit 27.

  The power receiving unit 21 receives wireless power. Specifically, the power reception unit 21 receives wireless power by converting radio waves for wireless power transmission received from the outside into power based on the control of the control unit 27. The power receiving unit 21 supplies the generated power to the storage battery 24. The power generated by the power receiving unit 21 may be directly supplied to the electronic device 20 without being stored in the storage battery 24. In the present embodiment, the first radio wave for radio power transmission radiated from the power transmitter 10 is used as the radio wave for radio power transmission received from the outside.

  The power receiving unit 21 includes an antenna 21A and a rectifier circuit 21B. The antenna 21 </ b> A receives the above-described first radio wave for wireless power transmission from the power transmitter 10. The rectifier circuit 21B converts the first radio wave received by the antenna 21A into DC power. The rectifier circuit 21 </ b> B supplies the converted DC power to the storage battery 24. There may be a plurality of antennas 21A. By receiving radio waves using the plurality of antennas 21A, the intensity of the received radio waves can be increased or noise can be reduced.

  The communication unit 22 performs wireless communication with an external device based on the control of the control unit 27. The communication unit 22 communicates with, for example, the power transmitter 10. The electronic device 20 may perform wireless communication using the antenna 21 </ b> A of the power receiving unit 21 instead of the communication unit 22. The communication unit 22 may transmit information related to wireless power transmission, such as a request for wireless power transmission and a pilot signal for notifying the position of the electronic device 20 to the power transmitter 10. The communication unit 22 may receive information related to wireless power transmission such as a beacon and a response to a request for wireless power transmission from the power transmitter 10.

  In the present specification, a radio wave radiated from the electronic device 20 and used for wireless communication is referred to as a second radio wave. For example, as the second radio wave, a radio wave in a frequency band such as a 700 MHz to 3.5 GHz band, a 2.4 GHz band, or a 5.6 to 5.8 GHz band may be used.

  The storage unit 23 can be configured by a semiconductor memory or a magnetic memory. The storage unit 23 stores information used for processing of the electronic device 20 and a program describing processing contents for realizing each function of the electronic device 20. The storage unit 23 may also function as a work memory. In the present embodiment, the storage unit 23 stores, for example, information on a plurality of control modes of the electronic device 20 described later, predetermined conditions for switching the control modes, and the like.

  The storage battery 24 stores electric power used for the operation of the electronic device 20. The storage battery 24 is electrically connected to the power receiving unit 21. The storage battery 24 can store the power received by the power receiving unit 21. The storage battery 24 can also store power supplied from devices other than the power transmitter 10. For example, the storage battery 24 can store electric power supplied from a power source such as an outlet.

  The notification unit 25 notifies information using sound, vibration, images, and the like. The notification unit 25 includes, for example, a speaker, a vibrator, a display device, and the like. The display device can be, for example, a liquid crystal display (LCD), an organic electro-luminescence display (OELD), or an inorganic electro-luminescence display (IELD). Based on the control of the control unit 27, the notification unit 25 may notify information on the remaining amount of the storage battery 24, information on wireless power transmission from the power transmitter 10, information on a control mode of the electronic device 20 described later, and the like. .

  The input unit 26 receives an input operation from the user. The input unit 26 includes, for example, a physical key such as a power button, an input device such as a touch panel provided integrally with the display device of the notification unit 25, and a pointing device such as a mouse. When operated by the user, the input unit 26 transmits the user operation to the control unit 27 as electronic information.

  The control unit 27 is one or more processors that control and manage the entire electronic device 20 including each function of the electronic device 20. The control unit 27 may be configured by a processor such as a CPU that executes a program that defines a control procedure, or a dedicated processor specialized for processing each function. The control unit 27 may include a plurality of control units including a first control unit 27A, a second control unit 27B, and the like for each function to be provided. The control unit 27 may activate and deactivate each function provided by the control unit by starting and stopping the first control unit 27A and the second control unit 27B.

  The control unit 27 scans a predetermined frequency band among the frequency bands of radio waves that can be received by the electronic device 20. Specifically, the control unit 27 determines whether or not radio waves in a predetermined frequency band are received from the frequency bands of radio waves that can be received by the power receiving unit 21 or the communication unit 22. At that time, the control unit 27 may stop scanning radio waves in other frequency bands. For example, the control unit 27 uses the power receiving unit 21 or the communication unit 22 to scan the frequency band of the first radio wave radiated from the power transmitter 10, and does not scan at least a predetermined frequency band other than the first radio wave. May be.

(Electronic device control mode)
The control unit 27 controls the electronic device 20 in a plurality of control modes. The control mode defines whether to enable or disable control of each function provided by the electronic device 20. With reference to FIG. 3, an example of control of the electronic device 20 using a plurality of control modes by the control unit 27 will be described. The control unit 27 may control the electronic device 20 by a control mode such as a power-on mode, a sleep mode, a wireless power supply mode, and a power-off mode. In addition, the electronic device 20 performs a startup process for starting or terminating the electronic device 20, a calculation process for performing a calculation related to the operation of the electronic device 20, a screen display for displaying a screen on the display device, and an operation for receiving a user operation from the input device Functions such as reception, wireless communication that performs scanning and transmission / reception of radio waves other than the first radio wave for wireless communication, and wireless power feeding that performs scanning and transmission / reception of the first radio wave for wireless power supply are provided. Validity or invalidity of these functions is defined for each control mode, and the control unit 27 controls only the validated functions. For example, the power-on mode is a control mode of the electronic device 20 at a normal time. In the power-on mode, all functions of startup processing, arithmetic processing, screen display, operation reception, wireless communication, and wireless power transmission are enabled. On the other hand, the wireless power supply mode is, for example, a control mode of the electronic device 20 when the remaining amount of the storage battery 24 is low. In the wireless power supply mode, only the startup process and wireless power transmission are enabled, and other functions are disabled. The power consumption in the electronic device 20 varies depending on the function to be enabled. For example, the control unit 27 may switch from a power-on mode with high power consumption to a sleep mode with low power consumption or a wireless power supply mode with low power consumption according to whether there is a user operation or the remaining amount of the storage battery 24. Good. By switching the control mode, it is possible to obtain an effect such as extending the operating time of the electronic device 20 or extending the lifetime of each device of the electronic device 20. In the following description, a mode in which a part of functions other than the functions related to wireless power transmission is limited compared to other control modes among the plurality of control modes is referred to as a first control mode. In the control mode shown in FIG. 3, the first control mode may be a sleep mode or a wireless power supply mode.

(Control of electronic equipment in the first control mode)
In the first control mode, the control unit 27 scans the frequency band of the first radio wave and does not scan at least a predetermined frequency band other than the first radio wave. For example, the predetermined frequency band may be a frequency band other than the first radio wave radiated from the power transmitter 10 among the frequency bands of radio waves that can be received by the power receiving unit 21 or the communication unit 22. In this case, in the first control mode, the control unit 27 scans the frequency band of the first radio wave for wireless power transmission by the power receiving unit 21 or the communication unit 22, and the communication unit 22 uses the frequency band other than the first radio wave. Scanning may be stopped.

  When the control unit 27 receives the first radio wave from the power transmission device 10 by the power reception unit 21, the control unit 27 radiates the second radio wave requesting the power transmission device 10 for wireless power transmission from the communication unit 22. The control unit 27 may set information for uniquely specifying the electronic device 20 or information on the amount of power to be transmitted in the request for wireless power transmission using the second radio wave. These pieces of information may be arbitrary information used for determining whether to perform wireless power transmission to the electronic device 20 by the power transmission device 10.

  When receiving the first radio wave from the power transmitter 10 by the power receiving unit 21, the control unit 27 may determine whether it is possible to receive wireless power transmission from the power transmitter 10 based on the first radio wave. The control unit 27 may determine whether it is possible to receive wireless power transmission from the power transmitter 10 based on whether or not a signal such as a beacon is included in the first radio wave received from the power transmitter 10. In the present embodiment, the beacon may be any beacon. For example, the beacon may be a radio beacon beacon or a Wi-Fi (registered trademark) beacon. In the case of a Wi-Fi beacon, for example, it is determined whether it is possible to receive wireless power transmission from the power transmitter 10 based on whether or not a predetermined keyword such as “Charging Spot” is included in an SSID (Service Set Identifier). May be. Further, the control unit 27 determines whether or not it is possible to receive wireless power transmission from the power transmitter 10 depending on whether or not the received first radio wave from the power transmitter 10 has an intensity of a predetermined value or more. Good. When the control unit 27 determines that the wireless power transmission from the power transmitter 10 can be received based on the first radio wave, the control unit 27 radiates the second radio wave requesting the power transmission 10 to the power transmission by the communication unit 22. Also good.

  The control unit 27 radiates the second radio wave requesting wireless power transmission to the power transmitter 10, and then receives the first radio wave for wireless power transmission radiated from the power transmitter 10 by the power receiving unit 21. The control unit 27 converts the received first radio wave into DC power by the power receiving unit 21 and stores it in the storage battery 24. The control unit 27 radiates the second radio wave requesting the power transmission to the power transmitter 10 and then does not receive the first radio wave for wireless power transmission from the power transmitter 10 for a predetermined period, or performs the radio power transmission from the power transmitter 10. When the first radio wave not to be received is received, the first radio wave scan described above may be resumed.

  The control unit 27 may limit the operation of at least a part of the electronic device 20 in the first control mode. For example, in the first control mode, the control unit 27 restricts all or part of the operations that are not used for wireless power feeding from the power transmitter 10 such as the above-described arithmetic processing, screen display, operation reception, and wireless communication. May be.

  The control unit 27 includes a first control unit 27A that performs processing related to wireless power transmission from the power transmitter 10 in the first control mode, and a second control that performs processing related to the operation of the restricted electronic device 20 in the first control mode. The unit 27B may be provided. The control unit 27 may restrict at least a part of the operation of the electronic device 20 by stopping the operation of the second control unit 27B in the first control mode.

  When the control unit 27 determines that the remaining amount of the storage battery 24 satisfies a predetermined condition using the first threshold in a control mode other than the first control mode, the control unit 27 may shift to the first control mode. The predetermined condition using the first threshold value may be defined as, for example, “the remaining amount of the storage battery 24 is less than 5% of full charge”. When the control unit 27 determines that the remaining amount of the storage battery 24 is less than 5% of the full charge in the control mode other than the first control mode, the control unit 27 shifts to the first control mode in order to avoid power depletion of the electronic device 20. To do. The control unit 27 may perform processing for receiving wireless power transmission in the first control mode, and may restrict at least some operations of the other electronic devices 20. The predetermined condition using the first threshold may be an arbitrary condition. Further, the predetermined condition using the first threshold may be a condition that varies depending on the current control mode. For example, the control unit 27 uses a condition that “the remaining amount of the storage battery 24 is less than 10% of the full charge” in the power-on mode with large power consumption, and “the remaining amount of the storage battery 24 is full in the sleep mode with low power consumption. The condition “less than 5% of charge” may be used. The predetermined condition in which the remaining amount of the storage battery 24 uses the first threshold may be set in combination with a condition other than the remaining amount of the storage battery 24. For example, the conditions other than the remaining amount of the storage battery 24 include a condition regarding the temperature at which the storage battery 24 can be charged, a condition regarding the intensity of the received first radio wave, and the like.

  When the control unit 27 determines that the remaining amount of the storage battery 24 satisfies a predetermined condition using a second threshold value different from the first threshold value in the first control mode, the control unit 27 shifts to a control mode other than the first control mode. May be. The predetermined condition using the second threshold may be defined, for example, as “the remaining amount of the storage battery 24 is 40% or more of full charge”. When the control unit 27 determines that the remaining amount of the storage battery 24 is 40% or more of the full charge as a result of charging the storage battery 24 in the first control mode, the control unit 27 cancels the first control mode, and sets the first power-on mode or the like. You may transfer to control modes other than control mode. As described above, the control unit 27 uses the hysteresis threshold value that makes the first threshold value used for the determination of the shift to the first control mode different from the second threshold value used for the determination of the release of the first control mode. Thereby, it can suppress that the control part 27 repeats switching of control mode by repeating up and down in the vicinity of the threshold value of the storage battery 24. Thereby, it is possible to suppress power consumption accompanying excessive switching of the control mode. The predetermined condition using the second threshold may be an arbitrary condition, similar to the predetermined condition using the first threshold described above.

  The control unit 27 may shift to the first control mode when a predetermined operation is received by the input unit 26 in a control mode other than the first control mode. The predetermined operation may be any operation such as pressing of the power button, touch panel operation, or mouse click.

  The predetermined operation may be a power-off operation for turning off the electronic device 20. For example, when the user performs a power-off operation by pressing the power button during control in a control mode other than the first control mode, the control unit 27 causes the electronic device 20 to transition to the first control mode. Also good. Thereby, the control part 27 may implement the process regarding wireless power transmission in the state where the power of the electronic device 20 seems to be turned off from the user.

  When the control unit 27 receives an operation for shifting to a control mode other than the first control mode by the input unit 26 in the first control mode, the remaining amount of the storage battery 24 satisfies a predetermined condition using the second threshold value. When not satisfy | filling, it does not need to transfer to control modes other than 1st control mode. For example, in the first control mode, the control unit 27 receives an operation for shifting to a control mode other than the first control mode, such as a power-on mode, by a user operation on the touch panel. At this time, if the control unit 27 determines that the remaining amount of the storage battery 24 is 40% or more of full charge, the control unit 27 cancels the first control mode and shifts to a control mode other than the first control mode such as the power-on mode. . On the other hand, if the control part 27 determines with the residual amount of the storage battery 24 not being 40% or more of full charge, it will continue 1st control mode.

  When receiving power transmission from a device other than the power transmitter 10 in the first control mode, the control unit 27 may not receive the first radio wave by the power receiving unit 21. The controller 27 charges the storage battery 24 with the first radio wave from the power transmitter 10 in the first control mode. If the control part 27 detects the other power transmission means which can charge the storage battery 24 faster than wireless power transmission in 1st control mode, it will switch to charge of the storage battery 24 by another power transmission means. When the control unit 27 switches to charging the storage battery 24 by another power transmission unit in the first control mode, the power reception unit 21 does not receive the first radio wave. For example, when the electronic device 20 is connected to a power source such as an outlet during scanning of the frequency band of the first radio wave, the control unit 27 uses the power reception unit 21 or the communication unit 22 to transmit the first radio wave for wireless power transmission. Is stopped, and charging of the storage battery 24 by the power source is started. When the electronic device 20 is connected to a power source such as an outlet during wireless power transmission using the first radio wave, the control unit 27 stops receiving the first radio wave by the power receiving unit 21 and charges the storage battery 24 using the power source. Start.

  When the control unit 27 receives a predetermined operation from the input unit 26 in the first control mode, the control unit 27 may scan the frequency band of the first radio wave. The predetermined operation may be, for example, a touch panel operation by a user or a power button press. When receiving these user operations, the control unit 27 may scan the frequency band of the first radio wave.

  The control unit 27 may scan the frequency band of the first radio wave at a predetermined interval in the first control mode. The predetermined interval may vary depending on predetermined conditions such as the remaining capacity of the storage battery 24, the current time, and the position of the electronic device 20. In the first control mode, for example, the control unit 27 scans the frequency band of the first radio wave at intervals of 10 seconds. When the remaining amount of the storage battery 24 reaches less than 3%, the scan interval is set to 30 seconds. Good. The control unit 27 may increase the scan interval when the current time is in the late night when a restaurant or the like that provides a wireless power transmission service by the power transmitter 10 is not open. In addition, when the position of the electronic device 20 is in a range where a large number of power transmitters 10 such as downtowns are installed, the control unit 27 shortens the scan interval and places the power transmitters 10 such as mountainous areas. In this case, the scan interval may be increased.

(Example of electronic device operation)
An example of the operation of the electronic device 20 according to an embodiment of the present disclosure will be described with reference to FIG.

  Step S101: The control unit 27 determines whether or not a condition for shifting to the first control mode is satisfied. When it determines with not satisfy | filling the transfer conditions to 1st control mode (step S101-No), the control part 27 repeats this step. The conditions for shifting to the first control mode include “the remaining amount of the storage battery 24 is less than the first threshold” or “accepting a user operation for shifting to the first control mode by the input unit 26”, etc. Is included.

  Step S102: When it is determined that the condition for shifting to the first control mode is satisfied (step S101—Yes), the control unit 27 shifts the control mode of the electronic device 20 to the first control mode.

  Step S103: The control unit 27 scans the frequency band of the first radio wave, and does not scan at least a predetermined frequency band other than the first radio wave.

  Step S104: The control unit 27 restricts at least part of the operation of the electronic device 20.

  Step S105: When receiving the first radio wave from the power transmitter 10 by the power receiving unit 21, the control unit 27 determines whether it is possible to receive wireless power transmission from the power transmitter 10 based on the first radio wave. When it is not determined that the wireless power transmission from the power transmitter 10 can be received (step S105—No), the control unit 27 continues the processing of step S103 and step S104.

  Step S <b> 106: When it is determined that wireless power transmission from the power transmitter 10 can be received (Step S <b> 105 -Yes), the control unit 27 causes the communication unit 22 to transmit a second radio wave that requests wireless power transmission to the power transmitter 10. Radiate.

  Step S107: The control unit 27 determines whether or not the first radio wave from the power transmitter 10 is received by the power receiving unit 21. When the first radio wave is not received by the power receiving unit 21 (step S107—No), the control unit 27 continues the processing of step S103 and step S104.

  Step S108: When the second radio wave is received by the power receiving unit 21 (step S107-Yes), the control unit 27 converts the first radio wave into electric power by the power receiving unit 21.

  Step S109: The control unit 27 determines whether or not a condition for shifting to a control mode other than the first control mode is satisfied. When it determines with not satisfy | filling the conditions for transfer to control modes other than 1st control mode (step S109-No), the control part 27 continues the process of step S108. The condition for shifting to a control mode other than the first control mode is “the remaining amount of the storage battery 24 is equal to or greater than a second threshold different from the first threshold” or “other than the first control mode by the input unit 26” Accepting a user operation for shifting to the control mode ”.

  Step S110: When it is determined that the condition for shifting to the control mode other than the first control mode is satisfied (Yes in Step S109), the control unit 27 shifts the control mode to a control mode other than the first control mode, and this process Exit.

  As described above, according to the present embodiment, the electronic device 20 receives the first electric wave radiated from the storage battery 24, the power transmitter 10, and converts the first electric wave into electric power, and wireless communication. The communication unit 22 that radiates the second radio wave used for the control and the control unit 27 that performs control in a plurality of control modes are provided. In the first control mode, the control unit 27 scans the frequency band of the first radio wave and does not scan at least a predetermined frequency band other than the first radio wave. When the control unit 27 receives the first radio wave from the power transmission device 10 by the power reception unit 21, the control unit 27 radiates the second radio wave requesting the power transmission device 10 for wireless power transmission from the communication unit 22. In this way, in the first control mode, by limiting scanning of at least a predetermined frequency band other than the first radio wave, low power of the power stored in the storage battery 24 can be suppressed, and the first radio wave of a longer time can be suppressed. Scanning is possible. In addition, by limiting transmission / reception of radio waves other than the first radio wave, noise is reduced and the intensity of the first radio wave used for wireless power transmission is increased. For this reason, the usefulness of the technique which supplies electric power to the electronic device 20 using an electromagnetic wave improves.

  According to the present embodiment, when the control unit 27 receives the first radio wave from the power transmitter 10 by the power receiving unit 21, the control unit 27 determines that there is a possibility of receiving wireless power transmission from the power transmitter 10 based on the first radio wave. In this case, the communication unit 22 radiates a second radio wave that requests the power transmitter 10 to perform wireless power transmission. Thereby, the low power of the electric power stored in the storage battery 24 is suppressed, and the time during which the electronic device 20 can be operated becomes longer.

  According to the present embodiment, the control unit 27 restricts at least a part of the operation of the electronic device 20 in the first control mode. Thereby, the low power of the electric power stored in the storage battery 24 is suppressed, and the time during which the electronic device 20 can be operated becomes longer.

  According to the present embodiment, the control unit 27 includes a first control unit 27A and a second control unit 27B. The control unit 27 restricts at least a part of the operation of the electronic device 20 by stopping the operation of the second control unit 27B in the first control mode. As described above, the restriction of the operation of the electronic device 20 is realized by being linked to the physical activation and stop of the control unit 27, so that the effect of suppressing the power consumption of the electronic device 20 is enhanced.

  According to the present embodiment, when the control unit 27 determines that the remaining amount of the storage battery 24 satisfies a predetermined condition using the first threshold in a control mode other than the first control mode, the control unit 27 shifts to the first control mode. To do. Thereby, even if operation by a user is not performed, the process regarding wireless power transmission is started according to the residual amount of the storage battery 24. FIG.

  According to this embodiment, when the control unit 27 determines that the remaining amount of the storage battery 24 satisfies the predetermined condition using the second threshold value different from the first threshold value in the first control mode, the first control is performed. Transition to a control mode other than mode. Thereby, the switching of the control mode is prevented from being excessively repeated by repeating the up and down operation in the vicinity of the threshold value of the remaining capacity of the storage battery 24. For this reason, power consumption accompanying switching of the control mode is suppressed.

  According to the present embodiment, when the control unit 27 receives an operation for shifting to a control mode other than the first control mode by the input unit 26 in the first control mode, the remaining amount of the storage battery 24 is set to the second threshold value. When the predetermined condition using is not satisfied, the control mode is not shifted to a control mode other than the first control mode. Thereby, even if it is a case where the end instruction | indication of explicit wireless power transmission is received by the user, if the remaining capacity of the storage battery 24 is not enough, the electronic device 20 can continue the process regarding wireless power transmission.

  According to the present embodiment, the electronic device 20 further includes the input unit 26 that receives an operation by the user. When the control unit 27 receives a predetermined operation from the input unit 26 in a control mode other than the first control mode, the control unit 27 shifts to the first control mode. Thereby, the process regarding radio wave power transmission can be explicitly performed by a user operation, and the usefulness of the technique for supplying power to the electronic device 20 using radio waves is improved.

  According to the present embodiment, the predetermined operation is a power-off operation. Thereby, since the user can designate a period when the electronic device 20 is not used and perform processing related to wireless power transmission, the usefulness of the technique of supplying power to the electronic device 20 using radio waves is improved.

  According to the present embodiment, the control unit 27 does not receive the first radio wave by the power reception unit 21 when receiving power transmission from a device that is not the power transmitter 10 in the first control mode. Thereby, the control part 27 can switch to the charge of the storage battery 24 by another power transmission means, if the other power transmission means which can charge the storage battery 24 faster than wireless power transmission is detected also during wireless power transmission.

  According to the present embodiment, when the control unit 27 receives a predetermined operation from the input unit 26 in the first control mode, the control unit 27 scans the frequency band of the first radio wave. Thereby, the user can explicitly scan the frequency band of the first radio wave at an appropriate timing, and the usefulness of the technology for supplying power to the electronic device 20 using the radio wave is improved.

  According to the present embodiment, the control unit 27 scans the frequency band of the first radio wave at predetermined intervals in the first control mode. The predetermined interval varies depending on predetermined conditions. Thereby, an effective scan of the frequency band of the first radio wave can be performed, and the usefulness of the technology for supplying power to the electronic device 20 using the radio wave is improved.

  Although the above-described embodiments have been described as representative examples, it will be apparent to those skilled in the art that many changes and substitutions can be made within the spirit and scope of the present disclosure. Accordingly, the present disclosure should not be construed as being limited by the above-described embodiments, and various modifications or changes can be made without departing from the scope of the claims. For example, functions and the like included in each means or each step can be rearranged so as not to be logically contradictory, and a plurality of means or steps can be combined into one or divided. is there.

  The present disclosure has been described in the embodiment in which the power reception unit 21, the communication unit 22, the control unit 27, and the like are arranged in the electronic device 20. The processing described as the role of each of the power reception unit 21 and the communication unit 22 can be realized only by the power reception unit 21 according to the use of the electronic device 20 or the like. Moreover, although the above-mentioned embodiment is the structure which the control part 27 scans frequency bands, such as a 1st electromagnetic wave, the structure which the charging part 21 performs said scan may be sufficient. Furthermore, for example, the contents of the present disclosure can be realized by remotely controlling the power receiving unit 21 and the communication unit 22 of the electronic device 20 from the control unit 27 such as a server installed outside the electronic device 20. .

  Moreover, although several control mode was illustrated in this indication, the control mode which the electronic device 20 can take is not restricted to this. The number of control modes may be any number. The functions of the electronic device 20 that can be controlled for each control mode may be defined according to the actual use of the electronic device 20.

DESCRIPTION OF SYMBOLS 1 Power transmission system 10 Power transmitter 11 Power transmission part 11A Antenna 11B Oscillator 12 Communication part 13 Storage part 14 Storage battery 15 Control part 20 Electronic equipment 20A, 20B, 20C Electronic equipment 21 Power receiving part 21A Antenna 21B Rectification circuit 22 Communication part 23 Storage part 24 Storage battery 25 Notification Unit 26 Input Unit 27 Control Unit 27A First Control Unit 27B Second Control Unit

Claims (13)

A storage battery,
A power receiving unit that receives the first radio wave emitted by the power transmitter and converts the first radio wave into electric power;
A communication unit that emits a second radio wave used for wireless communication;
An electronic device comprising a control unit that performs control in a plurality of control modes,
The controller is
In the first control mode, the frequency band of the first radio wave radiated by the power transmitter is scanned, and the frequency band of the receivable radio wave is performed in a mode other than the first control mode . Stop scanning at least a predetermined frequency band other than one radio frequency band,
An electronic device that, when receiving the first radio wave from a power transmitter by the power receiving unit, radiates the second radio wave that requests wireless power transmission to the power transmitter by the communication unit. When the control unit receives the first radio wave from the power transmitter by the power receiving unit, and determines that the wireless power transmission from the power transmitter may be received based on the first radio wave, the control unit The electronic device according to claim 1 , wherein the communication unit radiates the second radio wave requesting the wireless power transmission to an electric machine. The control unit restricts an operation of at least a part of the electronic device in the first control mode;
The electronic device according to claim 1 . The control unit includes a first control unit and a second control unit,
The control unit limits the operation of at least a part of the electronic device by stopping the operation of the second control unit in the first control mode.
The electronic device as described in any one of Claim 1 to 3 . The control unit shifts to the first control mode when determining that the remaining amount of the storage battery satisfies a predetermined condition using a first threshold in a control mode other than the first control mode. 5. The electronic device according to any one of 1 to 4 . When the control unit determines that the remaining amount of the storage battery satisfies a predetermined condition using a second threshold value different from the first threshold value in the first control mode, the control unit controls other than the first control mode. The electronic device according to claim 5 , wherein the electronic device shifts to a mode. In the first control mode, when the control unit receives an operation for shifting to a control mode other than the first control mode, the remaining amount of the storage battery uses the second threshold value. The electronic device according to claim 6 , wherein the electronic device does not shift to a control mode other than the first control mode when a predetermined condition is not satisfied. The electronic device according to any one of claims 1 to 7 ,
It further includes an input unit that accepts user operations,
When the control unit receives a predetermined operation from the input unit in a control mode other than the first control mode, the control unit shifts to the first control mode. The electronic device according to claim 8 , wherein the predetermined operation is a power-off operation. Wherein, in the first control mode, when receiving a transmission from the non-electric power transmitter device and does not receive the first radio wave by the receiving unit, to any one of claims 1 9 The electronic device described. The electronic device according to claim 7 or 8 , wherein the control unit performs the scan of the frequency band of the first radio wave when a predetermined operation is received by the input unit in the first control mode. The control unit performs the scan of the frequency band of the first radio wave at predetermined intervals in the first control mode,
The predetermined interval varies depending on a predetermined condition.
The electronic device according to any one of claims 1 to 11 . Control is performed in a plurality of control modes, a storage battery, a power receiving unit that receives a first radio wave radiated by a power transmitter, and converts the first radio wave into electric power, a communication unit that radiates a second radio wave used for wireless communication, and A control method for an electronic device comprising:
In the first control mode, the frequency band of the first radio wave radiated by the power transmitter is scanned, and the frequency band of the receivable radio wave is performed in a mode other than the first control mode . Stopping scanning of at least a predetermined frequency band other than one radio frequency band;
And a step of radiating the second radio wave requesting the power transmitter for wireless power transmission by the communication unit when the power reception unit receives the first radio wave from the power transmitter.

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