JP7073048B2 - Electronic devices, control methods and programs for electronic devices - Google Patents

Description

The present invention relates to an electronic device that receives electric power in a non-contact manner from an opposing power feeding device.

In recent years, it has a power supply device that has a power supply coil for non-contact power output without physically connecting with a connector, and a power reception coil for non-contact reception of power supplied from the power supply device. Power supply systems including electronic devices (power receiving devices) are known.

Conventionally, in such a power supply system, when an electronic device receives a power smaller than the received power for charging before the start of power reception, the electronic device mutually authenticates with the power supply device by the corresponding power supply method. A technique for receiving power from is known (Patent Document 1).

Japanese Unexamined Patent Publication No. 2015-109794

However, in the prior art disclosed in the above-mentioned patent document, when an electronic device receives an output of a frequency different from the feeding frequency, an unnecessary radio signal is transmitted and wasteful power is consumed. There is.

Further, there is also a problem that the unnecessary wireless signal authenticates the other unintended power supply device and causes another power supply device to transmit unnecessary power.

Therefore, an object of the present invention is to more efficiently transmit and receive wireless signals and electric power exchanged between a power feeding device that executes a wireless power feeding function and an electronic device.

In order to achieve the above object, the electronic device of the present invention is an electronic device that receives power from an opposing power feeding device in a non-contact manner, and is a receiving means for receiving the power and a voltage output from the receiving means. A voltage detecting means for detecting a voltage, a frequency detecting means for detecting a frequency output from the receiving means, and a transmitting means for transmitting a radio signal indicating that the electronic device is a non-contact device capable of receiving the electric power. And, when the voltage detecting means detects a voltage within a predetermined range, the voltage detecting means has a determining means for determining whether or not to transmit the radio signal according to the frequency detected by the frequency detecting means, and the radio signal. When it is determined to transmit, the radio signal is transmitted before the receiving means starts receiving power, and the receiving means starts receiving power in response to the response to the radio signal. ..

According to the present invention, it is to more efficiently transmit and receive wireless signals and electric power exchanged between a power feeding device that executes a wireless power feeding function and an electronic device.

It is a figure for demonstrating the power feeding system in 1st Embodiment. It is a block diagram of the power supply system in 1st Embodiment. The flowchart which shows the operation of the electronic device in 1st Embodiment. It is a block diagram of the power supply system in 2nd Embodiment. The flowchart which shows the operation of the electronic device in 2nd Embodiment.

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

The embodiment described below is an example as a means for realizing the present invention, and may be appropriately modified or modified depending on the configuration of the apparatus to which the present invention is applied and various conditions. It is also possible to appropriately combine the embodiments.

[First Embodiment]
Hereinafter, the first embodiment of the present invention will be described in detail with reference to the drawings.

As shown in FIG. 1, the power supply system according to the first embodiment includes a power supply device 10 and an electronic device 20.

The power feeding device 10 supplies electric power to the electronic device 20 in a non-contact manner via the power feeding coil 101 shown in FIG. 2, and the electronic device 20 supplies power from the power feeding device 10 in a non-contact manner via the power receiving coil 201 shown in FIG. Receive the power to be. Further, the power feeding device 10 and the electronic device 20 wirelessly communicate with each other by the communication unit 110 and the communication unit 210.

The power supply device 10 is a power supply device capable of performing power supply and communication to the electronic device 20 by placing the electronic device 20 on the power supply device, but the form is not limited to this, and for example, the power supply device to the vehicle body. Etc. may be used.

The power feeding device 10 may be a power feeding device that supplies electric power to the electronic device 20 in a non-contact manner by electromagnetic induction, or may be a power feeding device that supplies electric power to the electronic device 20 in a non-contact manner by electromagnetic field resonance. May be good.

The electronic device 20 is an electronic device capable of storing the electric power supplied from the power feeding device 10 in the storage unit 207 shown in FIG. The electronic device 20 is a device that can be operated by the electric power supplied from the power storage unit 207, and includes a mobile body such as a car, a mobile device such as a digital camera and a mobile phone, a memory having a wireless interface, a battery, and the like. Its form is not limited.

The power feeding device 10 wirelessly transmits the first electric power from the power feeding coil 101 at regular intervals to determine whether or not the electronic device 20 is within a predetermined range. When the electronic device 20 is within a predetermined range, a second electric power larger than the first electric power is transmitted to charge the electronic device 20.

The power feeding device 10 wirelessly transmits a magnetic field for short-range wireless communication from the communication coil 102 at regular intervals. Further, the feeding frequency, which is the frequency of the signal transmitted from the feeding coil 101, includes a frequency in the range of at least 6.765 MHz to 6.795 MHz. The feeding frequency is the first frequency. Further, the communication frequency transmitted from the communication coil 102 in a non-contact manner before the power feeding device 10 communicates with the electronic device 20 includes a frequency in the range of at least 13.553 MHz to 13.567 MHz. The communication frequency is the second frequency.

FIG. 2 is a diagram showing a block configuration of a system according to a first embodiment having a power feeding device 10 and an electronic device 20.

<About power supply device 10>
As shown in FIG. 2, the power supply device 10 includes a power supply coil 101, a communication coil 102, a resonance unit 103, a power supply unit 104, a detection unit 105, an oscillation unit 106, a switching unit 107, a control unit 108, a notification unit 109, and a communication unit. It has 110, a storage unit 111, and an operation unit 112.

The power feeding coil 101 wirelessly transmits electric power to the electronic device 20 via the power receiving coil 201.

The feeding coil 101 can be coupled to the power receiving coil 201 of the electronic device 20 by having a loop shape including at least an inductance component.

The communication coil 102 wirelessly transmits a magnetic field for short-range wireless communication at regular intervals. For example, it communicates with a short-range wireless communication device that resonates in the 13.56 MHz band, such as an RFID tag or a non-contact IC card. The specific use of the communication coil 102 will be described in the second embodiment.

The communication coil 102 has a loop shape including at least an inductance component, so that it can communicate with a short-range wireless communication device.

The resonance unit 103 is a circuit that matches the impedances of the feeding coil 101 and the feeding unit 104, or adjusts the resonance frequency of the feeding coil 101.

It is desirable that the resonance portion 103 is configured by combining passive elements having an inductance component or a capacitance component in series and parallel, and the selection method of the combination is appropriately selected according to the state to be matched or adjusted.

It may be possible to change or switch the value of the passive element of the resonance unit 103 described above, and the value may be changed according to the state and position of the electronic device 20 by the control from the control unit 108. And switching may be controlled.

The resonance unit 103 is matched so that the resonance frequency of the feeding coil 101 is about the same as the frequency of the alternating current power generated by the oscillation unit 106.

The feeding unit 104 is a circuit having a function of adjusting the AC signal generated by the oscillating unit 106 to an AC signal of a predetermined power and outputting it to the resonance unit 103.

The power supply unit 104 includes, for example, a power amplification unit composed of a switching amplifier and a DCDC converter that changes a voltage input from a DC power supply (not shown) to a predetermined voltage according to a control signal from the control unit 108. It consists of a power adjustment unit. The form of the feeding unit 104 is not limited to the above-mentioned configuration as long as it has the above-mentioned function. Further, the power feeding unit 104 can detect the transmitted power and detect whether or not an object exists in a predetermined range on the power feeding device 10 according to the change in the transmitted power. Further, the load fluctuation of the electronic device 20 and the insertion of foreign matter other than the electronic device 20 are detected according to the change of the transmitted power during the power feeding period, and the fluctuation detection signal is transmitted to the control unit 108.

The detection unit 105 detects the voltage related to the impedance of the communication coil 102. The voltage related to the impedance of the communication coil 102 is, for example, a voltage at the end of the coil or a voltage corresponding to the voltage, a voltage corresponding to the current of the coil, a voltage corresponding to the power reflected from the coil, or the like. The detection unit 105 is formed by, for example, a combination of a rectifier circuit and an AD converter.

The oscillation unit 106 is a circuit that constantly generates a signal having a predetermined frequency and inputs it to the feeding unit 104 and the detection unit 105, and is composed of a crystal oscillator or the like. The predetermined frequency is an ISM band frequency band belonging to the HF band such as 6.78 MHz or 13.56 MHz as long as it is a frequency band that is permitted to output high power up to about 50 W. Often, it may be a frequency band belonging to the LF band such as several hundred KHz.

The oscillating unit 106 is composed of a crystal oscillator, a phase-locked loop including a voltage-controlled oscillating circuit, and the like, and can oscillate a communication frequency that is N / M times the feeding frequency, with M and N as positive integers. It may have a different configuration.

The switching unit 107 selectively switches the connection between the feeding coil 101 and the resonance unit 103 and the connection between the communication coil 102 and the detection means 105. Further, the switching unit 107 opens and closes an internal switch in response to a control signal from the control unit 108.

The control unit 108 is a means for controlling the entire power feeding device 10, and operates by using a program stored in the storage unit 111. The control unit 108 is a processing circuit such as a CPU or an MPU. The control unit 108 adjusts the value of the variable passive element of the resonance unit 103. Further, the control unit 108 adjusts the electric power to be supplied to the electronic device 20 by sending a control signal to the power supply unit 104. Further, the control unit 108 receives the voltage related to the impedance of the communication coil 102 detected by the detection unit 105, or the information related to the voltage. The control unit 108 may measure the voltage received from the detection unit 105 by using the AD conversion function provided inside.

Further, the control unit 108 inputs a power supply frequency to the power supply unit 104 or inputs a communication frequency to the detection unit 105 by sending a control signal to the oscillation unit 106. Further, the control unit 108 controls the switch included in the switching unit 107 by sending a control signal to the switching unit 107.

Further, the control unit 108 controls to notify the user of the power supply end notification or the power supply failure notification by sending the control signal to the notification unit 109. The power supply end notification is a notification given when it is not necessary to charge the electronic device 20. The power supply disabled notification is a notification given when it is necessary to charge the electronic device 20 and the electronic device 20 cannot be powered.

Further, the control unit 108 transmits / receives a command to / from the electronic device 20 by transmitting / receiving a control signal to / from the communication unit 110. The above-mentioned command may include identification information for identifying a destination, a command code indicating an operation instructed by the command, and the like.

The control unit 108 can also transmit the command only to the electronic device 20 by controlling the communication unit 110 so as to change the identification information included in the command. Further, the control unit 108 reads and writes the information of the storage unit 111 by transmitting and receiving a control signal to and from the storage unit 111. Further, the control unit 108 detects the user's input by receiving a signal from the operation unit 112.

The notification unit 109 can notify the user of the power supply end notification or the power supply failure notification according to the control signal from the control unit 108. The notification unit 109 may be configured by means for notifying voice such as a buzzer or chime, or may be configured by means for displaying an image such as a monitor, a panel, or a screen.

The communication unit 110 is a circuit in which the power feeding device 10 transmits / receives data to / from the electronic device 20. When transmitting data to the electronic device 20, the communication unit 110 receives the transmission data encoded based on the predetermined protocol stored in the storage unit 111 from the control unit 108 and via the modulation circuit. After the transmission signal is modulated, the data is transmitted.

When the communication unit 110 receives data from the electronic device 20, the communication unit 110 inputs the reception data to the control unit 108, and the control unit 108 decodes the data based on a predetermined protocol stored in the storage unit 111. .. As the above-mentioned predetermined protocol, for example, a communication protocol related to Bluetooth (registered trademark) or a protocol related to Wifi can be adopted. Further, a protocol compatible with the protocol for short-range wireless communication defined by ISO14443, ISO15693, and NFC (Near Field Communication) standards may be used.

The storage unit 111 includes a rewritable memory, a computer program that temporarily controls the operation of each part of the power feeding device 10, information such as parameters related to the operation of each part, information received from the electronic device 20 by the communication unit 110, and the like. To record. Further, the storage unit 111 records a management table for managing the target to be fed by the power feeding device 10. Information included in the device information acquired from the electronic device 20 by the power feeding device 10 is registered in the management table recorded in the storage unit 111. The storage unit 111 stores information such as a computer program that controls the operation of each unit of the power feeding device 10 and parameters related to the operation of each unit.

Further, the storage unit 111 stores a program related to a communication method for the power feeding device 10 to communicate with the electronic device 20.

Further, the storage unit 111 stores voltage characteristic data regarding the voltage detected by the detection unit 105 when the electronic device 20 does not exist in a predetermined range on the power supply device 10. In addition, this voltage characteristic data will be referred to as a "first voltage characteristic" hereafter.

The operation unit 112 receives an input from the user to the power supply device 10. The operation unit 112 may be directly operated like a button or a touch panel, or may be indirectly operated like a wireless operation such as a remote controller. The configuration of each part shown in 101 to 112 of the power feeding device 10 is not limited to the above-mentioned configuration, and if it has the same function, each part may have a plurality of parts, or each part may have a different function. It may be the one that may be fused with other parts.

<About electronic device 20>
As shown in FIG. 2, the electronic device 20 includes a power receiving coil 201, a resonance unit 202, a rectifying unit 203, a smoothing unit 204, a voltage detection unit 205, a power receiving unit 206, a power storage unit 207, a control unit 208, a notification unit 209, and a communication unit. It has a unit 210, a storage unit 211, an operation unit 212, and a frequency detection unit 213.
The power receiving coil 201 receives electric power from the power feeding device 10 in a non-contact manner via the power feeding coil 101.

The power receiving coil 201 can be coupled to the feeding coil 101 of the feeding device 10 by having a loop shape including at least an inductance component.

The resonance unit 202 is a circuit that matches the impedances of the power receiving coil 201 and the rectifying unit 203, or matches the resonance frequency of the power receiving coil 201.

Further, the resonance unit 202 is designed so that the resonance frequency becomes the feeding frequency. The resonance portion 202 is configured by combining passive elements having an inductance component or a capacitance component in series and parallel, and it is desirable that the combination is appropriately selected according to the state to be matched. Further, the resonance unit 202 may change the magnitudes of the inductance component and the capacitance component according to the control signal from the control unit 208, switch the circuit, and adjust the value of the variable passive element. The circuit composed of the power receiving coil 201 and the resonance unit 202 is an example of the first receiving unit.

Further, the signal received by the resonance unit 202 is output to the rectifying unit 203 and the frequency detection unit 213.

The rectifying unit 203 is a circuit that rectifies an AC signal received from the resonance unit 202. The rectifying unit 203 is composed of semiconductor elements such as diodes and MOSFETs.

The smoothing unit 204 is a circuit that smoothes the signal rectified by the rectifying unit 203 and converts it into a DC signal. The smoothing portion 204 has at least a capacitor that holds an electric charge, and further has a choke coil and a switch.

The voltage detection unit 205 measures the voltage of the signal smoothed by the smoothing 204. Further, the voltage information regarding the measured data is transmitted to the control unit 208, and the rectified voltage is transmitted to the power receiving unit 206.

The power receiving unit 206 switches whether or not to transmit the signal received from the voltage detection unit 205 to the power storage unit 207 according to the mode and state of the electronic device 20 by the control performed by the control unit 208. The power receiving unit 206 includes semiconductor elements such as FETs. The power receiving unit 206 converts the electric power received from the voltage detecting unit 205 into a constant voltage. The constant voltage generated by the power receiving unit 206 is supplied to each unit of the electronic device 20. Further, the power receiving unit 206 charges the power storage unit 207 by the control performed by the control unit 208.

The power storage unit 207 is a battery that can be attached to and detached from the electronic device 20. Further, the power storage unit 207 is a rechargeable secondary battery, for example, a lithium ion battery or the like. The power storage unit 207 can supply electric power to each unit of the electronic device 20. Further, the storage unit 207 transmits the storage state to the control unit 208.

The control unit 208 is a means for controlling the entire electronic device 20, and operates by using a program stored in the storage unit 211. Further, the control unit 208 may perform control for switching the circuit of the resonance unit 202 and adjusting the value of the variable passive element by transmitting a control signal to the resonance unit 202. Further, the control unit 208 receives voltage information from the voltage detection unit 205. Further, the control unit 208 controls whether or not to transmit the signal received from the voltage detection unit 205 to the power storage unit 207 by transmitting the control signal to the power receiving unit 206.

Further, the control unit 208 can charge the power storage unit 207 with the electric power received from the power feeding device 10 by transmitting the control signal to the power receiving unit 206. The control unit 208 may detect the remaining power of the power storage unit 207 by using the AD conversion function contained therein when controlling the power receiving unit 206. Further, control may be performed while switching between trickle charge control, high-speed charge control, constant voltage control, constant current control, and the like according to the remaining amount of electric power. Further, the control unit 208 controls to notify the user of the power supply end notification or the power supply failure notification by transmitting the control signal to the notification unit 209.

Further, the control unit 208 can transmit and receive commands to and communicate with the power feeding device 10 by controlling the communication unit 210. The above-mentioned command may include identification information for identifying a destination and information for responding to a command code or the like indicating an operation instructed by the command. The control unit 208 may request the power supply device 10 to change the power supply power by using the communication unit 210 according to the battery state. If sufficient power is not supplied from the power feeding device for the control unit 208 to operate, the control unit 208 is operated after charging the power storage unit 207.

The notification unit 209 can notify the user of the power supply end notification or the power supply failure notification according to the control signal from the control unit 208. The notification unit 209 may be configured by means for notifying voice such as a buzzer or a chime, or may be configured by means for displaying an image such as a monitor, a panel, or a screen.

The communication unit 210 is a circuit in which the electronic device 20 transmits / receives data to / from the power supply device 10. At the time of data transmission, the communication unit 210 receives transmission data encoded based on a predetermined protocol stored in the storage unit 211 from the control unit 208, and modulates the transmission signal via the modulation circuit. After you go, send the data.

When receiving data, the communication unit 210 inputs the reception data to the control unit 208, and the control unit 208 decodes the data based on a predetermined protocol stored in the storage unit 211. As the above-mentioned predetermined protocol, for example, a communication protocol related to Bluetooth (registered trademark) or a protocol related to Wifi can be adopted. Further, a protocol compatible with the protocol for short-range wireless communication defined by ISO14443, ISO15693, and NFC (Near Field Communication) standards may be used. The communication unit 210 transmits an advertisement signal defined by the Bluetooth (registered trademark) standard according to a predetermined state, and transmits service information including information indicating non-contact power transmission to a surrounding power supply device. You may. The advertised signal is a signal that informs surrounding devices of the existence of an electronic device, and the electronic device has a function such as non-contact power transmission and can receive power in a non-contact manner. Information indicating that may be included. In the case of this embodiment, the power feeding device 10 requests the electronic device 20 to authenticate by notifying the power feeding device 10 that the electronic device 20 has a non-contact power feeding function by using an advertisement signal.

The storage unit 211 includes a rewritable memory, and temporarily records a computer program that temporarily controls the operation of each part of the power feeding device 10, information such as parameters related to the operation of each part, information transmitted from the power feeding device 10, and the like.

The storage unit 211 stores information such as a computer program that controls the operation of each unit of the electronic device 20 and parameters related to the operation of each unit.

Further, the storage unit 211 records device information of the electronic device 20, power receiving capacity information of the electronic device 20, display data, and the like. The device information of the electronic device 20 includes the identification ID of the electronic device 20, the manufacturer name, the device name, the date of manufacture, the communication method corresponding to the electronic device 20, and the electronic device 20 wirelessly transmitted from the power supply device 10. Information indicating whether or not the user has a means for receiving the power to be generated is included.

The frequency detection unit 213 measures the frequency of the signal output from the resonance unit 213. The frequency is detected based on the peak frequency of the frequency component, and the frequency information regarding the measured data is transmitted to the control unit 208.

Further, the frequency detection unit 213 is composed of a filter circuit (not shown) or the like that passes through the feeding frequency. As for the configuration of the filter circuit, it is desirable to use a bandpass filter designed to pass the peak frequency band of the feeding frequency by combining coils and capacitors in series and parallel. By doing so, it becomes possible to determine whether or not the feeding frequency is being received.

The configuration of each part shown in 201 to 213 of the electronic device 20 is not limited to the above-mentioned configuration, and when the electronic device 20 has the same function, each part may have a plurality of parts or have different functions. It may be the one that may be fused with other parts.

Further, in the first embodiment, the power feeding device 10 transmits power to the electronic device 20 in a non-contact manner, and the electronic device 20 receives power from the power feeding device 10 in a non-contact manner. "Non-contact" may be paraphrased as "wireless" or "non-contact".

<Operation of electronic device 20>
The process performed by the electronic device 20 according to the first embodiment will be described with reference to the flowchart of FIG. The process can be realized by the control unit 208 executing the computer program stored in the storage unit 211.

In S301, the control unit 208 determines whether the measured voltage is within a predetermined range based on the voltage information transmitted from the voltage detection unit 205. When the measured voltage is within a predetermined voltage range set in advance, the control unit 208 determines that the measured voltage is within a predetermined range. When the control unit 208 determines that the measured voltage is within a predetermined range, this flowchart proceeds from S301 to S302. If the control unit 208 does not determine that the measured voltage is within a predetermined range, the flowchart returns from S301 to S301. The voltage within a predetermined range is a voltage at which the transmitting means can operate a circuit for transmitting the radio signal.

In S302, the control unit 208 determines whether or not the measured frequency is the feeding frequency based on the frequency information transmitted from the frequency detection unit 213. When the peak frequency of the measured frequency is the feeding frequency, the control unit 208 determines that the measured frequency is the feeding frequency. When the control unit 208 determines that the measured frequency is the feeding frequency, this flowchart proceeds from S302 to S303. If the control unit 208 does not determine that the measured frequency is the feeding frequency, this flowchart returns from S302 to S301.

In S303, the control unit 208 transmits a wireless signal to the power feeding device 10 by controlling the communication unit 210. This radio signal is an advertisement signal defined by the Bluetooth (registered trademark) standard having a role of notifying service information including information indicating non-contact power transmission to surrounding power supply devices, and is possessed by the opposing power supply device 10. It is transmitted to the communication unit 110. In S303, after the control unit 208 performs a process of transmitting a wireless signal to the power feeding device 10, this flowchart proceeds from S303 to S304.

In S304, the control unit 208 controls the communication unit 210 to determine whether or not the authentication response from the power feeding device 10 has been received. When the power feeding device 10 receives the wireless signal transmitted by the electronic device 20, the power feeding device 10 transmits an authentication response to the electronic device 20. When the control unit 208 determines that the authentication response has been received from the power feeding device 10, this flowchart proceeds from S304 to S305. If the control unit 208 does not determine that the authentication response has been received from the power feeding device 10, this flowchart returns from S304 to S301.

In S305, the control unit 208 starts transmitting information for controlling the power supply. The electronic device 20 controls the communication unit 210. Information for performing non-contact power supply transmission with the power supply device 10 is transmitted. After the control unit 208 starts transmitting information for controlling the power supply, this flowchart proceeds from S305 to S306.

In S306, the control unit 208 starts receiving power by controlling the power receiving unit 206. The power feeding device 10 receives the electric power transmitted by the electronic device 20 and controls the power receiving unit 206 to convert the received electric power into a constant voltage. After the control unit 208 starts receiving power by controlling the power receiving unit 206, this flowchart proceeds from S306 to S307.

In S307, the control unit 208 determines whether or not to end the power reception. The control unit 208 acquires the storage state of the storage unit 207, and determines that the power reception is terminated when the storage state exceeds the predetermined storage amount. Further, by controlling the communication unit 210, the determination result is transmitted to the power feeding device 10. When the control unit 208 determines that the power reception is terminated, this flowchart ends. If the control unit 208 does not determine that the power reception is completed, the flowchart returns from S307 to S306.

Further, the flowcharts of S301 to S307 shown in FIG. 3 may be repeated after the completion.

By performing the operation processing by the electronic device 20 as described above, wasteful power consumption due to the wireless signal that is not required by the electronic device is avoided, and the wireless signal that is not required by the electronic device is required for another power feeding device. It is possible to prevent the transmission of power without power.

[Second Embodiment]
Hereinafter, the second embodiment of the present invention will be described in detail with reference to the drawings. Further, in order to simplify the explanation, the description regarding the common part with the first embodiment will be omitted, and the difference from the first embodiment will be particularly described.

The power supply system according to the second embodiment is composed of the power supply device 10 shown in FIG. 1 and the electronic device 20 as in the first embodiment.

The power feeding device 10 supplies electric power to the electronic device 20 in a non-contact manner via the power feeding coil 101 shown in FIG. 4, and the electronic device 20 supplies power from the power feeding device 10 in a non-contact manner via the power receiving coil 201 shown in FIG. Receive the power to be. The power feeding device 10 transmits a magnetic field for short-range wireless communication to the communication coil 214 of the electronic device 20 via the communication coil 102 shown in FIG. 4 to perform communication.

The electronic device 20 receives a magnetic field for short-range wireless communication from the power feeding device 10 via the communication coil 214 shown in FIG.

Applications for short-range wireless communication include exchanging authentication information for long-distance wireless communication between the power supply device 10 and the electronic device 20, such as Wifi and Bluetooth (registered trademark), and exchanging information for power supply control. When the communication coil 102 and the communication coil 214 communicate with each other, the power receiving coil 201 may receive a magnetic field for short-range wireless communication.

FIG. 4 is a diagram showing a block configuration of a system according to a second embodiment having a power feeding device 10 and an electronic device 20.

As shown in FIG. 4, the electronic device 20 further includes a communication coil 214 in addition to the configuration of the first embodiment.

The resonance unit 202 has at least a first resonance circuit that matches the resonance frequency of the power receiving coil 201 and a second resonance circuit that matches the resonance frequency of the communication coil 214. Further, the first resonance circuit and the second resonance circuit may be switched according to the control signal from the control unit 208. Further, the first resonance circuit of the resonance unit 202 is designed so that the resonance frequency becomes the feeding frequency, and the second resonance circuit of the resonance unit 202 is designed so that the resonance frequency becomes the communication frequency. Further, the resonance unit 202 outputs the signal received by the first resonance circuit to the rectifier unit 203, and outputs the signal received by the second resonance circuit to the frequency detection unit 213. Here, the circuit configured by the first resonance circuit of the reception coil 201 and the resonance unit 202 is an example of the first reception unit. Further, the circuit composed of the communication coil 214 and the second resonance circuit of the resonance unit 202 is an example of the second reception unit.

Further, the frequency detection unit 213 has a communication circuit (not shown) and communicates with the power feeding device 10 at a communication frequency using a protocol for short-range wireless communication defined by an NFC (Near Field Communication) standard. It is configured as follows.

When a predetermined command is received by the above-mentioned communication method by using a communication circuit (not shown), the frequency detection unit 213 determines that the frequency detection unit 213 has a communication frequency and transmits the communication result information to the control unit 208. The configuration of each part shown in 201 to 214 of the electronic device 20 is not limited to the above-mentioned configuration, and when the electronic device 20 has the same function, each part may have a plurality of parts, or each part may have a different function. It may be the one that may be fused with other parts.

<Operation of electronic device 20>
The process performed by the electronic device 20 according to the second embodiment will be described with reference to the flowchart of FIG. The process can be realized by the control unit 208 executing the computer program stored in the storage unit 211.

In S401, the control unit 208 determines whether the measured voltage is within a predetermined range based on the voltage information transmitted from the voltage detection unit 205. When the measured voltage is within a predetermined voltage range set in advance, the control unit 208 determines that the measured voltage is within a predetermined range. When the control unit 208 determines that the measured voltage is within a predetermined range, this flowchart proceeds from S401 to S402. If the control unit 208 does not determine that the measured voltage is within a predetermined range, this flowchart returns from S401 to S401. The voltage within a predetermined range is a voltage at which the circuit for transmitting the radio signal by the transmitting means can operate.

In S402, the control unit 208 performs communication processing with the power feeding device 10 by controlling the communication unit 210. The electronic device 20 communicates with the power feeding device 10 using the protocol for short-range wireless communication defined by the NFC standard, so that the frequency of the output of the second resonance circuit of the resonance unit 202 determines the communication frequency. Detects whether or not it has, and acquires communication result information. In S402, after the control unit 208 performs communication processing with the power feeding device 10, this flowchart proceeds from S402 to S403.

In S403, the control unit 208 determines whether or not the detected frequency is the communication frequency based on the communication result information transmitted from the frequency detection unit 213. When the communication result information indicates the success of communication, the control unit 208 determines that the detected frequency is the communication frequency. When the control unit 208 determines that the detected frequency is the communication frequency, this flowchart returns from S403 to S401. If the control unit 208 does not determine that the detected frequency is the detection frequency, this flowchart proceeds from S403 to S404.

In S404, the control unit 208 transmits a wireless signal to the power feeding device 10 by controlling the communication unit 210. This radio signal is an advertisement signal defined by the Bluetooth (registered trademark) standard having a role of notifying service information including information indicating non-contact power transmission to surrounding power supply devices, and is possessed by the opposing power supply device 10. It is transmitted to the communication unit 110. In S303, after the control unit 208 performs a process of transmitting a wireless signal to the power feeding device 10, this flowchart proceeds from S403 to S405.

In S405, the control unit 208 controls the communication unit 210 to determine whether or not the authentication response from the power feeding device 10 has been received. When the power feeding device 10 receives the wireless signal transmitted by the electronic device 20, the power feeding device 10 transmits an authentication response to the electronic device 20. When the control unit 208 determines that the authentication response has been received from the power feeding device 10, this flowchart proceeds from S405 to S406. If the control unit 208 does not determine that the authentication response has been received from the power feeding device 10, this flowchart returns from S405 to S401.

In S406, the control unit 208 starts transmitting information for controlling the power supply. The electronic device 20 controls the communication unit 210. Information for performing non-contact power supply transmission with the power supply device 10 is transmitted. After the control unit 208 starts transmitting information for controlling the power supply, this flowchart proceeds from S406 to S407.

In S407, the control unit 208 starts receiving power by controlling the power receiving unit 206. The power feeding device 10 receives the electric power transmitted by the electronic device 20 and controls the power receiving unit 206 to convert the received electric power into a constant voltage. After the control unit 208 starts receiving power by controlling the power receiving unit 206, this flowchart proceeds from S407 to S408.

In S408, the control unit 208 determines whether or not to end the power reception. The control unit 208 acquires the storage state of the storage unit 207, and determines that the power reception is terminated when the storage state exceeds the predetermined storage amount. Further, by controlling the communication unit 210, the determination result is transmitted to the power feeding device 10. When the control unit 208 determines that the power reception is terminated, this flowchart ends. If the control unit 208 does not determine that the power reception is finished, the flowchart returns from S408 to S407.

Further, the flowcharts of S401 to S408 shown in FIG. 5 may be repeated after the completion.

By performing the operation processing by the electronic device 20 as described above, wasteful power consumption due to the wireless signal that is not required by the electronic device is avoided, and the wireless signal that is not required by the electronic device is required for another power feeding device. It is possible to prevent the transmission of power without power.

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

Claims (17)

An electronic device that receives power in a non-contact manner from an opposing power supply device.
The receiving means for receiving the electric power and
A voltage detecting means for detecting the voltage output from the receiving means, and a voltage detecting means.
A frequency detecting means for detecting a frequency output from the receiving means, and a frequency detecting means.
A transmission means for transmitting a wireless signal indicating that the electronic device is a non-contact device capable of receiving the electric power, and a transmission means.
When the voltage detecting means detects a voltage within a predetermined range, the voltage detecting means has a determining means for determining whether or not to transmit the radio signal according to the frequency detected by the frequency detecting means.
When it is determined to transmit the wireless signal, the wireless signal is transmitted before the receiving means starts receiving electric power .
An electronic device characterized in that it starts receiving electric power by the receiving means in response to a response to the radio signal. The electronic device according to claim 1, wherein the frequency detecting means detects a frequency based on the peak frequency of a frequency component output from the receiving means. The electronic device according to claim 1 or 2, wherein the receiving means has a first receiving unit that resonates at a first frequency. The electronic device according to claim 3, wherein the frequency detecting means has a filter circuit that passes through the first frequency, and detects the first frequency by using the filter circuit. The electronic device according to claim 3 or 4, wherein the determination means transmits the radio signal when the frequency detection means detects the first frequency. The electronic device according to claim 3 or 4, wherein the determination means does not transmit the radio signal when the frequency detection means does not detect the first frequency. The electronic device according to claim 1 or 2, wherein the receiving means has a first receiving means that resonates at a first frequency and a second receiving means that resonates at a second frequency. The electronic device according to claim 7, wherein the frequency detecting means has a communication circuit that performs communication by the second frequency, and detects the second frequency by using the communication circuit. The electronic device according to claim 7 or 8, wherein the determination means does not transmit the radio signal when the frequency detection means detects the second frequency. The electronic device according to claim 7 or 8, wherein the determination means transmits the radio signal when the frequency detection means does not detect the second frequency. The electronic device according to any one of claims 7 to 10, wherein the second frequency includes a frequency in the range of at least 13.553 MHz to 13.567 MHz. The electronic device according to any one of claims 3 to 11, wherein the first frequency includes a frequency in the range of at least 6.765 MHz to 6.795 MHz. The electronic device according to claim 8, wherein the communication circuit communicates using a communication method according to an NFC standard. The electronic device according to any one of claims 1 to 13, wherein the wireless signal is an advertisement signal defined by the Bluetooth standard. The electronic device according to any one of claims 1 to 14, wherein the voltage within the predetermined range is a voltage at which the transmitting means can operate to transmit the wireless signal. It is a control method of an electronic device having a receiving means for receiving electric power in a non-contact manner from an opposing power feeding device.
A voltage detection step for detecting the voltage output from the receiving means, and
A frequency detection step for detecting a frequency output from the receiving means,
A transmission step of transmitting a radio signal indicating that the electronic device is a non-contact device capable of receiving the electric power, and a transmission step.
When the voltage detection step detects a voltage within a predetermined range, the voltage detection step has a determination step of determining whether or not to transmit the radio signal according to the frequency detected in the frequency detection step.
When it is determined to transmit the wireless signal, the wireless signal is transmitted before the receiving means starts receiving electric power, and the receiving means starts receiving electric power in response to the response to the wireless signal. A characteristic electronic device control method. A computer-readable program for operating a computer as each means of the electronic device according to any one of claims 1 to 15.

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