JP2014007863A - Power supply device, control method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To detect foreign matter and to control power feeding according to the presence or absence of foreign matter.
A power supply apparatus includes a means for detecting a current flowing through the power supply means, a means for detecting a voltage of the power supply means, and a current flowing through the power supply means that is not smaller than a predetermined current. And a control means for performing a predetermined process for restricting the power supply performed by the power supply means when the voltage of the power supply means is greater than a predetermined voltage, and a current flowing through the power supply means is greater than the predetermined current. If the voltage of the power supply means is not greater than the predetermined voltage, the control means performs the predetermined processing.
[Selection] Figure 2

Description

  The present invention relates to a power supply apparatus that supplies power to the outside.

  In recent years, a power feeding system including a power feeding device having a primary coil for outputting power wirelessly without being connected by a connector, and an electronic device having a secondary coil for wirelessly receiving power supplied from the power feeding device. Are known.

  In such a power supply system, it is known that an electronic device charges a battery with electric power received from a power supply device via a secondary coil (Patent Document 1).

JP 2001-275266 A

  Conventionally, a power feeding device supplies power to an electronic device via a primary coil, and the electronic device receives power supplied from the power feeding device via a secondary coil.

  However, when a foreign object such as metal is inserted between the primary coil and the secondary coil, the power output from the power supply device is supplied to the foreign material, and the power supply device is There was a problem that proper power supply could not be performed.

  In order to prevent such problems, the power supply apparatus detects whether or not a foreign object exists in the vicinity of the power supply apparatus when supplying power, and if a foreign object is detected, power is not supplied to the foreign object. Thus, it is necessary to control power feeding.

  Accordingly, an object of the present invention is to detect a foreign object and to control power feeding according to the presence or absence of the foreign object.

  The power supply device according to the present invention includes a power supply means for performing wireless power supply, a means for detecting a current flowing through the power supply means, a means for detecting a voltage of the power supply means, and a current flowing through the power supply means. Control means for performing a predetermined process for restricting the power supply performed by the power supply means when the voltage of the power supply means is greater than a predetermined voltage when the voltage is not smaller than the current. When the current flowing through the means is smaller than the predetermined current and the voltage of the power feeding means is not larger than the predetermined voltage, the control means performs the predetermined processing.

  The control method according to the present invention is a control method for controlling a power feeding device including a power feeding means for performing wireless power feeding, the step of detecting a current flowing through the power feeding means, and the step of detecting a voltage of the power feeding means. And a predetermined process for restricting the power supply performed by the power supply means when the current flowing through the power supply means is not smaller than a predetermined current and the voltage of the power supply means is larger than the predetermined voltage. And when the current flowing through the power supply means is smaller than the predetermined current and the voltage of the power supply means is not larger than the predetermined voltage, the control means performs the predetermined process. And a step of performing.

  The program according to the present invention includes a step of detecting a current flowing through the power supply unit, a step of detecting a voltage of the power supply unit, and a case where the current flowing through the power supply unit is not smaller than a predetermined current, When the voltage of the means is larger than a predetermined voltage, a step of performing a predetermined process for restricting the power feeding performed by the power feeding means; and a case where the current flowing through the power feeding means is smaller than the predetermined current. When the voltage of the power supply means is not larger than the predetermined voltage, the control means is a program for causing a computer to execute the step of performing the predetermined processing.

  According to the present invention, it is possible to detect a foreign object and to control power feeding according to the presence or absence of the foreign object.

It is a figure which shows an example of the electric power feeding system in Example 1. FIG. It is a figure which shows an example of the block diagram of the electric power feeding system in Example 1. FIG. FIG. 3 is a diagram illustrating an example of a configuration of a reflected power detection circuit 112 of the power supply apparatus 100 according to the first embodiment. 3 is a flowchart illustrating an example of authentication processing performed by the power supply apparatus according to the first embodiment. 3 is a flowchart illustrating an example of a power supply control process performed by the power supply apparatus according to the first embodiment. 3 is a flowchart illustrating an example of a foreign object detection process performed by the power supply apparatus according to the first embodiment.

[Example 1]
Hereinafter, Example 1 of the present invention will be described in detail with reference to the drawings. The power supply system according to the first embodiment includes a power supply apparatus 100 and an electronic device 200 as illustrated in FIG. In the power supply system according to the first embodiment, when the distance between the power supply apparatus 100 and the electronic device 200 is within a predetermined range, the power supply apparatus 100 performs wireless power supply to the electronic device 200. Further, when the distance between the power supply apparatus 100 and the electronic device 200 is within a predetermined range, the electronic device 200 receives the power output from the power supply apparatus 100 wirelessly. In addition, when the distance between the power supply apparatus 100 and the electronic device 200 does not exist within a predetermined range, the electronic device 200 cannot accept power from the power supply apparatus 100. Note that the predetermined range is a range in which the power supply apparatus 100 and the electronic device 200 can communicate with each other.

  Note that the power supply apparatus 100 may be capable of wirelessly supplying power to a plurality of electronic devices in parallel.

  The electronic device 200 may be an imaging device such as a camera or a playback device that plays back audio data and video data. Further, the electronic device 200 may be a mobile device such as a mobile phone or a smartphone. Electronic device 200 may be a battery pack including battery 211. Further, the electronic device 200 may be a device such as a car that is driven by electric power supplied from the power supply device 100. The electronic device 200 may be a device that receives a television broadcast, a display that displays video data, or a personal computer. Electronic device 200 may be a device that operates using power supplied from power supply device 100 even when battery 211 is not attached.

  FIG. 2 is a block diagram of the power feeding system according to the first embodiment. As shown in FIG. 2, the power feeding apparatus 100 includes a conversion unit 101, an oscillator 102, a power generation unit 103, a matching circuit 104, a communication unit 105, a power feeding antenna 106, a CPU 107, a ROM 108, a RAM 109, a display unit 110, an operation unit 111, and A reflected power detection circuit 112 is included. Furthermore, the power supply apparatus 100 includes a current detection unit 113, a voltage detection unit 114, and a temperature detection unit 115.

  When the AC power supply (not shown) and the power supply apparatus 100 are connected, the conversion unit 101 converts AC power supplied from the AC power supply (not shown) into DC power, and supplies the converted DC power to the power supply apparatus 100. To do.

  The oscillator 102 oscillates a frequency used to control the power generation unit 103 so as to convert the power supplied from the conversion unit 101 into power corresponding to the target value set by the CPU 107. The oscillator 102 uses a crystal resonator or the like.

  The power generation unit 103 generates power to be output to the outside via the feeding antenna 106 based on the power supplied from the conversion unit 101 and the frequency oscillated by the oscillator 102. The power generation unit 103 includes an FET or the like inside, controls the current flowing between the source and drain terminals of the internal FET according to the frequency oscillated by the oscillator 102, and generates power for output to the outside. Generate. The power generated by the power generation unit 103 is supplied to the matching circuit 104 via the reflected power detection circuit 112. Further, the power generated by the power generation unit 103 includes a first power and a second power.

  The first power is power that the power supply apparatus 100 supplies to the electronic device 200 in order to perform wireless communication with the electronic device 200. The second power is power that is supplied to the electronic device 200 when the power supply apparatus 100 supplies power to the electronic device 200. For example, the first power is 1 W or less, and the second power is 2 W to 10 W. Note that the second power may be 10 W or more. Note that the first power is lower than the second power. In addition, the first power is not limited to 1 W or less as long as the power is used for the power supply apparatus 100 to perform wireless communication.

  When the power supply apparatus 100 supplies the first power to the electronic device 200, the communication unit 105 performs wireless communication with the electronic device 200 via the power supply antenna 106 in conformity with the NFC (Near Field Communication) standard. be able to. The NFC standard is, for example, a standard defined in ISO / IEC 18092 or a standard defined in ISO / IEC 21481. However, when the power supply apparatus 100 supplies the second power to the electronic device 200, the communication unit 105 cannot perform wireless communication with the electronic device 200 in accordance with the NFC standard via the power supply antenna 106. To do.

  The matching circuit 104 is a resonance circuit for performing resonance between the power feeding antenna 106 and the power receiving antenna of the device that is the power feeding target of the power feeding device 100. The matching circuit 104 is a circuit for performing impedance matching between the power generation unit 103 and the feeding antenna 106. The matching circuit 104 includes a coil (not shown) and a capacitor (not shown).

  The CPU 107 sets the inductance value of the matching circuit 104 and the capacitance value of the matching circuit 104 in order to set the resonance frequency f of the power supply antenna 106 to a predetermined frequency. Note that the resonance frequency f of the power feeding antenna 106 is a frequency used for resonance between the power feeding device 100 and a device that is a power feeding target of the power feeding device 100.

  When power is output from the power supply apparatus 100 to the outside, the CPU 107 sets the inductance value of the matching circuit 104 and the capacitance value of the matching circuit 104 in order to set the resonance frequency f of the power supply antenna 106 to a predetermined frequency. To do. The predetermined frequency is, for example, a frequency of 13.56 MHz. Further, the matching circuit 104 can detect a change in the current flowing through the power feeding antenna 106 and the voltage supplied to the power feeding antenna 106.

  Note that, in a state where the resonance frequency f of the power supply antenna 106 is set to a predetermined frequency, the power generated by the power generation unit 103 is supplied to the power supply antenna 106 via the matching circuit 104.

  The communication unit 105 is a circuit used to perform wireless communication corresponding to the NFC standard between the power supply apparatus 100 and the electronic device 200. When the power supply apparatus 100 transmits control data (hereinafter referred to as a command) for controlling the electronic device 200 to the electronic device 200, the communication unit 105 is based on a protocol corresponding to the NFC standard. Modulates the power generated by

  The communication unit 105 performs pulse shift signal corresponding to a command to be transmitted to the electronic device 200 by performing ASK (Amplitude Shift Keying) modulation using amplitude displacement on the first power supplied from the power generation unit 103. Convert to Thereafter, the communication unit 105 transmits the converted pulse signal to the electronic device 200 via the power feeding antenna 106. The pulse signal transmitted to the electronic device 200 is analyzed by the electronic device 200 and detected by the electronic device 200 as bit data including information “1” and information “0”. ASK modulation is modulation using amplitude displacement, and is used for communication between an IC card and a card reader.

  Further, the communication unit 105 includes an encoding circuit corresponding to a predetermined encoding method. The communication unit 105 encodes response data from the electronic device 200 and control data from the electronic device 200 in response to a command transmitted to the electronic device 200 in accordance with a change in the current flowing through the power feeding antenna 106 detected by the matching circuit 104. Demodulated by the circuit. Accordingly, the communication unit 105 can receive response data for the command transmitted to the electronic device 200 and control data transmitted from the electronic device 200 from the electronic device 200 based on the load modulation method.

  The communication unit 105 transmits a command to the electronic device 200 in accordance with an instruction from the CPU 107. Furthermore, when receiving response data or control data from the electronic device 200, the communication unit 105 demodulates the received response data or control data and supplies the demodulated data to the CPU 107.

  The power feeding antenna 106 is an antenna for outputting the power generated by the power generation unit 103 to the outside. The power supply apparatus 100 supplies power to the electronic device 200 via the power supply antenna 106 or transmits a command to the electronic device 200 via the power supply antenna 106. In addition, the power supply apparatus 100 receives control data from the electronic device 200 and response data corresponding to the command transmitted to the electronic device 200 via the power supply antenna 106.

  A CPU (Central Processing Unit) 107 controls the power supply apparatus 100 by executing a computer program stored in the ROM 108. The CPU 107 controls the power supplied to the electronic device 200 by controlling the power generation unit 103.

  The ROM 108 stores information such as a computer program for controlling the power supply apparatus 100 and parameters related to the power supply apparatus 100.

  The RAM 109 is a rewritable memory, and records a computer program for controlling the power supply apparatus 100, information such as parameters regarding the power supply apparatus 100, data received from the electronic device 200 by the communication unit 105, and the like.

  The display unit 110 displays video data supplied from any one of the RAM 109 and the ROM 108.

  The operation unit 111 provides a user interface for operating the power supply apparatus 100. The operation unit 111 includes a power button of the power supply apparatus 100, a mode switching button of the power supply apparatus 100, and the like, and each button includes a switch, a touch panel, and the like. The CPU 107 controls the power supply apparatus 100 according to the input signal input via the operation unit 111.

  The reflected power detection circuit 112 detects information indicating the amplitude voltage V1 of the traveling wave of power output from the power supply antenna 106 and information indicating the amplitude voltage V2 of the reflected wave of power output from the power supply antenna 106. Information indicating the amplitude voltage V1 and information indicating the amplitude voltage V2 detected by the reflected power detection circuit 112 are supplied to the CPU 107. The CPU 107 records information indicating the amplitude voltage V <b> 1 and information indicating the amplitude voltage V <b> 2 supplied from the reflected power detection circuit 112 in the RAM 109.

  An example of the configuration of the reflected power detection circuit 112 is shown in FIG. As shown in FIG. 3, the reflected power detection circuit 112 includes a toroidal core 301, a capacitor 302, a capacitor 303, a diode 304, a resistor 305, a capacitor 306, a capacitor 307, a diode 308, and a resistor 309. Further, the reflected power detection circuit 112 includes an A / D converter 310 and an A / D converter 311.

  The reflected power detection circuit 112 detects the traveling wave of the power output from the feeding antenna 106 as the voltage of the capacitor 307 by CM (inductive coupling and capacitive coupling) coupling. Further, the reflected power detection circuit 112 changes the detected voltage of the capacitor 307 from an analog value to a digital value by the A / D converter 310 and then supplies it to the CPU 107. The reflected power detection circuit 112 detects the reflected wave of the power output from the feeding antenna 106 as the voltage of the capacitor 303 by CM coupling. Further, the reflected power detection circuit 112 changes the detected voltage of the capacitor 303 from an analog value to a digital value by the A / D converter 311 and then supplies it to the CPU 107.

  In the reflected power detection circuit 112, inductive coupling is performed by the toroidal core 301, and capacitive coupling is performed by the capacitor 302 and the capacitor 306.

  The CPU 107 detects the voltage supplied from the A / D converter 310 as a traveling wave amplitude voltage V1 and detects the voltage supplied from the A / D converter 311 as a reflected wave amplitude voltage V2. The CPU 107 obtains the voltage reflection coefficient ρ from the traveling wave amplitude voltage V1 and the reflected wave amplitude voltage V2. Furthermore, the CPU 107 periodically calculates a voltage standing wave ratio VSWR (Voltage Standing Wave Ratio) based on the voltage reflection coefficient ρ.

  The voltage standing wave ratio VSWR is a value indicating a relationship between a traveling wave of power output from the power feeding antenna 106 and a reflected wave of power output from the power feeding antenna 106. The closer the value of the voltage standing wave ratio VSWR is to 1, the smaller the reflected power, the less the loss of power supplied from the power supply apparatus 100 to an external electronic device, and the better the efficiency.

  The following formula (1) represents the voltage reflection coefficient ρ.

  The following formula (2) represents the voltage standing wave ratio VSWR.

  Hereinafter, the voltage standing wave ratio VSWR is referred to as “VSWR”.

  The CPU 107 can detect whether there is a foreign object in the vicinity of the power supply apparatus 100 using the calculated VSWR. The foreign material includes a metal or an IC (Integrated Circuit) card. Further, the CPU 107 can detect whether or not the electronic device 200 exists in the vicinity of the power supply apparatus 100 using the calculated VSWR.

  The current detection unit 113 detects a current supplied from the conversion unit 101 to the power generation unit 103. Information indicating the current detected by the current detection unit 113 is supplied from the current detection unit 113 to the CPU 107.

  The voltage detection unit 114 detects the voltage supplied from the conversion unit 101 to the power generation unit 103. Information indicating the voltage detected by the voltage detection unit 114 is supplied from the voltage detection unit 114 to the CPU 107.

  The temperature detection unit 115 detects the temperature in the vicinity of the power supply apparatus 100. The temperature detection unit 115 includes a thermistor used to detect the temperature. Information indicating the temperature detected by the temperature detection unit 115 is supplied from the temperature detection unit 115 to the CPU 107.

  Next, an example of the configuration of the electronic device 200 will be described with reference to FIG. The electronic device 200 includes a power receiving antenna 201, a matching circuit 202, a rectifying / smoothing circuit 203, a communication unit 204, a CPU 205, a ROM 206, a RAM 207, a current / voltage detection unit 208, a regulator 209, a charge control unit 210, and a battery 211.

  The power receiving antenna 201 is an antenna for receiving power supplied from the power supply apparatus 100. The electronic device 200 receives power from the power supply apparatus 100 via the power reception antenna 201 and performs wireless communication with the power supply apparatus 100 in conformity with the NFC standard. In addition, when the electronic device 200 receives a command from the power supply apparatus 100 via the power receiving antenna 201, the electronic apparatus 200 transmits response data corresponding to the command received from the power supply apparatus 100 to the power supply apparatus 100.

  The matching circuit 202 is a resonance circuit for performing impedance matching so that the power receiving antenna 201 resonates at the same frequency as the resonance frequency f of the power supply antenna 106. The matching circuit 202 includes a variable capacitor, a coil, a resistor, and the like, like the matching circuit 104. The matching circuit 202 controls the matching circuit 202 so that the power receiving antenna 201 resonates at the same frequency as the resonance frequency f of the power feeding antenna 106. In addition, the matching circuit 202 supplies power received by the power receiving antenna 201 to the rectifying and smoothing circuit 203.

  The rectifying and smoothing circuit 203 removes commands and noise from the power received by the power receiving antenna 201 to generate DC power. Further, the rectifying / smoothing circuit 203 supplies the generated DC power to the regulator 209 via the current / voltage detection unit 208. The rectifying / smoothing circuit 203 supplies the command removed from the power received by the power receiving antenna 201 to the communication unit 204. The DC power generated by the rectifying / smoothing circuit 203 is supplied to the regulator 209.

  The communication unit 204 analyzes the command supplied from the rectifying / smoothing circuit 203 according to the NFC standard communication protocol and supplies the command analysis result to the CPU 205. When the first power is supplied from the power supply apparatus 100 to the electronic device 200, the CPU 205 causes the communication unit to change the load included in the communication unit 204 in order to transmit response data to the command to the power supply apparatus 100. 204 is controlled. When the load included in the communication unit 204 changes, the current flowing through the power supply antenna 106 changes. Thereby, the power feeding apparatus 100 receives response data to the command transmitted from the electronic device 200 by detecting a change in the current flowing through the power feeding antenna 106.

  The CPU 205 determines which command the command received by the communication unit 204 is based on the analysis result of the command supplied from the communication unit 204, and performs processing specified by the command code corresponding to the received command, The electronic device 200 is controlled to perform the operation. The CPU 205 controls the electronic device 200 by executing a computer program stored in the ROM 206.

  The ROM 206 stores a computer program that controls the electronic device 200. The ROM 206 records information about the electronic device 200 and the like. The RAM 207 is a rewritable memory and records a computer program for controlling the electronic device 200, data transmitted from the power supply apparatus 100, and the like.

  The current / voltage detection unit 208 detects the voltage and current of the power supplied from the rectifying / smoothing circuit 203 and supplies the detected voltage information and current information to the CPU 205.

  The regulator 209 controls to supply one of the power supplied from the rectifying / smoothing circuit 203 and the power supplied from the battery 211 to the electronic device 200 in accordance with an instruction from the CPU 205.

  The charging control unit 210 controls charging of the battery 211 when power is supplied from the regulator 209. The battery 211 is a battery that can be attached to and detached from the electronic device 200. The battery 211 is a rechargeable secondary battery, such as a lithium ion battery. The battery 211 may be other than a lithium ion battery.

  Note that the feeding antenna 106 and the power receiving antenna 201 may be a helical antenna, a loop antenna, or a planar antenna such as a meander line antenna.

  In the first embodiment, the power supply apparatus 100 performs wireless power supply to the electronic device 200 based on the magnetic field resonance method, but is not limited thereto.

  For example, the power feeding apparatus 100 may perform wireless power feeding to the electronic device 200 based on electric field coupling instead of the magnetic field resonance method. In this case, it is necessary to provide an electrode in the power feeding apparatus 100 and an electrode in the electronic device 200, and power is supplied from the electrode of the power feeding apparatus 100 to the electrode of the electronic device 200 by radio.

  Further, for example, the power feeding apparatus 100 may perform wireless power feeding to the electronic device 200 based on electromagnetic induction instead of the magnetic field resonance method.

  Further, for example, the power supply apparatus 100 may perform wireless power supply to the electronic device 200 based on a standard (“Qi” standard) defined in WPC (Wireless Power Consortium) instead of the magnetic field resonance method. Good.

  Further, for example, the power feeding apparatus 100 may perform wireless power feeding to the electronic device 200 based on a standard defined in WPT (Wireless Power Transmisson) instead of the magnetic field resonance method.

  Further, for example, the power supply apparatus 100 may perform wireless power supply to the electronic device 200 based on a standard defined in CEA (Consumer Electronics Association) instead of the magnetic field resonance method.

  Further, for example, the power supply apparatus 100 may perform wireless power supply to the electronic device 200 based on a standard defined in BWF (Broadband Wireless Forum) instead of the magnetic field resonance method.

  Further, for example, the power supply apparatus 100 may perform wireless power supply to the electronic device 200 based on a standard defined in TTA (Telecommunications Technology Association) instead of the magnetic field resonance method.

  The power supply apparatus 100 supplies power to the electronic device 200 wirelessly. However, “wireless” may be rephrased as “non-contact” or “non-contact”.

  In the first embodiment, the power supply apparatus 100 performs wireless communication with the electronic device 200 in accordance with the NFC standard. For this reason, the CPU 107 controls the power feeding device 100 so that the resonance frequency f of the power feeding antenna 106 is 13.56 MHz.

(Authentication process)
The authentication process performed by the power supply apparatus 100 will be described with reference to the flowchart of FIG. The authentication process is a process in which a device placed in the vicinity of the power supply apparatus 100 and the power supply apparatus 100 perform authentication for power supply. The authentication process illustrated in FIG. 4 is a process performed by the power supply apparatus 100 when the power supply apparatus 100 is on and the power supply apparatus 100 is in a mode for outputting power. The authentication process can be realized by the CPU 107 executing a computer program stored in the ROM 108.

  In step S <b> 401, the CPU 107 controls the oscillator 102, the power generation unit 103, and the matching circuit 104 so that the first power is output via the feeding antenna 106. In this case, the flowchart proceeds from S401 to S402.

  In S402, the CPU 107 detects whether or not the amount of change in VSWR is greater than or equal to a first predetermined value. In this case, the CPU 107 calculates the amount of change in VSWR from the difference between the value of VSWR calculated at a specific timing and the value of VSWR calculated at a timing different from the specific timing. Further, the CPU 107 compares the calculated change amount of VSWR with the first predetermined value. The first predetermined value is a value for detecting whether an object exists within a predetermined range from the power supply apparatus 100. Note that the first predetermined value is recorded in the ROM 108 in advance.

  When it is detected that the amount of change in VSWR is greater than or equal to the first predetermined value (Yes in S402), the CPU 107 detects that an object exists within a predetermined range from the power supply apparatus 100. In this case (Yes in S402), the flowchart proceeds from S402 to S403. When it is detected that the amount of change in VSWR is not greater than or equal to the first predetermined value (No in S402), the CPU 107 detects that no object exists within a predetermined range from the power supply apparatus 100. In this case (No in S402), the flowchart returns from S402 to S401.

  In step S403, the CPU 107 controls the matching circuit 104 and the communication unit 105 so as to transmit an authentication command to the object detected in step S402. The authentication command is used to perform authentication for power supply between the object detected in S402 and the power supply apparatus 100.

  The authentication command is a command for requesting the object detected in S402 for identification information, power reception information, charging information, and state information. The identification information is information indicating the ID or address of the object detected in S402. The power reception information is information indicating how much power the object detected in S402 can receive and information indicating the value of power received from the power supply apparatus 100 by the object detected in S402. The charging information includes information indicating the remaining capacity of the battery connected to the object detected in S402 and information related to charging performed by the object detected in S402. The state information includes information indicating the operation performed on the object detected in S402 and information indicating the power consumption consumed by the object detected in S402. When the authentication command is transmitted, the CPU 107 controls the timer 107a so as to measure the time elapsed since the authentication command was transmitted. In this case, the flowchart proceeds from S403 to S404.

  In step S404, the CPU 107 determines whether a response to the authentication command has been detected. In S403, when the time measured by the timer 107a has passed the first time T1 or longer, if the response to the authentication command is not detected, the CPU 107 determines that the response to the authentication command has not been detected (S404). No). In this case (No in S404), it is considered that the object detected in S402 is in a state where it cannot communicate with the power supply apparatus 100. For this reason, even if the power supply apparatus 100 supplies the second power to an object existing in the vicinity of the power supply apparatus 100, it cannot detect whether the power is normally supplied. For this reason, the power supply apparatus 100 does not perform power supply to an object that cannot communicate with the power supply apparatus 100. Therefore, if the CPU 107 determines that a response to the authentication command has not been detected (No in S404), the process proceeds from S404 to S409.

  In S404, when a response to the authentication command is detected before the time measured by the timer 107a has passed the first time T1 or more, the CPU 107 determines that a response to the authentication command has been detected (Yes in S404). Therefore, if the CPU 107 determines that a response to the authentication command has been detected (Yes in S404), the process proceeds from S404 to S405. The response to the detected authentication command includes identification information, power reception information, charging information, and status information. The CPU 107 records identification information, power reception information, charging information, and state information acquired using the authentication command in the RAM 109.

  In step S405, the CPU 107 determines whether the object detected in step S402 is a predetermined electronic device in response to the response to the authentication command detected in step S404. The predetermined electronic device is a device including at least power receiving means for receiving the second power from the power supply apparatus 100. For example, when the object detected in S402 is the electronic device 200 shown in FIG. 2, the CPU 107 determines that the object detected in S402 is a predetermined electronic device. For example, when the object detected in S402 is an IC card specified in the NFC standard or the like, the CPU 107 determines that the object detected in S402 is not a predetermined electronic device. For example, when the object detected in S402 is a metal, the CPU 107 determines that the object detected in S402 is not a predetermined electronic device. When the CPU 107 determines that the object detected in S402 is a predetermined electronic device (Yes in S405), the process proceeds from S405 to S406. When the CPU 107 determines that the object detected in S402 is not a predetermined electronic device (No in S405), the process proceeds from S405 to S408.

  In step S406, the CPU 107 performs a foreign object detection process. The foreign object detection process is a process for detecting whether there is a foreign object in the vicinity of the power supply apparatus 100. When the foreign object detection process is performed, a foreign object detection flag is set in the RAM 109 when a foreign object is detected within a predetermined range. The foreign object detection flag is information indicating that a foreign object has been detected within a predetermined range. When the foreign object detection process is performed, the foreign object detection flag is not set in the RAM 109 when no foreign object is detected within a predetermined range. The foreign object detection process will be described later. When the foreign object detection process is performed, the process proceeds from S406 to S407.

  In step S <b> 407, the CPU 107 determines whether a foreign object is detected according to whether a foreign object detection flag is set in the RAM 109. When the foreign object detection flag is set, the CPU 107 determines that a foreign object has been detected (Yes in S407). In this case (Yes in S407), the flowchart proceeds from S407 to S408. When the foreign object detection flag is not set, the CPU 107 determines that no foreign object is detected (No in S407). In this case (No in S407), the flowchart proceeds from S407 to S410.

  In step S408, the CPU 107 controls the display unit 110 so as to display a predetermined warning indicating that a foreign object has been detected. Further, the CPU 107 may control the display unit 110 so as to display information for prompting the removal of the foreign matter. Further, the CPU 107 controls the matching circuit 104 and the communication unit 105 so as to transmit a command for notifying that the foreign object has been detected to the electronic device 200 when the electronic device 200 exists within a predetermined range. Also good. In this case, in the flowchart, the process proceeds from S408 to S409.

  In step S <b> 409, the CPU 107 performs a predetermined process for limiting the power output via the power supply antenna 106. For example, it is assumed that the predetermined process includes a process for the CPU 107 to control any one of the power generation unit 103 and the matching circuit 104 so as to reduce the power output via the feeding antenna 106. Further, for example, the predetermined process may include a process for the CPU 107 to control any one of the power generation unit 103 and the matching circuit 104 so as to stop the output of power. In this case, this flowchart ends.

  In step S410, the CPU 101 detects whether or not a device to be fed is selected. For example, when the object detected in S <b> 402 is the electronic device 200, when detecting that the battery 211 is not fully charged, the CPU 107 selects the electronic device 200 as a power supply target. Note that when the object detected in S402 is the electronic device 200, when it is detected that the battery 211 is fully charged, the CPU 107 does not select the electronic device 200 as a power supply target. Further, when the object detected in S402 is the electronic device 200, if it is detected that commercial power is supplied to the electronic device 200 via the AC adapter, the CPU 107 sets the electronic device as a power supply target. Do not select 200. When the CPU 107 detects that a device to be fed is not selected (No in S410), the flowchart returns from S410 to S401. If the CPU 107 detects that a device to be fed is selected (Yes in S410), the process proceeds from S410 to S411.

  In step S411, the CPU 107 performs power supply control processing. The power supply control process is a process for outputting the second power while confirming the state of the power supply target device. The power supply control process will be described later. When the power supply control process is performed, this flowchart ends.

  In the first embodiment, the predetermined electronic device is a device including at least a power receiving unit for receiving the second power from the power supply apparatus 100. However, the predetermined electronic device may be a device including a charging unit for charging the battery using the power supplied from the power supply apparatus 100 in addition to the power receiving unit.

(Power supply control processing)
Next, power supply control processing performed by the power supply apparatus 100 in S411 of the flowchart of FIG. 4 will be described using the flowchart of FIG. The power supply control process can be realized by the CPU 107 executing a computer program stored in the ROM 108. In the following, the power supply control process will be described as an example where the electronic device 200 is selected as the power supply target.

  In step S <b> 501, the CPU 107 controls the oscillator 102, the power generation unit 103, and the matching circuit 104 so that the second power is output via the feeding antenna 106. When the output of the second power is started, the CPU 107 controls the timer 107a so as to measure the time elapsed since the start of the output of the second power. Note that the value of the second power is set based on at least one of power reception information, charging information, and state information of the electronic device 200. In this case, the flowchart proceeds from S501 to S502.

  In S502, the CPU 107 performs a foreign object detection process as in S406. When the foreign object detection process is performed, the process proceeds from S502 to S503.

  In S503, the CPU 107 determines whether or not a foreign object has been detected, as in S407. If it is determined that a foreign object has been detected (Yes in S503), the process proceeds from S503 to S510. If it is determined that no foreign matter has been detected (No in S503), the process proceeds from S503 to S504.

  In step S504, the CPU 107 determines whether or not the time measured by the timer 107a has passed the power supply time TP. The power supply time TP is a time for the power supply apparatus 100 to output the second power to the electronic device 200. Note that the power supply time TP is set by the CPU 107 based on information acquired from the electronic device 200. It is assumed that information indicating the power supply time TP is recorded in the RAM 109. When it is determined by the CPU 107 that the time measured by the timer 107a has passed the power supply time TP (Yes in S504), the process proceeds from S504 to S505. When it is determined by the CPU 107 that the time measured by the timer 107a has not passed the power feeding time TP (No in S504), the flowchart returns from S504 to S501.

  In step S <b> 505, the CPU 107 controls the oscillator 102, the power generation unit 103, and the matching circuit 104 so that the first power is output via the feeding antenna 106. When the output of the first power is started, the CPU 107 controls the timer 107a so as to measure the time elapsed since the start of the output of the first power. In this case, in the flowchart, the process proceeds from S505 to S506.

  In step S <b> 506, the CPU 107 controls the matching circuit 104 and the communication unit 105 so as to transmit a state detection command to the electronic device 200. The state detection command is used to detect the state of the electronic device 200. The state detection command is a command for requesting the electronic device 200 for charging information, power reception information, and state information. When the state detection command is transmitted, the CPU 107 controls the timer 107a so as to measure the time elapsed since the transmission of the state detection command. In this case, the flowchart proceeds from S506 to S507.

  When the electronic device 200 receives the state detection command, the CPU 205 detects charging information, power reception information, and state information. The CPU 205 detects information indicating the value of power received by the electronic device 200 from the power supply apparatus 100 from the voltage information and current information supplied from the current / voltage detection unit 208, and detects this as power reception information. Thereafter, the CPU 205 controls the communication unit 204 to transmit charging information, power reception information, and state information to the power supply apparatus 100 as a response to the state detection command.

  In step S507, the CPU 107 determines whether a response to the state detection command has been detected. When the CPU 107 determines that a response to the state detection command has not been detected (No in S507), the process proceeds from S507 to S511. When the CPU 107 determines that a response to the state detection command has been detected (Yes in S507), the process proceeds from S507 to S508. Note that the CPU 107 records the charging information, power reception information, and state information acquired using the state detection command in the RAM 109.

  In S508, the CPU 107 performs foreign object detection processing in the same manner as in S406. When the foreign object detection process is performed, the flowchart proceeds from S508 to S509.

  In step S509, the CPU 107 determines whether a foreign object has been detected, as in step S407. If it is determined that a foreign object has been detected (Yes in S509), the process proceeds from S509 to S510. If it is determined that no foreign matter has been detected (No in S509), the process proceeds from S509 to S512.

  In S510, the CPU 107 controls the display unit 110 to display a warning indicating that a foreign object has been detected, as in S408. In this case, in the flowchart, the process proceeds from S510 to S511.

  In step S <b> 511, the CPU 107 performs a predetermined process for limiting the power output via the power supply antenna 106. For example, it is assumed that the predetermined process includes a process for the CPU 107 to control any one of the power generation unit 103 and the matching circuit 104 so as to reduce the power output via the feeding antenna 106. Further, for example, the predetermined process may include a process for the CPU 107 to control any one of the power generation unit 103 and the matching circuit 104 so as to stop the output of power. In addition, for example, in the predetermined process, the CPU 107 controls one of the power generation unit 103 and the matching circuit 104 so that the power output via the power feeding antenna 106 is switched from the second power to the first power. It may include a process for performing. In this case, this flowchart ends.

  In step S512, the CPU 107 detects whether or not the electronic device 200 has been removed from the predetermined range.

  For example, the CPU 107 determines that the electronic device 200 has been removed from the predetermined range when the voltage detected by the voltage detection unit 114 has not changed more than a specific value and the VSWR has changed more than a first predetermined value. To detect. In this case, when the voltage detected by the voltage detection unit 114 has not changed more than a specific value and the VSWR has not changed more than the first predetermined value, the CPU 107 determines that the electronic device 200 is within a predetermined range. Detect that it has not been removed.

  Further, for example, when the current detected by the current detection unit 113 has not changed more than a specific value and the VSWR has changed more than a first predetermined value, the CPU 107 removes the electronic device 200 from the predetermined range. Detect that In this case, when the current detected by the current detection unit 113 has not changed more than a specific value and the VSWR has not changed more than the first predetermined value, the CPU 107 determines that the electronic device 200 is within the predetermined range. Detect that it has not been removed.

  When the CPU 107 detects that the electronic device 200 has been removed from the predetermined range (Yes in S512), the process proceeds from S512 to S511. When the CPU 107 detects that the electronic device 200 has not been removed from the predetermined range (No in S512), the process proceeds from S512 to S513.

  In S513, the CPU 107 determines whether or not the time measured by the timer 107a has exceeded the communication time TC. The communication time TC is a time for the power supply apparatus 100 to output the first power to the electronic device 200. Note that the communication time TC is set by the CPU 107 based on information acquired from the electronic device 200. It is assumed that information indicating the communication time TC is recorded in the RAM 109. When the CPU 107 determines that the time measured by the timer 107a has passed the communication time TC (Yes in S513), the flowchart returns from S513 to S501. When it is determined by the CPU 107 that the time measured by the timer 107a has not passed the communication time TC (No in S513), this flowchart returns from S513 to S505.

  The CPU 107 periodically acquires the power reception information of the electronic device 200 using the state detection command until it is determined that the time measured by the timer 107a has passed the communication time TC or longer. This is because the power reception information of the electronic device 200 is used in the foreign object detection process described later. For this reason, the CPU 107 acquires power reception information from the electronic device 200 at a timing of every second until it is determined that the time measured by the timer 107a has passed the communication time TC or more, or every 10 seconds. Power reception information is acquired from the electronic device 200 at the timing. In this case, the CPU 107 detects the amount of change in the value of the power received by the electronic device 200 from the power supply apparatus 100 from the power reception information acquired at the timing of every second. At this time, the detected amount of change in the value of the electric power received by the electronic device 200 from the power supply apparatus 100 is referred to as a “first change amount”. Further, the CPU 107 detects the amount of change in the value of the power received by the electronic device 200 from the power supply apparatus 100 from the power reception information acquired at the timing of every 10 seconds. At this time, the detected amount of change in the value of the electric power received by the electronic device 200 from the power supply apparatus 100 is referred to as a “second change amount”.

  The first change amount is detected from power reception information acquired at a timing of every 1 second, and the second change amount is detected from power reception information acquired at a timing of every 10 seconds. However, it is not limited to this. For example, the first change amount may be detected from power reception information acquired at a timing of every 2 seconds, and the second change amount may be detected from power reception information acquired at a timing of every 5 seconds. It may be detected. The first change amount may be any one that is detected using power reception information detected at a timing different from the second change amount.

(Foreign matter detection processing)
Next, the foreign object detection processing performed by the power supply apparatus 100 in any one of S406 in the flowchart in FIG. 4, S502 in the flowchart in FIG. 5, and S508 in the flowchart in FIG. 5 will be described using the flowchart in FIG. To do. The foreign object detection process can be realized by the CPU 107 executing a computer program stored in the ROM 108. The foreign object detection process will be described below by taking as an example the case where the electronic device 200 exists within a predetermined range.

  When a foreign object is placed in the vicinity of the power supply apparatus 100, the foreign object may generate heat by the power output from the power supply apparatus 100. In this case, the temperature in the vicinity of the power supply apparatus 100 may increase.

  Therefore, in S601, the CPU 107 detects whether or not the temperature detected by the temperature detection unit 115 is equal to or higher than a second predetermined value. The second predetermined value is a value indicating a predetermined temperature for detecting whether or not there is a foreign object in the vicinity of the power supply apparatus 100. The predetermined temperature is, for example, a temperature of 40 ° C. or higher. It is assumed that the second predetermined value is recorded in the ROM 108 in advance. When it is detected that the temperature detected by the temperature detection unit 115 is equal to or higher than the second predetermined value (Yes in S601), the flowchart proceeds from S601 to S610. When it is detected that the temperature detected by the temperature detection unit 115 is not equal to or higher than the second predetermined value (No in S601), the flowchart proceeds from S601 to S602.

  When a foreign object is placed in the vicinity of the power supply apparatus 100, a part of the power output from the power supply apparatus 100 is supplied to the foreign object, and the electronic device 200 may change so that the power received from the power supply apparatus 100 decreases. is there.

  Therefore, in S602, the CPU 107 detects whether or not the received power received by the electronic device 200 is equal to or greater than a third predetermined value. In this case, the CPU 107 detects the value of the received power received by the electronic device 200 from the power supply apparatus 100 based on the received power information acquired from the electronic device 200 using the state detection command. Further, CPU 107 compares the detected received power with a third predetermined value. The third predetermined value is a value indicating electric power for detecting whether or not there is a foreign object in the vicinity of the power supply apparatus 100. It is assumed that the third predetermined value is recorded in the ROM 108 in advance. When it is detected that the received power of the electronic device 200 is greater than or equal to the third predetermined value (Yes in S602), the flowchart proceeds from S602 to S603. When it is detected that the received power of the electronic device 200 is not equal to or greater than the third predetermined value (No in S602), the flowchart proceeds from S602 to S611.

  In S603, the CPU 101 detects whether or not the first change amount is smaller than a fourth predetermined value. The fourth predetermined value is a value indicating the amount of change in power for detecting whether or not there is a foreign object in the vicinity of the power supply apparatus 100. It is assumed that the fourth predetermined value is recorded in the ROM 108 in advance. When it is detected that the first change amount is smaller than the fourth predetermined value (Yes in S603), the flowchart returns from S603 to S601. When it is detected that the first change amount is not smaller than the fourth predetermined value (No in S603), the flowchart proceeds from S603 to S604. When it is detected that the first change amount is smaller than the fourth predetermined value (Yes in S603), the CPU 105 determines that no foreign object is placed near the power supply apparatus 100, and again in S601. Process.

  In step S604, the CPU 101 detects whether or not the second change amount is smaller than a fifth predetermined value. The fifth predetermined value is a value indicating the amount of change in power for detecting whether or not there is a foreign object in the vicinity of the power supply apparatus 100. It is assumed that the fifth predetermined value is recorded in the ROM 108 in advance. When it is detected that the second change amount is smaller than the fifth predetermined value (Yes in S604), the flowchart returns from S604 to S601. When it is detected that the second change amount is not smaller than the fifth predetermined value (No in S604), the flowchart proceeds from S604 to S605. When it is detected that the second change amount is smaller than the fifth predetermined value (Yes in S604), the CPU 105 determines that no foreign object is placed in the vicinity of the power supply apparatus 100, and again in S601. Process.

  In step S <b> 605, the CPU 101 detects whether the power output via the power supply antenna 106 is equal to or greater than a sixth predetermined value. The sixth predetermined value is a value indicating the power for determining whether the power output from the power supply apparatus 100 is the first power or the second power. It is assumed that the sixth predetermined value is recorded in the ROM 108 in advance. When it is detected that the power output via the power feeding antenna 106 is equal to or greater than the sixth predetermined value (Yes in S605), the CPU 105 determines that the power output via the power feeding antenna 106 is the second power. It is determined that In this case, the CPU 105 determines that the power supply apparatus 100 is not performing wireless communication conforming to the NFC standard. When it is detected that the power output via the power supply antenna 106 is equal to or greater than the sixth predetermined value (Yes in S605), the process proceeds from S605 to S606.

  If it is detected that the power output via the power supply antenna 106 is not equal to or greater than the sixth predetermined value (No in S605), the CPU 105 determines that the power output via the power supply antenna 106 is the first power. Judge that there is. In this case, the CPU 105 determines that the power supply apparatus 100 is performing wireless communication complying with the NFC standard. When it is detected that the power output via the power feeding antenna 106 is not equal to or greater than the sixth predetermined value (No in S605), the process proceeds from S605 to S608.

  When a foreign object is placed in the vicinity of the power supply apparatus 100, the current flowing through the power supply apparatus 100 may increase rapidly due to the influence of the foreign object.

  Therefore, in S606, the CPU 107 detects whether or not the current detected by the current detection unit 113 is equal to or greater than a seventh predetermined value. The seventh predetermined value is a value indicating a predetermined current for detecting whether or not there is a foreign object in the vicinity of the power supply apparatus 100. It is assumed that the seventh predetermined value is recorded in the ROM 108 in advance. When it is detected that the current detected by the current detection unit 113 is equal to or greater than the seventh predetermined value (Yes in S606), the flowchart proceeds from S606 to S610. When it is detected that the current detected by the current detection unit 113 is not equal to or greater than the seventh predetermined value (No in S606), the process proceeds from S606 to S607.

  When a foreign object is placed in the vicinity of the power supply apparatus 100, the voltage in the power supply apparatus 100 may rapidly decrease due to the influence of the foreign object.

  Therefore, in S607, the CPU 107 detects whether or not the voltage detected by the voltage detection unit 114 is equal to or less than an eighth predetermined value. The eighth predetermined value is a value indicating a predetermined voltage for detecting whether or not there is a foreign object in the vicinity of the power supply apparatus 100. It is assumed that the eighth predetermined value is recorded in the ROM 108 in advance.

  When it is detected that the voltage detected by the voltage detection unit 114 is equal to or lower than the eighth predetermined value (Yes in S607), the flowchart proceeds from S607 to S610. When it is detected that the voltage detected by the voltage detection unit 114 is not equal to or lower than the eighth predetermined value (No in S607), the flowchart proceeds from S607 to S608.

  When a foreign object is placed in the vicinity of the power supply apparatus 100, the reflection of power output from the power supply apparatus 100 may increase abruptly due to the influence of the foreign object, and the VSWR may change so as to increase rapidly.

  Therefore, in S608, the CPU 107 detects whether or not the amount of change in VSWR is greater than or equal to a ninth predetermined value. The ninth predetermined value is a value indicating the amount of change in VSWR for detecting whether there is a foreign object in the vicinity of the power supply apparatus 100. Note that the ninth predetermined value is recorded in the ROM 108 in advance. Note that the ninth predetermined value is larger than the first predetermined value. For example, the ninth predetermined value is assumed to be a value of 1 or more. If it is detected that the amount of change in VSWR is greater than or equal to the ninth predetermined value (Yes in S608), the process proceeds from S608 to S610. When it is detected that the amount of change in VSWR is not equal to or greater than the eighth predetermined value (No in S608), the flowchart proceeds from S608 to S609.

  In step S <b> 609, the CPU 107 cancels the foreign object detection flag in the RAM 109. In this case, this flowchart ends. If the foreign object detection flag is not set in the RAM 109, the process of S609 may be omitted.

  In step S <b> 610, the CPU 107 sets a foreign object detection flag in the RAM 109. In this case, this flowchart ends.

  When a foreign object is placed in the vicinity of the power supply apparatus 100, the reflection of power output from the power supply apparatus 100 may increase abruptly due to the influence of the foreign object, and the VSWR may change so as to increase rapidly.

  In step S611, the CPU 107 detects whether the value of VSWR is equal to or greater than a tenth predetermined value. The tenth predetermined value is a value indicating VSWR for detecting whether or not a foreign object exists in the vicinity of the power supply apparatus 100. It is assumed that the tenth predetermined value is recorded in the ROM 108 in advance. For example, it is assumed that the tenth predetermined value is a value of 2 to 3 or more. If it is detected that the value of VSWR is greater than or equal to the tenth predetermined value (Yes in S611), the flowchart proceeds from S611 to S608. If it is detected that the value of VSWR is not equal to or greater than the tenth predetermined value (No in S611), the flowchart proceeds from S611 to S603.

  When it is detected that the first change amount is smaller than the fourth predetermined value (Yes in S603), the CPU 105 performs the process of S601 again, but the present invention is not limited to this. . For example, when it is detected that the first change amount is smaller than the fourth predetermined value (Yes in S603), the CPU 107 may perform the processes of S608 to S610.

  When it is detected that the second change amount is smaller than the fifth predetermined value (Yes in S604), the CPU 105 performs the process of S601 again, but the present invention is not limited to this. . For example, when it is detected that the second change amount is smaller than the fifth predetermined value (Yes in S604), the CPU 107 may perform the processes of S608 to S610.

  If it is detected that the power output via the power supply antenna 106 is not equal to or greater than the sixth predetermined value (No in S605), the CPU 105 can accurately detect a foreign object in the processing of S606 and S607. become unable. This is because when the power supply apparatus 100 performs wireless communication conforming to the NFC standard, the current detection unit 113 and the voltage detection unit 114 are affected by the wireless communication conforming to the NFC standard, so that the current and voltage are accurately detected. This is because there is a possibility that it cannot be performed. For this reason, when it is detected that the power output through the power feeding antenna 106 is not equal to or greater than the sixth predetermined value (No in S605), the CPU 107 performs the process of S608 without performing the processes of S606 and S607. To do.

  As described above, the power supply apparatus 100 according to the first embodiment detects whether or not a foreign object exists in the vicinity of the power supply apparatus 100. Furthermore, the power supply apparatus 100 limits the output of power depending on whether or not a foreign object exists in the vicinity of the power supply apparatus 100.

  The power supply apparatus 100 is configured to limit the output of power when an object existing in the vicinity of the power supply apparatus 100 is not a predetermined electronic device (No in S405). As a result, the power supply apparatus 100 can prevent power from being supplied to the foreign object, so that other electronic devices existing in the vicinity of the power supply apparatus 100 can be prevented from being affected by the foreign object. In this case, when the foreign object is an IC card, the power supply apparatus 100 can protect the IC card from the power output from the power supply apparatus 100.

  In addition, when the temperature detected by the temperature detection unit 115 is equal to or higher than the second predetermined value (Yes in S601), the power supply apparatus 100 limits the power output. Thereby, the power supply apparatus 100 can prevent power from being supplied to the foreign object, and can prevent other electronic devices existing near the power supply apparatus 100 from being affected by the foreign object.

  In addition, when the current detected by the current detection unit 113 is equal to or greater than the seventh predetermined value (Yes in S606), the power supply apparatus 100 limits the power output. Thereby, the power supply apparatus 100 can prevent power from being supplied to the foreign object, and can prevent other electronic devices existing near the power supply apparatus 100 from being affected by the foreign object.

  In addition, when the voltage detected by the voltage detection unit 114 is equal to or lower than the eighth predetermined value (Yes in S607), the power supply apparatus 100 limits the power output. Thereby, the power supply apparatus 100 can prevent power from being supplied to the foreign object, and can prevent other electronic devices existing near the power supply apparatus 100 from being affected by the foreign object.

  In addition, when it is detected that the amount of change in VSWR is greater than or equal to the ninth predetermined value (Yes in S608), the power supply apparatus 100 limits the power output. Thereby, the power supply apparatus 100 can prevent power from being supplied to the foreign object, and can prevent other electronic devices existing near the power supply apparatus 100 from being affected by the foreign object.

  Therefore, the power feeding apparatus 100 according to the first embodiment can detect foreign matter and appropriately control power feeding according to the presence or absence of the foreign matter.

  In the first embodiment, the current detection unit 113 detects the current supplied from the conversion unit 101 to the power generation unit 103. However, it is not limited to this. For example, the current detection unit 113 may detect a current flowing in the reflected power detection circuit 112 instead of the current supplied from the conversion unit 101 to the power generation unit 103. Further, for example, the current detection unit 113 may detect a current flowing through the matching circuit 104 instead of the current supplied from the conversion unit 101 to the power generation unit 103. For example, the current detection unit 113 may detect a current flowing through the power feeding antenna 106 instead of the current supplied from the conversion unit 101 to the power generation unit 103.

  In the first embodiment, the voltage detection unit 114 detects the voltage supplied from the conversion unit 101 to the power generation unit 103. However, it is not limited to this. For example, the voltage detection unit 114 may detect the voltage of the reflected power detection circuit 112 instead of the voltage supplied from the conversion unit 101 to the power generation unit 103. For example, the voltage detection unit 114 may detect the voltage of the matching circuit 104 instead of the voltage supplied from the conversion unit 101 to the power generation unit 103. For example, the voltage detection unit 114 may detect the voltage of the feeding antenna 106 instead of the voltage supplied from the conversion unit 101 to the power generation unit 103.

  In the first embodiment, the power supply apparatus 100 uses the VSWR to detect a foreign object, but is not limited thereto. The power supply apparatus 100 may detect a foreign object using a standing wave ratio SWR (Standing Wave Ratio) instead of the VSWR. In addition, the power feeding apparatus 100 may detect a foreign object using information indicating reflection of power output from the power feeding antenna 106 instead of the VSWR.

  In the first embodiment, the power supply apparatus 100 and the electronic device 200 perform wireless communication complying with the NFC standard. However, the power supply apparatus 100 and the electronic device 200 may perform close proximity wireless communication other than wireless communication complying with the NFC standard as long as close proximity wireless communication is performed. The power supply apparatus 100 and the electronic device 200 may perform wireless communication based on the FeliCa (registered trademark) standard instead of wireless communication based on the NFC standard. In addition, the power supply apparatus 100 and the electronic device 200 may perform wireless communication based on RFID (Radio Frequency IDentification) instead of wireless communication based on the NFC standard. In addition, the power supply apparatus 100 and the electronic device 200 may perform wireless communication complying with the MIFARE (registered trademark) standard (ISO / IEC 14443) instead of wireless communication complying with the NFC standard. . In addition, the power supply apparatus 100 and the electronic device 200 may perform wireless communication conforming to the TransferJet (registered trademark) standard instead of wireless communication conforming to the NFC standard.

  In the first embodiment, in order to resonate between the power supply apparatus 100 and the electronic device 200, the resonance frequency of the power supply antenna 106 and the resonance frequency of the power reception antenna 201 are set to 13.56 MHz. However, it is not limited to this. For example, when the power supply apparatus 100 and the electronic device 200 perform wireless communication conforming to the TransferJet standard instead of wireless communication conforming to the NFC standard, the resonance frequency of the power supply antenna 106 and the resonance frequency of the power reception antenna 201 are 4.48 GHz. To be. When the power supply apparatus 100 performs wireless power supply corresponding to the Qi standard instead of the magnetic field resonance method, the resonance frequency of the power supply antenna 106 and the resonance frequency of the power reception antenna 201 are set to any one frequency between 100 kHz and 250 kHz. It may be made to become. Further, the resonance frequency of the power supply antenna 106 and the resonance frequency of the power reception antenna 201 may be 6.78 MHz, or a frequency of several hundred kHz or less.

  In the first embodiment, the power supply apparatus 100 performs wireless communication and power supply in accordance with the NFC standard using the power supply antenna 106. However, the power feeding apparatus 100 may have an antenna for performing wireless communication compliant with the NFC standard and an antenna for performing power feeding.

(Other examples)
The power supply apparatus 100 according to the present invention is not limited to the power supply apparatus 100 described in the first embodiment. For example, the power supply apparatus 100 according to the present invention can be realized by a system including a plurality of apparatuses.

  The various processes and functions described in the first embodiment can also be realized by a computer program. In this case, the processing according to the present invention can be executed by a computer program, and various functions described in the first embodiment are realized.

  Needless to say, the computer program according to the present invention may realize various processes and functions described in the first embodiment by using an OS (Operating System) running on the computer.

  The computer program according to the present invention is read from a computer-readable recording medium and executed by the computer. As the computer-readable recording medium, a hard disk device, an optical disk, a CD-ROM, a CD-R, a memory card, a ROM, or the like can be used. The computer program according to the present invention may be provided from an external device to a computer via a communication interface and executed by the computer.

100 power supply device 200 electronic device

Claims (14)

Power supply means for performing wireless power supply;
Means for detecting a current flowing in the power supply means;
Means for detecting the voltage of the power supply means;
When the current flowing through the power supply means is not smaller than a predetermined current and the voltage of the power supply means is larger than the predetermined voltage, a predetermined process for limiting the power supply performed by the power supply means is performed. Control means,
When the current flowing through the power supply means is smaller than the predetermined current and the voltage of the power supply means is not larger than the predetermined voltage, the control means performs the predetermined processing. Power supply device to do.   2. The predetermined process is not performed when a current flowing through the power feeding unit is smaller than the predetermined current and a voltage of the power feeding unit is larger than the predetermined voltage. The electric power feeder as described in. A step of detecting a value of reflection of the predetermined power when predetermined power is output by the power supply means;
The power supply apparatus according to claim 1, wherein the control unit controls whether or not the predetermined processing is performed using the reflection value.   The power feeding device according to claim 3, wherein when the reflection value is larger than a predetermined value, the control unit performs the predetermined process.   The control means performs the predetermined process when the amount of change in the reflection of the predetermined power detected using the reflection value is larger than the predetermined amount of change. The electric power feeder as described in.   When power for wireless communication is output by the power supply means, the predetermined processing is not performed even if the current flowing through the power supply means is not smaller than the predetermined current. The power supply device according to claim 1, wherein the power supply device is a power supply device.   When power for performing wireless communication is output by the power supply unit, the predetermined process is not performed even when the voltage of the power supply unit is not greater than the predetermined voltage. The power feeding device according to any one of claims 1 to 6. Having means for detecting the temperature;
The power supply apparatus according to any one of claims 1 to 7, wherein when the detected temperature is not lower than a predetermined temperature, the control means performs the predetermined process. When an object is detected within a predetermined range, the control means performs the predetermined process,
The power supply device according to any one of claims 1 to 8, wherein the object does not have means for receiving power supplied from the power supply device.   The power supply apparatus according to any one of claims 1 to 9, wherein the predetermined process includes a process for making electric power output by the power supply apparatus smaller than a predetermined value.   The power supply apparatus according to any one of claims 1 to 10, wherein the predetermined process includes a process for preventing the power supply unit from outputting power. The control means starts the predetermined process after a predetermined warning is given,
The power supply apparatus according to claim 1, wherein the predetermined warning includes a warning for notifying that a foreign object has been detected. A control method for controlling a power supply apparatus including a power supply means for performing wireless power supply,
Detecting a current flowing through the power supply means;
Detecting the voltage of the power supply means;
When the current flowing through the power supply means is not smaller than a predetermined current and the voltage of the power supply means is larger than the predetermined voltage, a predetermined process for limiting the power supply performed by the power supply means is performed. Steps,
When the current flowing through the power supply means is smaller than the predetermined current and the voltage of the power supply means is not larger than the predetermined voltage, the control means includes a step of performing the predetermined processing. Control method. Detecting a current flowing through the power supply means;
Detecting the voltage of the power supply means;
When the current flowing through the power supply means is not smaller than a predetermined current and the voltage of the power supply means is larger than the predetermined voltage, a predetermined process for limiting the power supply performed by the power supply means is performed. Steps,
When the current flowing through the power supply means is smaller than the predetermined current and the voltage of the power supply means is not larger than the predetermined voltage, the control means performs the step of performing the predetermined processing. A program to make it run.

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