JP7538915B2 - Power supply device, method and program performed by the power supply device - Google Patents

Description

The present invention relates to a non-contact power supply system that supplies power from a power supply device to a power receiving device in a non-contact manner.

In recent years, contactless power supply systems have become known that transmit and receive power contactlessly using electromagnetic induction or magnetic resonance methods without connecting a power receiving device to a power supply device by wire. Patent Document 1 describes a technology in which, when power is supplied from a power supply device, communication information is superimposed on the power supply carrier to perform power supply and communication simultaneously, and when power supply is not performed, the power supply is controlled so that only communication is performed.

JP 2010-284006 A

However, in the above-mentioned Patent Document 1, if a communication device other than a power receiving device is placed on the power supply device, the power supply device may start supplying power without detecting the other communication device, and may transmit unnecessary power to the communication device that is not the power supply target. This problem is also true when power supply and communication are performed in a time-division manner.

The present invention was made in consideration of the above problems, and its purpose is to realize a technology that searches for communication devices other than the power receiving device before the power receiving device is detected and power supply starts, thereby preventing power from being supplied to communication devices other than the power receiving device.

In order to solve the above problems and achieve the object, the power supply device of the present invention has a communication means that performs a plurality of polling processes using a plurality of communication methods in Near Field Communication (NFC) and a power transmission means that wirelessly transmits power to a power receiving device, and when an object that is different from the power receiving device and responds to any of the plurality of polling processes is detected by the plurality of polling processes using the plurality of communication methods in the NFC, the power transmission means limits the power transmitted to the power receiving device and receives identification information of the power receiving device .

According to the present invention, by searching for communication devices other than the power receiving device before the power receiving device is detected and power supply is started, it is possible to prevent power from being supplied to communication devices other than the power receiving device.

FIG. 1 is a system configuration diagram of the present embodiment. FIG. 1 is a block diagram showing a device configuration of the present embodiment. 4 is a flowchart showing a power supply operation according to the first embodiment. 4 is a flowchart showing a first search process in FIG. 3 . 4 is a flowchart showing a device information storage process in FIG. 3 . 4 is a flowchart showing a second search process in FIG. 3 . 10 is a flowchart showing a power supply operation according to the second embodiment.

The following describes in detail the form for carrying out the present invention. Note that the embodiment described below is one example for realizing the present invention, and should be appropriately modified or changed depending on the configuration of the device to which the present invention is applied and various conditions, and the present invention is not limited to the following embodiment. In addition, the present invention may be configured by appropriately combining parts of each of the embodiments described below.

<System configuration> First, the configuration of the contactless power supply system of this embodiment will be described with reference to Figure 1.

The non-contact power supply system of this embodiment can supply power wirelessly to the power receiving device 30 that is present within the power supply area of the power supply device 10 without a wired connection. In wireless power supply, power is transmitted and received by receiving electromagnetic waves radiated from the antenna of the power supply device 10 by the antenna of the power receiving device 30. In addition, in the non-contact power supply system, the power supply device 10 and the power receiving device 30 transmit and receive various information used for power supply control by wireless communication.

The power supply device 10 and the power receiving device 30 communicate wirelessly using a predetermined protocol such as NFC (Near Field Communication). When the power supply device 10 detects the power receiving device 30 within the power supply area and communication area of the power supply device 10, the power supply device 10 communicates wirelessly with the power receiving device 30 and starts power supply after authenticating the power receiving device 30. Note that the communication area of the power supply device 10 is wider than the power supply area.

The non-contact power supply system of this embodiment assumes that, in addition to the power supply device 10 and the power receiving device 30 to be supplied with power, a communication device 40 capable of communicating with the power supply device 10 exists within the power supply area and communication area of the power supply device 10. The communication device 40 is an object that is not a power supply object in this embodiment. In this embodiment, only one communication device 40 is illustrated, but there may be multiple communication devices. Furthermore, when a communication device 40 other than the power receiving device 30 exists within the power supply area and communication area of the power supply device 10, the non-contact power supply system of this embodiment controls so as not to start supplying power to the power receiving device 30, except when power supply is specifically permitted.

The power supply device 10 of this embodiment is a stationary type that can supply power to and communicate with the power receiving device 30 while the power receiving device 30 is placed, but is not limited to this and may be a device that supplies power to a moving object such as an automobile. The power supply device 10 of this embodiment may also be a power supply device that wirelessly supplies power to the power receiving device 30 by electromagnetic induction, or a power supply device that wirelessly supplies power to the power receiving device 30 by electromagnetic field resonance.

The power receiving device 30 can charge a battery with power supplied from the power supply device 10. The power receiving device 30 also operates with power supplied from a battery. The power receiving device 30 may be, for example, an imaging device such as a digital camera, a communication terminal such as a mobile phone or a type of mobile phone such as a smartphone, an electronic device such as a mobile player that plays audio and video, or a mobile object such as an automobile that operates with battery power. The power receiving device 30 may also be a medical device capable of wireless communication, a mouse, a speaker, or a peripheral device such as a memory or a battery.

The communication device 40 may be a card-type or sticker-type electronic device that operates using power received from the power supply device 10 when communicating with the power supply device 10. The communication device 40 may also be a mobile object such as an automobile that operates using battery power, an imaging device such as a digital camera, a communication terminal such as a mobile phone or a type of smartphone, or an electronic device such as a mobile player that plays audio and video. The communication device 40 may also be a medical device capable of wireless communication, a mouse, a speaker, or a peripheral device such as a memory or a battery.

<Device configuration> Next, the configuration of the power supply device 10, the power receiving device 30, and the communication device 40 in the non-contact power supply system of this embodiment will be described with reference to FIG. 2.

First, we will explain the configuration and functions of the power supply device 10.

The power supply device 10 has an antenna 11, a matching circuit 12, a power adjustment circuit 13, an oscillator 14, a converter 15, a modulator/demodulator circuit 16, a RAM 17, a ROM 18, a notification unit 19, a CPU 20, and a power connector 21.

The antenna 11 is used to wirelessly transmit power to the power receiving device 30 via the antenna 31, or to communicate with the power receiving device 30 and the communication device 40 via the antenna 31 and the antenna 41. The antenna 11 is preferably coil-shaped and coupled to the antenna 31 and the antenna 41 by an inductance component, but is not limited thereto, and may be coupled by capacitance.

The matching circuit 12 is a circuit that matches the impedance of the antenna 11 and the power adjustment circuit 13, or matches the resonant frequency of the antenna 11. The matching circuit 12 is configured by combining passive elements having an inductance component or a capacitance component in series and parallel, and it is desirable to select the combination appropriately according to the state in which matching is desired. In addition, the values of the variable passive elements of the matching circuit 12 may be changeable or switchable, and the values and switching may be controlled according to the state or position of the power receiving device 30 or the communication device 40 under the control of the CPU 20.

The power adjustment circuit 13 is a circuit that has the function of adjusting the AC signal generated by the oscillator 14 to an AC signal of a predetermined power and outputting it to the matching circuit 12. The power adjustment circuit 13 includes a power amplification unit constituted by, for example, a switching amplifier, and a power adjustment unit constituted by, for example, a DC-DC converter that changes the voltage input from the conversion unit 15 to a predetermined voltage in response to a control signal from the modulation/demodulation circuit 16 or the CPU 20. Note that the power adjustment circuit 13 is not limited to the above configuration as long as it has the above-mentioned power amplification function and power adjustment function.

The oscillator 14 is a circuit that constantly generates a signal of a predetermined frequency and inputs it to the power adjustment circuit 13, and includes a quartz crystal oscillator. The predetermined frequency may be a frequency band that is permitted to output high power up to about 50 W, such as an ISM band frequency band in the HF band, such as 6.78 MHz or 13.56 MHz, or a frequency band in the LF band, such as several hundred KHz.

The conversion unit 15 is a circuit for distributing the power input from the power connector 21 to each part, and is a circuit for converting the commercial AC power supply voltage into a specified DC voltage.

Each part of the power supply device 10 operates using power supplied from the conversion unit 15.

The modulation/demodulation circuit 16 is a circuit that modulates and demodulates the voltage signals of the antenna 11, matching circuit 12, and power adjustment circuit 13 so that the power supply device 10 can transmit and receive data to and from the power receiving device 30 or the communication device 40.

When transmitting data, the modulation and demodulation circuit 16 receives from the CPU 20 data to be transmitted that has been coded based on a specific protocol stored in the ROM 18, and modulates the transmission signal by inputting the data to the power adjustment circuit 13 via the modulation circuit. Depending on the signal input from the modulation and demodulation circuit 16 to the power adjustment circuit 13, the signal output by the power adjustment circuit 13 is amplitude modulated, and data can be transmitted via the antenna 11.

When receiving data, the modulation/demodulation circuit 16 detects a change in the voltage or current of the matching circuit 12 and demodulates the data to be received through a demodulation circuit composed of a filter, a comparator, a switch, etc. The modulation/demodulation circuit 16 inputs the data to be received to the CPU 20, which decodes the data based on a predetermined protocol stored in the ROM 18. The predetermined protocol may be, for example, a protocol for short-range wireless communication defined by ISO/IEC 14443, ISO/IEC 15693, or ISO/IEC 18092 (NFC), or a protocol compatible with these.

RAM 17 is a volatile memory that temporarily stores computer programs that control the operation of each part of power supply device 10, information such as parameters related to the operation of each part, and data received from power receiving device 30 and communication device 40 by modem circuit 16. RAM 17 also stores a management table for managing the target devices to which power supply device 10 supplies power. The management table stored in RAM 17 registers device information received by power supply device 10 from power receiving device 30 and communication device 40.

The ROM 18 is a non-volatile memory that stores computer programs that control the operation of each part of the power supply device 10 and parameters related to the operation of each part. The ROM 18 also stores a program related to a communication method for the power supply device 10 to communicate with the power receiving device 30 and the communication device 40.

The notification unit 19 notifies the user when the power supply device 10 is in a state where power supply is possible or when power supply is restricted. The notification unit 19 may be a display unit such as a display, an audio output unit such as a speaker, or a combination of these.

The CPU 20 is an arithmetic processing device for controlling the entire power supply device 10, and operates according to a program stored in the ROM 18. The program here includes programs for executing various flowcharts described later. The CPU 20 also changes and switches the value of the variable passive element of the matching circuit 12. The CPU 20 also adjusts the power supplied to the power receiving device 30 by controlling the power adjustment circuit 13. The CPU 20 may measure the power supply output from the power adjustment circuit 13 using an internal AD conversion function. The CPU 20 also transmits and receives commands to and from the power receiving device 30 and the communication device 40 by controlling the modulation and demodulation circuit 16. The command includes identification information for identifying the destination and a command code indicating the operation instructed by the command. The CPU 20 can also transmit commands only to the power receiving device 30 or only to the communication device 40 by controlling the modulation and demodulation circuit 16 to change the identification information included in the command.

The power connector 21 is a connector for obtaining power from a commercial power source.

The power supply device 10 of this embodiment performs power supply control to wirelessly supply sufficient power to the power receiving device 30 to charge the battery 39 in the power receiving device 30. The power supply control of this embodiment is realized by at least the antenna 11, the power adjustment circuit 13, the oscillator 14, and the CPU 20, and may further include a matching circuit 12.

In addition, in this embodiment, communication between the power supply device 10 and the power receiving device 30 or the communication device 40 is realized by at least the antenna 11, the power adjustment circuit 13, the oscillator 14, the modulation/demodulation circuit 16, the ROM 18, and the CPU 20, and may further include a matching circuit 12.

The configuration of each of the parts 11 to 21 of the power supply device 10 is not limited to that described above. If they have similar functions, there may be multiple parts, each part may have a different function, or each part may be combined with other blocks.

Next, the configuration and functions of the power receiving device 30 of this embodiment will be described.

The power receiving device 30 has an antenna 31, a matching circuit 32, a rectifying and smoothing circuit 33, a regulator 34, a modulation and demodulation circuit 35, a CPU 36, a RAM 37, a ROM 38, and a battery 39.

The antenna 31 is used to wirelessly receive power from the power supply device 10 via the antenna 11, or to communicate with the power supply device 10 via the antenna 11. It is preferable that the antenna 31 is coil-shaped and coupled to the antenna 11 by an inductance component, but this is not limited thereto, and the antenna 31 may be coupled by capacitance.

The matching circuit 32 is a circuit that matches the impedance of the antenna 31 and the rectifying and smoothing circuit 33, or matches the resonant frequency of the antenna 31. The matching circuit 32 is configured by combining passive elements having an inductance component or a capacitance component in series and in parallel, and it is desirable to select the combination appropriately according to the state to be matched. In addition, it may be possible to change or switch the values of the variable passive elements of the matching circuit 32, and the values and switching may be controlled by the CPU 36 according to the mode and load state of the power receiving device 30.

The rectifying and smoothing circuit 33 is a circuit that converts the AC power output from the matching circuit 32 into DC power, and includes diodes and capacitors.

The regulator 34 is a circuit that converts the voltage of the DC power output from the rectifying and smoothing circuit 33 into a predetermined voltage. The predetermined voltage generated by the regulator 34 is supplied to each part of the power receiving device 30. The regulator 34 is also connected to the battery 39, and charges the battery 39 with the power supplied from the power supply device 10 under the control of the CPU 36.

The modulation/demodulation circuit 35 is a circuit that modulates and demodulates the voltage signal of the antenna 31 and the matching circuit 32 so that the power receiving device 30 transmits and receives data to and from the power supply device 10. In addition, when receiving data, the modulation/demodulation circuit 35 detects a change in the voltage or current of the matching circuit 32, and demodulates the data to be received through a demodulation circuit composed of a filter, a comparator, a switch, and the like. The modulation/demodulation circuit 16 inputs the data to be received to the CPU 36, and the CPU 36 decodes the data based on a predetermined protocol stored in the ROM 38. When transmitting data, the modulation/demodulation circuit 16 receives data to be transmitted that is coded based on a predetermined protocol stored in the ROM 38 from the CPU 36, and modulates the transmission signal through the modulation circuit. The modulation circuit of the modulation/demodulation circuit 35 includes a switch and a resistor, and load modulation is performed by varying the load according to the transmission data signal, and data can be transmitted through the antenna 31. The specified protocol may be, for example, a short-range wireless communication protocol defined by ISO/IEC14443, ISO/IEC15693, or ISO/IEC18092 (NFC), or a protocol compatible with these.

The CPU 36 is an arithmetic processing device for controlling the entire power receiving device 30, and operates according to a program stored in the ROM 38. The program here includes programs for executing various flowcharts described later. The CPU 36 also changes and switches the value of the variable passive element of the matching circuit 32. The CPU 36 also charges the battery 39 with the power supplied from the power supply device 10 by controlling the regulator 34. When controlling the regulator 34, the CPU 36 may detect the remaining charge of the battery 39 using an internal AD conversion function. The CPU 36 may also perform control while switching between trickle charge control, high-speed charge control, constant voltage control, constant current control, etc. according to the remaining charge of the battery 39. The CPU 36 transmits and receives commands to and from the power supply device 10 by controlling the modulation and demodulation circuit 35. The command includes identification information for identifying the destination and information for responding to a command code indicating an operation instructed by the command. In addition, the CPU 36 may control the modem circuit 35 to request the power supply device 10 to change the power supply depending on the power storage state of the battery 39. Also, if the power supply device 10 does not supply enough power for the CPU 36 to operate, the battery 39 is charged and then the CPU 36 is operated by the battery 39.

RAM 37 is a volatile memory that temporarily stores computer programs that control the operation of each part of the power receiving device 30, information such as parameters related to the operation of each part, data received from the power supply device 10, etc.

The ROM 38 is a non-volatile memory that stores computer programs that control the operation of each part of the power receiving device 30 and parameters related to the operation of each part. The ROM 38 also stores device information of the power receiving device 30, power receiving capability information of the power receiving device 30, and display data. The device information of the power receiving device 30 includes the identification information (ID) of the power receiving device 30, the manufacturer's name, the device name, the date of manufacture, the communication method supported by the power receiving device 30, and information indicating whether the power receiving device 30 has a function to receive wireless power from the power supply device 10. The CPU 36 can transmit various information stored in the ROM 38 to the power supply device 10 by controlling the modulation/demodulation circuit 35.

The battery 39 is a battery that can be attached to and detached from the power receiving device 30. The battery 39 is also a rechargeable secondary battery, such as a lithium ion battery. The battery 39 supplies power to each part of the power receiving device 30.

The configuration of each of the parts 31 to 39 of the power receiving device 30 is not limited to that described above, and if they have the same function, each part may be present in multiples, may have a different function, or may be combined with other blocks. Also, in this embodiment, the power supply device 10 transmits power wirelessly to the power receiving device 30, and the power receiving device 30 receives power wirelessly from the power supply device 10, but "wireless" may be rephrased as "non-contact" or "contactless."

Next, the configuration and functions of the communication device 40 of this embodiment will be described.

The communication device 40 of this embodiment has an antenna 41, a matching circuit 42, a modulation/demodulation circuit 43, a CPU 44, a RAM 45, and a ROM 46.

Note that the communication device 40 has many commonalities with the configuration of the power receiving device 30, so the following explanation will focus on the differences with the power receiving device 30.

The communication device 40 of this embodiment does not have a battery, so it does not charge the battery with the power supplied from the power supply device 10, but it can receive power from the power supply device 10 to operate the communication device 40.

The CPU 44 performs almost the same control as the CPU 36 of the power receiving device 30, but does not perform charging control.

The communication device 40 may have a battery, similar to the power receiving device 30, if the communication device 40 is in a form in which the battery is not charged with the power supplied from the power supply device 10. Examples of a form in which the battery is not charged include a state in which the battery is fully charged or a state in which charging is limited.

The configuration of each unit 41 to 46 of the communication device 40 is not limited to the above configuration, and if they have similar functions, there may be multiple units of each unit, they may have different functions, or they may be combined with other blocks.

<Power supply operation> Next, the power supply operation by the power supply device 10 of this embodiment will be described with reference to FIG. 3. The process of FIG. 3 is realized by the CPU 20 of the power supply device 10 executing a program stored in the ROM 18. The same applies to FIG. 4 to FIG. 6 described later.

In S301, the CPU 20 controls the modem circuit 16 to perform a first search process for searching for the power receiving device 30. The details of the first search process will be described later. When the CPU 20 finishes the first search process, the process proceeds to S302.

In S302, the CPU 20 transmits an authentication request to the power receiving device 30 detected in S301. The CPU 20 transmits an authentication command to the power receiving device 30 by controlling the modulation and demodulation circuit 16 based on a predetermined communication protocol. After transmitting the authentication request, the CPU 20 advances the process to S303.

In S303, the CPU 20 determines whether an authentication response has been received from the power receiving device 30. The CPU 20 receives an authentication response signal generated by the CPU 36 when the authentication process is successful in the power receiving device 30 via the modem circuit 16. This authentication response signal includes device information of the power receiving device 30. The device information includes the ID, functions, and specifications of the power receiving device 30, and also includes information on whether the device is capable of supplying power. If the CPU 20 determines that an authentication response has not been received from the power receiving device 30 (NO in S303), it repeats the process of S303 until it receives an authentication response, but if it has not received an authentication response from the power receiving device 30 for a predetermined period of time, it ends the process. If the CPU 20 determines that an authentication response has been received from the power receiving device 30 (YES in S303), it proceeds to S304.

In S304, the CPU 20 analyzes the device information included in the authentication response signal received from the power receiving device 30 and determines whether the power receiving device 30 is a device that can supply power. If the CPU 20 determines that the power receiving device 30 is a device that can supply power (YES in S304), the process proceeds to S305, and if the CPU 20 determines that the power receiving device 30 is not a device that can supply power (NO in S304), the process ends.

In S305, the CPU 20 performs a device information storage process to store device information of the power receiving device 30. The details of the device information storage process will be described later. When the CPU 20 finishes the device information storage process, the process proceeds to S306.

In S306, the CPU 20 controls the modem circuit 16 to perform a second search process to search for a communication device 40 other than the power receiving device 30. The second search process will be described in detail later. When the CPU 20 finishes the second search process, the process proceeds to S307.

In S307, the CPU 20 determines whether the power supply device 10 is in a state where it can supply power to the power receiving device 30. The CPU 20 determines whether power supply is possible by checking a flag indicating that power supply is possible, among the information stored in the RAM 17. If the CPU 20 determines that the power supply device 10 is in a state where it can supply power to the power receiving device 30 (YES in S307), the process proceeds to S308, and if the CPU 20 determines that power supply is not possible (NO in S307), the process ends.

In S308, the CPU 20 performs control to start power supply to the power receiving device 30. Here, the control to start power supply means that the CPU 20 transmits a control signal to the power adjustment circuit 13 to transmit to the power receiving device 30 sufficient power to charge the battery 39 of the power receiving device 30. When a predetermined time has elapsed since the CPU 20 started power supply to the power receiving device 30, the process proceeds to S309.

In S309, the CPU 20 performs control to stop power supply to the power receiving device 30, and resets a flag, which is among the information stored in the RAM 17, indicating that power supply is possible. Here, the control to stop power supply refers to control in which the CPU 20 limits the output of the power adjustment circuit 13 to a level of power sufficient for communication with the power receiving device 30. When the CPU 20 performs control to stop power supply, the process proceeds to S310.

In S310, the CPU 20 performs the same process as in S302. After sending the authentication request, the CPU 20 advances the process to S311.

In S311, the CPU 20 performs the same process as S303. If the CPU 20 determines that an authentication response has not been received from the power receiving device 30 (NO in S311), it repeats the process of S311 until an authentication response is received, but if an authentication response has not been received from the power receiving device 30 for a predetermined time, it ends the process. Also, if the CPU 20 determines that an authentication response has been received from the power receiving device 30 (YES in S311), it advances the process to S312.

In S312, the CPU 20 determines whether to supply power to the power receiving device 30 again. The CPU 20 analyzes the device information included in the authentication response signal received in S311 and determines whether the power receiving device 30 is in a state where it can supply power again. If the CPU 20 determines that the power receiving device 30 is in a state where it can supply power again (YES in S312), it returns the process to S306 and repeats the process from S306, and if it determines that the power receiving device 30 is not in a state where it can supply power again (NO in S312), it ends the process. Note that if the result is NO in S312, the process may not end and the process may be repeated from S301.

<First search process (S301)> Next, the first search process in S301 of FIG. 3 will be explained using FIG. 4.

In S401, the CPU 20 searches for the power receiving device 30 by controlling the modem circuit 16 based on the first communication method stored in the ROM 18. After the CPU 20 searches for the power receiving device 30 using the first communication method, the process proceeds to S402.

In S402, the CPU 20 determines whether there is a response from the power receiving device 30 to the search by the first communication method performed in S401. If the CPU 20 confirms a response from the power receiving device 30 (YES in S402), the process proceeds to S407, and if the CPU 20 does not confirm a response from the power receiving device 30 for a predetermined period of time (NO in S402), the process proceeds to S403.

In S403, the CPU 20 searches for the power receiving device 30 by controlling the modem circuit 16 based on the second communication method stored in the ROM 18. After the CPU 20 searches for the power receiving device 30 using the second communication method, the process proceeds to S404.

In S404, the CPU 20 determines whether there has been a response from the power receiving device 30 to the search using the second communication method in S403. If the CPU 20 confirms a response from the power receiving device 30 (YES in S404), the process proceeds to S407, and if the CPU 20 has not confirmed a response from the power receiving device 30 for a predetermined period of time (NO in S404), the process proceeds to S405.

In S405, the CPU 20 searches for the power receiving device 30 by controlling the modem circuit 16 based on the third communication method stored in the ROM 18. After the CPU 20 searches for the power receiving device 30 using the third communication method, the process proceeds to S406.

In S406, the CPU 20 determines whether there is a response from the power receiving device 30 to the search by the third communication method in S406. If the CPU 20 confirms a response from the power receiving device 30 (YES in S406), the process proceeds to S407, and if the CPU 20 does not confirm a response from the power receiving device 30 for a predetermined time (NO in S406), the process returns to S401 and the process from S401 is repeated.

The first search process using the first, second, and third communication methods is, for example, a polling process that sequentially transmits Type A, Type B, and Type F request commands using NFC, but is not limited to this. The same applies to the second search process described below.

The search processes using the first, second, and third communication methods in S401 to S406 may be performed in any order. Furthermore, as long as the processes are performed in parallel, they are not limited to processes using three communication methods, and may be processes using fewer than three types or processes using four or more types. In this embodiment, processes using three communication methods are illustrated, but are not limited to this. Furthermore, the above-mentioned search processes may be performed periodically and repeatedly at predetermined time intervals.

In S407, the CPU 20 determines whether any devices detected in S401 to S406 exist other than the power receiving device 30. If the CPU 20 determines that devices other than the power receiving device exist (YES in S407), the process proceeds to S408, and if the CPU 20 determines that devices other than the power receiving device do not exist (NO in S407), the process ends.

In S408, the CPU 20 controls the notification unit 19 to issue an error notification to inform the user that power supply cannot be started due to the detection of multiple devices, and prompts the user to remove the communication device 40 from the communication range of the power supply device 10. After the CPU 20 finishes the error notification, the process proceeds to S409.

In S409, the CPU 20 determines whether re-searching for the power receiving device 30 is possible. After notifying the user of an error, the CPU 20 determines that re-searching is possible when the user removes the communication device 40 and operates the power supply device 10. If the CPU 20 determines that re-searching for the power receiving device 30 is possible (YES in S409), the process returns to S401 and repeats the process from S401. If the CPU 20 determines that re-searching for the power receiving device 30 is not possible (NO in S409), the process of S409 is repeated until re-searching is possible. Also, if the CPU 20 continues to determine that re-searching is not possible for a predetermined period of time, the process ends.

<Device information storage process (S305)> Next, the device information storage process in S305 of FIG. 3 will be explained using FIG. 5.

In S501, the CPU 20 acquires the identification information of the power receiving device 30 from the authentication information acquired in S303. After acquiring the identification information of the power receiving device 30, the CPU 20 advances the process to S502.

In S502, the CPU 20 stores the identification information of the power receiving device 30 acquired in S501 in the RAM 17. After storing the identification information of the power receiving device 30 in the RAM 17, the CPU 20 advances the process to S503.

In S503, the CPU 20 associates the information about the communication method by which the power receiving device 30 was detected with the identification information of the power receiving device 30 acquired in S502, and stores the information in the RAM 17. After the CPU 20 associates the information about the communication method by which the power receiving device 30 was detected with the identification information of the power receiving device 30 and stores the information in the RAM 17, the CPU 20 proceeds to S504.

In S504, the CPU 20 determines whether the authentication information acquired in S303 contains any other identification information besides the identification information of the power receiving device 30. This is because there are devices that support multiple communication methods. If the CPU 20 determines that there is no other identification information (NO in S504), the process ends, and if it determines that there is other identification information (YES in S504), the process returns to S501 and the process from S501 is repeated.

<Second search process (S306)> Next, the second search process in S306 of FIG. 3 will be explained using FIG. 6.

In S601, the CPU 20 determines whether the power receiving device 30 supports the first communication method. The CPU 20 makes this determination using the information stored in the RAM 17 by the device information storage process in S305. If the CPU 20 determines that the power receiving device 30 supports the first communication method (YES in S601), the process proceeds to S604. If the CPU 20 determines that the power receiving device 30 does not support the first communication method (NO in S601), the process proceeds to S602.

In S602, the CPU 20 determines whether the power receiving device 30 supports the second communication method. The CPU 20 makes this determination using the information stored in the RAM 17 by the device information storage process in S305. If the CPU 20 determines that the power receiving device 30 supports the second communication method (YES in S602), the process proceeds to S606. If the CPU 20 determines that the power receiving device 30 does not support the second communication method (NO in S602), the process proceeds to S603.

In S603, the CPU 20 determines whether the power receiving device 30 supports the third communication method. The CPU 20 makes this determination using the information stored in the RAM 17 by the device information storage process in S305. If the CPU 20 determines that the power receiving device 30 supports the second communication method (YES in S603), the process proceeds to S608, and if the CPU 20 determines that the power receiving device 30 does not support the third communication method (NO in S603), the process ends.

In S604, the CPU 20 searches for a communication device 40 other than the power receiving device 30 by controlling the modem circuit 16 based on the second communication method stored in the ROM 18. After searching for a communication device 40 using the second communication method, the CPU 20 advances the process to S605.

In S605, the CPU 20 determines whether there has been a response from the communication device 40 in response to the search using the second communication method in S604. If the CPU 20 determines that there has been a response from the communication device 40 (YES in S605), the process proceeds to S613, and if the CPU 20 determines that there has been no response from the communication device 40 for a predetermined period of time (NO in S605), the process proceeds to S610b.

In S606, the CPU 20 searches for a communication device 40 other than the power receiving device 30 by controlling the modem circuit 16 based on the third communication method stored in the ROM 18, and proceeds to S607.

In S607, the CPU 20 determines whether there has been a response from the communication device 40 in response to the search using the third communication method in S606. If the CPU 20 determines that there has been a response from the communication device 40 (YES in S607), the process proceeds to S613, and if the CPU 20 determines that there has been no response from the communication device 40 for a predetermined period of time (NO in S607), the process proceeds to S610c.

In S608, the CPU 20 searches for a communication device 40 other than the power receiving device 30 by controlling the modulation and demodulation circuit 16 based on the first communication method stored in the ROM 18, and proceeds to S609.

In S609, the CPU 20 determines whether there has been a response from the communication device 40 in response to the search using the first communication method in S608. If the CPU 20 determines that there has been a response from the communication device 40 (YES in S609), the process proceeds to S613, and if the CPU 20 determines that there has been no response from the communication device 40 for a predetermined period of time (NO in S609), the process proceeds to S610a.

When the ID of the power receiving device 30 is searched for in each of the processes of S604, S606, and S608, the CPU 20 stores the ID information in the RAM 17.

In S610a, the CPU 20 determines whether the power supply device 10 has searched for the communication device 40 using the first to third communication methods, and then determines whether to end the search for the communication device 40. If the CPU 20 determines that the power supply device 10 has searched for the communication device 40 using the first to third communication methods and ends the search (YES in S610a), the process proceeds to S611. If the CPU 20 determines that the power supply device 10 has not searched for the communication device 40 using the first to third communication methods and continues the search (NO in S610a), the process proceeds to S604.

In S610b, the CPU 20 performs the same process as S610a. The CPU 20 determines whether the power supply device 10 has searched for the communication device 40 using the first to third communication methods, and then determines whether to end the search for the communication device 40. If the CPU 20 determines that the power supply device 10 has searched for the communication device 40 using the first to third communication methods and ends the search (YES in S610b), the process proceeds to S611. If the CPU 20 determines that the power supply device 10 has not searched for the communication device 40 using the first to third communication methods and continues the search (NO in S610b), the process proceeds to S606.

In S610c, the CPU 20 performs the same process as S610a and S610b. The CPU 20 determines whether the power supply device 10 has searched for the communication device 40 using the first to third communication methods, and then determines whether to end the search for the communication device 40. If the CPU 20 determines that the power supply device 10 has searched for the communication device 40 using the first to third communication methods and ends the search (YES in S610c), the process proceeds to S611. If the CPU 20 determines that the power supply device 10 has not searched for the communication device 40 using the first to third communication methods and continues the search (NO in S610c), the process proceeds to S608.

In S611, the CPU 20 analyzes the information stored in the RAM 17 to determine whether the ID of the power receiving device 30 was detected in the search processes of S604, S606, and S608. If the CPU 20 determines that the ID of the power receiving device 30 was detected in the processes of S604, S606, and S608 (YES in S611), the process proceeds to S612. If the CPU 20 determines that the ID of the power receiving device 30 was not detected (NO in S611), the process proceeds to S613.

In S612, the CPU 20 sets a flag stored in the RAM 17 indicating that power supply is possible, thereby transitioning the power supply device 10 to a state in which it is possible to supply power to the power receiving device 30. When the flag indicating that power supply is possible is set, the power supply device 10 is able to supply power to the power receiving device 30. After the CPU 20 sets the flag stored in the RAM 17 indicating that power supply is possible, the processing ends.

In S613, the CPU 20 resets the flag stored in the RAM 17 indicating that power supply is possible, thereby transitioning the power supply device 10 to a state in which power supply to the power receiving device 30 is not possible. When the flag indicating that power supply is possible is reset, the power supply device 10 cannot start supplying power to the power receiving device 30. After resetting the flag stored in the RAM 17 indicating that power supply is possible, the CPU 20 advances the process to S614.

In S614, the CPU 20 controls the notification unit 19 to issue an error notification to inform the user that power supply cannot be started due to the presence of the communication device 40 or the absence of the power receiving device 30, and proceeds to S615. By issuing the error notification, the user is prompted to remove the communication device 40 from the communication range of the power supply device 10, or to place the power receiving device 30 within the communication range of the power supply device 10.

In S615, the CPU 20 determines whether re-searching for the power receiving device 30 and the communication device 40 is possible. After notifying the user of an error, the CPU 20 determines that re-searching is possible if the user removes the communication device 40 or places the power receiving device 30 and operates the power supply device 10. If the CPU 20 determines that re-searching for the power receiving device 30 and the communication device 40 is possible (YES in S615), the process proceeds to S616. If the CPU 20 determines that re-searching for the power receiving device 30 is not possible (NO in S615), the process of S615 is repeated until re-searching is possible. If the CPU 20 continues to determine that re-searching is not possible for a predetermined time, the process ends and returns to the start point in FIG. 3.

In S616, the CPU 20 determines whether the re-search for the power receiving device 30 and the communication device 40 has been performed a predetermined number of times or more. If the CPU 20 determines that the re-search for the power receiving device 30 and the communication device 40 has been performed a predetermined number of times or more (YES in S616), the process ends. If the CPU 20 determines that the re-search for the power receiving device 30 and the communication device 40 has not been performed a predetermined number of times or more (NO in S616), the process returns to S601 and the process from S601 is repeated.

As described above, according to the power supply control of this embodiment, even if the power receiving device 30 is detected by the first search process, if a communication device 40 other than the power receiving device 30 is detected by the second search process, control is performed so that power supply cannot be started. In other words, in a situation where a communication device 40 other than the power receiving device 30 is placed on the power supply device 10 from the beginning or is placed at the same time as the power receiving device 30, power supply to the power receiving device 30 can be restricted. In this way, by searching for a communication device 40 other than the power receiving device 30 at a predetermined timing before power supply, power supply to the power receiving device 30 can be started without supplying power to the communication device 40 other than the power receiving device 30.

[Embodiment 2] Next, embodiment 2 will be described.

In the following, for ease of explanation, the differences from the first embodiment will be mainly described. Also, the system configuration and device configuration of this embodiment are similar to those of the first embodiment shown in Figs. 1 and 2, but the operation process of the power supply device 10 is different from that of the first embodiment.

In this embodiment, as in the first embodiment, the start of power supply is restricted so as not to supply power to communication devices 40 other than the power receiving device 30 by searching for communication devices 40 other than the power receiving device 30 at a predetermined timing before power supply. In particular, in this embodiment, in a situation where a communication device 40 is inserted during the operation processing of the power supply device 10, control is performed to restrict power supply to the power receiving device 30 when the power supply device 10 performs communication processing with the power receiving device 30 every time. Furthermore, in order to minimize the communication processing performed every time, authentication with the power receiving device 30 is not performed every time, and a search for a communication device 40 is performed when a command indicating a power supply request is received from the power receiving device 30.

<Power supply operation> Next, the power supply operation by the power supply device 10 of embodiment 2 will be described with reference to FIG. 7. Note that the process of FIG. 7 is realized by the CPU 20 executing a computer program stored in the ROM 18.

S701, S702, S703, and S704 in Figure 7 perform the same processing as S301, S302, S303, and S304 in Figure 3.

In S705, the CPU 20 determines whether a power supply request has been received from the power receiving device 30. If it is determined that a power supply request has been received (YES in S705), the process proceeds to S706. If it is determined that a power supply request has not been received (NO in S705), the process ends.

In S706, the CPU 20 determines whether the power corresponding to the power supply request received from the power receiving device 30 in S705 is within a predetermined value. The predetermined value corresponds to the power value transmitted when the power supply device 10 communicates with the power receiving device 30. The predetermined value may be changed arbitrarily depending on the state of the power supply device 10 and the power receiving device 30. If the CPU 20 determines that the requested power from the power receiving device 30 is within the predetermined value (YES in S706), the process proceeds to S709. If the CPU 20 determines that the requested power from the power receiving device 30 exceeds the predetermined value (NO in S706), the process proceeds to S707.

S707, S708, S709, and S710 in Figure 7 perform the same processing as S306, S307, S308, and S309 in Figure 3.

As described above, according to the power supply control of this embodiment, even if a communication device 40 other than the power receiving device 30 is placed while the power supply device 10 is performing communication processing with the power receiving device 30 before power supply starts, power supply is controlled so that it cannot start. In this way, by searching for communication devices 40 other than the power receiving device 30 during communication processing before power supply starts, power supply to the power receiving device 30 can be started without supplying power to communication devices 40 other than the power receiving device 30.

[Other embodiments]
The present invention can also be realized by a process in which a program for implementing one or more of the functions of the above-described embodiments is supplied to a system or device via a network or a storage medium, and one or more processors in a computer of the system or device read and execute the program. The present invention can also be realized by a circuit (e.g., ASIC) that implements one or more of the functions.

10...power supply device, 11...antenna, 20...CPU, 30...power receiving device, 31...antenna, 36...CPU, 40...communication device, 41...antenna, 44...CPU

Claims (10)

A communication means for performing a plurality of polling processes in a plurality of communication methods in Near Field Communication (NFC);
A power transmitting unit that wirelessly transmits power to the power receiving device,
The power transmission means is
When an object that is different from the power receiving device and responds to any of the plurality of polling processes in the plurality of communication methods in the NFC is detected, power transmission to the power receiving device is limited ;
A power supply device that receives identification information of the power receiving device . The power supply device according to claim 1, characterized in that the communication means performs the multiple polling processes when a power supply request is received from the power receiving device. The power supply device according to claim 1 or 2, characterized in that the communication means detects the power receiving device by multiple polling processes using multiple communication methods in the NFC. The power supply device according to any one of claims 1 to 3, characterized in that the communication means performs polling processing in a communication method supported by the power receiving device after polling processing in a communication method not supported by the power receiving device. The power supply device according to any one of claims 1 to 4, characterized in that the power transmission means limits the power transmitted to the power receiving device when the object is detected by a polling process using a communication method that is not supported by the power receiving device. The power supply device according to any one of claims 1 to 5, further comprising a notification means for notifying the power receiving device that the power transmitted to the power receiving device will be limited when the object is detected. The power supply device according to any one of claims 1 to 6, characterized in that even if the power transmission means receives a signal via the communication means to identify that the power receiving device has the function of wirelessly receiving power from the power receiving device, if multiple polling processes using multiple communication methods in the NFC detect an object other than the power receiving device that responds to any of the multiple polling processes, the power transmission means limits the power transmitted to the power receiving device. The power supply device according to claim 1 , wherein the power receiving device receives information indicating a communication method supported by the power receiving device. A method performed by a power supply device, comprising:
A plurality of polling processes are performed using a plurality of communication methods in Near Field Communication (NFC),
Wirelessly transmits power to the receiving device,
When an object that is different from the power receiving device and responds to any of the plurality of polling processes in the plurality of communication methods in the NFC is detected , power transmission to the power receiving device is limited ;
receiving an identification of the powered device ; A program for causing a computer to function as the power supply device according to any one of claims 1 to 8 .

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