JP6835431B2 - Power receiving device and power receiving program - Google Patents

Description

The present invention relates to a power receiving device and a power receiving program.

There is known a wireless power feeding technology in which a power transmitting device transmits power in a non-contact manner to a power receiving device which is a mobile terminal such as a mobile phone or a smartphone. For example, when the magnetic field resonance method is used, the power transmission device can transmit electric power to a power receiving device located in a space tens of centimeters or even several meters away. In the magnetic field resonance method, for example, the power transmission device forms a magnetic field by passing a current through the coil of the power transmission circuit, and the current flows through the coil of the power receiving device that has entered the magnetic field, so that power is transmitted from the power transmission device to the power receiving device. Will be done. The power receiving device supplies the received power to each part such as a battery in the power receiving device. Further, in the magnetic field resonance method, a plurality of power receiving devices may simultaneously receive power transmitted by one power transmitting device.

In the magnetic field resonance method, for example, in the power transmission method advocated by AirFuel (formerly A4WP), an industry standard group for wireless power feeding, the power transmission device intermittently passes a current through the coil in order to detect a nearby power receiving device. Intermittent power is transmitted after a certain pause. In the following, the intermittent power transmitted from the power transmission device after a certain pause period may be referred to as a "beacon signal". When the power receiving device enters the power supply area, the magnetic field condition changes. This change in the condition of the magnetic field causes a change in the voltage value or the current value in the power transmission circuit of the power transmission device. In this case, the power transmission circuit of the power transmission device switches the transmission of the beacon signal to the continuous power transmission in order to supply power to the power receiving device detected by the change of the voltage value or the current value.

Further, the power receiving device detects that there is a power transmitting device in the vicinity capable of starting continuous power transmission by receiving the beacon signal from the power transmitting device. Then, when the power receiving device enters the power supply available area of the power transmission device, the power receiving device receives the continuous power transmitted from the power transmitting device and supplies the received power to each part such as a battery.

Japanese Unexamined Patent Publication No. 2006-335342

However, the power receiving device using the above technique cannot notify the user of the existence of another power transmission device when receiving continuous power transmitted from one power transmission device. Therefore, the power supply to each part of the power receiving device may not be sufficient. For example, there is an upper limit to the power transmission capacity of a power transmission device, and when a plurality of power receiving devices receive power at the same time, the power received per power receiving device becomes smaller than when only one power receiving device receives power. there is a possibility. Even in such a case, when the power receiving device receives continuous power transmitted from a specific power transmission device, the power receiving device cannot receive the beacon signal transmitted from another power transmission device. The presence of other power transmission equipment cannot be notified. As a result, the power receiving device does not switch to the power supply by receiving the power transmitted from the other power transmission device, and continues to supply insufficient power using the power transmitted from the specific power transmission device. Will continue.

One aspect is to provide a power receiving device and a power receiving program that can notify the presence of another power transmitting device when receiving continuous power transmitted from the power transmitting device.

In one embodiment, the power receiving device has a power supply control unit and an output unit. The power supply control unit controls power supply by the electric power transmitted from the first power transmission device. The output unit outputs information about a second power transmission device different from the first power transmission device when receiving a signal satisfying a predetermined condition in a state where power is supplied by the transmitted electric power.

According to one aspect, there is an effect that the presence of another power transmission device can be notified when the continuous power transmitted from the power transmission device is received.

FIG. 1 is a diagram showing an example of the positional relationship between the power transmission device and the power receiving terminal. FIG. 2 is a diagram showing an example of a peripheral area of the power transmission device. FIG. 3A is a diagram showing an example of a waveform showing the level of the beacon signal transmitted by the power transmission device. FIG. 3B is a diagram showing an example of a waveform showing the level of continuous electric power transmitted by the power transmission device. FIG. 4 is a diagram showing an example of the functional configuration. FIG. 5 is a diagram showing an example of a beacon pattern table. FIG. 6 is a diagram showing an example of a beacon pattern. FIG. 7A is a diagram showing an example of comparison between a waveform showing the level of electric power received from the power transmission device and the beacon pattern. FIG. 7B is a diagram showing another example of comparison between the waveform showing the level of electric power received from the power transmission device and the beacon pattern. FIG. 7C is a diagram showing another example of comparison between the waveform showing the level of electric power received from the power transmission device and the beacon pattern. FIG. 7D is a diagram showing another example of comparison between the waveform showing the level of electric power received from the power transmission device and the beacon pattern. FIG. 7E is a diagram showing another example of comparison between the waveform showing the level of electric power received from the power transmission device and the beacon pattern. FIG. 8 is a diagram showing an example of the displayed message. FIG. 9 is a flowchart showing an example of the flow of operation by the power transmission device. FIG. 10A is a flowchart showing an example of the flow of operation by the power receiving terminal. FIG. 10B is a flowchart showing an example of the flow of operation by the power receiving terminal. FIG. 11 is a flowchart showing an example of the received power determination process by the power receiving terminal. FIG. 12 is a flowchart showing an example of the power transmission device detection process by the power receiving terminal. FIG. 13 is a diagram showing an example of a mask value table. FIG. 14 is a diagram showing an example of comparison between the mask pattern and the waveform showing the level of the beacon signal. FIG. 15 is a flowchart showing an example of the power transmission device detection process by the power receiving terminal in the second embodiment. FIG. 16 is a diagram showing an example of the positional relationship between the power transmission device and the power receiving terminal in the third embodiment. FIG. 17 is a diagram showing an example of the displayed message in the third embodiment. FIG. 18 is a flowchart showing an example of the received power determination process by the power receiving terminal in the third embodiment. FIG. 19 is a flowchart showing an example of the power transmission device detection process by the power receiving terminal in the third embodiment. FIG. 20 is a diagram showing an example of the hardware configuration of the power receiving terminal. FIG. 21 is a diagram showing an example of the hardware configuration of the power transmission device.

Hereinafter, examples of the power receiving device and the power receiving program disclosed in the present application will be described in detail with reference to the drawings. The present invention is not limited to this embodiment. In addition, each embodiment can be appropriately combined as long as the processing contents do not contradict each other.

[System configuration]
First, the non-contact power supply system in this embodiment will be described. The non-contact power supply system in this embodiment is composed of two or more power receiving terminals and two or more power transmission devices. The power receiving terminal is, for example, a mobile terminal and is an example of a device such as a mobile phone, a smartphone or a tablet terminal, but the present invention is not limited to this, and other portable devices may be used. The power receiving terminal is an example of a power receiving device.

The power transmission device is, for example, a stationary device that transmits electric power, and is installed on a table or a wall surface of an office, a living room, a restaurant, or the like. The power transmission device is not limited to this, and may be a stand-type device or a portable device.

FIG. 1 is a diagram showing an example of the positional relationship between the power transmission device and the power receiving terminal. As shown in FIG. 1, the non-contact power feeding system 1 has a plurality of power transmission devices 10 and 20 and a plurality of power receiving terminals 100 and 200. In addition, when expressing the plurality of power transmission devices 10 and 20 without distinguishing them, it may be expressed as "power transmission device 99", and when expressing the plurality of power receiving terminals 100 and 200 without distinguishing them, "power receiving". It may be described as "terminal 999". Note that FIG. 1 shows an example in which the non-contact power feeding system 1 includes two power transmission devices 10 and 20 and two power receiving terminals 100 and 200, but the present invention is not limited to this, and three or more power transmission devices 99. It may be configured to include three or more power receiving terminals 999.

In FIG. 1, the power receiving terminal 100 receives continuous power transmitted from the power transmission device 10 and supplies power to various parts such as a battery (not shown). Further, the power receiving terminal 100 receives the intermittent power (hereinafter, may be referred to as "beacon signal") transmitted from the power transmission device 20 after a certain pause period, so that the power transmission device 20 is in the vicinity. Detect that there is. Further, the power receiving terminal 100 wirelessly performs communication such as transmitting a power supply request with the power transmission devices 10 and 20 by P2P (peer-to-peer).

The positional relationship between the power receiving terminal 100 and the power transmission device 10 will be described with reference to FIG. FIG. 2 is a diagram showing an example of a peripheral area of the power transmission device. By entering the communication range 10-3 shown in FIG. 2, the power receiving terminal 100 can perform P2P communication with the power transmission device 10 by using a wireless communication means such as Bluetooth (registered trademark) LE. For example, the communication range 10-3 is about several meters to 100 meters around the power transmission device 10, but is not limited to this.

Further, the power receiving terminal 100 can detect the beacon signal transmitted from the power transmission device 10 by entering the beacon detection range 10-2 shown in FIG. For example, the beacon detection range 10-2 is about 1 m to several meters around the power transmission device 10, but is not limited to this. In the beacon detection range 10-2, the power receiving terminal 100 can obtain the power required for supplying power to each part even when the power transmission device 10 transmits continuous power instead of the beacon signal. difficult. Therefore, when the power receiving terminal 100 exists in the beacon detection range 10-2, the power supply may not be possible at all or the power supply may be insufficient.

Further, when the power receiving terminal 100 enters the power supply enable area 10-1 shown in FIG. 2, it can receive the continuous power transmitted from the power transmission device 10 and supply the power to each part. For example, the power supply available area 10-1 is about 10 cm to 1 m around the power transmission device 10, but is not limited to this.

Returning to FIG. 1, the power transmission device 10 transmits a beacon signal when power is not transmitted to any of the power receiving terminals 100 and 200. For example, when the power receiving terminal 100 enters the power supply capable region 10-1, the power transmission device 10 detects the power receiving terminal 100 by the change of the voltage value or the current value in the power transmission circuit. Further, when the power transmission device 10 receives the power supply request from the power receiving terminal 100 in the power supply enable area 10-1, the power transmission device 10 stops the transmission of the beacon signal and switches to the continuous power transmission. When the power receiving terminal 100 notifies the end of power reception, the power transmission device 10 stops the continuous power transmission and switches to the beacon signal transmission. In this embodiment, the transmission of the beacon signal and the continuous power transmission are in an alternative relationship, and the power transmission device 10 does not simultaneously transmit the beacon signal and the continuous power. That is, the power transmission device 10 transmits a beacon signal when the power transmission device 10 is not currently transmitting continuous power and can start the continuous power transmission based on the power supply request transmitted by the power receiving device.

The beacon signal and continuous electric power transmitted by the power transmission device 10 will be described with reference to FIGS. 3A and 3B. FIG. 3A is a diagram showing an example of a waveform showing the level of the beacon signal transmitted by the power transmission device. For example, as shown in FIG. 3A, the beacon signal 4001 is an electric power 4011 that is intermittently transmitted with a pause period 4013 in between. As an example, in the Airfeel specification, intermittent power transmission and pause periods are repeated, for example, with a length of 250 milliseconds as one cycle. Specifically, intermittent power 4011 is delivered for 10 to 30 ms, followed by a rest period 4013 of 220 to 240 ms in length, and then delivered again. The voltage value and period of the beacon signal 4001 shown in FIG. 3A is an example, and one period of the beacon signal includes a plurality of intermittent powers 4011 having different voltage values and lengths, and a plurality of pauses having different lengths. The configuration may include a combination of periods 4013.

Further, when the power transmission device 10 receives a power supply request from any of the power receiving terminals 999 by wireless communication means such as P2P communication, the power transmission device 10 stops the transmission of the beacon signal and switches to the continuous power transmission shown in FIG. 3B. FIG. 3B is a diagram showing an example of a waveform showing the level of continuous electric power transmitted by the power transmission device. As shown in FIG. 3B, the continuous power 4101 is the power that is continuously transmitted without interposing the pause period 4013 as shown in FIG. 3A. The power transmission device 10 detects, for example, that the power receiving terminal 100 has entered the power supply available region 10-1 shown in FIG. 2 by changing the voltage value or the current value in the power transmission circuit. Further, when the power transmission device 10 receives the power supply request from the power receiving terminal 100, the power transmission device 10 stops the transmission of the beacon signal and switches to the continuous power transmission.

Returning to FIG. 1, for example, since the power receiving terminals 100 and 200 are in the power supply enable area 10-1 of the power transmission device 10, it is possible to receive power from the power transmission device 10 and supply power to each part. .. In this case, if the power transmission capacity of the power transmission device 10 is insufficient, the power received by the power receiving terminals 100 and 200 is smaller than that in the case where only one of the power receiving terminals receives power from the power transmission device 10.

In the example shown in FIG. 1, since the power transmission device 10 continuously transmits power to the power receiving terminal 100 and the power receiving terminal 200 in the power supply enable area 10-1, the beacon signal is not transmitted. On the other hand, since neither of the power receiving terminals 100 and 200 is in the power supply enable area 20-1, the power transmission device 20 transmits a beacon signal without transmitting continuous power. In this case, since the power receiving terminal 100 shown in FIG. 1 is in the power supply enable area 10-1, it can receive the continuous power transmitted by the power transmission device 10, and further, it is also in the beacon detection range 20-2 of the power transmission device 20. Since it is included, the beacon signal transmitted from the power transmission device 20 can be detected. As a result, the power receiving terminal 100 can detect that the power transmitting device 20 is in the vicinity and the power transmitting device 20 does not continuously transmit power to another power receiving terminal, for example, the power receiving terminal 200.

For example, in FIG. 1, the power receiving terminal 100 within the power supply enable area 10-1 of the power transmission device 10 receives continuous power transmitted from the power transmission device 10 and supplies power to each part. Can be done. However, since the power transmission device 10 also supplies power to the power receiving terminal 200, the power receiving terminal 100 may not be able to receive sufficient power from the power transmission device 10.

In such a case, in this embodiment, the power receiving terminal 100 can receive the beacon signal from the power transmission device 20 even when the power is received from the power transmission device 10. The power transmission devices 10 and 20 do not transmit the beacon signal when the continuous power is being transmitted. Further, when the power transmission devices 10 and 20 are transmitting the beacon signal, the power transmission devices 10 and 20 can start the continuous power transmission based on the power supply request received from the power receiving terminal 100. As a result, the power receiving terminal 100 can detect that the power transmission device 20 capable of starting continuous power transmission to the power receiving terminal 100 is in the vicinity by detecting the beacon signal transmitted from the power transmission device 20. ..

In this way, when the power receiving terminal receives the beacon signal from the first power transmission device while receiving power in a non-contact manner, the power receiving terminal notifies the user of the existence of the second power transmission device, so that sufficient power can be transmitted. The existence of the power transmission device can be notified to the user.

Next, the functional configuration of the non-contact power supply system 1 in this embodiment will be described with reference to FIG. FIG. 4 is a diagram showing an example of the functional configuration. The power receiving terminal 100 shown in FIG. 4 and the power transmission device 10 or 20 are wirelessly connected so that P2P communication can be performed by using a wireless communication means such as BlueTooth (registered trademark) LE. Since the power receiving terminal 200 and the power transmission device 20 shown in FIG. 1 have the same configurations as the power receiving terminal 100 and the power transmission device 10, respectively, detailed description of the functional configuration will be omitted.

[Functional configuration of power receiving terminal]
The power receiving terminal 100 includes a communication unit 110, a power receiving unit 111, a conversion unit 112, a storage unit 120, and a control unit 130. The communication unit 110 is wirelessly connected to the power transmission devices 10 and 20, and controls information communication between the power transmission devices 10 and 20. For example, the communication unit 110 is realized by a communication circuit and an antenna, and communicates with the power transmission devices 10 and 20 by a wireless communication means such as P2P.

The power receiving unit 111 receives power including a beacon signal from the power transmission device 99. The power receiving unit 111 starts receiving power including the beacon signal according to the instruction from the control unit 130, and outputs the power to the conversion unit 112. Further, the power receiving unit 111 supplies the received continuous power to each unit such as a battery (not shown) in accordance with the instruction from the control unit 130.

The conversion unit 112 is a processing unit that converts the received power into a received signal that can be handled by the control unit 130. The conversion unit 112 outputs the power output from the power receiving unit 111 as a voltage value. For example, the conversion unit 112 receives the voltage applied to the load that consumes the received power by the sampling circuit of the high impedance input, and outputs it as an A / D converted value. The conversion unit 112 can increase the detection sensitivity, for example, by making the impedance of the load higher than usual. As an example, in the case of a load of 5Ω during normal power supply, if a load of 25Ω is used, the sensitivity will be five times higher. This has the effect that even when the received power is small, it can be converted into a received signal without being buried in noise.

When the beacon pattern and the received signal are cross-correlated, if each has a DC component, a non-zero correlation value may appear due to the product of the signal, even if the signal is originally completely uncorrelated. In order to prevent such an incorrect correlation value from being calculated, the conversion unit 112 may remove the DC component when outputting the received signal. The conversion unit 112 removes the direct current component by, for example, applying the received signal to an HPF (high-pass filter) or obtaining the average value of the received signal and subtracting the average value from the individual values of the original received signal. As will be described later, the average value of the sample values of the received signal from which the DC component has been removed is 0.

The storage unit 120 stores programs and data used by the power receiving terminal 100. For example, the storage unit 120 is realized by a semiconductor memory element such as a RAM (Random Access Memory) or a flash memory, or a storage device such as a hard disk or an optical disk. Further, the storage unit 120 appropriately stores information used for each process performed by the control unit 130, such as a message output by the power receiving terminal 100.

As shown in FIG. 4, the storage unit 120 has a pattern DB 121 and a threshold value DB 122. The pattern DB 121 stores a beacon pattern table for determining whether or not the received beacon signal satisfies the condition.

The beacon signal pattern table stores the beacon signal pattern for each unit time when the period of the beacon signal that matches the conditions is subdivided into short unit times. The unit time is, for example, 5 milliseconds (ms), but is not limited to this. Further, the pattern can be represented by, for example, "0" and "1", but the pattern is not limited to this, and may be configured to take continuous values.

FIG. 5 is a diagram showing an example of a beacon pattern table. The beacon pattern table shown in FIG. 5 shows an example in which the beacon patterns for two cycles are stored when the cycle of the beacon signal is “250 milliseconds”. The beacon pattern table may store, for example, a beacon pattern for one cycle, or may store a beacon pattern for three or more cycles.

As shown in FIG. 5, the beacon pattern table stores "m", "ms", and "Pp (m)" in association with each other. "M" indicates the number of the pattern. Further, "ms" indicates the value at which millisecond (ms) the "m" th pattern is. Specifically, "XY" in the "ms" column indicates that "after Xms and before Yms". For example, in FIG. 5, "0-5" indicates "after 0 ms and before 5 ms".

Further, "Pp (m)" indicates the "m" th pattern. For example, FIG. 5 shows that the "1" th pattern at "0-5" ms is "0" and the "2" th pattern at "5-10" ms is "1".

In the beacon pattern table shown in FIG. 5, for example, in the first cycle, power transmission starts at "5" ms and continues for 30 ms until it stops at "35" ms. Indicates to do. Further, in the second cycle, it is shown that the power transmission is started at the time of "255 ms" and the power transmission is continued for the same 30 ms until it is stopped at the time of "285" ms.

Returning to FIG. 4, the threshold value DB 122 stores the threshold value used for various processes. For example, the threshold value DB 122 stores “2” as the threshold value of the cross-correlation value between the power level and the beacon pattern, which will be described later. Further, the threshold value DB 122 stores "5" V as a first threshold value regarding the voltage value of the electric power received from the power transmission device 10. Further, the threshold value DB 122 stores "30"% as a threshold value for generating an opportunity for power supply monitoring. Specific processing using each stored threshold value will be described later.

Next, each function of the control unit 130 will be described. For example, the control unit 130 is realized by executing various programs stored in the storage device inside the power receiving terminal 100 using the RAM as a work area by a CPU (Central Processing Unit), an MPU (Micro Processing Unit), or the like. To. Further, the control unit 130 may be realized by an integrated circuit such as an ASIC (Application Specific Integrated Circuit) or an FPGA (Field Programmable Gate Array).

The control unit 130 includes a monitoring control unit 131, a device detection unit 132, a power reception notification unit 133, a power supply determination unit 134, and a notification control unit 135, and realizes information processing functions and operations described below. Or execute. The internal configuration of the control unit 130 is not limited to the configuration shown in FIG. 4, and may be another configuration as long as it is a configuration for performing information processing described later. Further, the monitoring control unit 131, the device detection unit 132, the power reception notification unit 133, the power supply determination unit 134, and the notification control unit 135 are examples of electronic circuits such as processors or examples of processes executed by the processors.

The monitoring control unit 131 is a processing unit that generates an opportunity for power supply monitoring or terminates power supply monitoring. For example, the monitoring control unit 131 controls the start or stop of receiving power including the beacon signal by outputting an instruction to the power receiving unit 111 and the conversion unit 112 when a predetermined condition is satisfied. The monitoring control unit 131 is an example of the power supply control unit.

For example, the monitoring control unit 131 improves the detection sensitivity for the beacon signal by instructing the conversion unit 112 to increase the load of the power receiving circuit more than usual when controlling the start of receiving the beacon signal. .. Further, the monitoring control unit 131 outputs an instruction regarding the determination of the beacon signal to the device detection unit 132, and outputs an instruction regarding the determination of the power reception status to the power reception notification unit 133.

Specifically, the monitoring control unit 131 refers to the threshold value DB 122 and controls the start of power reception of the beacon signal when the condition such as the remaining battery level of the power receiving terminal 100 exceeds the threshold value or falls below the threshold value. .. For example, when the monitoring control unit 131 detects that the remaining battery level is less than "30"%, it controls the start of receiving the beacon signal. Further, the monitoring control unit 131 may be configured to control the stop of receiving the beacon signal when it is determined that the power transmission device 99 is receiving sufficient power.

The device detection unit 132 is a processing unit that detects a power transmission device 99 that can start power transmission by determining whether or not the waveform indicating the level of the received power matches the beacon pattern. When the device detection unit 132 receives the input of the received power level from the conversion unit 112, the device detection unit 132 refers to the pattern DB 121 and determines to what extent the waveform indicating the received power level and the beacon pattern match. When the device detection unit 132 receives an instruction from the monitoring control unit 131, the device detection unit 132 initializes the number of acquisitions “n” of the beacon signal sample. For example, the device detection unit 132 sets the sample acquisition number n to the initial value “0”. The device detection unit 132 is an example of a pattern determination unit and a signal strength determination unit.

When the device detection unit 132 determines that the waveform indicating the power level matches the beacon pattern, the device detection unit 132 outputs information indicating that there is a power transmission device 99 that does not transmit continuous power in the vicinity to the power supply determination unit 134. To do. Further, when the device detection unit 132 does not detect a waveform indicating the level of power determined to match the beacon pattern, the device detection unit 132 supplies information indicating that there is no power transmission device 99 capable of starting continuous power transmission in the vicinity. Output to the determination unit 134.

In this embodiment, the device detection unit 132 receives the power of the beacon signal when the cross-correlation value calculated from the sample value and the beacon pattern at a specific time point exceeds the threshold value stored in the threshold value DB 122. It is determined that the waveform indicating the level matches the beacon pattern. The device detection unit 132 samples Prb (m) adjusted so that the average value of the detection values Pr (m) exceeding the number of samples for a predetermined cycle of the beacon signal, for example, one cycle of the beacon pattern becomes 0. Used as a value. Prb (m) is output from, for example, the conversion unit 112. Further, the device detection unit 132 uses the pattern value Ppb (m) subtracted so that the average value of all beacon patterns becomes 0 as the pattern value.

The comparison between the calculated sample value and the pattern value will be described with reference to FIGS. 6 to 7E. FIG. 6 is a diagram showing an example of a beacon pattern. Ppb (m) 7000 of the table shown on the right side of FIG. 6 indicates a pattern value subtracted so that the average value of the beacon pattern Pp (m) of the beacon pattern table shown in FIG. 5 becomes 0. In FIGS. 6 to 7E, the graph on the left side of the drawing, which has the same reference numerals as each column of the table on the right side of the drawing, shows a graph in which the values shown in each column are plotted. The device detection unit 132 compares the sample value Prb (m) of the received beacon signal with the pattern value Ppb (m) shown in FIG.

The device detection unit 132 calculates the cross-correlation value C between the beacon signal and the beacon pattern by, for example, applying the sample value Prb (m) and the pattern value Ppb (m) to the following equation (1). In the equation (1), M indicates the number of samples for one cycle of the beacon pattern.

FIG. 7A is a diagram showing an example of comparison between a waveform showing the level of electric power received from the power transmission device and the beacon pattern. As the level of the electric power shown in FIG. 7A, the sample value Prb (m) in which the DC component is removed from the electric power received by the power receiving unit 111 is used. The same applies to FIGS. 7B to 7E.

Graph 7001 plotting Prb (m) of the table shown on the right side of FIG. 7A corresponds to Graph 7000. In this case, the cross-correlation value C, which is the sum of Ppb (m) and Prb (m), is as high as "5.28" and exceeds the stored threshold value "2", so that the device detection unit 132 receives. It is determined that the beacon signal matches the beacon pattern.

FIG. 7B is a diagram showing another example of comparison between the waveform showing the level of electric power received from the power transmission device and the beacon pattern. FIG. 7B shows an example in which continuous power and a beacon pattern are compared instead of a beacon signal which is power transmitted intermittently. As shown in FIG. 7B, the detection value Pr (m) of the continuously transmitted power of the continuously transmitted power is plotted as shown in Graph 7100. On the other hand, when receiving the power continuously transmitted, the Prb (m) adjusted so that the average value of all the acquired Pr (m) becomes 0 is shown in column 7101 of the table. All become 0. As a result, the cross-correlation value C, which is the sum of Ppb (m) and Prb (m), becomes "0", which is equal to or less than the stored threshold value "2". Therefore, the device detection unit 132 determines the level of the received power. It is determined that the waveform shown does not match the beacon pattern.

FIG. 7C is a diagram showing another example of comparison between the waveform showing the level of electric power received from the power transmission device and the beacon pattern. In FIG. 7C, an example in which the beacon signal transmitted by the power transmission device 10 is weakened due to, for example, a long distance from the power transmission device 10 to the power receiving terminal 100 will be described. The detected value Pr (m) of the weakened beacon signal takes values of "0" and "0.50", for example, as shown in Graph 7200. The Pr (m) adjusted so that the average value of the acquired Pr (m) becomes 0 has the values of "-0.06" and "0.44" as shown in the table column 7201. Take. In this case, the cross-correlation value C, which is the sum of Ppb (m) and Prb (m), is "2.64", which exceeds the stored threshold value "2". Therefore, the device detection unit 132 receives the beacon signal of the received beacon signal. It is determined that the waveform indicating the power level matches the beacon pattern.

FIG. 7D is a diagram showing another example of comparison between the waveform showing the level of electric power received from the power transmission device and the beacon pattern. FIG. 7D shows an example of comparing Graph 7000 with Graph 7301 showing a random power level. In this case, the product of Ppb (m) and Prb (m) is random, and the cross-correlation value C is "−0.38". That is, since the cross-correlation value C is equal to or less than the stored threshold value “2”, the device detection unit 132 determines that the waveform indicating the level of the received power does not match the beacon pattern.

FIG. 7E is a diagram showing another example of comparison between the waveform showing the level of electric power received from the power transmission device and the beacon pattern. In FIG. 7E, the graph 7000 and the graph 7401 showing the power level of the beacon signal have the same waveform, but there is a time lag. In this case, the cross-correlation value C is “−0.72”, which is equal to or less than the stored threshold value “2”. However, when there is a time lag between the beacon signal and the beacon pattern in this way, for example, by applying to equation (2), the time lag between the beacon signal and the beacon pattern can be absorbed and cross-correlation can be achieved. The value C can be calculated.

For example, in the equation (1), the m-th sample value Prb (m) and the m-th pattern value Ppb (m) were multiplied, but in the equation (2), the (n-M + m) th-th. The sample value Prb (n−M + m) is multiplied by Ppb (m). Since (n-M + m) changes as the number of times the sample is acquired n increases, the time lag between the waveform indicating the power level of the beacon signal and the beacon pattern is absorbed by using the equation (2). Then, the cross-correlation value C can be calculated.

Returning to FIG. 4, the power receiving notification unit 133 is a processing unit that determines the current received power and notifies the power supply determination unit 134. For example, the power receiving notification unit 133 refers to the threshold value DB 122 and compares the first threshold value for the received power and the second threshold value larger than the first threshold value with the current received power output from the power receiving unit 111. The power receiving notification unit 133 initializes the power receiving flag “Fr” according to the instruction from the monitoring control unit 131. For example, the power receiving notification unit 133 sets the power receiving flag Fr to "impossible". The power receiving notification unit 133 is an example of a power determination unit.

For example, when the current received power exceeds the first threshold value and is equal to or less than the second threshold value, the power receiving notification unit 133 notifies the power supply determination unit 134 that the power is being received but the received power is insufficient. .. Similarly, when the current received power is equal to or less than the first threshold value, the power receiving notification unit 133 notifies the power supply determination unit 134 that the power is not being received, and the current power received is the second. If it exceeds the threshold value of, the power supply determination unit 134 is notified that sufficient power has been received. When the current received power exceeds the first threshold value, the power receiving notification unit 133 sets the power receiving flag "Fr" to "OK" as being receiving power, and the current received power is equal to or less than the first threshold value. If, the power receiving flag "Fr" is set to "impossible".

The power supply determination unit 134 is a processing unit that determines the power supply status based on the information of the current power reception status and the presence / absence of the nearby power transmission device 99. Specifically, the power supply determination unit 134 receives input of information regarding the presence / absence of a nearby power transmission device 99 from the device detection unit 132, and receives input of information regarding the current power reception status from the power reception notification unit 133. Then, the power supply determination unit 134 outputs the result of determination regarding the power supply status and the presence / absence of the nearby power transmission device 99 to the notification control unit 135.

For example, when it is determined that sufficient power has been received, the power supply determination unit 134 outputs a determination result regarding the power supply status to the notification control unit 135. Further, when it is determined that the power supply determination unit 134 is receiving power but the received power is insufficient, or is not receiving power, the power supply determination unit 134 further determines the presence or absence of the nearby power transmission device 99, and further determines the power supply status and the nearby power transmission device 99. The determination result regarding the presence / absence of is output to the notification control unit 135.

The notification control unit 135 is a processing unit that outputs the determination result regarding the power supply status and the presence / absence of the nearby power transmission device 99 input from the power supply determination unit 134 to the user of the power reception terminal 100. For example, the notification control unit 135 outputs information to the user of the power receiving terminal 100 by displaying a message on a display (not shown) of the power receiving terminal 100. Further, the notification control unit 135 may be configured to output information to the user of the power receiving terminal 100 by using a speaker, a vibrator, or the like (not shown). The notification control unit 135 is an example of an output unit.

An example of the information output by the notification control unit 135 will be described with reference to FIG. FIG. 8 is a diagram showing an example of the displayed message. As shown in (a) to (e) of reference numeral 9001 of FIG. 8, the notification control unit 135 displays a message on the display according to the power supply status of the power receiving terminal 100 and the presence / absence of the power transmission device 99 in the vicinity.

The notification control unit 135 outputs the message (a) shown in FIG. 8 when a determination result indicating that sufficient power has been received is input from the power supply determination unit 134. That is, the notification control unit 135 outputs the message "Power is being received with sufficient power."

Further, when the notification control unit 135 receives a determination result from the power supply determination unit 134 that the power is being received but the received power is insufficient and there is a power transmission device 10 or 20 transmitting a beacon signal in the vicinity. , The message (b) shown in FIG. 8 is output. That is, the notification control unit 135 outputs the message "Power is being received, but the power is not sufficient. There is a free power transmission device nearby."

Further, the notification control unit 135 has input from the power supply determination unit 134 a determination result that the power is being received but the received power is insufficient and there is no power transmission device 10 or 20 transmitting a beacon signal in the vicinity. In this case, the message (c) shown in FIG. 8 is output. That is, the notification control unit 135 outputs the message "Power is being received, but the power is not sufficient. There is no free power transmission device nearby."

Further, when the notification control unit 135 receives a determination result from the power supply determination unit 134 that the power transmission device 10 or 20 is not receiving power and is transmitting a beacon signal in the vicinity, the message shown in FIG. 8 is input. (D) is output. That is, the notification control unit 135 outputs the message "Power cannot be received, but there is a vacant power transmission device nearby."

Further, when the notification control unit 135 receives a determination result from the power supply determination unit 134 that the power is not being received and that there is no power transmission device 10 or 20 transmitting a beacon signal in the vicinity, the notification control unit 135 is shown in FIG. Output the message (e). That is, the notification control unit 135 outputs the message "Power cannot be received. There is no free power transmission device nearby."

As described above, the power receiving terminal 100 displays a message regarding the power supply status and the presence / absence of the nearby power transmission device 20 to inform the user of the presence of another power transmission device 20 while receiving power from the power transmission device 10. You can notify.

[Functional configuration of power transmission device]
Next, returning to FIG. 4, the functional configuration of the power transmission device 10 will be described. The power transmission device 10 includes a communication unit 11, a storage unit 12, a power transmission unit 13, and a control unit 14. The communication unit 11 is a processing unit that is wirelessly connected to the power receiving terminals 100 and 200 and controls information communication between the power receiving terminals 100 and 200. For example, the communication unit 11 is realized by a communication circuit and an antenna, and communicates with the power receiving terminals 100 and 200 by a wireless communication means such as P2P.

The storage unit 12 stores programs and data used by the power transmission device 10. For example, the storage unit 12 is realized by a semiconductor memory element such as a RAM or a flash memory, or a storage device such as a hard disk or an optical disk. Further, the storage unit 12 appropriately stores information used for each process performed by the control unit 14.

The power transmission unit 13 is a processing unit that switches and transmits a beacon signal and continuous electric power. For example, the power transmission unit 13 normally transmits a beacon signal, and when instructed by the control unit 14, the transmission of the beacon signal is switched to continuous power transmission. The power transmission unit 13 is realized by, for example, a power transmission circuit and an antenna.

The control unit 14 is realized by executing various programs stored in the internal storage device of the power transmission device 10 by the CPU, MPU, or the like using the RAM as a work area. The control unit 14 may be realized by an integrated circuit such as an ASIC or FPGA. Further, the control unit 14 is an example of an electronic circuit such as a processor or an example of a process executed by the processor or the like.

The control unit 14 is a processing unit that controls the start or end of power reception by the power receiving terminal 999. For example, the control unit 14 detects the start of power reception by the power receiving terminal 999 based on the change in the voltage value or the current value in the power transmission circuit and the information received from the power receiving terminal 999 through the communication unit 11, and instructs to switch the power. Is output to the power transmission unit 13. When the control unit 14 detects a change in the voltage value or the current value in the power transmission circuit during the transmission of the beacon signal, the control unit 14 determines that the power receiving terminal 100 has entered the power supply enable area 10-1. Further, the control unit 14 outputs an instruction to switch the transmission of the beacon signal to the continuous power transmission to the power transmission unit 13 when the power supply request is received from the power receiving terminal 100 that has entered the power supply enable area 10-1.

Further, the control unit 14 transmits a beacon signal to continuously transmit power when the power receiving terminal 100 ends receiving power, such as when the power receiving terminal 100 notifies the end of power reception during continuous power transmission. An instruction to switch to is output to the power transmission unit 13. The control unit 14 may be configured to continue continuous power transmission when it is determined that another power receiving terminal 200 exists in the power supply enable area 10-1. In this case, the power transmission device 10 sends the power transmission unit 13 to the power transmission unit 13 in order to maintain continuous power transmission even when the power reception terminal 100 ends receiving power when another power reception terminal 200 is receiving power. On the other hand, no instruction is output and continuous power transmission is continued.

[Flow of operation of power transmission device]
Next, the operation flow of the power transmission device 10 in this embodiment will be described with reference to FIG. FIG. 9 is a flowchart showing an example of the flow of operation by the power transmission device. First, the power transmission device 10 transmits a beacon signal (step S101), and whether or not the power receiving terminal 100 has entered the power supply enable area 10-1 depending on whether or not a change in a voltage value or a current value in the power transmission circuit is detected. Is determined (step S111).

If it is determined that the change in the voltage value or the current value has not been detected (step S111: No), the power transmission device 10 continues to send a beacon signal and returns to step S111 (step S141).

On the other hand, when it is determined that the change in the voltage value or the current value is detected (step S111: Yes), the power transmission device 10 performs P2P communication with the power receiving terminal 100 (step S113), and the power receiving terminal 100 transmits the P2P communication. It is determined whether or not the power supply request has been received (step S121). If it is determined that the power supply request has not been received (step S121: No), the power transmission device 10 continues to send a beacon signal and returns to step S111 (step S141).

On the other hand, when it is determined that the power supply request has been received (step S121: Yes), the power transmission device 10 stops the transmission of the beacon signal and starts the continuous power transmission (step S123). As a result, the power receiving terminal 100 can receive the continuous power transmitted from the power transmission device 10.

Next, the power transmission device 10 determines whether or not the information indicating the end of power reception has been received from the power receiving terminal 100 (step S131). When it is determined that the information indicating the end of power reception has been received (step S131: Yes), the power transmission device 10 stops the continuous power transmission (step S137), returns to step S101, and transmits the beacon signal. ..

When it is determined that the information indicating the end of power reception has not been received (step S131: No), the power transmission device 10 determines whether or not the communication with the power receiving terminal 100 is interrupted (step S133). When it is determined that the communication with the power receiving terminal 100 is interrupted (step S133: Yes), the power transmission device 10 stops the continuous power transmission (step S137), returns to step S101, and transmits the beacon signal. Do.

On the other hand, when it is determined that the communication with the power receiving terminal 100 is not interrupted (step S133: No), the power transmission device 10 continues to continuously transmit power (step S135). After that, the process returns to step S131 and the process is repeated.

[Operation flow of power receiving terminal]
Next, the flow of operation by the power receiving terminal 100 will be described with reference to FIGS. 10A and 10B. 10A and 10B are flowcharts showing an example of the flow of operation by the power receiving terminal. In FIGS. 10A and 10B, an example in which two power transmission devices A and B are installed will be described. First, the power receiving terminal 100 generates a monitoring trigger (step S201) and activates the power receiving circuit (step S203), for example, based on an instruction by the user.

Next, the power receiving terminal 100 determines whether or not the power transmission device A capable of supplying power is detected by detecting the beacon signal or detecting the continuous transmission of electric power (step S211). If it is determined that the power transmission device A has not been detected (step S211: No), the process proceeds to step S251 through the terminal a.

On the other hand, when it is determined that the power transmission device A has been detected (step S211: Yes), the power receiving terminal 100 transmits a power receiving request via the communication unit 110, performs a procedure, and then continuously sends the power transmission device A. Power is received and power supply to each part is started (step S213). Detailed description of the procedure by the communication unit 110 will be omitted. Next, the power receiving terminal 100 determines whether or not the received power exceeds a predetermined reference value (step S221). When it is determined that the received power is equal to or less than a predetermined reference value (step S221: No), the power receiving terminal 100 shifts to step S251 through the terminal a. On the other hand, when it is determined that the received power exceeds a predetermined reference value (step S221: Yes), the power receiving terminal 100 ends the process.

Moving to FIG. 10B, the power receiving terminal 100 determines whether or not a beacon signal matching the stored beacon pattern can be detected in order to detect whether or not there is a power transmission device other than the power transmission device A that can supply power. (Step S251). Since the power transmission device A that transmits continuous power does not transmit the beacon signal, when the power receiving terminal 100 detects the beacon signal, the power transmission device B that can supply power different from the power transmission device A is nearby. Can be detected.

When it is determined that the beacon signal cannot be detected (step S251: No), the power receiving terminal 100 notifies that there is no power transmission device capable of supplying power (step S265), and proceeds to step S271. On the other hand, when it is determined that the power receiving terminal 100 has been able to detect the beacon signal (step S251: Yes), the power receiving terminal 100 notifies that the power transmission device B different from the power transmission device A has been detected (step S251: Yes). S263), the process proceeds to step S271.

Then, the power receiving terminal 100 determines whether or not the power transmitted from the power transmission device A is being received (step S271). If it is determined that power is not being received (step S271: No), the process ends through the terminal b. If it is determined that power is being received (step S271: Yes), the power receiving terminal 100 continues to receive the power transmitted from the power transmission device A (step S273), and ends the process.

[Flow of power receiving power judgment processing]
Next, the flow of processing by the power receiving terminal 100 will be described in more detail with reference to FIGS. 11 and 12. FIG. 11 is a flowchart showing an example of the received power determination process by the power receiving terminal. First, the monitoring control unit 131 generates a monitoring trigger and outputs an instruction to the power receiving unit 111, the conversion unit 112, the device detection unit 132, and the power receiving notification unit 133 (step S301). The device detection unit 132 sets the sample acquisition number n to “0” (step S303). Further, the power receiving notification unit 133 sets the power receiving flag Fr to "impossible" (step S305).

Next, the power receiving unit 111 activates the power receiving circuit (step S307), acquires the detected value Pr (n) of the received power, and outputs it to the conversion unit 112 and the power receiving notification unit 133 (step S311). Next, the power receiving notification unit 133 calculates the total Pra (n) of the detected values Pr (n) using, for example, the following formula (3) (step S313).

The sum of the detected values Pr (n), Pra (n), indicates the level of power received by the power receiving unit 111 from the power transmission device 99. In the formula (3), "K" is a specified number of times for obtaining Pra (n), for example, the number of samples for one cycle of the beacon pattern.

Next, the power receiving notification unit 133 refers to the threshold value DB 122 and determines whether or not the total Pra (n) exceeds the first threshold value “Pth” regarding the received power (step S321). When it is determined that the threshold value is equal to or less than the first threshold value (step S321: No), that is, when it is determined that the power is not received, the process proceeds to the power transmission device detection process through the terminal c.

On the other hand, when it is determined that the power receiving notification unit 133 exceeds the first threshold value (step S321: Yes), the power receiving flag Fr is set to "OK" (step S323). Then, the power receiving notification unit 133 refers to the threshold value DB 122 and determines whether or not the total sum Pra (n) exceeds the second threshold value “Pd” regarding the received power (step S331). When it is determined that the value is equal to or less than the second threshold value (step S331: No), that is, when it is determined that the power is being received but the power is not sufficient, the process proceeds to the power transmission device detection process through the terminal c.

On the other hand, when it is determined that the power receiving notification unit 133 exceeds the second threshold value (step S331: Yes), the power receiving notification unit 133 outputs the determination result to the power supply determination unit 134. The power supply determination unit 134 outputs a determination result regarding the power reception status to the notification control unit 135. The notification control unit 135 outputs the message (a) (step S333), and ends the process.

[Flow of power transmission device detection process]
FIG. 12 is a flowchart showing an example of the power transmission device detection process by the power receiving terminal. First, the conversion unit 112 calculates the sample value Prb (n) subtracted so that the average value of the detection values Pr (n) becomes 0, and outputs the sample value Prb (n) to the device detection unit 132 (step S351). Next, the device detection unit 132 reads the m-th pattern value Ppb (m) of the beacon pattern table from the pattern DB 121, and sets the (n-M + m) -th sample value Prb (n-M + m) and the pattern value Ppb (m). ) And. Then, the device detection unit 132 calculates C (n), which is the sum of the products of Prb (n−M + m) and Pp (n), as a cross-correlation value (step S353). C (n) is calculated by, for example, the equation (2).

Next, the device detection unit 132 determines whether or not the cross-correlation value C (n) exceeds the pattern threshold value “Cth” stored in the threshold value DB 122 (step S361). When it is determined that C (n) exceeds Cth (step S361: Yes), the device detection unit 132 determines that there is a power transmission device 99 that does not transmit continuous power in the vicinity of the power transmission determination unit 134. Output to.

Next, the power supply determination unit 134 determines whether or not the power reception flag Fr is set to “OK” (step S371). When it is determined that Fr is “OK” (step S371: Yes), the power supply determination unit 134 outputs the determination result regarding the power reception status and the presence / absence of the nearby power transmission device 99 to the notification control unit 135. Upon receiving the determination result, the notification control unit 135 outputs the message (b) (step S373) and returns to step S301 through the terminal d.

On the other hand, when the power supply determination unit 134 determines that Fr is “impossible” (step S371: No), the power supply determination unit 134 outputs the determination result regarding the power reception status and the presence / absence of the nearby power transmission device 99 to the notification control unit 135. Upon receiving the determination result, the notification control unit 135 outputs the message (d) (step S375), and returns to step S301 through the terminal d.

Returning to step S361, when the device detection unit 132 determines that C (n) is Cth or less (step S361: No), the number n of the acquired sample values Prb (n) is the specified number of times N. It is determined whether or not it exceeds (step S381). The specified number of times N is, for example, the number of samples for one cycle of the beacon pattern. When the device detection unit 132 determines that the number of sample acquisitions n is equal to or less than the specified number of times N (step S381: No), the device detection unit 132 increments the number of sample acquisitions n by 1 (step S383), and proceeds to step S311 through the terminal e. go back.

When it is determined that the number of times the sample is acquired n exceeds the specified number of times N (step S381: Yes), the device detection unit 132 feeds the determination result that there is no power transmission device 99 capable of starting continuous power transmission in the vicinity. Output to the determination unit 134. The power supply determination unit 134 determines whether or not the power reception flag Fr is set to “OK” (step S391). When it is determined that Fr is “OK” (step S391: Yes), the power supply determination unit 134 outputs the determination result regarding the power reception status and the presence / absence of the nearby power transmission device 99 to the notification control unit 135. Upon receiving the determination result, the notification control unit 135 outputs the message (c) (step S393) and ends the process.

On the other hand, when the power supply determination unit 134 determines that Fr is “impossible” (step S391: No), the power supply determination unit 134 outputs the determination result regarding the power reception status and the presence / absence of the nearby power transmission device 99 to the notification control unit 135. Upon receiving the determination result, the notification control unit 135 outputs the message (e) (step S395) and returns to step S301 through the terminal d.

As described above, according to the present embodiment, when the power receiving terminal 100 receives the power transmitted from the power transmission device 10 in a non-contact manner and receives a beacon signal different from the power being received, the power transmission device 100 receives the power transmission device. Notify the user of the existence of 20. Thereby, for example, the power receiving terminal 100 can notify the user of the existence of the power transmission device 20 capable of transmitting sufficient power when the received power that can be received from the power transmission device 10 is insufficient. Since the user of the power receiving terminal 100 who has received the notification can know the existence of the power transmission device 20 capable of transmitting sufficient power, the power can be received from the power transmission device 20 by moving to the vicinity of the power transmission device 20.

In the first embodiment, the apparatus detection unit 132 determines whether or not a beacon signal satisfying a predetermined condition is received by the cross-correlation value C (n) calculated from the sample value Prb (m) and the pattern value Ppb (m). ) Was used, but the embodiment is not limited to this. For example, the device detection unit 132 may be configured to determine whether or not the beacon signal and the beacon pattern match based on the degree of matching between the beacon signal and the predetermined mask pattern. In this embodiment, a process of detecting a beacon signal will be described using a mask pattern including an upper limit value and a lower limit value of a sample value considered to match the beacon pattern.

[Functional configuration]
First, the functional configuration of the video output device 700 in this embodiment will be described. Since the functional configurations of the power receiving terminal 100 and the power transmission device 10 are the same as those of the first embodiment, detailed description thereof will be omitted. The present embodiment is different from the first embodiment in that the mask value table is stored in the pattern DB 121 instead of the beacon pattern table. FIG. 13 is a diagram showing an example of a mask value table. In the mask value table shown in FIG. 13, "m" and "ms" are the same as "m" and "ms" in the beacon pattern table shown in FIG. 5, so detailed description thereof will be omitted.

In FIG. 13, “Pml (m)” and “Pmu (m)” indicate the lower limit value and the upper limit value of the m-th mask, respectively. For example, in the "1" th pattern shown in FIG. 13, the lower limit of the mask is "−0.30" and the upper limit of the mask is “0.30”. In this case, if the first sample value exceeds the lower limit of the mask "-0.30" and falls below the upper limit of the mask "0.30", it is determined that the sample value satisfies the condition. Will be done. The lower limit value and the upper limit value of the mask are determined based on, for example, the beacon pattern Pp (m) shown in FIG. In this embodiment, Pp (m) before adjustment is used instead of Ppb (m) adjusted so that the average value of the beacon patterns becomes 0.

Next, among the processes in each processing unit, the points different from those in the first embodiment will be described. In this embodiment, Prb (m) adjusted so that the average value of all detected values becomes 0 is not used. In this embodiment, as a sample value, the conversion unit 112 normalizes the detection value Pr (m) of the beacon signal by using the sum of the detection values Pr (m) for one cycle of the beacon pattern Pr (m). Is calculated.

Prn (m) is calculated by, for example, multiplying the detected value Pr (m) by the value obtained by dividing the average value of the beacon patterns by the average value of the detected values Pr (m). When the average value of the beacon pattern shown in FIG. 5 is "0.12" and the average value of the detection values Pr (m) "50" for one cycle of the beacon pattern is "0.16", Prn ( m) is the product of the detected value Pr (m) and "0.12 / 0.16". For example, when Pr (1) is "0.28", the conversion unit 112 calculates the normalized value "0.21" as Prn (1).

A specific example of the sample value determination process using the mask pattern will be described with reference to FIG. FIG. 14 is a diagram showing an example of comparison between the mask pattern and the waveform showing the level of the beacon signal. In FIG. 14, graph 8001 shows the upper limit value Pmu (m) of the mask, and graph 8011 shows the lower limit value Pml (m) of the mask. Further, Graph 8101 shows a value Prn (m) obtained by normalizing the detected value Pr (m). For example, in FIG. 14, the sample value 8111 at a particular time point is located between graph 8001 and graph 8011. In such a case, the apparatus detection unit 132 determines that the sample value 8111 satisfies the condition because the sample value 8111 exceeds the lower limit value of the mask shown in the graph 8011 and is lower than the upper limit value of the mask shown in the graph 8001.

In this embodiment, for example, the device detection unit 132 has a ratio of sample values that are above the lower limit of the mask and below the upper limit of the sample values for one cycle calculated from the acquired beacon signal. Calculate "Cm". Then, when the calculated Cm exceeds the predetermined threshold value Cmth, the device detection unit 132 determines that the beacon signal satisfying the predetermined condition has been received. For example, out of 50 sample values, "30" sample values are above the lower limit of the mask and below the upper limit, and Cmth is "0.5". In this case, the device detection unit 132 has a beacon signal that satisfies a predetermined condition because the ratio Cm of the sample values that are above the lower limit of the mask and below the upper limit is "0.6" among all the sample values. Judged as having received.

[Processing flow]
Subsequently, the power transmission device detection process in this embodiment will be described with reference to FIG. Since the operation flow of the power transmission device 10 and the power receiving terminal 100 and the power receiving power determination process of the power receiving terminal 100 are the same as those in the first embodiment, detailed description thereof will be omitted. FIG. 15 is a flowchart showing an example of the power transmission device detection process by the power receiving terminal in the second embodiment. In the following description, since the same steps as those shown in FIG. 12 are the same steps, detailed description thereof will be omitted.

First, the conversion unit 112 calculates Prn (n) obtained by normalizing Pr (n) and outputs it to the device detection unit 132 (step S451). Next, the device detection unit 132 compares the output Prn (n) with the mask upper limit value Pmu (n) and the mask lower limit value Pml (n) (step S453).

Next, the device detection unit 132 determines whether or not Prn (n) exceeds Pml (n) and falls below Pmu (n) (step S461). When the device detection unit 132 determines that the value exceeds Pml (n) and falls below Pmu (n) (step S461: Yes), the device detection unit 132 increments the number of sample values that match the conditions by 1 (step S463). On the other hand, when it is determined that Prn (n) is Pmu (n) or more or Pml (n) or less (step S461: No), the device detection unit 132 proceeds to step S465.

Next, the device detection unit 132 calculates the ratio Cm of the number of sample values that match the conditions to the total number of samples, and determines whether or not Cm exceeds a predetermined threshold value Cmth (step S465). When it is determined that Cm exceeds Cmth (step S465: Yes), the process proceeds to step S371. On the other hand, when it is determined that Cm is Cmth or less (step S465: No), the device detection unit 132 proceeds to step S381.

According to this embodiment, has the beacon signal satisfying the predetermined conditions been received without calculating the sum of the products of the sample value and the pattern value and without requiring processing such as removing the DC component from the received signal? It can be determined whether or not.

In addition to the above-described embodiment, for example, the power receiving terminal 999 can estimate the change in the distance from the power transmission device 99 according to the change in the strength of the received beacon signal. In addition, the power receiving terminal 999 can also output the estimated change in distance as a message to the user of the power receiving terminal 999. In this embodiment, a process in which the power receiving terminal 999 outputs a change in the distance from the power transmission device 99 will be described.

[Explanation of change in distance and output message]
For example, when the distance between the power transmission device 10 and the power receiving terminal 100 becomes long, the beacon signal transmitted from the power transmission device 10 is weakened, so that the cross-correlation value C (n) indicating the degree of matching between the beacon signal and the beacon pattern is small. Become. Specifically, when the power transmission device 10 and the power receiving terminal 100 are close to each other, the degree of matching between the received beacon signal and the beacon pattern becomes high as shown in FIG. 7A. On the other hand, when the distance between the power transmission device 10 and the power receiving terminal 100 becomes long, the degree of matching between the beacon signal and the beacon pattern becomes low as shown in FIG. 7C due to the weakening of the beacon signal.

In this embodiment, the power receiving terminal 100 approaches the power transmission device 10 by comparing the previously calculated cross-correlation value C (n-1) with the newly calculated cross-correlation value C (n). Determine if it has been done. For example, when C (n) is larger than C (n-1), the power receiving terminal 100 can estimate that the power receiving terminal 100 is close to the power transmission device 10. On the contrary, when C (n) is smaller than C (n-1), the power receiving terminal 100 can estimate that the power receiving terminal 100 is away from the power transmission device 10.

A change in the distance between the power receiving terminals 300, 400 and 500 and the power transmission device 20 and a message output based on the change in the distance will be described with reference to FIGS. 16 and 17. FIG. 16 is a diagram showing an example of the positional relationship between the power transmission device and the power receiving terminal in the third embodiment. Since the power receiving terminals 300, 400, and 500 shown in FIG. 16 have the same configurations as the power receiving terminals 100 shown in FIG. 4, detailed description thereof will be omitted. Further, in FIG. 16, the beacon detection range 20-2 of the power transmission device 20 is widely set so as to include the entire power supply enable area 10-1 of the power transmission device 10. In FIG. 16, a plurality of power receiving terminals 300, 400, and 500 receive continuous power from the power transmission device 10 at the same time.

In the example shown in FIG. 16, the power receiving terminal 300 enters the beacon detection range 20-2 of the power transmission device 20 by moving in the direction of the arrow (1), so that the beacon signal transmitted from the power transmission device 20 is detected. Therefore, the cross-correlation value C (n-1) can be calculated. On the other hand, the power receiving terminal 300 cannot receive power from any of the power transmission devices 10 and 20 at the position 300-a after the movement.

In such a case, the power receiving terminal 300 outputs the message shown by (d) + (f) in reference numeral 9101 of FIG. 17, for example. FIG. 17 is a diagram showing an example of the displayed message in the third embodiment. That is, when the power receiving terminal 300 moves to the position 300-a, it says, "I have not been able to receive power, but there is a vacant power transmission device nearby." Output one message. As a result, the power receiving terminal 300 can notify the user not only whether or not there is a power transmission device capable of receiving power, but also whether or not the user is close to the power transmission device.

Next, since the power receiving terminal 300 enters the power supply available area 10-1 of the power transmission device 10 by moving in the direction of the arrow (4), the power receiving terminal 300 receives the continuous power transmitted from the power transmission device 10. Can be done. However, since the power transmission device 10 also supplies power to the power receiving terminal 200 at the same time, the power receiving terminal 300 cannot receive sufficient power. Further, since the power receiving terminal 300 is closer to the power transmission device 20, the cross-correlation value C (n) calculated by receiving the beacon signal at the position 300-b after the movement is calculated by the beacon signal received before the movement. It becomes larger than the cross-correlation value C (n-1).

In such a case, the power receiving terminal 300 outputs, for example, the message shown in (b) + (f) of FIG. That is, when the power receiving terminal 300 moves to the position 300-b, it says, "I am receiving power, but the power is not enough. There is a vacant power transmission device nearby." "I am approaching a vacant power transmission device." Two messages are output.

Further, although the power receiving terminal 400 illustrated in FIG. 16 is within the beacon detection range 20-2 of the power transmission device 20, it moves away from the power transmission device 20 by moving in the direction of the arrow (3). As a result, the cross-correlation value C (n) calculated after the movement is smaller than the cross-correlation value C (n-1) calculated before the movement. Further, at the position 400-a after the movement, power cannot be received from either the power transmission devices 10 and 20.

In such a case, the power receiving terminal 400 outputs, for example, the message shown in (d) + (h) of FIG. That is, when the power receiving terminal 400 moves to the position 400-a, it says, "I cannot receive power, but there is a vacant power transmission device nearby." And "I am moving away from the vacant power transmission device." 2 Output one message.

Then, the power receiving terminal 400 moves further away from the power transmission device 20 by moving in the direction of the arrow (6) from the position 400-a, while moving to the position 400-b included in the power supply enable area 10-1 of the power transmission device 10. enter in.

In such a case, the power receiving terminal 400 outputs, for example, the message shown in (b) + (h) of FIG. That is, when the power receiving terminal 400 moves to the position 400-b, it says, "I am receiving power, but the power is not enough. There is a vacant power transmission device nearby." "I am moving away from the vacant power transmission device." Two messages are output.

Further, the power receiving terminal 500 illustrated in FIG. 16 is within the beacon detection range 20-2 of the power transmission device 20, and then moves in the direction of the arrow (2). However, the distance from the position 500-a after the movement to the power transmission device 20 does not change from the distance from the power receiving terminal 500 before the movement to the power transmission device 20. As a result, the cross-correlation value C (n) calculated after the movement does not change from the cross-correlation value C (n-1) calculated before the movement. Further, at the position 500-a after the movement, the power receiving terminal 500 cannot receive power from any of the power transmission devices 10 and 20.

In such a case, the power receiving terminal 500 outputs, for example, the message shown in (d) + (g) of FIG. That is, when the power receiving terminal 500 moves to the position 500-b, it says, "I am not receiving power, but there is a vacant power transmission device nearby." And "I am not approaching the vacant power transmission device." Output two messages.

Further, the power receiving terminal 500 moves in the direction of the arrow (5), but the distance from the position 500-b after the movement to the power transmission device 20 also changes from the distance from the position 500-a before the movement to the power transmission device 20. Not. Further, the position 500-b after the movement is included in the power supply available area 10-1 of the power transmission device 10.

In such a case, the power receiving terminal 500 outputs the message shown in (b) + (g) of FIG. 17, for example. That is, when the power receiving terminal 500 moves to the position 500-b, it says, "I am receiving power, but the power is not enough. There is a vacant power transmission device nearby." "I am approaching a vacant power transmission device." Outputs two messages, "No."

As described above, in this embodiment, the power receiving terminal 100 outputs a message according to the change in the distance from the power transmission device 10, so that the user can be notified of the approach status to the power transmission device 10. Although the configuration for simply comparing C (n-1) and C (n) has been described, the present invention is not limited to this. In this embodiment, the power receiving terminal 100 calculates the difference "Cd" between C (n-1) and C (n), and further determines whether or not the power receiving terminal 100 is close to the power transmission device 10. A configuration in which the approach threshold value “Dth” used in the case is stored in advance will be described. In this embodiment, the power receiving terminal 100 determines whether or not the distance to the power transmission device 10 has changed by comparing the difference Cd with the approach threshold value Dth. For example, the power receiving terminal 100 determines that the distance to the power transmission device 10 has not changed when the absolute value of the difference Cd is not 0 but is smaller than the approach threshold value Dth. As a result, a weak change in the beacon signal can be ignored.

Further, whether or not the power receiving terminal 100 is close to the power transmission device 10 is determined, for example, by comparing the strength of the beacon signal received after the second time with the strength of the beacon signal received before. The embodiment is not limited to this. For example, when the power receiving terminal 100 detects the beacon signal for the first time after creating the trigger for power supply monitoring, it is estimated that the power receiving terminal 100 has moved from the outside to the inside of the beacon detection range 10-2 of the power transmission device 10. In such a case, the power receiving terminal 100 may be configured to output a message indicating that it has approached the power transmission device 10.

[Functional configuration]
Also in this embodiment, since the functional configurations of the power receiving terminal 100 and the power transmission device 10 are the same as those in the first embodiment, detailed description thereof will be omitted. In this embodiment, the threshold value DB 122 further stores the approach threshold value “Dth”.

In this embodiment, the device detection unit 132 holds the previously calculated cross-correlation value “C (n-1)” between the beacon signal and the beacon pattern as “C0”. Further, when the device detection unit 132 receives the beacon signal after that, the device detection unit 132 newly calculates the cross-correlation value C (n) and calculates the difference "Cd" between the newly calculated C (n) and C0. To do. Further, the device detection unit 132 determines whether or not the power receiving terminal 100 is close to the power transmission device 10 by comparing the calculated difference Cd with the approach threshold value Dth.

For example, in the device detection unit 132, when the difference Cd is a positive value and is larger than Dth, that is, when the cross-correlation value C (n) is larger than the value obtained by adding Dth to C0, the power receiving terminal 100 It is determined that the power transmission device 10 is approaching. On the other hand, the device detection unit 132 receives power when the difference Cd is a negative value and is smaller than "-Dth", that is, when the value obtained by adding Dth to the cross-correlation value C (n) is smaller than C0. It is determined that 100 is moving away from the power transmission device 10. Further, the device detection unit 132 determines that the power receiving terminal 100 is not approaching the power transmission device 10 when the absolute value of the difference Cd is smaller than Dth, that is, when the difference between C (n) and C0 is smaller than Dth. To do.

Further, the power supply determination unit 134 determines a message to be output based on the determination result by the device detection unit 132 and the determination result of the power reception status by the power reception notification unit 133. The notification control unit 135 outputs a message determined by the power supply determination unit 134. The output message is a message indicated by any of reference numerals 9101 in FIG. When the power supply determination unit 134 determines that the power reception notification unit 133 has been able to receive sufficient power, the power supply determination unit 134 performs the same processing as in the first embodiment, and displays the message indicated by reference numeral 9001 (a) in FIG. Determine as the message to be output. Further, when the power transmission determination unit 134 does not detect a nearby vacant power transmission device in the device detection unit 132, the power transmission determination unit 134 performs the same processing as in the first embodiment, and the (c) or (e) of reference numeral 9001 in FIG. Determine as the message to output the message shown in.

[Processing flow]
Next, the flow of processing in this embodiment will be described with reference to FIGS. 18 and 19. Since the operation flow of the power transmission device 10 and the power receiving terminal 100 is the same as that of the first embodiment, detailed description thereof will be omitted. FIG. 18 is a flowchart showing an example of the received power determination process by the power receiving terminal in the third embodiment. In the following description, since the same steps as those shown in FIG. 11 are the same steps, detailed description thereof will be omitted.

After step S303, the device detection unit 132 initializes the number of times the beacon signal is detected “Fc” and the detection level “C0” of the beacon signal, and proceeds to step S305 (step S504).

Further, when the device detection unit 132 determines that the total Pra (n) is equal to or less than the first threshold value “Pth” (step S321: No), the number n of the acquired sample values Prb (n) is , It is determined whether or not the specified number of times N is exceeded (step S541). When it is determined that n is N or less (step S541: No), the device detection unit 132 increments n by 1 (step S543) and returns to step S311 through the terminal f. On the other hand, when it is determined that n exceeds N (step S541: Yes), the process proceeds to the power transmission device detection process through the terminal g.

The device detection unit 132 also proceeds to step S541 when it is determined in step S331 that the total Pra (n) is equal to or less than the second threshold value “Pd” (step S331: No).

FIG. 19 is a flowchart showing an example of the power transmission device detection process by the power receiving terminal in the third embodiment. In the following description, since the same steps as those shown in FIG. 12 are the same steps, detailed description thereof will be omitted.

When the device detection unit 132 determines in step S361 that the cross-correlation value C (n) is smaller than the pattern threshold value Cth (step S361: No), the beacon signal detection number Fc and the beacon signal detection level C0. And are initialized (step S681). After that, the process proceeds to step S391.

After that, the power supply determination unit 134 determines whether or not the power reception flag Fr is set to “OK” (step S391). When the power supply determination unit 134 determines that Fr is “OK” (step S391: Yes), the power supply determination unit 134 proceeds to step S393. On the other hand, when the power supply determination unit 134 determines that Fr is “impossible” (step S391: No), the power supply determination unit 134 outputs the determination result regarding the power reception status and the presence / absence of the nearby power transmission device 99 to the notification control unit 135. Upon receiving the determination result, the notification control unit 135 outputs the message (e) (step S395), and returns to step S504 through the terminal h.

After the message is output in step S373 or step S375, the device detection unit 132 determines whether or not the number of times "Fc" of detecting the beacon signal is the second or later (step S601). When it is determined that the Fc is not the second or later time (step S601: No), the device detection unit 132 sets the Fc to "second time or later" (step S605), and then proceeds to step S621.

When it is determined that the Fc is the second time or later (step S601: Yes), the device detection unit 132 subtracts the immediately preceding detection level C0 from the cross-correlation value C (n) between the beacon signal and the beacon pattern. "Cd" is calculated (step S603). Then, the device detection unit 132 compares the calculated Cd with the approach threshold value “Dth” (step S611).

When Cd is a negative value and is −Dth or less (step S611: Cd ≦ −Dth), the device detection unit 132 outputs a message (h) (step S613). When the absolute value of Cd is less than Dth (step S611: -Dth <Cd <Dth), the device detection unit 132 outputs a message (g) (step S615). When Cd is a positive value and is Dth or more (step S611: Dth ≦ Cd), the device detection unit 132 outputs a message (f) (step S617).

Then, the device detection unit 132 sets the calculated C (n) to C0 (step S621), and waits until a predetermined time elapses (step S623). After that, the process returns to step S504 through the terminal h, and the process is repeated.

Through the above processing, the power receiving terminal 100 can determine whether or not it is close to the power transmission device 10 and output the determination result to the user.

Although the examples of the present invention have been described so far, the present invention may be implemented in various different forms other than the above-described examples. For example, the processes shown in FIGS. 9 to 12, 15, 18, and 19 are not limited to the above order, and may be performed simultaneously as long as the processing contents do not contradict each other. It may be replaced and carried out.

Further, each component of each of the illustrated devices is a functional concept, and does not necessarily have to be physically configured as shown in the figure. That is, the specific form of distribution / integration of each device is not limited to the one shown in the figure. That is, all or a part thereof can be functionally or physically distributed / integrated in an arbitrary unit according to various loads, usage conditions, and the like. For example, the power supply determination unit 134 and the notification control unit 135 of the power receiving terminal 100 may be integrated, or the device detection unit 132 and the power supply determination unit 134 may be integrated. Further, each processing function performed by each device may be realized by a CPU and a program analyzed and executed by the CPU, or may be realized as hardware by wired logic.

When receiving power from the power transmission device 10, the power receiving terminal 100 can start receiving power without detecting the beacon signal transmitted from the power transmission device 10 in advance. For example, when the power receiving terminal 100 enters the power supply enable area 10-1 shown in FIG. 1, the power transmission device 10 has already transmitted continuous power to another power receiving terminal 200, so that the power transmission device 10 emits a beacon. It may not receive a signal. Even in this case, the power receiving terminal 100 can start receiving the continuous power transmitted from the power transmission device 10 by receiving the continuous power without receiving the beacon signal from the power transmission device 10.

In addition to the case where the power receiving terminal 100 receives a beacon signal that newly satisfies the condition after starting the continuous power receiving from the power transmission device 10, for example, the power receiving terminal 100 has already started receiving the continuous power. It may have received a beacon signal that meets other conditions. In this case, when the device detection unit 132 continues to receive the beacon signal that has already been received even after starting to receive the continuous power transmitted from another power transmission device, the power transmission device 99 is in the vicinity. It may be configured to determine that.

The first threshold value regarding the received power stored in the threshold value DB 122 may be any value smaller than the second threshold value, and the first threshold value may be zero. In this case, if even a small amount of power can be received, the power receiving terminal 100 attempts to detect another power transmission device 99 while continuing to receive the continuous power transmitted from the power transmission device 99.

Further, in the third embodiment, the configuration for determining whether or not the power receiving terminals 300, 400 and 500 approach the same power transmission device 20 has been disclosed, but the present invention is not limited to this. For example, in the example shown in FIG. 16, when the power receiving terminal 200 does not receive the continuous power transmitted from the power transmission device 10, the power receiving terminal 400 moves from the position 400-a to the position 400-b in FIG. This case will be described. In this case, the power receiving terminal 400 moves away from the power transmission device 20, but approaches another power transmission device 10 capable of starting continuous power transmission. In such a case, the power receiving terminal 400 may output the message "You are approaching an empty power transmission device" instead of the message "You are moving away from an empty power transmission device." That is, the power receiving terminal 400 notifies the user that it is approaching another power transmission device 10 instead of notifying that it is moving away from the power transmission device 20. This makes it possible to more efficiently notify the user of the approach to either the power transmission device 10 or 20.

The beacon detection ranges 10-2 and 20-2 shown in FIG. 1 are examples. For example, the beacon detection range 10-2 of the power transmission device 10 includes the entire power supply enable area 20-1 of the power transmission device 20. It may be configured to be widely set.

The conditions used by the monitoring control unit 131 to control the start or stop of power reception of the beacon signal are not limited to the remaining battery level described above, and other conditions such as time and position information may be used. .. Specifically, when a predetermined time arrives, a predetermined time elapses, or the power receiving terminal 100 approaches a preset position, the monitoring control unit 131 starts or stops receiving a beacon signal. It may be configured to control. In addition, for example, the monitoring control unit 131 may be configured to set the position where power has been received in the past, and when the information transmitted from the power transmission device 99 is received by wireless communication or the like, the beacon signal is received. It may be configured to start.

Further, the monitoring control unit 131 may be controlled so as to always receive the beacon signal without using the preset conditions, and the reception of the beacon signal is started based on the request from the user of the power receiving terminal 100. Alternatively, it may be configured to control the stop.

Regarding the configuration for comparing various threshold values with the detected value, etc., the configuration for determining whether or not the detected value, etc. exceeds the threshold value has been described, but the present invention is not limited to this, and whether the detected value, etc. is equal to or higher than the threshold value. It may be configured to determine whether or not.

[Hardware configuration]
Next, the hardware configuration of the power receiving terminal 999 and the power transmission device 99 will be described with reference to FIGS. 20 and 21. FIG. 20 is a diagram showing an example of the hardware configuration of the power receiving terminal. The power receiving terminal 999 includes a power receiving circuit 1001, a communication circuit 1002, a CPU 1003, a power supply circuit 1004, a power receiving power sampling circuit 1005, a memory 1006, a display 1007, a speaker 1008, and a vibrator 1009. In addition, the parts shown in FIG. 20 are connected to each other by the bus 1010 either directly or through an interface. Further, the antenna 1011 is connected to the power receiving circuit 1001, and the antenna 1012 is connected to the communication circuit 1002.

The power receiving circuit 1001 receives power including a beacon signal from the power transmission device 99 through the antenna 1011. The communication circuit 1002 communicates with the power transmission device 99 through the antenna 1012. The communication circuit 1002 is, for example, an interface such as a chip built in a board. The power supply circuit 1004 uses the power received by the power receiving circuit 1001 to supply power to various parts such as a battery (not shown). The received power sampling circuit 1005 converts the power received by the power receiving circuit 1001 into a received signal that can be handled by the CPU 1003. The display 1007, the speaker 1008, and the vibrator 1009 output various information.

The memory 1006 stores a power receiving program having the same function as each processing unit included in the control unit 130 shown in each of the above embodiments. Further, the pattern DB 121 and the threshold value DB 122 are stored in the memory 1006. Various data for realizing the power receiving program are stored in the memory 1006. As an example of the memory 1006, in addition to the HDD, another computer-readable recording device such as a ROM (Read Only Memory), a RAM, or a CD-ROM may be used.

Further, the CPU 1003 and the memory 1006 realize the functions of the storage unit 120, the control unit 130, and the like shown in FIG. 4, for example.

For example, the CPU 1003 reads various programs stored in the memory 1006 and generates a process for realizing various functions on the memory 1006. Then, the CPU 1003 performs various processes by executing the process generated on the memory 1006 together with each unit.

Next, the hardware configuration of the power transmission device 99 will be described. FIG. 21 is a diagram showing an example of the hardware configuration of the power transmission device. The power transmission device 99 includes a power transmission circuit 2001, a communication circuit 2002, a CPU 2003, and a memory 2006. In addition, the parts shown in FIG. 21 are connected to each other by a bus 2010. Further, the antenna 2011 is connected to the power transmission circuit 2001, and the antenna 2012 is connected to the communication circuit 2002.

The power transmission circuit 2001 transmits electric power through the antenna 2011. The communication circuit 2002 communicates with the power receiving terminal 999 through the antenna 2012. The communication circuit 2002 is an interface such as a chip built into a board. The power supply circuit 2004 supplies electric power to the power transmission circuit 2001.

The memory 2006 stores a power transmission program having the same function as the control unit 14 shown in each of the above embodiments. In addition, various data for realizing the power transmission program are stored in the memory 2006. As an example of the memory 2006, in addition to the HDD, another computer-readable recording device such as a ROM, RAM, or CD-ROM may be used.

Further, the CPU 2003 and the memory 2006 realize the functions of the storage unit 12, the control unit 14, and the like shown in FIG. 4, for example.

For example, the CPU 2003 reads various programs stored in the memory 2006 and generates a process for realizing various functions on the memory 2006. Then, the CPU 2003 performs various processes by executing the process generated on the memory 2006 together with each unit.

The above program is stored in another computer (or server) connected to the power receiving terminal 999 and the power transmission device 99 via a public line, the Internet, a LAN, a WAN (Wide Area Network), or the like. Is also good. In this case, the power receiving terminal 999 reads a program from another computer or the like via the communication circuit 1002 shown in FIG. 20 and executes the program. Further, the power transmission device 99 reads a program from another computer or the like via the communication circuit 2002 shown in FIG. 21 and executes the program.

1 Non-contact power supply system 10, 20 Power transmission device 10-1, 20-1 Power supply area 10-2, 20-2 Beacon detection range 10-3 Communication range 11 Communication unit 12 Storage unit 13 Power transmission unit 14 Control unit 100, 200 , 300, 400, 500 Power receiving terminal 110 Communication unit 111 Power receiving unit 112 Conversion unit 120 Storage unit 121 Pattern DB
122 Threshold DB
130 Control unit 131 Monitoring control unit 132 Device detection unit 133 Power reception notification unit 134 Power supply judgment unit 135 Notification control unit

Claims (9)

A power supply control unit that controls power supply by electric power transmitted from the first power transmission device,
In a state in which power supply by the power transmitted from the first power transmitting device is carried out, when receiving a predetermined condition is satisfied signals from different second power transmission device and the first power transmitting device, before Symbol second As device information related to the power transmission device of the above, an output unit that outputs the device information including information indicating whether or not power can be supplied by the power transmitted from the second power transmission device to a means for notifying the user.
A power receiving device characterized by having. Whether or not the sum of the products in the predetermined period exceeds the predetermined reference value by calculating the product of the plurality of detected values detected from the signals received within the predetermined period and the values stored in advance. Further has a pattern determination unit for determining
The power receiving unit according to claim 1, wherein the output unit determines that the received signal satisfies the predetermined condition when it is determined that the total sum of the products exceeds the predetermined reference value. apparatus. It is determined whether or not the plurality of detected values detected from the signals received within the predetermined period fall within the range of the upper limit value and the lower limit value stored in advance, and fall within the range within the predetermined period. Further has a pattern determination unit for determining whether or not the total number of detected values determined to exceed a predetermined reference value.
The first aspect of claim 1, wherein the output unit determines that the received signal satisfies the predetermined condition when it is determined that the total number of the detected values exceeds the predetermined reference value. Power receiving device. Further having a power determination unit for determining whether or not the received power received from the first power transmission device is smaller than the first threshold value.
The output unit, when the received power is determined to be smaller than the first threshold value, any one of claims 1 to 3 and outputs the device information including the information about the received power The power receiving device according to one. The power determination unit further determines whether or not the received power exceeds a second threshold value smaller than the first threshold value.
The output unit receives the device information including information indicating that the received power is insufficient when it is determined that the received power is smaller than the first threshold value and exceeds the second threshold value. The power receiving device according to claim 4, wherein the power receiving device outputs the power. The output unit receives a signal when it is determined that the received power is smaller than the first threshold value and exceeds the second threshold value and does not receive a signal satisfying the predetermined condition, or the received power is the second. The device including information indicating that power cannot be supplied by the power transmitted from the second power transmission device when it is determined that the value is equal to or less than the threshold value of the above and the signal satisfying the predetermined condition is not received. The power receiving device according to claim 5, wherein the power receiving device is characterized by outputting information. A signal strength determining unit that determines which is greater, the first strength of the signal received at the first time point or the second strength of the signal received at the second time point after the first time point. Have more
A first aspect of the present invention, wherein the output unit outputs the device information including information on a change in the distance between the second power transmission device and the own device based on the determination result in the signal strength determination unit. The power receiving device according to any one of 6. When the signal strength determination unit determines that the first strength is higher, the output unit outputs the device information including information indicating that the distance is far, and the second output unit. The power receiving device according to claim 7, wherein when it is determined that the strength of the device is greater than the strength of the device, the device information including the information indicating that the distance is approaching is output. On the computer
The process of controlling the power supply by the electric power transmitted from the first power transmission device,
In a state in which power supply by the power transmitted from the first power transmitting device is carried out, when receiving a predetermined condition is satisfied signals from different second power transmission device and the first power transmitting device, before Symbol second As the device information related to the power transmission device of the above, the process of outputting the device information including the information indicating whether or not the power can be supplied by the electric power transmitted from the second power transmission device to the means for notifying the user is executed. Power receiving program.

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