JP6497452B2 - Power receiving device and power receiving control program - Google Patents

Description

  The present invention relates to a technique for receiving power from a non-contact power supply apparatus.

  For example, in the case of magnetic resonance type non-contact power feeding, power can be supplied even if the power feeding device and the power receiving device are some distance apart. According to such non-contact power feeding, it is conceivable that the power receiving device detects the power feeding device by short-range wireless communication and requests the detected power feeding device to feed power, thereby automating the charging procedure. However, since the communication distance by short-range wireless is generally longer than the distance that can be fed, the power supply from the detected feeding device may fail.

  Further, the power receiving device may detect a plurality of power feeding devices.

JP 2013-172502 A

  In one aspect, an object of the present invention is to reduce unnecessary power supply requirements.

  The power receiving device according to one aspect receives (A) a detection unit that detects a power feeding device by short-range wireless communication, and (B) receives a power supply among the plurality of power feeding devices when detecting the plurality of power feeding devices. A selection unit that preferentially selects a power supply device included in a performance list in which a power supply device with a record is registered, and (C) a request unit that requests wireless power supply to the selected power supply device by short-range wireless communication. , (D) a registration unit that registers the power supply device in the result list when the power supply is received from the unregistered power supply device.

  In one aspect, unnecessary power supply requirements can be reduced.

FIG. 1 is a diagram illustrating an arrangement example of a power receiving device and a power feeding device. FIG. 2 is a diagram illustrating an example of a sequence. FIG. 3 is a diagram illustrating an example of a detection list. FIG. 4 is a diagram illustrating an example of a performance list. FIG. 5 is a diagram illustrating an example of a sequence. FIG. 6 is a diagram illustrating an example of a performance list. FIG. 7 is a diagram illustrating an example of a sequence. FIG. 8 is a diagram illustrating a hardware configuration example of the power supply apparatus. FIG. 9 is a diagram illustrating a hardware configuration example of the power receiving apparatus. FIG. 10 is a diagram illustrating a module configuration example of the power receiving device. FIG. 11 is a diagram showing a main process (A) flow. FIG. 12 is a diagram showing a main process (A) flow. FIG. 13 is a diagram showing a main process (A) flow. FIG. 14 is a diagram showing a selection process (A) flow. FIG. 15 is a diagram illustrating an arrangement example of the power receiving device and the power feeding device according to the second embodiment. FIG. 16 is a diagram illustrating an example of a detection list according to the second embodiment. FIG. 17 is a diagram illustrating an example of a performance list according to the second embodiment. FIG. 18 is a diagram showing a main process (B) flow. FIG. 19 is a diagram illustrating a selection process (B) flow. FIG. 20 is a diagram illustrating an example of a detection list according to the third embodiment. FIG. 21 is a diagram illustrating an example of a detection list according to the third embodiment. FIG. 22 is a diagram showing a main process (C) flow. FIG. 23 is a diagram showing a main process (C) flow. FIG. 24 is a diagram showing a main process (C) flow. FIG. 25 is a diagram showing a main process (C) flow.

[Embodiment 1]
FIG. 1 shows an arrangement example of the power receiving apparatus 101 and the power feeding apparatus 103. The power receiving apparatus 101 is charged by receiving power supplied from the power supply apparatus 103. The power receiving apparatus 101 is a portable electronic device such as a mobile phone terminal or a wearable terminal. The power receiving apparatus 101 may be an apparatus that moves by itself, such as an automobile, a bicycle, or a drone.

  In conventional wireless power feeding using an electromagnetic induction method, power feeding is performed by bringing the power receiving apparatus 101 close to the power feeding apparatus 103. On the other hand, in the wireless power feeding by the magnetic field resonance method, power can be fed even if it is several tens of centimeters to several meters away. The wireless power feeding by the magnetic field resonance method is a kind of non-contact wireless power feeding method.

  In wireless power feeding using the magnetic field resonance method, a short-distance wireless communication path is established separately from the magnetic field resonance, and power supply is controlled via the communication path. Specifically, parameters necessary for power supply such as the ID of the power receiving apparatus 101 and the power feeding apparatus 103 and the received power value are communicated.

  The power supply range 105a is a range in which power supply by the power supply apparatus 103a is successful. The power supply range 105b is a range in which power supply by the power supply apparatus 103b is successful. The communication range 107a is a range in which near field communication by the power supply apparatus 103a is successful. The communication range 107b is a range in which near field communication by the power supply apparatus 103b is successful. The communication range 107a is wider than the power supply range 105a. The communication range 107b is wider than the power supply range 105b.

  Since the power receiving apparatus 101 in this example is located within the communication range 107a, the power receiving apparatus 103a is detected by short-range wireless communication. However, since the power receiving apparatus 101 is located outside the power feeding range 105a, power supply from the power feeding apparatus 103a to the power receiving apparatus 101 fails.

  On the other hand, since the power receiving apparatus 101 is located within the communication range 107b, the power receiving apparatus 103b is detected by short-range wireless communication. And since the power receiving apparatus 101 is located in the electric power feeding range 105b, the electric power supply from the electric power feeding apparatus 103b to the power receiving apparatus 101 succeeds.

  Conventionally, when the power receiving apparatus 101 detects the power supply apparatus 103 a and the power supply apparatus 103 b, it cannot be determined whether the power supply from each power supply apparatus 103 is successful. If the power supply apparatus 103a is first requested to supply power, unnecessary communication is performed. In addition, the start of power reception is delayed.

  In the present embodiment, in the power receiving apparatus 101, the power supply apparatus 103 that has once successfully supplied power is registered in the performance list held by itself. Then, the power supply request is sent to the power supply apparatus 103 registered in the result list from the next time. If it is assumed that the arrangement of the power receiving apparatus 101 and the power feeding apparatus 103 is approximately the same every time, unnecessary communication is not performed after the second time. In addition, the start of power reception is not delayed.

  FIG. 2 shows an example of the sequence. It is assumed that the ID of the power supply apparatus 103a is PS020735. The ID of the power supply apparatus 103b is PS064824. Hereinafter, the ID of the power supply apparatus 103 may be referred to as a power supply apparatus ID.

  The power receiving apparatus 101 first searches for a nearby power supply apparatus 103 by short-range wireless communication. The power supply apparatus 103a transmits a beacon for short-range wireless communication (including the ID of the power supply apparatus 103a) (S201). The power supply apparatus 103b also transmits a short-range wireless communication beacon (including the ID of the power supply apparatus 103b) (S203). The power receiving apparatus 101 detects these power supply apparatuses 103a and 103b by receiving these beacons (S205). The power receiving apparatus 101 registers the detected ID of the power feeding apparatus 103a and the ID of the power feeding apparatus 103b in the detection list held by itself (S207). The detection list is newly generated every time the power supply apparatus 103 is searched.

  FIG. 3 shows an example of the detection list. The detection list in this example includes a record (hereinafter referred to as a detection record) corresponding to the detected power supply apparatus 103. The detection record has a field for setting the power supply apparatus ID and a selection flag field. In the initial state, the selection flag is set to OFF. When the power supply apparatus 103 is selected as the power supply request destination, the selection flag corresponding to the power supply apparatus 103 is turned ON. The first detection record in this example corresponds to the power supply apparatus 103a, and the second detection record similarly corresponds to the power supply apparatus 103b.

  Returning to the description of FIG. Next, the power receiving apparatus 101 collates each detected power supply apparatus 103 with the result list to determine whether or not the same power supply apparatus 103 is registered in the result list.

  FIG. 4 shows an example of the result list. The result list has a record (hereinafter referred to as a result record) for setting the ID of the power supply apparatus 103 that has a record of power supply. In this example, it is assumed that the power supply apparatus 103a and the power supply apparatus 103b are not registered. It is assumed that the illustrated power feeding device ID “PS012345” has been registered elsewhere.

  Returning to the description of FIG. In this example, it is determined that there is no matching power supply apparatus 103 (S209). If there is no matching power supply apparatus 103, one of the detected power supply apparatuses 103 is selected. In this example, the power supply apparatus 103a is selected according to the order of the detection list (S211).

  The power receiving apparatus 101 requests the selected power supply apparatus 103a to establish a communication path (S213). Specifically, a communication channel establishment request signal is sent to the power supply apparatus 103a (S215).

  Upon receiving the communication path establishment request signal, the power supply apparatus 103a responds to the power reception apparatus 101 (S217). Specifically, a response signal to the communication path establishment request is sent to the power receiving apparatus 101 (S219).

  When receiving a response signal to the request for establishing a communication path, the power receiving apparatus 101 executes a communication path establishment process (S221). The power supply apparatus 103a also executes a communication path establishment process (S223). Then, a communication path is established between the power receiving apparatus 101 and the power feeding apparatus 103a.

  The power receiving apparatus 101 requests power supply to the power supply apparatus 103a via this communication path (S225). Specifically, a power supply request signal is sent to the power supply apparatus 103a (S227).

  Upon receiving the power supply request signal, the power supply apparatus 103a responds to the power reception apparatus 101 (S229). Specifically, a response signal to the power supply request is sent to the power receiving apparatus 101 (S231).

  Then, the power supply apparatus 103a starts a power supply operation (S233). However, since the power receiving apparatus 101 is located outside the power supply range 105a of the power supply apparatus 103a, it does not receive power. As a result, the power receiving apparatus 101 determines that power reception has failed (S235).

  The sequence continues in FIG. 5 via terminal A and terminal B. The power receiving apparatus 101 next selects the power supply apparatus 103b from the detection list (S501).

  Then, the power receiving apparatus 101 requests the selected power supply apparatus 103b to establish a communication path (S503). Specifically, a communication channel establishment request signal is sent to the power supply apparatus 103b (S505).

  Upon receiving the communication path establishment request signal, the power supply apparatus 103b responds to the power reception apparatus 101 (S507). Specifically, a response signal to the communication path establishment request is sent to the power receiving apparatus 101 (S509).

  When receiving a response signal to the request for establishing a communication path, the power receiving apparatus 101 executes a communication path establishment process (S511). The power supply apparatus 103b also executes a communication path establishment process (S513). Then, a communication path is established between the power receiving apparatus 101 and the power feeding apparatus 103b.

  The power receiving apparatus 101 requests power supply to the power supply apparatus 103b through this communication path (S515). Specifically, a power supply request signal is sent to the power supply apparatus 103b (S517).

  Upon receiving the power supply request signal, the power supply apparatus 103b responds to the power reception apparatus 101 (S519). Specifically, a response signal to the power supply request is sent to the power receiving apparatus 101 (S521).

  Then, the power supply apparatus 103b starts a power supply operation (S523). Since the power receiving apparatus 101 is located within the power supply range 105b of the power supply apparatus 103b, the power receiving operation is started (S525). Since power reception has succeeded, the power receiving apparatus 101 registers the ID of the power supply apparatus 103b in the result list (S527).

  As a result, as shown in FIG. 6, the second record in which the power supply device ID “PS064824” is set is added to the result list.

  The sequence at the next charging opportunity will be described with reference to FIG. Assume that the power receiving apparatus 101 is in the position shown in FIG.

  The power supply apparatus 103a transmits a beacon for short-range wireless communication (including the ID of the power supply apparatus 103a) (S701). The power supply apparatus 103b also transmits a short-range wireless communication beacon (including the ID of the power supply apparatus 103b) (S703). The power receiving apparatus 101 detects these power supply apparatuses 103a and 103b by receiving these beacons (S705). The power receiving apparatus 101 registers the detected ID of the power supply apparatus 103a and the ID of the power supply apparatus 103b in the detection list (S707).

  The power receiving apparatus 101 collates with the result list and determines that there is a matching power supply apparatus 103 (S709). If there is a matching power supply apparatus 103, the power supply apparatus 103 is selected. In this example, since ID = 064824 matches, the power receiving apparatus 101 selects the power feeding apparatus 103b (S711).

  The power receiving apparatus 101 requests the selected power supply apparatus 103b to establish a communication path (S713). Specifically, a communication path establishment request signal is sent to the power supply apparatus 103b (S715).

  Upon receiving the communication path establishment request signal, the power supply apparatus 103b responds to the power reception apparatus 101 (S717). Specifically, a response signal to the communication path establishment request is sent to the power receiving apparatus 101 (S719).

  When receiving a response signal to the request for establishing a communication path, the power receiving apparatus 101 executes a communication path establishment process (S721). The power supply apparatus 103b also executes a communication path establishment process (S723). Then, a communication path is established between the power receiving apparatus 101 and the power feeding apparatus 103b.

  The power receiving apparatus 101 requests power supply to the power supply apparatus 103b via this communication path (S725). Specifically, a power supply request signal is sent to the power supply apparatus 103b (S727).

  Upon receiving the power supply request signal, the power supply apparatus 103b responds to the power reception apparatus 101 (S729). Specifically, a response signal to the power supply request is sent to the power receiving apparatus 101 (S731).

  Then, the power supply apparatus 103b starts a power supply operation (S733). Since the power receiving apparatus 101 is located within the power supply range 105b of the power supply apparatus 103b, the power receiving operation is started (S735).

  As described above, the power receiving apparatus 101 does not perform unnecessary communication with the power supply apparatus 103a.

  FIG. 8 illustrates a hardware configuration example of the power supply apparatus 103. The power supply apparatus 103 includes a CPU (Central Processing Unit) 801, a ROM (Read Only Memory) 803, a RAM (Random Access Memory) 805, a communication antenna 807, a communication circuit 809, a power transmission antenna 811, a power transmission circuit 813, and a power supply circuit 815. .

  The CPU 801 executes a program for controlling the power supply apparatus 103. The ROM 803 holds a program executed by the CPU 801. The RAM 805 is used as a load area when the CPU 801 executes a program. The communication antenna 807 transmits or receives radio waves for performing short-range wireless communication with the power receiving apparatus 101. The communication circuit 809 generates a radio wave signal transmitted from the communication antenna 807 and analyzes the radio wave signal received by the communication antenna 807. The power transmission antenna 811 performs magnetic field resonance with the power receiving antenna of the power receiving apparatus 101 in the magnetic field resonance type power supply. The power transmission circuit 813 sends the power obtained from the power supply circuit 815 to the power transmission antenna 811 so as to be supplied by magnetic field resonance. The power supply circuit 815 converts power from an external power supply (for example, AC power supply) into power to the power transmission circuit 813.

  FIG. 9 illustrates a hardware configuration example of the power receiving apparatus 101. The power receiving apparatus 101 includes a CPU 901, a ROM 903, a RAM 905, a nonvolatile memory 907, a communication antenna 909, a communication circuit 911, a power receiving antenna 913, a power receiving circuit 915, and a power supply circuit 917.

  The CPU 901 executes a program for controlling the power receiving apparatus 101. The ROM 903 holds a program executed by the CPU 901. The RAM 905 is used as a load area when the CPU 901 executes a program. The nonvolatile memory 907 stores a detection list and a performance list. The communication antenna 909 transmits or receives a radio wave for performing short-range wireless communication with the power supply apparatus 103. The communication circuit 911 generates a radio wave signal transmitted from the communication antenna 909 and analyzes the radio wave signal received by the communication antenna 909. The power receiving antenna 913 resonates with the magnetic field generated by the power supply apparatus 103 in the magnetic field resonance type power supply. The power receiving circuit 915 provides the power obtained from the power receiving antenna 913 to the power supply circuit 917. Further, the power receiving circuit 915 measures the received power. The power supply circuit 917 converts the power provided from the power receiving circuit 915 into a voltage suitable for the electronic device (or drive device) in the power receiving apparatus 101. The power supply circuit 917 further charges the power provided from the power receiving circuit 915.

  FIG. 10 illustrates a module configuration example of the power receiving apparatus 101. The power receiving apparatus 101 includes a detection unit 1001, a selection unit 1003, a request unit 1005, a power reception processing unit 1007, a registration unit 1009, a detection list storage unit 1021, and a performance list storage unit 1023.

  The detection unit 1001 detects the power supply apparatus 103 by short-range wireless communication. When a plurality of power supply apparatuses 103 are detected, the selection unit 1003 selects the power supply apparatuses 103 one by one. The request unit 1005 requests the selected power supply apparatus 103 to supply power wirelessly. The power reception processing unit 1007 controls the power reception circuit 915 to perform processing for receiving wireless power supply. The registration unit 1009 registers the power supply apparatus 103 that has become a power supply source in the result list. The detection list storage unit 1021 stores a detection list. The achievement list storage unit 1023 stores the achievement list.

  The detection unit 1001, the selection unit 1003, the request unit 1005, the power reception processing unit 1007, and the registration unit 1009 described above cause the processor (for example, the CPU 901) to execute hardware resources (for example, FIG. 9) and the processing described below. This is realized using a program.

  The detection list storage unit 1021 and the result list storage unit 1023 described above are realized using hardware resources (for example, FIG. 9).

  Subsequently, processing in the power receiving apparatus 101 will be described. For example, when the charge amount falls below a threshold value, the main process is activated. In the present embodiment, the main process (A) is started. FIG. 11 shows a main process (A) flow. The detection unit 1001 waits for search timing (S1101). In this example, the detection unit 1001 searches for the power supply apparatus 103 periodically.

  When the search timing is reached, the detection unit 1001 first initializes the detection list (S1103). There are no detection records in the detection list in the initial state.

  The detection unit 1001 determines whether an unreceived beacon is received during the search period (S1105). That is, the detection unit 1001 determines whether a new beacon that is not currently recognized has been received.

  If it is determined that an unreceived beacon has been received, the detection unit 1001 provides a new detection record (S1107), and sets the power supply apparatus ID included in the beacon in the detection record (S1109). The detection unit 1001 further sets the selection flag in the detection record to OFF (S1111). Then, the process proceeds to S1113.

  On the other hand, if it is determined in S1105 that an unreceived beacon has not been received, the process proceeds to S1113.

  The detection unit 1001 determines whether or not the search period has passed (S1113). The search period is, for example, a period of a predetermined time length from the search timing in S1101. If it is determined that the search period has not elapsed, the process returns to S1105 and the above-described process is repeated.

  On the other hand, when determining that the search period has elapsed, the selection unit 1003 determines whether one or more power supply apparatuses 103 have been detected in the search period (S1115). That is, the selection unit 1003 determines whether one or more detection records are set.

  If it is determined that no power supply apparatus 103 has been detected during the search period, the process returns to S1101 and the above-described process is repeated.

  If it is determined that one or more power supply apparatuses 103 have been detected during the search period, the process proceeds to the process of S1201 illustrated in FIG.

  Turning to the description of FIG. The selection unit 1003 executes a selection process (S1201). In the selection process, the ID of the power supply apparatus 103 is selected one by one from the detection list in a predetermined procedure. In the present embodiment, the selection process (A) is executed. The selection process (A) will be described later with reference to FIG.

  When the selection process is completed, the request unit 1005 determines whether or not the power supply apparatus ID has been selected in the selection process (S1203). Note that when all the power supply device IDs are selected, the selection unit 1003 does not select the power supply device ID even if the next selection process is performed.

  If it is determined that the power supply apparatus ID has been selected in the selection process, the request unit 1005 transmits a communication path establishment request signal to the power supply apparatus 103 specified by the ID (S1205). Then, the request unit 1005 determines whether a response signal to the communication path establishment request has been received (S1207). If it is determined that the response signal for the request for establishing the communication path has not been received, the request unit 1005 determines whether the response period has elapsed (S1209). If it is determined that the response period has not elapsed, the processing returns to the processing shown in S1207 and the above-described processing is repeated. If it is determined that the response period has elapsed, the process returns to S1201 and the above-described process is repeated. That is, the selection unit 1003 selects the next power supply device ID.

  On the other hand, when it is determined in S1207 that a response signal to the communication path establishment request has been received, the request unit 1005 executes a communication path establishment process (S1211).

  When the communication path is established, the request unit 1005 transmits a power supply request signal to the power supply apparatus 103 (S1213). The request unit 1005 determines whether or not a response signal to the power supply request has been received (S1215). If it is determined that the response signal for the power supply request has not been received, the request unit 1005 determines whether the response period has elapsed (S1217). If it is determined that the response period has not elapsed, the process returns to S1215 and the above-described process is repeated. If it is determined that the response period has elapsed, the process returns to S1201 and the above-described process is repeated. That is, the selection unit 1003 selects the next power supply device ID.

  On the other hand, if it is determined in S1215 that a response signal to the power supply request has been received, the process proceeds to S1301 illustrated in FIG.

  Turning to the description of FIG. The power reception processing unit 1007 determines whether power is received from the power supply apparatus 103 (S1301). If it is determined that the power is received from the power supply apparatus 103, the power reception processing unit 1007 continues the power reception operation until the charging is completed (S1305). In addition, when a continuous power supply is requested | required in S1213 of FIG. 12, it is not necessary to perform a process anew. If a temporary power supply is requested in S1213, a continuous power supply is requested again. The registration unit 1009 provides a new performance record in the performance list and sets the ID of the power supply apparatus 103 in the performance record (S1307). However, if the ID of the power supply apparatus 103 has already been registered, the process of S1307 is omitted. Then, the main process (A) is finished.

  On the other hand, if it is determined in S1301 that power is not received from the power supply apparatus 103, the power reception processing unit 1007 determines whether or not a standby period has elapsed (S1303). If it is determined that the standby period has not elapsed, the process returns to S1301, and the above-described process is repeated. If it is determined that the standby period has elapsed, the power reception has failed, and the process proceeds to S1201 shown in FIG. Then, the selection unit 1003 selects the next power supply device ID.

  Returning to the description of FIG. As described above, in the selection process executed in S1201, when all the power supply device IDs included in the detection list are selected and there is no unselected power supply device ID, the power supply device ID is not selected. If it becomes such, it will determine with having not selected electric power feeder ID in S1203, and will transfer to the process of S1101 shown in FIG. That is, the next search timing is waited without receiving power at the search timing.

  FIG. 14 shows a selection process (A) flow. The selection unit 1003 determines whether there is an unselected power supply apparatus ID in the detection list (S1401). Specifically, the selection unit 1003 determines whether there is a detection record whose selection flag is OFF. When there is a detection record in which the selection flag is OFF, the selection unit 1003 determines that there is an unselected power supply apparatus ID. When there is no detection record in which the selection flag is OFF, the selection unit 1003 determines that there is no unselected power supply apparatus ID.

  When it is determined that there is no unselected power supply apparatus ID, the selection unit 1003 does not select the power supply apparatus ID (S1403). Then, the selection process (A) is finished, and the process returns to the caller main process (A).

  On the other hand, if it is determined that there is an unselected power supply apparatus ID, the selection unit 1003 determines whether one or more power supply apparatus IDs are registered in the result list (S1405). If it is determined that one or more power supply apparatus IDs are registered in the achievement list, the selection unit 1003 identifies one power supply apparatus ID in the achievement list (S1407). The order in which the power supply device IDs are specified in the achievement list is arbitrary. Then, the selection unit 1003 determines whether or not the identified power supply apparatus ID matches any of the unselected power supply apparatus IDs in the detection list (S1409).

  If it is determined that the power supply device ID specified in S1407 matches any of the unselected power supply device IDs in the detection list, the selection unit 1003 selects the power supply device ID (S1411). Further, the selection unit 1003 sets a selection flag corresponding to the power supply apparatus ID to ON in the detection list (S1413). If the selection flag is turned ON, the power supply apparatus ID is not selected in the subsequent selection process. When the selection process (A) is completed, the process returns to the caller's main process (A).

  On the other hand, in S1409, when it is determined that the power supply device ID specified in S1407 does not match any of the unselected power supply device IDs in the detection list, the selection unit 1003 displays an unspecified power supply device ID in the result list. It is determined whether or not there is (S1415). If it is determined that there is an unspecified power supply apparatus ID in the result list, the process returns to S1407 and the above-described process is repeated.

  On the other hand, if it is determined that there is no unspecified power supply device ID in the result list, the process proceeds to S1417.

  In S1405, when it is determined that no power supply device ID is registered in the result list, the process proceeds to S1417.

  The selection unit 1003 identifies one unselected power supply device ID in the detection list (S1417). For example, the selection unit 1003 identifies the power supply apparatus ID according to the order of the detection list. However, the specific method is arbitrary. Then, the selection unit 1003 selects the power supply apparatus ID (S1419). The selection unit 1003 sets the selection flag corresponding to the power supply apparatus ID to ON in the detection list (S1421). When the selection process (A) is completed, the process returns to the caller's main process (A).

  According to the present embodiment, unnecessary power supply requests can be reduced.

  For example, there is an aspect that can suppress the traffic. In addition, there is an aspect that power can be started early. Furthermore, there is also an aspect in which communication with an unexpected power supply apparatus 103 (for example, a power supply apparatus 103 in a neighboring house) can be avoided.

[Embodiment 2]
In the present embodiment, an example will be described in which, when a plurality of power supply apparatuses 103 are detected by a beacon of short-range wireless communication, the power supply apparatus 103 having a higher beacon radio wave intensity is preferentially selected.

  FIG. 15 illustrates an arrangement example of the power receiving device 101 and the power feeding device 103 according to the second embodiment. It is assumed that the ID of the power supply apparatus 103c is PS085934.

  The power supply range 105c is a range in which power supply by the power supply apparatus 103c is successful. The communication range 107c is a range in which near field communication by the power supply apparatus 103c is successful. The communication range 107c is wider than the power supply range 105c.

  The power receiving apparatus 101 is located in the communication range 107a, the communication range 107b, and the communication range 107c. The power receiving apparatus 101 is included in the power supply range 105b and the power supply range 105c, but is not included in the power supply range 105a. In this example, it is assumed that the radio wave intensity when the power receiving apparatus 101 receives the beacon of the power feeding apparatus 103c is higher than the radio wave intensity when the power receiving apparatus 101 receives the beacon of the power feeding apparatus 103b.

  At the stage where neither ID of the power supply apparatus 103b and the power supply apparatus 103c is registered in the result list, the power supply apparatus 103c that is the transmission source of the beacon with high radio wave intensity is selected first.

  If one of the IDs of the power supply apparatus 103b and the power supply apparatus 103c is registered in the performance list, the power supply apparatus 103 corresponding to the ID registered in the performance list is selected first.

  If the IDs of both the power supply apparatus 103b and the power supply apparatus 103c are registered in the result list, the power supply apparatus 103c that is the transmission source of the beacon with high radio wave intensity is selected first.

  Since it is assumed that the power supply apparatus 103 with higher radio field intensity is closer, there is a high possibility of successful power reception. Therefore, the frequency of requesting unnecessary power supply is reduced.

  FIG. 16 shows an example of a detection list according to the second embodiment. The detection record in the present embodiment has a field for setting the radio wave intensity. In this example, the first detection record corresponds to the power supply apparatus 103a, the second detection record corresponds to the power supply apparatus 103b, and the third detection record also corresponds to the power supply apparatus 103c.

The first detection record indicates that the radio wave intensity in the beacon received from the power supply apparatus 103a is “S ₁ ”. The second detection record indicates that the radio wave intensity in the beacon received from the power supply apparatus 103b is “S ₂ ”. The third detection record indicates that the radio wave intensity in the beacon received from the power supply apparatus 103c is “S ₃ ”.

  In FIG. 17, the example of the performance list which concerns on Embodiment 2 is shown. The configuration of the result list is the same as that in the first embodiment. The first performance record in this example corresponds to the power supply apparatus 103b, and the second performance record corresponds to the power supply apparatus 103c. That is, this example assumes that the power supply apparatus 103b and the power supply apparatus 103c are already registered. Note that the third record is assumed to be registered at another location.

  In the present embodiment, the main process (B) is executed instead of the main process (A). FIG. 18 shows a main process (B) flow. The processing shown in S1101 to S1111 is the same as in the case of FIG. The detection unit 1001 sets the radio wave intensity when the beacon is received in the new detection record provided in S1107 (S1801). The processes shown in S1113 and S1115 are the same as those in FIG. The processing after the terminal C is the same as that in the main processing (A).

  In this embodiment, a selection process (B) is executed instead of the selection process (A) shown in FIG. FIG. 19 shows a selection process (B) flow. The processes shown in S1901 to S1905 are the same as those in S1401 to S1405 shown in FIG.

  In S1905, when it is determined that one or more power supply device IDs are registered in the performance list, the selection unit 1003 identifies one unselected power supply device ID in the detection list in descending order of radio wave intensity. (S1907).

  The selection unit 1003 determines whether the power supply device ID specified in S1907 matches any of the power supply device IDs in the performance list (S1909). If it is determined that the power supply device ID identified in S1907 matches any of the power supply device IDs in the performance list, the selection unit 1003 selects the power supply device ID (S1911). Further, the selection unit 1003 sets a selection flag corresponding to the power supply device ID in the detection list to ON (S1913). When the selection process (B) is completed, the process returns to the caller's main process (B).

  On the other hand, if it is determined in S1909 that the power supply device ID specified in S1907 does not match any of the power supply device IDs in the performance list, the selection unit 1003 selects S1907 among the unselected power supply device IDs in the detection list. In step S1915, it is determined whether there is an unspecified one.

  If it is determined that there is an unspecified power supply device ID in the detection list, the process returns to S1907 and the above-described process is repeated. That is, the selection unit 1003 selects the power transmission device ID having the next highest radio field intensity.

  On the other hand, if it is determined that there is no unspecified power supply device ID in the detection list, the process proceeds to S1917.

  In S1905, when it is determined that no power supply device ID is registered in the result list, the process proceeds to S1917.

  The selection unit 1003 identifies one of the unselected power supply device IDs in the detection list that has the highest radio field intensity (S1917).

  The processes shown in S1919 and S1921 are the same as those in S1419 and S1421 shown in FIG. When the selection process (B) is completed, the process returns to the caller's main process (B).

  According to the present embodiment, since a power feeding device with higher radio field strength of short-range wireless communication is selected with priority, it can be expected to receive power effectively.

[Embodiment 3]
In this embodiment, an example of a mode for collecting data of the power supply apparatus 103 registered in the result list (hereinafter referred to as a collection mode) will be described. Further, in the present embodiment, the power feeding apparatus 103 having a larger received power is selected.

  Hereinafter, the main process (A) described in the first embodiment and the main process (B) described in the second embodiment are referred to as a normal mode. In the normal mode, if power supply from the selected power supply apparatus 103 is successful, power reception from other power supply apparatuses 103 is not performed. As a result, the other power supply apparatuses 103 are not registered in the result list.

  In the collection mode described in this embodiment, temporary power supply in each detected power supply apparatus 103 is tried, and data of the power supply apparatus 103 registered in the result list is collected. That is, when power reception is successful for a plurality of power supply apparatuses 103 in the collection mode, all of the power supply apparatuses 103 that have successfully received power are registered in the performance list.

  As described above, if a large number of power supply apparatuses 103 are registered in the result list in the collection mode, another power supply having a proven record can be obtained in the next normal mode even if the power supply in some of the power supply apparatuses 103 with a proven record occurs. The device 103 is selected with priority. For example, even when the load is concentrated on the same power supply apparatus 103, it is not necessary to make an unnecessary power supply request.

  In the following description, the arrangement shown in FIG. 15 is assumed, and the received power from the power supply apparatus 103c is larger than the received power from the power supply apparatus 103b. Therefore, in this example, the power supply apparatus 103c is preferentially selected. If power is received from the power supply apparatus 103 having a large received power, charging is completed quickly.

  FIG. 20 shows an example of a detection list at the stage where the power supply apparatus 103 is detected. The detection record in the present embodiment has a field for setting the power feeding device ID, a field for the power reception flag, and a field for setting the power reception power.

  In this example, the first detection record corresponds to the power supply apparatus 103a, the second detection record corresponds to the power supply apparatus 103b, and the third detection record also corresponds to the power supply apparatus 103c. At this stage, since the temporary power supply by the power supply apparatus 103 has not been attempted yet, the power reception flag is OFF. In addition, the received power is not set.

FIG. 21 shows an example of a detection list after trying to temporarily supply power. This example shows a state in which power reception is successful by temporary power supply by the power supply apparatus 103b and the power supply apparatus 103c. Accordingly, the power reception flag of the second detection record corresponding to the power supply apparatus 103b is switched to ON, and the value of the power reception power is set. Similarly, the power reception flag of the third detection record corresponding to the power supply apparatus 103c is also switched ON, and the value of the power reception power is set. It is assumed that the received power “E ₃ ” from the power supply apparatus 103 c is larger than the received power “E ₂ ” from the power supply apparatus 103 b.

  On the other hand, since it is assumed that the power reception by the temporary power supply by the power supply apparatus 103a has failed, the power reception flag of the first detection record corresponding to the power supply apparatus 103a remains OFF, and the value of the received power is also set. Absent.

  FIG. 22 shows a main process (C) flow which is the collection mode. The processing shown in S1101 to S1109 is the same as in the case of FIG. The detection unit 1001 sets the power reception flag in the new detection record provided in S1107 to OFF (S2201). The received power is not set. The processes shown in S1113 and S1115 are the same as those in FIG. When the process of S1115 is finished, the process proceeds to the process of S1201 shown in FIG.

  Turning to the description of FIG. The processing shown in S1201 to S1217 is the same as that in FIG. If it is determined in S1215 that a response signal to the power supply request has been received, the process proceeds to S1301 illustrated in FIG.

  Turning to the description of FIG. The processing shown in S1301 and S1303 is the same as in the case of FIG. If it is determined in S1303 that the standby period has elapsed, power reception has failed, so the process returns to S1201 in FIG.

  If it is determined in S1301 that power has been received from the power supply apparatus 103, the power reception processing unit 1007 interrupts the power reception operation (S2401). In this example, it is assumed that continuous power supply is requested in S1213 of FIG. However, when a temporary power supply is requested in S1213, the process may not be performed again. The registration unit 1009 turns on the power reception flag in the detection record of the power feeding device ID selected in the selection process of S1201 (S2403). The registration unit 1009 sets the received power measured by the power receiving circuit 915 in the detection record (S2405). The registration unit 1009 provides a new record in the record list, and sets the power supply apparatus ID selected in the selection process in S1201 in the record record (S2407). However, if the power supply apparatus ID is already registered, the process of S2407 is omitted. And it returns to the process shown to S1201 of FIG. 23 via the terminal I, and repeats the process mentioned above.

  Returning to the description of FIG. If it is determined in S1203 of FIG. 23 that the power supply apparatus ID has not been selected, the process proceeds to S2501 of FIG. In this example, the selection process (A) described in the first embodiment is performed. However, the selection process (B) may be performed as in the second embodiment.

  Turning to the description of FIG. The selection unit 1003 determines whether there is a detection record whose power reception flag is ON (S2501). That is, the selection unit 1003 determines whether power is received from any of the power supply apparatuses 103.

  If it is determined that there is a detection record in which the power reception flag is ON, the selection unit 1003 selects the power supply device ID in the detection record in which the largest power reception power is set among the detection records in which the power reception flag is ON. (S2503).

  The power reception processing unit 1007 resumes the power reception operation from the power supply apparatus 103 indicated by the selected ID (S2505). The power reception processing unit 1007 continues the power reception operation until the charging is completed (S2507).

  On the other hand, if it is determined in S2501 that there is no detection record whose power reception flag is ON, the process returns to the process shown in S1101 of FIG.

  According to the present embodiment, it is possible to increase the number of power supply apparatuses 103 registered in the result list.

  In addition, since wireless power supply is requested to the power supply apparatus 103 having higher received power, power can be received effectively.

  Although the embodiment of the present invention has been described above, the present invention is not limited to this. For example, the functional block configuration described above may not match the program module configuration.

  Further, the configuration of each storage area described above is an example, and the above configuration is not necessarily required. Further, in the processing flow, if the processing result does not change, the processing order may be changed or a plurality of processes may be executed in parallel.

  The embodiment described above is summarized as follows.

  The power receiving device according to one aspect receives (A) a detection unit that detects a power feeding device by short-range wireless communication, and (B) receives a power supply among the plurality of power feeding devices when detecting the plurality of power feeding devices. A selection unit that preferentially selects a power supply device included in a performance list in which a power supply device with a record is registered, and (C) a request unit that requests wireless power supply to the selected power supply device by short-range wireless communication. , (D) a registration unit that registers the power supply device in the result list when the power supply is received from the unregistered power supply device.

  In this way, unnecessary power supply requests can be reduced. That is, on the premise of the same positional relationship, it is possible to stably receive power from a proven power supply device.

  Further, in the predetermined mode, the request unit may request wireless power supply to each of the plurality of power supply apparatuses and try to temporarily supply power. In the predetermined mode, the registration unit may register a power supply apparatus that has received temporary power supply among the plurality of power supply apparatuses in a performance list.

  In this way, it is possible to increase the number of power supply devices registered in the result list.

  Furthermore, in the predetermined mode, when the temporary power supply is received from two or more power supply devices among the plurality of power supply devices, the selection unit receives larger power from the two or more power supply devices. The selected power supply device may be selected. In the predetermined mode, the request unit may request wireless power feeding again to the power feeding apparatus having higher received power.

  In this way, power can be received effectively.

  Further, when two or more power supply devices among the plurality of power supply devices are included in the result list, the selection unit gives priority to a power supply device having higher radio field strength of short-range wireless communication among the two or more power supply devices. May be selected.

  In this way, it can be expected to receive power effectively.

  A program for causing the processor to perform the processing of the power receiving apparatus can be created. The program is a computer-readable storage medium such as a flexible disk, a CD-ROM, a magneto-optical disk, a semiconductor memory, or a hard disk. Alternatively, it may be stored in a storage device. Note that intermediate processing results are generally temporarily stored in a storage device such as a main memory.

Claims (5)

A detection unit for detecting a power feeding device by short-range wireless communication;
When a plurality of power supply devices are detected, among the plurality of power supply devices, a power supply device included in the result list in which a power supply device having a record of receiving power supply is registered is not included in the result list. and a selection unit that selects in preference to,
A request unit that requests wireless power feeding to the selected power feeding device by the short-range wireless communication, and
A power receiving device comprising: a registration unit that registers the power feeding device in the result list when receiving power supply from an unregistered power feeding device. In the predetermined mode, the request unit requests wireless power feeding to each of the plurality of power feeding devices, and tries to temporarily supply power,
The power receiving device according to claim 1, wherein in the predetermined mode, the registration unit registers, among the plurality of power feeding devices, the power feeding device that has received the temporary power supply in the result list. In the predetermined mode, when the temporary power supply is received from two or more power supply devices among the plurality of power supply devices, the selection unit has higher received power among the two or more power supply devices. Select the power supply device,
The power receiving device according to claim 2, wherein in the predetermined mode, the request unit requests wireless power feeding again to the power feeding device having the larger received power. When two or more power supply devices among the plurality of power supply devices are included in the performance list, the selection unit selects a power supply device having a higher radio field intensity of the short-range wireless communication among the two or more power supply devices. The power receiving device according to any one of claims 1 to 3, wherein the power receiving device is selected with priority. Detect power feeding device by short-range wireless communication,
When a plurality of power supply devices are detected, among the plurality of power supply devices, a power supply device included in the result list in which a power supply device having a record of receiving power supply is registered is not included in the result list. It is selected in preference to,
Requesting wireless power feeding to the selected power feeding device by the short-range wireless communication,
A power reception control program for causing a computer to execute a process of registering a power supply device in the result list when receiving power supply from an unregistered power supply device.

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