JP2014003835A - Electronic apparatus, power control system, and power control unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To share power among a plurality of electronic apparatuses each provided with a secondary battery so as to appropriately control their remaining drive times.SOLUTION: An electronic apparatus 2 provided with a secondary battery 20 calculates remaining drive time T1 by obtaining information on remaining battery capacity of the secondary battery 20 and a history of power consumption of the electronic apparatus 2. The electronic apparatus 2 calculates remaining drive time T2 by obtaining from an electronic apparatus 3 provided with a secondary battery 30 information on remaining battery capacity of the secondary battery 30 and a history of power consumption of the electronic apparatus 3. The electronic apparatus 2 carries out power transmitting/receiving between the electronic apparatus 2 and the electronic apparatus 3 on the basis of the remaining drive time T1 and the remaining drive time T2.

Description

  The present invention relates to an electronic device including a secondary battery, a power control system including a plurality of electronic devices each including a secondary battery, and a power control apparatus that controls a plurality of electronic devices each including a secondary battery.

There is known an electronic device system in which a plurality of electronic devices including secondary batteries charge each other's secondary batteries (for example, Patent Document 1).
In recent years, wireless remote control devices, headsets, and the like that are used in combination with electronic devices such as digital cameras, audio devices, and the like that use a secondary battery to enhance portability are becoming widespread. Electronic devices such as wireless remote control devices and headsets also include a secondary battery.

International Publication No. 2007/074771

  When a first electronic device including a secondary battery is used in combination with a second electronic device including another secondary battery, the secondary battery of either the first electronic device or the second electronic device is used. Cannot be used even if the battery is low. In view of such a problem, the present invention provides a plurality of electronic devices used in combination so that their remaining driving time (remaining operation time, usable time) is appropriately adjusted. The purpose is to allow electric power to be interchanged between electronic devices.

  An electronic device according to the present invention is an electronic device including a first secondary battery, and acquires first information for acquiring information on a remaining battery level of the first secondary battery and information on power consumption of the electronic device. Means, a second information acquisition means for acquiring information on the remaining battery level of the second secondary battery and information on power consumption of the external device from an external device comprising the second secondary battery, and a first secondary A first time calculating means for calculating a first remaining driving time during which the electronic device can be driven based on information on a remaining battery level of the battery and power consumed by the electronic device; and a remaining battery level of the second secondary battery. And second time calculation means for calculating a second remaining drive time during which the external device can be driven based on information on the power consumed by the external device, and a first remaining drive time calculated by the first time calculation means Calculated by the second time calculating means 2 based on the remaining drive time, characterized in that it comprises a power interchange means for transmitting and receiving electric power to and from an external device.

  ADVANTAGE OF THE INVENTION According to this invention, electric power can be interchanged so that those remaining drive time may be appropriately adjusted between several electronic devices each provided with a secondary battery.

1 is a block diagram relating to a power control system according to an embodiment of the present invention. FIG. It is a figure which shows the example of the interchange method of the electric power between the some electronic devices in the electric power control system by one embodiment of this invention. It is a figure which shows the example of the communication method between several electronic devices in the electric power control system by one embodiment of this invention. It is a block diagram regarding the 1st electronic device by the 1st Embodiment of this invention. It is a block diagram regarding the 2nd electronic device by the 1st Embodiment of this invention. It is one of the flowcharts regarding the power interchange process performed in the power control system by the 1st Embodiment of this invention. In the power control system by the 1st Embodiment of this invention, it is a figure which illustrates the display screen displayed during a power interchange process. It is one of the flowcharts regarding the power interchange process performed in the power control system by the 1st Embodiment of this invention. It is one of the flowcharts regarding the power interchange process performed in the power control system by the 1st Embodiment of this invention. It is one of the flowcharts regarding the power interchange process performed in the power control system by the 1st Embodiment of this invention. It is a block diagram regarding the electric power control apparatus by one embodiment of this invention. It is one of the flowcharts regarding the power interchange process performed in the power control system by the 2nd Embodiment of this invention. It is one of the flowcharts regarding the power interchange process performed in the power control system by the 2nd Embodiment of this invention. It is one of the flowcharts regarding the power interchange process performed in the power control system by the 2nd Embodiment of this invention. It is one of the flowcharts regarding the power interchange process performed in the power control system by the 2nd Embodiment of this invention. It is one of the flowcharts regarding the power interchange process performed in the power control system by the 2nd Embodiment of this invention. It is one of the flowcharts regarding the power interchange process performed in the power control system by the 2nd Embodiment of this invention. It is one of the flowcharts regarding the power interchange process performed in the power control system by the 2nd Embodiment of this invention. It is one of the flowcharts regarding the power interchange process performed in the power control system by the 2nd Embodiment of this invention. It is an example of the block block diagram of the server with which the power control system by one embodiment of this invention is equipped.

  FIG. 1 is a block diagram of a power control system according to an embodiment of the present invention. The power control system 1 includes an electronic device 2 including a secondary battery 20 and an electronic device 3 including a secondary battery 30. The electronic devices 2 and 3 are, for example, a digital camera and its remote monitor, a digital camera and its remote controller, an information terminal and a wireless connection type headset, and the electronic device 3 is used in combination with the electronic device 2. In the following description, the electronic device 2 is described as a camera 2 and the electronic device 3 is described as a remote monitor 3.

  Secondary batteries 20 and 30 are, for example, lithium ion batteries, nickel metal hydride storage batteries, and the like. Even if the remaining battery level of the secondary battery 30 of the remote monitor 3 remains, if the remaining battery level of the secondary battery 20 of the camera 2 does not remain, the user cannot use the remote monitor 3 effectively. The reverse is also true, and if the remaining battery level of the secondary battery 20 of the camera 2 remains, but the remaining battery level of the secondary battery 30 of the remote monitor 3 does not remain, the user activates the camera 2. It cannot be used.

  The camera 2 and the remote monitor 3 can exchange power with each other, and can solve the problem that only the remaining battery level of the secondary battery on one side is lost. For example, power is interchanged so that the remaining drive time in which the camera 2 is driven using the remaining battery capacity of the secondary battery 20 and the remaining drive time of the secondary battery 30 in the remote monitor 3 are the same. The problem that only the remaining battery level of the next battery runs out is solved.

  As a method of power interchange between the camera 2 and the remote monitor 3, there are methods exemplified in FIGS. In FIG. 2A, power is directly exchanged between the camera 2 and the remote monitor 3. For example, electric power is directly exchanged between the camera 2 and the remote monitor 3 using non-contact charging (non-contact charging) such as an electromagnetic induction method, an electromagnetic resonance method, and a radio wave method. Further, for example, the camera 2 and the remote monitor 3 are connected by a connection cable such as a USB cable, and power is directly exchanged between the camera 2 and the remote monitor 3 via the connection cable. Good.

  In FIG. 2B, power is interchanged between the camera 2 and the remote monitor 3 by interposing a power control device 4. The electronic device on the power transmission side of the camera 2 and the remote monitor 3 transmits power to the power control device 4. The electronic device on the power receiving side receives the electric power transmitted from the electronic device on the power transmission side from the power control device 4.

  Moreover, the camera 2 and the remote monitor 3 mutually transmit / receive information using various communications. As a communication method performed between the camera 2 and the remote monitor 3, there are methods exemplified in FIGS. The camera 2 can display images such as a through image and a menu screen on the remote monitor 3 using these communications.

  In FIG. 3A, the camera 2 and the remote monitor 3 are connected by wired communication using a connection cable such as a cross cable or a USB cable, or near field communication such as Wi-Fi (registered trademark) or Bluetooth (registered trademark). Direct communication.

  In FIG. 3B, the camera 2 and the remote monitor 3 transmit / receive information via the power control device 4. Each of the camera 2 and the remote monitor 3 and the power control device 4 transmit / receive information by wired communication or short-range wireless communication.

  In FIG.3 (c), the camera 2 and the remote monitor 3 transmit / receive information via the server 5. FIG. Each of the camera 2 and the remote monitor 3 communicates with the server 5 via the electric communication line 6.

  The communication method and the power accommodation method implemented by the power control system 1 include the power accommodation method illustrated in FIG. 2 (a) or (b), and FIG. 3 (a), (b), or (c). Can be arbitrarily combined with the communication method exemplified in the above. Note that the power accommodation method shown in FIGS. 2A and 2B and the communication method shown in FIGS. 3A to 3C are merely examples, and other power accommodation methods and communication methods are used. It may be used.

(First embodiment)
As a first embodiment of the present invention, a power control system that implements a combination of the power accommodation method illustrated in FIG. 2A and the communication method illustrated in FIG. 3A will be described. In the first embodiment, the power interchange method between the camera 2 and the remote monitor 3 is electromagnetic induction type non-contact charging. The communication method between the camera 2 and the remote monitor 3 is short-range wireless communication.

  FIG. 4 is a block configuration diagram of the camera 2. The camera 2 includes a secondary battery 20, an electromagnetic induction coil 21, a power controller 22, a CPU 23, a communication unit 24, a memory 25, a notification unit 26, and an operation unit 27. The electromagnetic induction coil 21 is used for electromagnetic induction type non-contact charging, and is used for power interchange illustrated in FIG. The power controller 22 controls charging of the secondary battery 20. In addition, the power controller 22 outputs information related to the remaining battery level of the secondary battery 20 to the CPU 23. The CPU 23 can execute various processes by controlling each part of the camera 2. The communication unit 24 is used for short-range wireless communication, and is used for communication illustrated in FIG. The notification unit 26 is a display monitor, an indicator lamp, or the like. The operation unit 27 is used for operating the camera 2.

  The memory 25 is a non-volatile storage medium. The memory 25 stores a registration ID database 251 and a power consumption history 252. The registration ID database 251 stores (registers) device IDs of devices that exchange power with the camera 2. The device that exchanges power with the camera 2 is, for example, the remote monitor 3.

  The power consumption history 252 is history information related to the power consumption of the camera 2 and stores the power consumption for a predetermined time (for example, one hour) of the camera 2. The CPU 23 can calculate the average power consumption per unit time of the camera 2 using the history information stored in the power consumption history 252. The power consumption of the camera 2 varies depending on whether or not the speedlight is used. By using history information, it is possible to cope with changes in power consumption according to the date and time (day and night) and seasons. The CPU 23 calculates the remaining drive time of the camera 2 based on a value obtained by dividing the remaining battery level of the secondary battery 20 by the average power consumption.

  FIG. 5 is a block diagram of the remote monitor 3. The remote monitor 3 includes a secondary battery 30, an electromagnetic induction coil 31, a power supply controller 32, a CPU 33, a communication unit 34, and a memory 35.

  Similarly to the electromagnetic induction coil 21, the electromagnetic induction coil 31 is used for electromagnetic contact type non-contact charging, and is used for interchange of electric power illustrated in FIG. The power controller 32 controls charging of the secondary battery 30. Further, the power controller 32 outputs information related to the remaining battery level of the secondary battery 30 to the CPU 33. The CPU 33 controls each part of the remote monitor 3 and executes various processes. The communication unit 34 is used for short-range wireless communication, and is used for communication illustrated in FIG. The notification unit 36 is a display monitor, an indicator lamp, or the like.

  The memory 35 is a non-volatile storage medium. In the memory 35, a device ID 351 and a power consumption history 352 are stored. The device ID 351 is information representing the remote monitor 3. The power consumption history 352 is history information related to the power consumption of the remote monitor 3, and stores the power consumption for a predetermined time (for example, one hour) of the remote monitor 3.

  FIG. 6 is a flowchart regarding handshake processing for power interchange between the camera 2 and the remote monitor 3. The processing of FIG. 6 is performed when the remaining battery level of the secondary battery 20 of the camera 2 becomes a predetermined amount or less, or when the camera 2 is in a mode for power interchange. 3 CPU 33.

In step S <b> 200, the CPU 33 of the remote monitor 3 determines whether a preparation signal has been received via the communication unit 34. The preparation signal is a signal for a plurality of electronic devices to start handshaking. The CPU 33 repeats the determination in step S200 while the negative determination is made in step S200.
In step S100, the CPU 23 of the camera 2 can receive signals within a predetermined distance from the camera 2 (a distance that can be charged by non-contact charging, for example, 50 cm) via the communication unit 24. Is sent around the camera 2. When the remote monitor 3 is located within a predetermined distance from the camera 2, the CPU 33 of the remote monitor 3 receives this preparation signal via the communication unit 34, makes an affirmative decision in step S200, and proceeds to step S201. Proceed with the process.

In step S <b> 101, the CPU 23 of the camera 2 determines whether a response signal to the preparation signal has been received via the communication unit 24. If the determination in step S101 is negative, the CPU 23 advances the process to step S100.
In step S <b> 201, the CPU 33 of the remote monitor 3 transmits a response signal to the camera 2 via the communication unit 34. The CPU 23 of the camera 2 receives this response signal via the communication unit 24, makes an affirmative decision in step S101, and advances the process to step S102.

  In step S <b> 102, the CPU 23 of the camera 2 starts short-range wireless communication with the remote monitor 3. On the other hand, in step S <b> 202, the CPU 33 of the remote monitor 3 starts near field communication with the camera 2. Thereby, communication between the camera 2 and the remote monitor 3 is established.

  In step S <b> 203, the CPU 33 of the remote monitor 3 transmits the device ID stored in the memory 35 to the camera 2 via the communication unit 34. In step S <b> 103, the CPU 23 of the camera 2 receives the device ID via the communication unit 24.

  In step S104, the CPU 23 of the camera 2 determines whether or not to approve the device ID received in step S103. This determination has the purpose of protecting the remaining battery level of the secondary battery 20 of the camera 2 from theft. For example, the CPU 23 of the camera 2 displays a screen as shown in FIG. 7A on the display monitor of the notification unit 26. If the user approves the device ID using the operation unit 27, an affirmative determination is made in step S104. Also, if the device ID received in step S103 is stored in the registration ID database 251, an affirmative determination is made in step S104. If the determination in step S104 is affirmative, the process in FIG. 6 proceeds to step S105. On the other hand, if a negative determination is made in step S104, the process proceeds to step S130 in FIG.

  In step S <b> 105, the CPU 23 of the camera 2 determines whether or not the device ID received in step S <b> 103 is stored in the registration ID database 251. If a negative determination is made in step S105, the process proceeds to step S106. If a positive determination is made in step S105, the process proceeds to step S110 in FIG.

In step S106, the CPU 23 of the camera 2 stores (registers) the device ID received in step S103 in the registration ID database 251 of the memory 25, and proceeds to the process of step S110 in FIG.
In step S204, the CPU 33 of the remote monitor 3 stores in the memory 35 that it communicates with the electronic device (here, camera 2) that has transmitted the preparation signal, and proceeds to the process of step S210 in FIG.

  In step S <b> 110 of FIG. 8, the CPU 23 of the camera 2 acquires the remaining battery level and the power consumption history 252 of the secondary battery 20 of the camera 2. On the other hand, in step S <b> 210, the CPU 33 of the remote monitor 3 acquires the remaining battery level and the power consumption history 352 of the secondary battery 30 of the remote monitor 3.

In step S <b> 211, the CPU 33 of the remote monitor 3 transmits the remaining battery level and power consumption history 352 of the secondary battery 30 of the remote monitor 3 acquired in step S <b> 210 to the camera 2.
In step S111, the CPU 23 of the camera 2 receives the remaining battery level and the power consumption history 352 of the secondary battery 30 of the remote monitor 3 transmitted by the remote monitor 3 in step S211.

  In step S112, the CPU 23 of the camera 2 calculates the remaining drive time T1 of the camera 2 based on the remaining battery level of the secondary battery 20 of the camera 2 and the power consumption history 252 acquired in step S110. For example, the CPU 23 of the camera 2 calculates the power consumed by the camera 2 per unit time (for example, 1 hour) from the history stored in the power consumption history 252. This may be calculated based on the power consumed in the last hour, or the average value of power consumption may be calculated using all the history stored in the power consumption history 252. Next, by dividing the remaining battery level of the secondary battery 20 of the camera 2 acquired in step S110 by the power consumed by the camera 2 calculated above per unit time (for example, one hour), the camera 2 The remaining drive time T1 is calculated.

  In step S113, the CPU 23 of the camera 2 calculates the remaining drive time T2 of the remote monitor 3 based on the remaining battery level of the secondary battery 30 of the remote monitor 3 and the power consumption history 352 acquired in step S111. The method for calculating the remaining drive time T2 is the same as the method for calculating the remaining drive time T1.

  In step S114, the CPU 23 of the camera 2 supplies power from either the camera 2 or the remote monitor 3 based on the magnitude relationship between the remaining drive time T1 calculated in step S112 and the remaining drive time T2 calculated in step S113. Decide if you want to be flexible. That is, which of the camera 2 and the remote monitor 3 determines which secondary battery is charged. For example, when the remaining drive time T1 is longer than the remaining drive time T2 (T1> T2), the CPU 23 of the camera 2 determines that the camera 2 charges the secondary battery 30 of the remote monitor 3. On the other hand, when the remaining drive time T1 is smaller than the remaining drive time T2 (T2 <T1), the CPU 23 of the camera 2 determines that the remote monitor 3 charges the secondary battery 20 of the camera 2. Information on the charging / charged relationship between the camera 2 and the remote monitor 3 determined in step S114 is referred to as accommodation direction information. If the remaining drive time T1 and the remaining drive time T2 are substantially equal, neither secondary battery is charged. Note that the remaining drive time T1 and the remaining drive time T2 are substantially equal means that the absolute value | T1-T2 | of the difference between the remaining drive time T1 and the remaining drive time T2 is equal to or less than a predetermined position.

  In step S115, the CPU 23 of the camera 2 determines whether or not the remote monitor 3 is in a position where it can be charged by non-contact charging. For example, the CPU 23 of the camera 2 transmits a signal having a signal intensity that can be received within a predetermined distance (for example, 50 cm) from the camera 2 to the periphery of the camera 2. The CPU 23 of the camera 2 makes a negative determination in step S115 when the predetermined response signal cannot be received, repeats the determination in step S115, and makes an affirmative determination in step S115 when there is a predetermined response signal from the remote monitor 3. The process proceeds to step S120 in FIG.

  In step S120 of FIG. 9, the CPU 23 of the camera 2 transmits the accommodation direction information determined in step S114 to the remote monitor 3. In step S220, the CPU 33 of the remote monitor 3 receives the accommodation direction information transmitted in step S120.

  In step S121, the CPU 23 of the camera 2 starts power accommodation based on the accommodation direction information. In step S221, the CPU 33 of the remote monitor 3 starts power accommodation based on the accommodation direction information.

  In step S122, the CPU 23 of the camera 2 controls the notification unit 26 based on the accommodation direction information. On the other hand, in step S222, the CPU 33 of the remote monitor 3 controls the notification unit 36 based on the accommodation direction information. For example, the indicator lamp of the notification unit 26 is turned on, or information on the accommodation direction is displayed on the display monitor of the notification unit 26. For example, as shown in FIG. 7B, a message that clearly indicates the accommodation direction is displayed on the display monitor of the notification unit 26. As shown in FIG. 7B, not only the power interchange direction but also the remaining drive times T1 and T2 may be displayed.

In step S <b> 123, the CPU 23 of the camera 2 acquires the remaining battery level and the power consumption history 252 of the secondary battery 20 of the camera 2. On the other hand, in step S <b> 223, the CPU 33 of the remote monitor 3 acquires the remaining battery level and the power consumption history 352 of the secondary battery 30 of the remote monitor 3.
In step S224, the CPU 33 of the remote monitor 3 transmits the remaining battery level and power consumption history 352 of the secondary battery 30 of the remote monitor 3 acquired in step S223 to the camera 2. In step S124, the CPU 23 of the camera 2 receives the remaining battery level and power consumption history 352 of the secondary battery 30 of the remote monitor 3 transmitted by the remote monitor 3 in step S224.
In step S125, the CPU 23 of the camera 2 calculates the remaining drive time T1 of the camera 2 based on the remaining battery level of the secondary battery 20 of the camera 2 and the power consumption history 252 acquired in step S123.
In step S126, the CPU 23 of the camera 2 calculates the remaining drive time T2 of the remote monitor 3 based on the remaining battery level of the secondary battery 30 of the remote monitor 3 and the power consumption history 352 acquired in step S124.

  In step S127, the CPU 23 of the camera 2 determines whether or not the remaining drive time T1 of the camera 2 calculated in step S125 matches the remaining drive time T2 of the remote monitor 3 calculated in step S126. If a negative determination is made in step S127, the process proceeds to step S123, and if a positive determination is made in step S127, the process proceeds to step S128.

In step S225, the CPU 33 of the remote monitor 3 determines whether or not an end signal for ending the power interchange process is transmitted from the camera 2. If the determination at step S225 is negative, the CPU 33 of the remote monitor 3 advances the process of FIG. 9 to step S223.
In step S128, the CPU 23 of the camera 2 transmits an end signal to the remote monitor 3. As a result, the CPU 33 of the remote monitor 3 makes an affirmative decision in step S225 and advances the process to step S230 in FIG. After step S128, the CPU 23 of the camera 2 also advances the process to step S130 in FIG.

  In step S <b> 130 of FIG. 10, the CPU 23 of the camera 2 controls the notification unit 26 to notify the end of power accommodation. For example, the CPU 23 of the camera 2 turns off the indicator lamp of the notification unit 26 and displays on the display monitor of the notification unit 26 that power interchange has been completed.

  In step S230, the CPU 33 of the remote monitor 3 notifies the end of power accommodation based on the end signal received from the camera 2. For example, the CPU 33 of the remote monitor 3 turns off the indicator lamp of the notification unit 36 and displays a message indicating that the power interchange has been completed on the display monitor of the notification unit 36.

  In step S131, the CPU 23 of the camera 2 disconnects communication with the remote monitor 3. In step S231, the CPU 33 of the remote monitor 3 disconnects communication with the camera 2. Then, the CPU 23 of the camera 2 and the CPU 33 of the remote monitor 3 end the processing relating to power interchange.

(Second Embodiment)
As the second embodiment of the present invention, the camera 2 and the remote monitor 3 combine the power interchange method illustrated in FIG. 2B and the communication method illustrated in FIG. 3B. A power control system that performs this will be described.

  In the second embodiment, the power interchange method between the camera 2 and the power control device 4 (see FIG. 2B) is electromagnetic induction type non-contact charging. Similarly, the power interchange method between the remote monitor 3 and the power control device 4 is electromagnetic induction type non-contact charging. The communication method between the camera 2 and the power control device 4 is short-range wireless communication. Similarly, the communication method between the remote monitor 3 and the power control device 4 is short-range wireless communication. The power control device 4 has a mounting table, and the camera 2 and the remote monitor 3 are mounted thereon.

  FIG. 11 is a block configuration diagram of the power control device 4. The power control device 4 includes electromagnetic induction coils 41 a and 41 b, communication units 42 a and 42 b, a CPU 43, and a memory 44.

  The electromagnetic induction coil 41 a performs power transmission by the electromagnetic induction method with the electromagnetic induction coil 21 of the camera 2. The electromagnetic induction coil 41 b performs power transmission by the electromagnetic induction method together with the electromagnetic induction coil 31 of the remote monitor 3. The electromagnetic induction coil 41a and the electromagnetic induction coil 41b are connected to each other. The camera 2 and the remote monitor 3 can exchange power with each other through the electromagnetic induction coils 41a and 41b. That is, the camera 2 can charge the secondary battery 30 of the remote monitor 3 through the electromagnetic induction coils 41a and 41b. Moreover, the remote monitor 3 can charge the secondary battery 20 of the camera 2 through the electromagnetic induction coils 41a and 41b.

  The communication unit 42 a performs short-range wireless communication with the communication unit 24 of the camera 2. The communication unit 42 b performs short-range wireless communication with the communication unit 34 of the remote monitor 3. The CPU 43 controls the communication units 42a and 42b. The memory 44 stores a control program executed by the CPU 43 and the like.

  FIG. 12 is a flowchart relating to a handshake process for performing power interchange among the camera 2, the remote monitor 3, and the power control device 4. The processing in FIG. 12 is executed by the CPU 23 of the camera 2, the CPU 33 of the remote monitor 3, and the CPU 44 of the power control device 4.

In step S340, the CPU 43 of the power control device 4 determines whether a preparation signal has been received via the communication unit 42a. The CPU 43 repeats the determination in step S340 while the negative determination is made in step S340.
In step S <b> 140, the CPU 23 of the camera 2 transmits a preparation signal to the power control device 4 via the communication unit 24. The CPU 43 of the power control device 4 receives this preparation signal via the communication unit 42a, makes an affirmative decision in step S340, and advances the process to step S341.

In step S <b> 141, the CPU 23 of the camera 2 determines whether a response signal to the preparation signal has been received via the communication unit 24. If the determination in step S141 is negative, the CPU 23 advances the process to step S140.
In step S341, the CPU 43 of the power control device 4 transmits a response signal to the camera 2 via the communication unit 42a. The CPU 23 of the camera 2 receives this response signal via the communication unit 24, makes an affirmative decision in step S141, and advances the process to step S142.

In step S240, the CPU 33 of the remote monitor 3 determines whether a preparation signal has been received via the communication unit 34. The CPU 33 repeats the determination in step S240 while the negative determination is made in step S240.
In step S342, the CPU 43 of the power control device 4 transmits a preparation signal to the remote monitor 3 via the communication unit 42b. The CPU 33 of the remote monitor 3 receives this preparation signal via the communication unit 34, makes an affirmative decision in step S240, and advances the process to step S241.

In step S343, the CPU 43 of the power control device 4 determines whether or not a response signal to the preparation signal has been received via the communication unit 42b. If the determination at step S343 is negative, the CPU 43 advances the process to step S342.
In step S <b> 241, the CPU 33 of the remote monitor 3 transmits a response signal to the power control device 4 via the communication unit 34. The CPU 43 of the power control device 4 receives this response signal via the communication unit 42b, makes an affirmative decision in step S343, and advances the process to step S344.

In step S142, the CPU 23 of the camera 2 starts short-range wireless communication with the power control device 4, and advances the process to step S143 in FIG.
In step S242, the CPU 33 of the remote monitor 3 starts short-range wireless communication with the power control device 4, and advances the process to step S345 in FIG.
In step S344, the CPU 43 of the power control device 4 starts short-range wireless communication with the camera 2 and with the remote monitor 3, and the process proceeds to step S243 in FIG.

  In step S243 of FIG. 13, the CPU 33 of the remote monitor 3 transmits the device ID stored in the memory 35 to the power control device 4 via the communication unit 34. In step S345, the CPU 43 of the power control device 4 receives the device ID via the communication unit 42b. The CPU 33 of the remote monitor 3 advances the process to step S250 of FIG. 14 after the process of step S243.

  In step S346, the CPU 43 of the power control device 4 transmits the device ID received in step S346 to the camera 2. In step S143, the CPU 23 of the camera 2 receives the device ID via the communication unit 24. Thereafter, the CPU 43 of the power control device 4 advances the processing to step S350 in FIG.

  In step S144, the CPU 23 of the camera 2 determines whether or not to approve the device ID received in step S143, as in step S104. If the determination in step S144 is affirmative, the process in FIG. 13 proceeds to step S145. On the other hand, if a negative determination is made in step S144, the process proceeds to step S170 in FIG.

In step S145, the CPU 23 of the camera 2 determines whether or not the device ID received in step S150 is stored in the registration ID database 251. If a negative determination is made in step S145, the process proceeds to step S146, and if a positive determination is made in step S145, the process proceeds to step S150 in FIG.
In step S146, the CPU 23 of the camera 2 stores (registers) the device ID received in step S143 in the registration ID database 251 of the memory 25, and proceeds to the process of step S150 in FIG.

  In step S150 of FIG. 14, the CPU 23 of the camera 2 acquires the remaining battery level and the power consumption history 252 of the secondary battery 20 of the camera 2. On the other hand, in step S250, the CPU 33 of the remote monitor 3 acquires the remaining battery level and the power consumption history 352 of the secondary battery 30 of the remote monitor 3.

In step S151, the CPU 23 of the camera 2 transmits the remaining battery level and the power consumption history 252 of the secondary battery 20 of the camera 2 acquired in step S150 to the power control device 4.
In step S350, the CPU 43 of the power control device 4 receives the remaining battery level and the power consumption history 252 of the secondary battery 20 of the camera 2 transmitted by the camera 2 in step S151.

In step S251, the CPU 33 of the remote monitor 3 transmits the remaining battery level and power consumption history 352 of the secondary battery 30 of the remote monitor 3 acquired in step S250 to the power control device 4.
In step S351, the CPU 43 of the power control device 4 receives the remaining battery level and power consumption history 352 of the secondary battery 30 of the remote monitor 3 transmitted by the remote monitor 3 in step S251.

The CPU 23 of the camera 2 proceeds to the process of step S160 in FIG. 16 after the process of step S151.
The CPU 33 of the remote monitor 3 proceeds to the process of step S260 in FIG. 16 after the process of step S251.
The CPU 43 of the power control apparatus 4 proceeds to the process of step S352 in FIG. 15 after the process of step S351.

  In step S352 of FIG. 15, the CPU 43 of the power control device 4 calculates the remaining drive time T1 of the camera 2 based on the remaining battery level of the secondary battery 20 of the camera 2 and the power consumption history 252 acquired in step S350. To do.

  In step S353, the CPU 43 of the power control device 4 calculates the remaining drive time T2 of the remote monitor 3 based on the remaining battery level of the secondary battery 30 of the remote monitor 3 and the power consumption history 352 acquired in step S351. .

  In step S354, the CPU 43 of the power control device 4 moves from either the camera 2 or the remote monitor 3 based on the magnitude relationship between the remaining drive time T1 calculated in step S352 and the remaining drive time T2 calculated in step S353. Decide whether to allow power. That is, which of the camera 2 and the remote monitor 3 determines which secondary battery is charged. For example, when the remaining drive time T1 is longer than the remaining drive time T2 (T1> T2), the CPU 43 of the power control device 4 determines that the camera 2 charges the secondary battery 30 of the remote monitor 3. On the other hand, when the remaining drive time T1 is smaller than the remaining drive time T2 (T2 <T1), the CPU 43 of the power control device 4 determines that the remote monitor 3 charges the secondary battery 20 of the camera 2. Information regarding the charging / charged relationship between the camera 2 and the remote monitor 3 determined in step S354 is also referred to as accommodation direction information. In addition, when the remaining drive time T1 and the remaining drive time T2 are equal, neither secondary battery is charged. After determining the accommodation direction information, the CPU 43 of the power control device 4 advances the process to the process of step S360 in FIG.

In step S360 of FIG. 16, the CPU 43 of the power control device 4 transmits the accommodation direction information determined in step S354 to the camera 2. In step S160, the CPU 23 of the camera 2 receives the accommodation direction information transmitted in step S360.
In step S361, the CPU 43 of the power control device 4 transmits the accommodation direction information determined in step S354 to the remote monitor 3. After the process of step S361, the CPU 43 of the power control device 4 proceeds to the process of step S362 in FIG.
In step S260, the CPU 33 of the remote monitor 3 receives the accommodation direction information transmitted in step S361. After the process of step S262, the CPU 33 of the remote monitor 3 proceeds to the process of step S263 in FIG.

In step S161, the CPU 23 of the camera 2 starts power accommodation based on the accommodation direction information. In step S261, the CPU 33 of the remote monitor 3 starts power accommodation based on the accommodation direction information.
In step S162, the CPU 23 of the camera 2 controls the notification unit 26 based on the accommodation direction information. On the other hand, in step S262, the CPU 33 of the remote monitor 3 controls the notification unit 36 based on the accommodation direction information. The CPU 23 of the camera 2 proceeds to the process of step S163 in FIG. 17 after the process of step S162.

  In step S163 of FIG. 17, the CPU 23 of the camera 2 acquires the remaining battery level and the power consumption history 252 of the secondary battery 20 of the camera 2. On the other hand, in step S <b> 263, the CPU 33 of the remote monitor 3 acquires the remaining battery level and the power consumption history 352 of the secondary battery 30 of the remote monitor 3.

In step S164, the CPU 23 of the camera 2 transmits the remaining battery level and the power consumption history 252 of the secondary battery 20 of the camera 2 acquired in step S163 toward the power control device 4. The CPU 23 of the camera 2 proceeds to the process of step S165 in FIG. 18 after the process of step S164.
In step S362, the CPU 43 of the power control device 4 receives the remaining battery level and the power consumption history 252 of the secondary battery 20 of the camera 2 transmitted in step S164.

In step S264, the CPU 33 of the remote monitor 3 transmits the remaining battery level and the power consumption history 352 of the secondary battery 30 of the remote monitor 3 acquired in step S263 to the power control device 4. The CPU 33 of the remote monitor 3 proceeds to the process of step S265 in FIG. 18 after the process of step S264.
In step S363, the CPU 43 of the power control device 4 receives the remaining battery level and power consumption history 352 of the secondary battery 30 of the remote monitor 3 transmitted in step S264. The CPU 43 of the power control device 4 proceeds to the process of step S364 in FIG. 18 after the process of step S363.

  In step S364 of FIG. 18, the CPU 43 of the power control device 4 calculates the remaining drive time T1 of the camera 2 based on the remaining battery level of the secondary battery 20 of the camera 2 and the power consumption history 252 acquired in step S362. To do.

  In step S365, the CPU 43 of the power control device 4 calculates the remaining drive time T2 of the remote monitor 3 based on the remaining battery level of the secondary battery 30 of the remote monitor 3 and the power consumption history 352 acquired in step S363. .

  In step S366, the CPU 43 of the power control device 4 determines whether or not the remaining drive time T1 of the camera 2 calculated in step S364 matches the remaining drive time T2 of the remote monitor 3 calculated in step S365. When a negative determination is made in step S366, the process proceeds to step S362 in FIG. 17, and when a positive determination is made in step S366, the process proceeds to step S367.

In step S <b> 265, the CPU 33 of the remote monitor 3 determines whether an end signal for ending the power accommodation process has been transmitted from the power control device 4. If the determination at step S265 is negative, the CPU 33 of the remote monitor 3 advances the process to step S263 in FIG.
In step S 367, the CPU 43 of the power control device 4 transmits an end signal toward the remote monitor 3. As a result, the CPU 33 of the remote monitor 3 makes an affirmative decision in step S265 and advances the process to step S270 in FIG.
In step S165, the CPU 23 of the camera 2 determines whether or not an end signal for ending the power accommodation process has been transmitted from the power control device 4. If the determination in step S165 is negative, the CPU 23 of the camera 2 advances the process to step S163 in FIG.
In step S <b> 368, the CPU 43 of the power control device 4 transmits an end signal toward the camera 2. As a result, the CPU 23 of the camera 2 makes an affirmative decision in step S165 and advances the process to step S170 in FIG.
After transmitting the end signal to both the camera 2 and the remote monitor 3, the CPU 43 of the power control device 4 advances the process to step S370 in FIG.

  In step S <b> 170 of FIG. 19, the CPU 23 of the camera 2 controls the notification unit 26 based on the end signal received from the power control device 4 to notify the end of power accommodation. For example, the CPU 23 of the camera 2 turns off the indicator lamp of the notification unit 26 and displays on the display monitor of the notification unit 26 that power interchange has been completed.

  In step S <b> 270, the CPU 33 of the remote monitor 3 controls the notification unit 36 based on the end signal received from the power control device 4 to notify the end of power accommodation. For example, the CPU 33 of the remote monitor 3 turns off the indicator lamp of the notification unit 36 and displays a message indicating that the power interchange has been completed on the display monitor of the notification unit 36.

  In step S <b> 171, the CPU 23 of the camera 2 disconnects communication with the power control device 4. In step S271, the CPU 33 of the remote monitor 3 disconnects communication with the power control device 4. In step S <b> 370, the CPU 43 of the power control device 4 disconnects both the communication with the camera 2 and the communication with the remote monitor 3. Then, the CPU 23 of the camera 2, the CPU 33 of the remote monitor 3, and the CPU 43 of the power control device 4 end the processing related to power interchange.

According to the embodiment described above, the following operational effects can be obtained.
The camera 2 according to the first embodiment of the present invention is an electronic device including the secondary battery 20.
The CPU 23 of the camera 2 acquires the information regarding the remaining battery level of the secondary battery 20 and the power consumption history 252 regarding the power consumption of the camera 2 from the memory 25 (step S110 in FIG. 8 and step S123 in FIG. 9).
The CPU 23 of the camera 2 acquires information related to the remaining battery level of the secondary battery 30 and the power consumption history 352 related to the power consumption of the remote monitor 3 from the remote monitor 3 including the secondary battery 30 (step S111 in FIG. 8, FIG. 9 step S124).
The CPU 23 of the camera 2 calculates the remaining drive time T1 of the camera 2 based on the remaining battery level of the secondary battery 20 and the power consumption history 252 (step S112 in FIG. 8 and step S125 in FIG. 9).
The CPU 23 of the camera 2 calculates the remaining drive time T2 of the remote monitor 3 based on the remaining battery level of the secondary battery 30 and the power consumption history 352 (step S113 in FIG. 8 and step S126 in FIG. 9).
Based on the remaining drive time T1 and the remaining drive time T2, the CPU 23 of the camera 2 transmits and receives power so that the remote monitor 3 matches (step S114 in FIG. 8 and step S127 in FIG. 9). Since the camera 2 has such a configuration, in the power control system 1 according to the first embodiment, the remaining drive time T1 between the camera 2 and the remote monitor 3 that are used in combination. And power can be accommodated so that T2 is adjusted appropriately.

Moreover, the power control apparatus 4 according to the second embodiment of the present invention includes a mounting table, the camera 2 including the secondary battery 20, and the remote monitor 3 including the secondary battery 30 used in combination with the camera 2. And can be mounted on the mounting table.
The CPU 43 of the power control device 4 acquires information about the remaining battery level of the secondary battery 20 and the power consumption history 252 regarding the power consumption of the camera 2 from the camera 2 (step S350 in FIG. 14 and step S362 in FIG. 17). .
The CPU 43 of the power control device 4 acquires information related to the remaining battery level of the secondary battery 30 and the power consumption history 352 related to the power consumption of the remote monitor 3 from the remote monitor 3 (step S351 in FIG. 14 and step S363 in FIG. 17). ).
The CPU 43 of the power control device 4 calculates the remaining drive time T1 of the camera 2 based on the remaining battery level of the secondary battery 20 and the power consumption history 252 (step S352 in FIG. 15 and step S364 in FIG. 18).
The CPU 43 of the power control device 4 calculates the remaining drive time T2 of the remote monitor 3 based on the remaining battery level of the secondary battery 30 and the power consumption history 352 (step S353 in FIG. 15 and step S365 in FIG. 18). .
Based on the remaining drive time T1 and the remaining drive time T2, the CPU 43 of the power control device 4 transmits and receives power so that the remote monitor 3 matches (step S354 in FIG. 15 and step S366 in FIG. 18). . Since the power control device 4 has such a configuration, in the power control system according to the second embodiment, the remaining drive time between the camera 2 and the remote monitor 3 used in combination. Power can be accommodated so that T1 and T2 are adjusted appropriately. In addition, by performing power interchange using the power control device 4, power interchange is performed only at a specific location, and the effect of increasing the safety by reducing the possibility of theft or the like is also obtained.

The embodiment described above can be implemented with the following modifications.
(Modification 1) In the first and second embodiments, power is interchanged so that the remaining drive time T1 and the remaining drive time T2 coincide. However, the target values of the remaining drive time T1 and the remaining drive time T2 due to power interchange may be set by the user.

(Modification 2) When the electronic device 3 is an electronic device that is not used in combination with the electronic device 2, for example, when both the electronic device 2 and the electronic device 3 are digital cameras, the power interchange method according to the present invention is applied. can do. In addition, when the number of electronic devices included in the power control system is three or more, the power interchange method according to the present invention can be applied to power interchange between three or more electronic devices. it can.

(Modification 3) The approval of the device ID 351 of the remote monitor 3 using the registration ID database 251 may be performed by the power control device 4 or the server 5. In addition, when it implements with the power control apparatus 4, what is necessary is just to memorize | store the registration ID database 251 in the memory 44. FIG.

  FIG. 20 is a block diagram of the server 5 that approves the device ID 351. The server 5 includes a communication unit 51, a CPU 52, and a memory 53. The communication unit 51 is connected to the telecommunication line 6 and is used for communication between the camera 2 and the remote monitor 3. The CPU 52 can execute various processes by controlling each unit of the server 5. The memory 53 is a nonvolatile storage medium. The memory 53 stores a registration ID database 251.

(Modification 4) The battery capacity of the secondary battery 30 of the remote monitor 3 is very small compared to the battery capacity of the secondary battery 20 (for example, less than 1/10 of the battery capacity of the secondary battery 20), and the secondary battery 30 If there is not enough battery capacity to charge the battery 20, power exchange from the remote monitor 3 toward the camera 2 may not be performed. The battery capacities of the secondary battery 20 and the secondary battery 30 are the same as those of the camera 2 and the power control device 4 when the remaining battery power is transmitted as in step S211 in FIG. 8, step S151 in FIG. 14, and step S251 in FIG. You may decide to transmit to.

(Modification 5) In the process of step S114 of FIG. 8 or step S354 of FIG. Further consideration may be given. The number of times of charging may be managed using, for example, the power controller 22 or the like. For example, when the number of times of charging is equal to or greater than a predetermined number, the CPU 23 may determine not to allow power interchange using the secondary battery 20. The predetermined number of times is, for example, several hundred to 1,000 times. The predetermined number of times may be corrected to be larger as the absolute value of the difference between the remaining drive time T1 and the remaining drive time T2 is larger.

(Modification 6) In step S114 of FIG. 8 and step S354 of FIG. 15, the CPU 23 of the camera 2 or the CPU 43 of the power control device 4 calculates the target value of the remaining drive time T1 as well as the direction of power interchange. You may decide. For example, the average value of the remaining drive time T1 and the remaining drive time T2 calculated in step S112 and step S113 in FIG. 8 may be calculated as the target value.

(Modification 7) In the second embodiment, the remaining drive times T1 and T2 are calculated and the power interchange direction is determined by the power control device 4. However, the camera is the same as in the first embodiment. 2 may be executed. In this case, the power control device 4 desirably transmits the received battery capacity and power consumption history 352 of the remote monitor 3 to the camera 2 after step S351 of FIG.

  The embodiments and modifications described above are merely examples, and the present invention is not limited to these contents as long as the features of the invention are not impaired. Further, the embodiments and modifications described above may be combined and executed as long as the features of the invention are not impaired.

DESCRIPTION OF SYMBOLS 1 Power control system 2 Camera 3 Remote monitor 4 Power control apparatus 5 Server 20, 30 Secondary battery

Claims (9)

An electronic device comprising a first secondary battery,
First information acquisition means for acquiring information on a remaining battery level of the first secondary battery and information on power consumption of the electronic device;
Second information acquisition means for acquiring information relating to the remaining battery level of the second secondary battery and information relating to power consumption of the external device from an external device comprising a second secondary battery;
First time calculating means for calculating a first remaining drive time during which the electronic device can be driven based on the remaining battery level of the first secondary battery and information on the power consumed by the electronic device;
Second time calculating means for calculating a second remaining drive time during which the external device can be driven based on the remaining battery level of the second secondary battery and information on the power consumed by the external device;
Based on the first remaining driving time calculated by the first time calculating means and the second remaining driving time calculated by the second time calculating means, power is transmitted to and received from the external device. Power interchange means to perform;
An electronic device comprising: The electronic device according to claim 1,
The electronic device according to claim 1, wherein the power interchange means transmits and receives power to and from the external device so that the first remaining drive time and the second remaining drive time coincide with each other. The electronic device according to claim 1 or 2,
The power interchange means does not transmit / receive power to / from the external device when the number of times of charging the first secondary battery or the second secondary battery is a predetermined number or more. Electronics. A first electronic device comprising a first secondary battery;
A second electronic device that is used in combination with the first electronic device and includes a second secondary battery, and a power control system comprising:
First information acquisition means for acquiring information on a remaining battery level of the first secondary battery and information on power consumption of the first electronic device;
Second information acquisition means for acquiring information on a remaining battery level of the second secondary battery and information on power consumption of the second electronic device;
A first time for calculating a first remaining driving time during which the first electronic device can be driven based on the remaining battery level of the first secondary battery and information on the power consumed by the first electronic device. A calculation means;
A second time for calculating a second remaining driving time during which the second electronic device can be driven based on the remaining battery level of the second secondary battery and information on the power consumed by the second electronic device. A calculation means;
Based on the first remaining drive time calculated by the first time calculation means and the second remaining drive time calculated by the second time calculation means, the first electronic device and the second electronic device Power interchange means for transmitting and receiving power to and from the device;
A power control system comprising: The power control system according to claim 4, wherein
The power interchange means performs power transmission / reception between the first electronic device and the second electronic device such that the first remaining driving time and the second remaining driving time coincide with each other. Power control system characterized by The power control system according to claim 4 or 5,
When the number of times the first secondary battery or the second secondary battery is charged is equal to or greater than a predetermined number of times, the power interchange means is configured to transmit power between the first electronic device and the second electronic device. A power control system characterized by not performing power transmission / reception. A first electronic device comprising a first secondary battery;
A power control device capable of mounting a second electronic device that is used in combination with the first electronic device and includes a second secondary battery,
First information acquisition means for acquiring information on a remaining battery level of the first secondary battery and information on power consumption of the first electronic device;
Second information acquisition means for acquiring information on a remaining battery level of the second secondary battery and information on power consumption of the second electronic device;
A first time for calculating a first remaining driving time during which the first electronic device can be driven based on the remaining battery level of the first secondary battery and information on the power consumed by the first electronic device. A calculation means;
A second time for calculating a second remaining driving time during which the second electronic device can be driven based on the remaining battery level of the second secondary battery and information on the power consumed by the second electronic device. A calculation means;
Based on the information on the remaining battery level of the first secondary battery acquired by the first information acquisition unit and the information on the remaining battery level of the second secondary battery acquired by the second information acquisition unit. Power control means for transmitting and receiving power between the first electronic device and the second electronic device to control the remaining battery power of the first and second electronic devices;
A power control apparatus comprising: The power control apparatus according to claim 7, wherein
The power control means controls the remaining battery power of the first and second electronic devices so that the first remaining drive time and the second remaining drive time coincide with each other. . The power control apparatus according to claim 7 or 8,
The power control means is configured to control power between the first electronic device and the second electronic device when the number of times of charging the first secondary battery or the second secondary battery is equal to or greater than a predetermined number. A power control device characterized by not transmitting and receiving power.

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