JP6173034B2 - Imaging device, lens, power transmission device, control method, and program - Google Patents

Description

The present invention relates to an imaging device, a lens, a power transmission device, a control method, and a program.

  With the recent increase in wireless communication media, non-contact power transmission devices capable of power transmission even without a contact portion between the power transmission side and the power reception side have been commercialized. Such a non-contact power transmission apparatus is often used for charging a controller of a mobile phone or a home game machine, for example.

  For example, in the non-contact power transmission device disclosed in Patent Document 1, power transmission for performing ID authentication is transmitted from the power transmission device by temporary power transmission, and communication such as ID authentication of the power reception device is performed to confirm safety. . After that, a technology that achieves both safety and power saving by supplying predetermined power by this power transmission is disclosed.

JP 2009-11129 A

  However, for example, in an imaging apparatus having an interchangeable lens attached to the camera body, the required power differs depending on the lens used. That is, the required power varies greatly depending on the type of lens used and the operating state of the lens (autofocus drive, zoom drive, camera shake prevention drive).

  When power is supplied in a non-contact manner to a power receiving apparatus in which the required power greatly changes in this way, the power transmitting apparatus always transmits power that is the sum of the assumed loads. Therefore, when power is transmitted to a power receiving apparatus in which the power greatly changes, there is a problem that power consumption of the power transmitting apparatus increases.

  The present invention has been made in view of the above-described problems, and an object of the present invention is to save power when power is transmitted to a power receiving apparatus in which required power varies depending on the type and operation state. And

The imaging apparatus according to the present invention is an imaging apparatus that can be attached with an interchangeable lens and supplies power to the mounted lens in a non-contact manner, and the power supply destination of the lens and the power supply from the mounted lens. Receiving means for receiving power supply related information associated with power required in advance, and power required according to the operating state of the lens with reference to power supply related information received by the receiving means produced, have a, a power transmission means for transmitting to the lens, the power transmitting means, in response to the transition to the low power consumption mode of the imaging apparatus, by referring to the power supply destination-related information, the feeding of the lens Electric power required for charging the backup battery unit is generated by the backup charging means as the previous, and is transmitted to the lens .

  According to the present invention, it is possible to save power when power is transmitted to a power receiving device whose required power varies depending on the type and operating state.

It is a block diagram which shows an example of schematic structure of the imaging device of this embodiment. It is a flowchart which shows operation | movement of the imaging device of this embodiment. It is a figure which shows an example of electric power feeding destination relevant information. It is a flowchart which shows operation | movement of the imaging device of this embodiment. It is a figure which shows the relationship between the operating state of the lens of this embodiment, and transmitted power.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. This embodiment demonstrates the case where the imaging device (camera) 10 is used as a non-contact electric power transmission apparatus.
FIG. 1 is a block diagram illustrating an example of a schematic configuration of the imaging apparatus 10.
The imaging device 10 includes a camera body 100 as a power transmission device, and a lens 200 as a power reception device that is interchangeably attached to the camera body 100.

The camera body 100 transmits power for driving the lens 200 to the lens 200.
The camera body 100 includes a power transmission side microcomputer control unit 101, a communication control unit 102, a power transmission control unit 103, a main battery unit 104, a power transmission circuit 105, a power transmission unit 107, and the like.
The power transmission side microcomputer control unit 101 controls the entire camera body 100. Specifically, various control commands such as auto focus control, aperture control, camera shake prevention control, etc., and operation of the lens 200 are performed through the communication control unit 102 for the lens 200 that performs control related to the shooting operation of the camera. The power supply destination switching instruction command according to the state is transmitted. The power transmission side microcomputer control unit 101 includes a ROM as a nonvolatile memory and a RAM as a volatile memory. The ROM stores a program executed by the power transmission side microcomputer control unit 101. The RAM stores power supply destination related information, which will be described later, received from the attached lens 200.

  Further, the power transmission side microcomputer control unit 101 preliminarily supplies a power supply destination (AF driving unit 209, camera shake prevention driving unit 210, diaphragm driving unit 211, backup, which will be described later) related to a lens operating state scheduled next in accordance with a shooting operation. The charging unit 212 and the power receiving side microcomputer control unit 201) are determined. The power transmission side microcomputer control unit 101 sets a power supply destination switching instruction command according to the power supply destination in the communication control unit 102, and transmits necessary power according to the operation state of the lens 200 with reference to the power supply destination related information. Set in the control unit 103.

  The power transmission circuit 105 converts the DC voltage of the main battery unit 104 into an AC voltage having a frequency based on the power set in the power transmission control unit 103 and supplies the AC voltage to the power transmission unit 107. In addition, the power transmission circuit 105 modulates a data signal such as a power supply destination switching instruction command or a lens control command set in the communication control unit 102 to an AC voltage generated by the power transmission circuit 105 via the pulse generation circuit 106, The power is supplied to the power transmission unit 107. The power transmission unit 107 transmits a power supply destination switching instruction command to the lens 200 by transmitting the supplied AC voltage to the lens 200.

The lens 200 receives power transmitted from the power transmission unit 107 of the camera body 100 by electromagnetic induction.
The lens 200 includes a power reception side microcomputer control unit 201, a communication control unit 202, a power reception control unit 203, a power reception circuit 204, a power supply destination switching unit 206, a power generation circuit 207, and a power reception unit 208. The lens 200 includes an AF driving unit 209, a camera shake preventing driving unit 210, an aperture driving unit 211, a backup charging unit 212, a backup battery unit 213, and the like.

The power receiving circuit 204 converts the power received by the power receiving unit 208 from an AC voltage to a DC voltage via the rectifier circuit 205 and supplies the converted voltage to the power generation circuit 207. In addition, the power receiving circuit 204 demodulates a data signal such as a modulated power supply destination switching instruction command or a lens control command out of the received power, and transmits the demodulated data signal to the power reception control unit 203.
If the transmitted command is a lens control command, the power reception control unit 203 transmits the command to the power receiving side microcomputer control unit 201 via the communication control unit 202. The power receiving side microcomputer control unit 201 controls the AF drive unit 209, the camera shake prevention drive unit 210, and the aperture drive unit 211 based on a lens control command. Further, when the transmitted command is a power supply destination switching instruction command, the power reception control unit 203 transmits the power supply destination switching unit 206 of the power generation circuit 207. The power supply destination switching unit 206 switches the power supply destination of the power supplied to the power generation circuit 207 based on the transmitted power supply destination switching instruction command. That is, the power supply destination switching unit 206 turns on the power to the AF drive unit 209, the camera shake prevention drive unit 210, the aperture drive unit 211, the backup charging unit 212, and the power receiving side microcomputer control unit 201 based on the power supply destination switching instruction command. / OFF control. By controlling the power supply destination switching unit 206 as described above, it is possible to turn off an unnecessary power source according to the operation state of the lens, and it is possible to suppress power consumption.

  When the power receiving side microcomputer control unit 201 receives a standby state instruction as a lens control command, the power receiving side microcomputer control unit 201 stops various operations of the lens 200, shifts the operation clock of the power receiving side microcomputer control unit 201 to a low speed clock, and a low power consumption mode. Migrate to In this case, power is supplied from a rechargeable backup battery unit 213 for maintaining microcomputer operation such as a lithium ion battery or a super capacitor. Since it is difficult to generate low power consumption with electric power that can be transmitted and received by electromagnetic induction, the non-contact power supply driving from the camera body 100 can be stopped for a predetermined time by using the backup battery unit 213. . With such a configuration, since the operation of the camera body 100 on the power transmission side can also be stopped, it is possible to further reduce power consumption.

Next, the operation of the imaging apparatus 10 will be described with reference to the flowchart shown in FIG. 2 and the power supply destination related information shown in FIG. Here, the operation when the lens 200 is attached to the camera body 100 will be described.
First, power supply destination related information will be described.
FIG. 3A is a diagram illustrating an example of the power supply destination related information. The power supply destination related information is stored in a part of the ROM of the power receiving side microcomputer control unit 201 of the lens 200. Further, the power supply destination related information is data that is transmitted by the power receiving side microcomputer control unit 201 in step S404 shown in FIG. 2 and that is received by the power transmission side microcomputer control unit 101 in step S304.

  The power supply destination related information shown in FIG. 3A is configured by associating the power supply destination, the power required at the power supply destination, and the standby time. In the power supply destination related information shown in FIG. 3A, eight types of power supply destinations can be designated. Here, the power receiving side stores a power receiving side microcomputer control unit, an AF driving unit, a camera shake preventing driving unit, an aperture driving unit, and a backup charging unit. Moreover, the information of the electric power required in each electric power feeding destination is memorize | stored as electric power. Further, as the standby time, a time to wait after stopping the power supply drive when the mode is shifted to the low power consumption mode is stored.

The command shown in FIG. 3B is an example of a power supply destination switching instruction command for controlling the power supply destination switching unit 206 received by the power reception control unit 203. The command command is data that is transmitted by the power transmission side microcomputer control unit 101 in step S305 shown in FIG. 2 and that is received by the power reception side microcomputer control unit 201 in step S405.
The command shown in FIG. 3B is composed of an 8-bit command part (power supply destination switching command) and an 8-bit or more data part (power supply destination switching instruction data) as incidental information accompanying the command part. Yes. Each bit of the data portion includes information on the power supply destination indicated by the power supply destination related information in FIG. Note that the command command is not limited to the power supply destination switching command, and may include a lens control command such as autofocus and aperture control of the lens 200. In this case, the power reception control unit 203 transmits the received command command to either the communication control unit 202 or the power supply destination switching unit 206 according to the content.

In the flowchart shown in FIG. 2, in step S301, the power transmission side microcomputer control unit 101 of the camera body 100 detects whether or not a lens is mounted. If the lens 200 is mounted, the process proceeds to step S302.
In step S302, the power transmission side microcomputer control unit 101 generates a power supply destination switching instruction command. The power supply destination switching instruction command includes a power supply destination switching command (f3h) shown in FIG. 3B and 1-byte power supply destination switching instruction data attached to the power supply destination switching command. Here, since the power receiving side microcomputer control unit 201 of the lens 200 is activated, the power receiving destination is only the power receiving side microcomputer control unit 201. Therefore, the power transmission side microcomputer control unit 101 generates binary data “0000001b” of Bit 0 = 1 (power supply of the power reception side microcomputer control unit) shown in Example 2 of FIG. At this time, the power transmission side microcomputer control unit 101 has not received the power supply destination related information shown in FIG. Therefore, the power transmission side microcomputer control unit 101 generates a power supply destination switching instruction command by reading the power supply destination switching instruction command that activates only the power reception side microcomputer control unit 201 stored in the ROM of the power transmission side microcomputer control unit 101. . The power transmission side microcomputer control unit 101 modulates the generated power supply destination switching instruction command via the pulse generation circuit 106 of the power transmission circuit 105 and transmits the power via the power transmission unit 107, whereby the power supply destination switching instruction command is sent to the lens 200. Send.

  In step S <b> 401, the power reception circuit 204 demodulates the modulated power supply destination switching instruction command and transmits it to the power reception control unit 203. The power reception control unit 203 transmits a power supply destination switching instruction command to the power supply destination switching unit 206 of the power generation circuit 207. The power supply destination switching unit 206 switches the power supply destination so as to supply power only to the power receiving side microcomputer control unit 201 based on the power supply destination switching instruction command. At this time, power is not supplied to the other power supply destinations (AF driving unit 209, camera shake prevention driving unit 210, aperture driving unit 211, and backup charging unit 212), and the power supply is kept off.

In step S402, the power receiving side microcomputer control unit 201 is activated by the supplied power. Further, the power receiving side microcomputer control unit 201 confirms the initial state of each unit, and acquires the presence / absence of an abnormality and the state of an unillustrated camera shake prevention and focus control switch.
In step S <b> 403, the power receiving side microcomputer control unit 201 transmits the current setting information to the camera body 100. Here, it is assumed that the power receiving unit 208 also has a function of transmitting information to the camera body 100.
In step S <b> 404, the power receiving side microcomputer control unit 201 transmits the power supply destination related information shown in FIG. 3A stored in the ROM of the power receiving side microcomputer control unit 201 to the camera body 100.

In step S303, the power transmission side microcomputer control unit 101 waits for a response from the lens 200, and proceeds to step S304 when a response is received. Here, it is assumed that the power transmission unit 107 also has a function of receiving information transmitted from the lens 200.
In step S304, the power transmission side microcomputer control unit 101 receives the power supply destination related information. This processing corresponds to an example of processing by the receiving unit. The power transmission side microcomputer control unit 101 stores the received power supply destination related information in the RAM.

In step S <b> 305, the power transmission side microcomputer control unit 101 acquires information on power to be transmitted in advance in order to perform autofocus control. For example, the power transmission side microcomputer control unit 101 refers to the power supply destination related information stored in the RAM, and adds the power required by the power reception side microcomputer control unit 201 and the power required by the AF drive unit 209. By calculating, information on the power to be transmitted is acquired. The power transmission side microcomputer control unit 101 generates power via the power transmission circuit 105 based on the calculated power information, and transmits the power to the lens 200 via the power transmission unit 107. This processing corresponds to an example of processing by the power transmission unit.
Further, the power transmission side microcomputer control unit 101 generates a power supply destination switching instruction command. This processing corresponds to an example of processing by the generation unit. Here, the power receiving side is the power receiving side microcomputer control unit 201 and the AF driving unit 209 in order to drive the power receiving side microcomputer control unit 201 and the AF driving unit 209. Therefore, the power transmission side microcomputer control unit 101 generates a power supply destination switching instruction command including the power supply destination switching instruction data shown in Example 3 of FIG. The power transmission side microcomputer control unit 101 modulates the generated power supply destination switching instruction command via the pulse generation circuit 106 of the power transmission circuit 105 and transmits the power via the power transmission unit 107, whereby the power supply destination switching instruction command is sent to the lens 200. Send. This processing corresponds to an example of processing by the transmission unit.

  Note that the power transmission side microcomputer control unit 101 may calculate in advance the necessary power according to the operating state of the lens 200 based on the power supply destination related information. Specifically, the power transmission side microcomputer control unit 101 associates the lens operating state and the power required according to the lens operating state based on the power supply destination and power of the power supply destination related information. Generate a table. For example, when the operation state of the lens 200 is autofocus, the power obtained by adding the power required by the power receiving side microcomputer control unit 201 and the power required by the AF driving unit 209 shown in FIG. A power supply destination management table associated with autofocus is generated. An example of the outline of the power supply destination management table will be described later with reference to FIG.

  In step S <b> 405, the power receiving circuit 204 converts the AC voltage received by the power receiving unit 208 into a DC voltage via the rectifier circuit 205 and supplies the DC voltage to the power generation circuit 207. In addition, the power receiving circuit 204 demodulates the modulated power supply destination switching instruction command and transmits the demodulated power supply destination switching instruction command to the power reception control unit 203. The power reception control unit 203 transmits a power supply destination switching instruction command to the power supply destination switching unit 206 of the power generation circuit 207. Based on the power supply destination switching instruction command, the power supply destination switching unit 206 switches the power supply destination so that power is supplied only to the power receiving side microcomputer control unit 201 and the AF driving unit 209. This process corresponds to an example of a process performed by the power supply destination switching unit.

In step S306, the power transmission side microcomputer control unit 101 generates an autofocus control command, modulates the control command via the pulse generation circuit 106 of the power transmission circuit 105, and transmits the control command by transmitting the power via the power transmission unit 107. Transmit to the lens 200.
In step S <b> 406, the power reception circuit 204 demodulates the modulated autofocus control command and transmits the demodulated autofocus control command to the power reception control unit 203. The power reception control unit 203 transmits a control command to the power receiving side microcomputer control unit 201 via the communication control unit 202. The power receiving side microcomputer control unit 201 performs autofocus control based on an autofocus control command.

After steps S306 and S406, the camera body 100 switches the power supply destination to the power receiving side microcomputer control unit 201, the AF drive unit 209, the camera shake prevention drive unit 210, and the aperture drive unit 211 in accordance with the operation state of the lens 200 and is necessary. Power is transmitted.
As described above, the camera body 100 receives the power supply destination related information according to the type of the lens 200 to be mounted, and generates the necessary power according to the operation state of the lens 200 with reference to the power supply destination related information. . Therefore, it is possible to save power by supplying necessary power according to the type and operating state of the lens 200.

  The lens 200 also switches the power supply destination and controls the lens 200 based on a power supply destination switching instruction command and a lens control command modulated according to the transmitted power. Therefore, accurate power consumption is supplied to the lens 200, and non-contact power transmission is possible without impairing the convenience of communication for controlling the lens 200.

Next, the operation of the imaging device 10 in the low power consumption mode will be described. The power transmission side microcomputer control unit 101 of the camera main body 100 stops unnecessary power when there is no operation by the user for a predetermined time, and the power consumption is reduced by switching to an operation state such as low-speed driving otherwise. Transition to power mode. In the low power consumption mode, it is necessary to perform the same process for the lens 200 to reduce power consumption.
Here, the operation of the imaging apparatus 10 in the low power consumption mode will be described with reference to the flowchart shown in FIG. Hereinafter, the process in which the pulse generation circuit 106 modulates the power supply destination switching instruction command and the lens control command and the power transmission unit 107 transmits power and the process in which the power reception circuit 204 demodulates are the same as those in the flowchart of FIG. Since this is the case, it will be omitted.

In step S501, the power transmission side microcomputer control unit 101 transmits to the lens 200 a standby state instruction for shifting the lens 200 to the standby operation in accordance with the shift to the low power consumption mode.
In step S601, the power receiving side microcomputer control unit 201 sets the AF driving unit 209, the image stabilization driving unit 210, the aperture driving unit 211, and the like to a predetermined standby state in accordance with the standby state instruction and shifts the operation clock to the low speed clock. Then, the low power consumption mode is entered.

In step S <b> 502, the power transmission side microcomputer control unit 101 first switches the power supply destination to the backup charging unit 212 in order to switch the power supplied to the power receiving side microcomputer control unit 201 to the backup battery unit 213, and the backup charging unit 212 performs backup. The battery unit 213 is charged.
Specifically, the power transmission side microcomputer control unit 101 refers to the power supply destination related information stored in the RAM and acquires information on the power required by the backup charging unit 212. The power transmission side microcomputer control unit 101 generates power via the power transmission circuit 105 based on the calculated power information, and transmits the power to the lens 200 via the power transmission unit 107.
Further, the power transmission side microcomputer control unit 101 generates a power supply destination switching instruction command. Here, in order to drive the backup charging unit 212, the power supply destination is the backup charging unit 212. Therefore, the power transmission side microcomputer control unit 101 generates a power supply destination switching instruction command including the power supply destination switching instruction data shown in Example 5 of FIG. The power transmission side microcomputer control unit 101 transmits the generated power supply destination switching instruction command to the lens 200.

  In step S <b> 602, the power receiving circuit 204 converts the AC voltage received by the power receiving unit 208 into a DC voltage via the rectifier circuit 205 and supplies the DC voltage to the power generation circuit 207. In addition, the power reception circuit 204 transmits a power supply destination switching instruction command to the power reception control unit 203. The power reception control unit 203 transmits a power supply destination switching instruction command to the power supply destination switching unit 206 of the power generation circuit 207. The backup charging unit 212 charges the backup battery unit 213 by switching the power supply destination so that the power supply destination switching unit 206 supplies power to the backup charging unit 212 based on the power supply destination switching instruction command.

In step S503, the power transmission side microcomputer control unit 101 stops power transmission when the charging of the backup battery unit 213 is completed. Next, after stopping power transmission, the power transmission side microcomputer control unit 101 starts counting the waiting time after stopping power supply driving. The power transmission side microcomputer control unit 101 counts based on the standby time included in the power supply destination related information. Note that while power transmission from the camera body 100 is stopped, the power-receiving-side microcomputer control unit 201 of the lens 200 continues to drive in the low power consumption mode by being supplied with power from the backup battery unit 213.
In step S504, the power transmission side microcomputer control unit 101 determines whether or not the standby time has elapsed. If the standby time has elapsed, the process returns to step S502 to charge the backup battery unit 213 again. If the standby time has not elapsed, the process proceeds to step S505. During the standby time, power transmission from the camera body 100 is stopped, so that power consumption can be significantly reduced.

In step S <b> 603, the power receiving side microcomputer control unit 201 always detects a state change such as the presence or absence of an unillustrated camera shake prevention, autofocus setting operation, or a low power consumption mode cancel command. If a state change is detected, the process proceeds to step S604.
In step S <b> 604, the power receiving side microcomputer control unit 201 transmits an activation request to the camera body 100.

In step S505, the power transmission side microcomputer control unit 101 waits for an activation request from the lens 200. When the activation request is received, the power transmission side microcomputer control unit 101 proceeds to processing for switching from the standby state to the normal photographing state.
Since the lens 200 has the backup battery unit 213 in this manner, power transmission from the camera body 100 to the lens 200 can be stopped, so that power consumption can be significantly reduced. Further, the standby time stored in the power supply destination related information can be individually set according to the charge capacity of the backup battery unit 213 of the lens 200. Therefore, since the backup battery unit 213 can be charged with the standby time corresponding to the type of the lens 200, power saving according to the type of the lens 200 can be achieved.

  FIG. 5 is a diagram illustrating the relationship between the lens operating state and the transmitted power, and the power supply destination management table described above will be schematically described. In FIG. 5, the horizontal axis represents a time lapse showing an example of an operation state from when the power receiving side microcomputer control unit 201 of the lens 200 is activated to the transition to the standby operation, and the vertical axis represents the load state relative to the lens operation state. , And power to be set. As shown in FIG. 5, since the load state changes according to the operating state of the lens, the power to be set differs greatly.

In the operating state of the lens for only initial communication that activates the power-receiving-side microcomputer control unit 201 at time Ta shown in FIG. 5, the driving of the lens 200 is unnecessary, so the power a is set small. The power supply destination switching instruction command at this time includes power supply destination switching instruction data shown in Example 2 of FIG.
In the operating state of the lens in which the camera shake prevention driving and the aperture driving that constantly require a load overlap each other as at time Tb shown in FIG. 5, the power b is set larger than the power a. The power supply destination switching instruction command at this time includes power supply destination switching instruction data shown in Example 6 of FIG.

In the operating state of the lens in which all the operations of camera shake prevention driving, aperture driving, and AF driving are overlapped as shown at time Tc in FIG. 5, the power c is set to the maximum power. The power supply destination switching instruction command at this time includes power supply destination switching instruction data shown in Example 4 of FIG.
As in the time Td shown in FIG. 5, in the lens state at the time of backup charging, the power is set to the same power as the power b in order to shorten the charging time. The power supply destination switching instruction command at this time includes power supply destination switching instruction data shown in Example 5 of FIG.

  As described above, the power transmission-side microcomputer control unit 101 sets the power corresponding to the lens operating state based on the power supply destination management table in which the lens operating state and the power required according to the lens operating state are associated with each other. Information is acquired and set in the power transmission control unit 103. The power transmission circuit 105 converts the DC voltage of the main battery unit 104 into an AC voltage based on the information on the power set in the power transmission control unit 103 and supplies the AC voltage to the power transmission unit 107, so that the power transmission circuit 105 responds to the lens operating state. Electric power can be transmitted to the lens 200. The shaded portion shown in FIG. 5 indicates power that becomes invalid when a certain amount of power is transmitted. Since the camera body 100 does not need to transmit power corresponding to the shaded portion shown in FIG. 5, it is possible to greatly reduce power consumption.

As mentioned above, although preferable embodiment of this invention was described, this invention is not limited to embodiment mentioned above, A various deformation | transformation and change are possible within the range of the summary.
For example, in the above-described embodiment, the electromagnetic induction type power transmission is described, but electromagnetic resonance type power transmission may be used.

In the above-described embodiment, the communication between the camera body 100 and the lens 200 is realized by modulation and demodulation to transmission power. However, the present invention is not limited to this, and the optical communication method and the radio wave communication method are different. You may implement | achieve using a communication means.
Further, in the above-described embodiment, the case where the power supply destination of the lens 200 is the AF driving unit 209, the camera shake prevention driving unit 210, the aperture driving unit 211, the backup charging unit 212, and the power receiving side microcomputer control unit 201 has been described. However, depending on the type of lens, one or more of the AF driving unit 209, the camera shake preventing driving unit 210, the aperture driving unit 211, the backup charging unit 212, and the power receiving side microcomputer control unit 201 may be used. Other power supply destinations may be added. In this case, the power supply destination related information corresponding to the power supply destination is stored in the lens.

  The present invention can also be realized by executing the following processing. That is, a program that realizes the functions of the above-described embodiments is supplied to the camera body 100 or the lens 200 via various storage media, and the computer (such as a microcomputer control unit) of the camera body 100 or the lens 200 reads the program. It is a process to be executed.

  DESCRIPTION OF SYMBOLS 10: Imaging device 101: Power transmission side microcomputer control part 102: Communication control part 103: Power transmission control part 104: Main battery part 105: Power transmission circuit 106: Pulse generation circuit 107: Power transmission part 201: Power receiving side microcomputer control part 202: Communication control Unit 203: power reception control unit 204: power reception circuit 205: rectifier circuit 206: power supply destination switching unit 207: power generation circuit 208: power reception unit 209: AF drive unit 210: camera shake prevention drive unit 211: aperture drive unit 212: backup charging unit 213: Backup battery unit

Claims (14)

An imaging device capable of mounting an interchangeable lens and supplying power to the mounted lens in a non-contact manner,
Receiving means for receiving, from the mounted lens, power supply destination related information in which a power supply destination of the lens and power required by the power supply destination are associated;
Reference to the power supply destination-related information received by the receiving means and generating a power required in accordance with the operation state of the lens, have a, a power transmission means for transmitting to the lens,
The power transmission means is required to charge the backup battery unit by the backup charging means as the power supply destination of the lens with reference to the power supply destination related information according to the transition of the imaging device to the low power consumption mode An image pickup apparatus that generates electric power to be transmitted to the lens . Generating means for generating a power supply destination switching instruction command for switching the power supply destination of the lens according to the operating state of the lens;
The imaging apparatus according to claim 1, further comprising: a transmission unit that transmits a power supply destination switching instruction generated by the generation unit to the lens. A modulation unit that modulates the power supply destination switching instruction command generated by the generation unit according to the power transmitted by the power transmission unit;
The imaging apparatus according to claim 2, wherein the power transmission unit transmits a power supply destination switching instruction command modulated by the modulation unit. In the power supply destination related information, a standby time is associated with the backup charging unit as a power supply destination of the lens,
The power transmission means responds to the elapse of the standby time associated with the backup charging means in the power supply destination related information after stopping the power transmission by completing the charging of the backup battery unit by the backup charging means. Te, wherein generating the power required for the backup charging means for charging the backup battery unit, the imaging apparatus according to any one of claims 1 to 3, characterized in that power transmission to the lens. Power supply destination of the lens, the power-receiving-side microcomputer control unit for controlling the lens, AF driving unit, claims 1, characterized in that it comprises at least one of the image stabilizing drive and diaphragm driver either 4 The imaging apparatus of Claim 1. An interchangeable lens that can be attached to an imaging device and is supplied with power from the attached imaging device in a non-contact manner,
Information relating the power supply destination and the power required at the power supply destination, the power supply destination related information used for generating the power supplied to the lens is transmitted to the imaging device, communicates means for receiving an instruction,
Power receiving means for receiving the power generated by the imaging device based on the power supply destination related information and the operating state of the lens;
Rechargeable backup battery,
As power supply destination of the lens, it has a, and a backup charging means for charging the backup battery unit,
When receiving an instruction to shift to the low power consumption mode from the imaging device by the communication unit, after the power receiving unit stops charging by completing the charging to the backup battery unit by the backup charging unit, The lens is driven by electric power charged by the backup battery unit . Receiving means for receiving a power supply destination switching instruction command for switching the power supply destination of the lens according to the operating state of the lens from the imaging device;
The lens according to claim 6 , further comprising: a power supply destination switching unit that switches a power supply destination that supplies the power received by the power reception unit based on a power supply destination switching instruction command received by the reception unit. The lens according to claim 6 or 7 , wherein a standby time is associated with the backup charging unit as a power supply destination of the lens in the power supply destination related information. Power supply destination of the lens, the power-receiving-side microcomputer control unit for controlling the lens, AF driving unit, 6 to claim, characterized in that it comprises at least one of the image stabilizing drive and diaphragm driver either 8 The lens according to item 1. A power transmission device in which power is supplied from a power transmission device to a power reception device in a contactless manner,
The power transmission device is:
Receiving means for receiving power supply destination related information in which a power supply destination of the power reception device and power required by the power supply destination are associated from the attached power reception device;
The power supply destination-related information received by the receiving means by referring to the generated power to be required depending on the operating state of the power receiving device, have a, a power transmission means for transmitting to the receiving device,
The power transmission means refers to the power supply destination related information according to the transition of the power transmission apparatus to the low power consumption mode, and charges the backup battery unit by the backup charging means as the power supply destination of the power receiving apparatus. An electric power transmission apparatus that generates necessary electric power and transmits the electric power to the power receiving apparatus. A control method for an imaging apparatus that can be mounted with an interchangeable lens and supplies power to the mounted lens in a non-contact manner,
A receiving step of receiving power supply destination related information in which a power supply destination of the lens and power required by the power supply destination are associated from the mounted lens;
A generation step of generating power required according to the operating state of the lens with reference to the power supply destination related information received by the reception step;
The generated power have a, a transmission step of transmitting to the lens,
In the generation step, it is necessary to charge the backup battery unit by the backup charging means as the power supply destination of the lens with reference to the power supply destination related information according to the transition of the imaging device to the low power consumption mode A method for controlling an imaging apparatus, characterized by generating power as follows. A control method for an interchangeable lens that is attachable to an imaging device and is supplied with power from the attached imaging device in a non-contact manner,
Information relating the power supply destination and the power required at the power supply destination, the power supply destination related information used for generating the power supplied to the lens is transmitted to the imaging device, It communicates receiving an instruction,
A power receiving step of receiving power generated by the imaging device based on the power supply destination related information and the operating state of the lens;
As power supply destination of the lens, it has a, and a backup charging step of charging the backup battery unit,
When receiving the instruction to shift to the low power consumption mode from the imaging device by the communication step, after the power reception of the power reception step is stopped by completing the charging to the backup battery unit by the backup charging step, A lens control method, wherein the lens is driven by electric power charged by the backup battery unit . A program for controlling an imaging device that can be mounted with an interchangeable lens and supplies power to the mounted lens in a non-contact manner,
In the computer of the imaging device,
A receiving step of receiving power supply destination related information in which a power supply destination of the lens and power required by the power supply destination are associated from the mounted lens;
A generation step of generating power required according to the operating state of the lens with reference to the power supply destination related information received by the reception step;
Transmitting the generated power to the lens ; and
In the generation step, it is necessary to charge the backup battery unit by the backup charging means as the power supply destination of the lens with reference to the power supply destination related information according to the transition of the imaging device to the low power consumption mode A program characterized by generating electric power . A program for controlling an interchangeable lens that can be attached to an imaging device and is supplied with power from the attached imaging device in a non-contact manner,
In the lens computer,
Information relating the power supply destination and the power required at the power supply destination, the power supply destination related information used for generating the power supplied to the lens is transmitted to the imaging device, It communicates receiving an instruction,
A power receiving step of receiving power generated by the imaging device based on the power supply destination related information and the operating state of the lens;
As a power supply destination of the lens, a backup charging step of charging a backup battery unit is performed ,
When receiving the instruction to shift to the low power consumption mode from the imaging device by the communication step, after the power reception of the power reception step is stopped by completing the charging to the backup battery unit by the backup charging step, A program that is driven by electric power charged by the backup battery unit .

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