JP2010026502A - Imaging apparatus and camera system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an imaging apparatus capable of reducing power consumption thereof, and of accurately maintaining the focused state with respect to an object, as necessary. <P>SOLUTION: The imaging apparatus includes: an optical system including a focus lens; a driving means for driving the focus lens; a supply means for supplying power to the driving means; a setting means for setting a power supply mode for specifying a method of supplying power to the driving means; and a control means for controlling the power supply from the supply means to the driving means. When a predetermined power supply mode is set, the control means determines according to a magnitude of a depth of field of the optical system whether the holding power for holding the state of the focus lens is supplied to the driving means, when the focus lens is stopped, and controls the supply of the holding power to the driving means, according to the result of the determination. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an imaging apparatus such as a digital still camera or a digital video camera having a driving unit capable of driving a focus lens.

  A conventional digital camera includes a motor (actuator) that drives a zoom lens, a focus lens, a diaphragm, and the like (see, for example, Patent Document 1). Such digital cameras have been proposed in which various factors such as motor driving sound, maximum operating speed, stop position accuracy, and power consumption are improved.

  In order to save power in the digital camera, it is conceivable that no electric power is supplied to a motor that is not driven. However, if electric power is not supplied to a motor provided in a general digital camera, the rotor cannot be stopped at a desired position, and the lens or the like cannot be controlled at a desired position. This will be described below using a stepping motor as an example.

  FIG. 12 shows a sectional view of the stepping motor. The stepping motor includes a rotor 10 made of a magnet and a stator 20 provided with an electromagnet. The stepping motor applies a current to the stator winding 22 to generate a magnetic field, and rotates the rotor 10 by attractive force generated between the magnetic field and the magnet of the rotor 10.

  In a stepping motor that drives a movable lens by micro-step driving, the current conduction to the stator winding 22 is not simply turned ON / OFF, but the ratio of the current flowing in two adjacent windings is finely controlled. Thus, the position of the rotor 10 is finely controlled. For this reason, if no current is supplied to the stator winding 22 of the stepping motor, a magnetic field is not generated in the stator winding 22, and the rotor 10 cannot be held at a desired position. For example, when power is supplied to the stator winding 22 and the rotor 10 is in a desired position (FIG. 12A), when the power supply is stopped, the rotor 10 is shifted from the desired position. To stop (FIG. 12B). Hereinafter, this operation will be specifically described. The electromagnet portion 24 that has generated a magnetic field by supplying current to the stator winding 22 is magnetized by the magnetic force of the rotor 10 when no current is supplied to the stator winding 22. Thereby, an attractive force is generated between the electromagnet portion 24 and the rotor (magnet) 10, and the rotor 10 moves to a predetermined position (stable point). That is, as shown in FIG. 12A, when the current to the stator winding 22 is no longer supplied to the adjacent electromagnet portion 24 that has been magnetized at a predetermined ratio, the magnetic force of the magnet of the rotor 10 is used. Magnetized evenly. Therefore, as shown in FIG. 12B, the rotor 10 stops at an intermediate position between the two adjacent electromagnet portions 24. This stop position is a stable point.

  FIG. 13 is a diagram illustrating a configuration of a driving unit that drives the focus lens by the stepping motor. As shown in FIG. 13A, when power is supplied to the stepping motor 33 that drives the focus lens 31 (when excitation is ON), the focus lens 31 is stopped at a desired stop position. On the other hand, when power is not supplied to the stepping motor 33 (when excitation is OFF), the focus lens 31 is stopped at a position shifted from a desired stop position as shown in FIG. That is, in such a motor, when the power to the motor is not supplied, the accuracy of the lens stop position is deteriorated.

JP 2008-92619 A

  In general, compact type digital cameras require accuracy of the focus lens stop position during still image shooting. Therefore, while the excitation is turned on, the focus lens stop position accuracy is not used during still image shooting. Therefore, control to turn off excitation is performed. As described above, in this compact digital camera, when the accuracy of the stop position of the focus lens is unnecessary, power supply to the drive member is stopped to save power.

  However, even in such a digital camera, the accuracy of the stop position of the focus lens may be required during moving image shooting. For example, when the zoom lens is driven to the telephoto side and the diaphragm is driven to the open side, the depth of field is shallow. In such a case, if the accuracy of the stop position of the focus lens is poor, the subject is not focused, and a moving image that is out of focus is captured.

  Also, the accuracy of the stop position of the focus lens may be required even during movie shooting. For example, this is a case where the digital camera displays image data generated by the image sensor on the liquid crystal monitor as a through image (during live view). In this case as well, a moving image that is out of focus is captured, and a through image that is out of focus is displayed.

  In addition, even in a digital camera system including an interchangeable lens and a camera body, the depth of field can be reduced in the interchangeable lens as compared with a compact type digital camera. Problems are likely to occur.

  In order to solve the above-described problems, an object of the present invention is to provide an imaging apparatus capable of accurately maintaining a focused state with respect to a subject as necessary while reducing power consumption of the imaging apparatus.

  In the first aspect, an imaging apparatus having the following configuration is provided. The imaging apparatus sets an optical system including a focus lens, a drive unit that drives the focus lens, a control unit that controls supply of power to the drive unit, and a power supply mode that defines a power supply method to the drive unit Setting means. When a predetermined power supply mode is set, the control means drives holding power for holding the state of the focus lens according to the depth of field of the optical system when the focus lens is stopped. It is determined whether or not to supply to the means, and the holding power supply to the driving means is controlled according to the determination result.

  With this configuration, when the imaging apparatus is set to a predetermined mode, for example, the power saving mode, when holding the focus lens and waiting, whether to supply the holding power to the driving unit according to the depth of field. Can be controlled.

  In a second aspect, a camera system including an interchangeable lens and a camera body is provided. The camera body includes a supply unit that supplies power to the interchangeable lens, a setting unit that sets a power supply mode that defines a power supply method, and a transmission unit that transmits setting information indicating the set power supply mode to the interchangeable lens. Is provided. The interchangeable lens includes an optical system including a focus lens, a drive unit that receives power from the supply unit and drives the focus lens, and a control unit that controls supply of power to the drive unit. The control means maintains the focus lens state according to the depth of field of the optical system when the focus lens is stopped when a predetermined power supply mode is set according to the setting information from the camera body. It is determined whether or not the holding power to be supplied is supplied to the driving means, and the supply of the holding power to the driving means is controlled according to the determination result.

  In a third aspect, an interchangeable lens that can be attached to a camera body is provided. The interchangeable lens is in accordance with an optical system including a focus lens, a drive unit that receives power from the camera body to drive the focus lens, a control unit that controls supply of power to the drive unit, and a control from the camera body. Setting means for setting a power supply mode that defines a power supply method to the drive means. The control means holds the state of the focus lens according to the depth of field of the optical system when the focus lens is stopped when a predetermined power supply mode is set by the camera body. It is determined whether or not power is supplied to the driving means, and the holding power supply to the driving means is controlled according to the determination result.

  When the imaging apparatus according to the present invention is set to a predetermined mode and stops the focus lens and waits, it determines whether to supply holding power to the driving unit according to information about the depth of field of the optical system. Then, the holding power is supplied to the driving means. Accordingly, it is possible to accurately maintain the focused state with respect to the subject as necessary while reducing power consumption in the imaging apparatus.

1 is a perspective view of a digital camera according to Embodiment 1. FIG. 1 is a block diagram illustrating a configuration example of a digital camera according to Embodiment 1. (A) The figure for demonstrating the setting information transmitted according to the control mode or control state of the camera main body of Embodiment 1, (b) The electric power supply set according to the control state of a camera system is demonstrated. Illustration for FIG. 6 is a diagram for determining whether to hold power to the focus drive unit according to setting information acquired by the interchangeable lens according to the first embodiment. The figure for judging whether holding electric power is supplied to a focus drive part according to the information about the depth of field of an embodiment Flowchart for explaining an operation example of the camera body of the embodiment Flowchart for explaining an operation example of the interchangeable lens of the embodiment (A) The figure explaining the power supply to the focus lens drive part in holding power ON setting, (b) The figure explaining the power supply to the focus lens drive part in holding power OFF setting Flowchart for explaining an operation example of the interchangeable lens of the embodiment Flowchart for explaining an operation example of the interchangeable lens of the embodiment The flowchart for demonstrating the operation example of the camera main body which concerns on other embodiment. (A) The figure for demonstrating the state inside a stepping motor when holding electric power is supplied with respect to a stepping motor, (b) The state inside a stepping motor when not supplying holding electric power with respect to a stepping motor is demonstrated. Illustration for (A) The figure for demonstrating the stop position of a focus lens when holding electric power is supplied with respect to a stepping motor, (b) The stop position of a focus lens when holding electric power is not supplied with respect to a stepping motor is demonstrated. Illustration to do

  Embodiments of the present invention will be described below with reference to the accompanying drawings.

(Embodiment 1)
1. Configuration 1-1 Overview of Overall Configuration FIG. 1 is a perspective view of a digital camera according to an embodiment. FIG. 2 is a hardware configuration diagram of the digital camera according to the embodiment.

  The digital camera 1 according to the present embodiment includes a camera body 2 and an interchangeable lens 3 that can be attached to and detached from the camera body 2.

  The camera body 2 includes a CMOS sensor 201, a mechanical shutter 202, a signal processor 203 (DSP), a buffer memory 204, a liquid crystal monitor 205, an electronic viewfinder 206 (EVF), a power supply 207, a body mount 208, a flash memory 209, and a card slot 210. CPU 211, shutter switch 212, strobe 213, microphone 214, and speaker 215.

  The interchangeable lens 3 includes a lens mount 301, a zoom lens 303, a focus lens 304, an optical system including an OIS lens 305, a focus drive unit 306 that drives the focus lens 304, an OIS drive unit 320 that drives the OIS lens 305, and an aperture 307. A diaphragm drive unit 308 that drives the diaphragm 307, a zoom ring 309, a focus ring 310, a lens controller 311, a buffer memory 312, a zoom lens position detector 313, a flash memory 314, and a gyro sensor 330.

1-2 Configuration of Camera Body The camera body 2 is configured to capture a subject image condensed by the optical system of the interchangeable lens 3 and record the captured image data in a storage medium.

  The CMOS sensor 201 includes a light receiving element, an AGC (gain control amplifier), and an AD converter. The light receiving element converts the optical signal collected by the optical system into an electrical signal, and generates image data. The AGC amplifies the electrical signal output from the CMOS sensor 201. The AD converter converts the electrical signal output from the CMOS sensor 201 into a digital signal. The CMOS sensor 201 performs various operations such as exposure, transfer, and electronic shutter according to the control signal received from the CPU 211. These various operations can be realized by a timing generator or the like.

  The mechanical shutter 202 switches between blocking and passing an optical signal incident on the CMOS sensor 201 that is incident through the optical system. The mechanical shutter 202 is driven by a mechanical shutter driving unit. The mechanical shutter drive unit includes mechanical parts such as a motor and a spring, and drives the mechanical shutter 202 under the control of the CPU 211. In short, the mechanical shutter 202 is opened and closed to adjust the amount of light hitting the CMOS sensor 201 over time.

  A signal processor (DSP) 203 performs predetermined image processing on the image data converted into a digital signal by the AD converter. Examples of the predetermined image processing include gamma conversion, YC conversion, electronic zoom processing, compression processing, and expansion processing, but are not limited thereto.

  The buffer memory 204 functions as a work memory when the signal processor 203 performs processing and when the CPU 211 performs control processing. The buffer memory 204 can be realized by, for example, a DRAM.

  The liquid crystal monitor 205 is disposed on the back surface of the camera body 2 and can display image data generated by the CMOS sensor 201 or image data obtained by performing predetermined processing on the image data. When the image signal input to the liquid crystal monitor 205 is output from the signal processor 203 to the liquid crystal monitor 205, the digital signal is converted into an analog signal by the DA converter.

  The electronic viewfinder 206 is arranged in the camera body 2 and can display image data generated by the CMOS sensor 201 or image data obtained by performing predetermined processing on the image data. Similarly, when an image signal input to the electronic viewfinder 206 is output from the signal processor 203 to the electronic viewfinder 206, the digital signal is converted from an analog signal by a DA converter.

  Display on the liquid crystal monitor 205 and the electronic viewfinder 206 is switched by the display switching means 217. That is, nothing is displayed on the electronic viewfinder 206 while an image is displayed on the liquid crystal monitor 205. Further, while the image is displayed on the electronic viewfinder 206, nothing is displayed on the liquid crystal monitor 205. The display switching unit 217 can be realized by a physical structure such as a changeover switch, for example. For example, when the signal processor 203 and the liquid crystal monitor 205 are electrically connected, the electrical connection between the signal processor 203 and the liquid crystal monitor 205 is disconnected by switching the changeover switch, and the signal processor 203 And the electronic viewfinder 206 are electrically connected. The display switching unit 217 may switch the display to the liquid crystal monitor 205 and the electronic viewfinder 206 based on a control signal from the CPU 211 or the like.

  As described above, the display on the liquid crystal monitor and the display on the electric viewfinder are switched. However, since this is a problem due to structural limitations, the display on the liquid crystal monitor and the display on the electronic viewfinder may be performed simultaneously. When displaying simultaneously, the image displayed on the liquid crystal monitor and the image displayed on the electronic view funder may be the same image or different images.

  The power source 207 supplies power to be consumed by the digital camera 1. The power source 207 may be, for example, a dry battery or a rechargeable battery. Further, the power source 207 may supply electric power supplied from outside via a cord to the digital camera 1.

  The body mount 208 is a member that enables the interchangeable lens 3 to be attached and detached together with the lens mount 301 of the interchangeable lens 3. The body mount 208 can be electrically connected to the interchangeable lens 3 using a connection terminal or the like, and can also be mechanically connected by a mechanical member such as a locking member. The body mount 208 can output a signal from the lens controller 311 included in the interchangeable lens 3 to the CPU 211 and can output a signal from the CPU 211 to the lens controller 311 of the interchangeable lens 3. That is, the CPU 211 can transmit and receive control signals, information on the optical system, and the like with the lens controller 311 on the interchangeable lens 3 side. In addition, the body mount 208 supplies the power supplied from the power source 207 to the lens controller 311. Thereby, the body mount 208 supplies power consumed in the interchangeable lens 3.

  The flash memory 209 is a storage medium used as a built-in memory. The flash memory 209 can store image data or image data obtained by performing predetermined processing on the image data. Also, digitized audio signals can be stored. In addition, it is possible to store programs and set values for controlling the CPU 211 in addition to image data and audio signals.

  The card slot 210 is a slot for attaching / detaching a memory card 218 as a storage medium. The memory card 218 can store image data or image data obtained by performing predetermined processing on the image data. Also, digitized audio signals can be stored.

  The CPU 211 controls the entire camera body 2. The CPU 211 may be realized by a microcomputer or a hard wired circuit. That is, the CPU 211 performs various controls. For various controls, 2-1. It describes in.

  The shutter switch 212 is a button provided on the upper surface of the camera body 2 and detects half-pressing and full-pressing operations from the user. When the shutter switch 212 receives a half-press operation from the user, the shutter switch 212 outputs a half-press signal to the CPU 211. On the other hand, the shutter switch 212 outputs a full-press signal to the CPU 211 when a full-press operation is received from the user. Based on these signals, the CPU 211 performs various controls. In the present embodiment, the full press signal is a shooting start signal.

  The strobe 213 irradiates the subject with light based on a control signal from the CPU 211. For example, the strobe 213 can be realized using a xenon lamp, a condenser, or the like. When configured in this manner, the strobe 213 accumulates high-voltage charges in a capacitor and applies the charges to the xenon lamp electrode to irradiate light.

  The microphone 214 converts sound into an electrical signal. The electrical signal output from the microphone 214 is converted into a digital signal by an AD converter. The digital signal converted by the AD converter is stored in the flash memory 209 or the memory card 218 under the control of the CPU 211.

  The speaker 215 converts an electrical signal into sound. The electric signal input to the speaker 215 is a signal converted from a digital signal to an electric signal by a DA converter. As the output to the DA converter, a digital signal read from the flash memory 209 or the memory card 218 is output under the control of the CPU 211.

  The mode switching dial 221 is an operation member attached to the outside of the camera body 2. The mode switching dial 221 is formed in a substantially circular shape, and allows one control mode to be selected from a plurality of control modes by a turning operation by a user. That is, the mode switching dial 211 can detect the control mode moved to a predetermined position so that one of a plurality of control modes can be selected. The plurality of control modes include “still image shooting mode”, “moving image shooting mode”, “playback mode”, and the like. For example, when an image indicating “still image shooting mode” described on the upper surface of the mode switching dial is moved to a predetermined position (selected position), the mode switching dial 221 is changed to “still image shooting mode”. A mode switching signal indicating this is output to the CPU 211. As a result, the switching of the control mode can be detected.

1-3 Configuration of Interchangeable Lens The optical system includes a zoom lens 303, a focus lens 304, an OIS lens 305, and an objective lens 302, and collects light from the subject. The zoom lens 303 is driven by the zoom ring 309 and adjusts the zoom magnification. The focus lens 304 is driven by the focus driving unit 306 or the focus ring 310 to adjust the focus. The OIS lens 305 is driven by the OIS driving unit 320. The focus lens 304, the zoom lens 303, and the OIS lens 305 are movable lenses.

  Here, the OIS lens 305 is movable in a plane perpendicular to the optical axis of the optical system. By moving the OIS lens 305 in a plane perpendicular to the optical axis of the optical system, the optical axis of the optical system can be bent. By moving the OIS lens 305 in a direction that cancels the blur of the digital camera 1 detected by the OIS drive unit 320 described later, image blur due to the blur of the digital camera 1 can be prevented.

  The focus driving unit 306 drives the focus lens 304 according to the control of the lens controller 311. In the present embodiment, an example is described in which the focus driving unit 306 is realized by a stepping motor and a driver. The focus driving unit 306 is configured to drive the focus lens 304 when power is supplied from the lens controller 311. The focus driving unit 306 stops the focus lens 304 at a desired position when power is supplied from the lens controller 311. On the other hand, when power is not supplied from the lens controller 311, the focus driving unit 306 stops the focus lens 304 at a position with a lower accuracy than a desired position. In short, the focus drive unit 306 differs in the accuracy of the stop position when the focus lens 304 is stopped and held depending on whether the power is supplied from the lens controller 311 or not. The focus driving unit 306 can stop the focus lens 304 at a desired position more finely (with higher accuracy) when power is supplied than when power is not supplied.

  Here, the focus driving unit 306 stops the focus lens 304 at a desired position when power is supplied, but it is not necessary to stop the focus lens 304 at a strict position. That is, the focus driving unit 306 may be anything that can stop the focus lens 304 with higher accuracy than the accuracy of the position where the focus lens 304 is stopped when power is not supplied from the lens controller 311.

  The OIS driving unit 320 drives the OIS lens 305 according to the control of the lens controller 311 based on the output of the gyro sensor 330. The optical image blur correction function can be realized by the gyro sensor 330, the lens controller 311, the OIS driving unit 320, and the OIS lens 305. The gyro sensor 330 detects the movement angular velocity of the digital camera 1. The lens controller 311 calculates the angular velocity of the digital camera 1 by integrating the angular velocity detected by the OIS driving unit 320. This is the amount of blurring of the digital camera 1. Then, the lens controller 311 instructs the OIS drive unit 320 to cancel the movement of the digital camera 1 and drive the OIS lens 305 so that the subject image does not move on the CMOS sensor 201 as much as possible. The OIS driving unit 320 drives the OIS lens 305 in accordance with this instruction. As described above, the OIS lens 305 can bend the optical axis of the optical system by moving in the plane perpendicular to the optical axis of the optical system. Thereby, it is possible to prevent the subject image from moving on the CMOS sensor 201 as much as possible.

  The diaphragm 307 adjusts the amount of light passing through the optical system. For example, the light can be adjusted by increasing or decreasing the opening formed by five blades or the like.

  The diaphragm drive unit 308 changes the size of the opening of the diaphragm 307. In the first embodiment, the size of the opening of the diaphragm 307 is changed based on the control of the lens controller 311. Here, the size of the opening can be designated by the F value. The diaphragm driving unit 308 drives the diaphragm 307 based on the control from the lens controller 311. However, the diaphragm driving unit 308 is not limited to this and may be driven by a mechanical method.

  Note that the aperture driving unit 308 includes an encoder that detects the size (position) of the aperture of the aperture and outputs it as an AV (Aperture Value) value (information regarding brightness). The aperture driving unit 308 outputs the AV value to the lens controller 311. AV values output from the aperture driving unit 308 are, for example, AV0 to AV5.

  The zoom ring 309 is provided outside the interchangeable lens 3 and drives the zoom lens 303 in accordance with a user operation. The zoom ring 309 mechanically drives the zoom lens 303 when rotated by the user.

  The focus ring 310 is provided outside the interchangeable lens 3 and drives the focus lens 304 in accordance with an operation from the user. When the focus ring 310 is rotated by the user, the sliding resistance detects the operation, and a signal related to the operation is input to the lens controller 311. The lens controller 311 controls the focus driving unit 306 in accordance with the input operation related signal. As a result, the focus driving unit 306 drives the focus lens 304.

  The lens controller 311 controls the entire interchangeable lens 3. The lens controller 311 may be realized by a microcomputer or a hard wired circuit. That is, the lens controller 311 executes various controls. Various controls of the lens controller 311 are described in section 2-2.

  The buffer memory 312 functions as a work memory when the lens controller 311 performs control processing. The buffer memory 312 can be realized by, for example, a DRAM.

  The flash memory 314 is configured to be electrically connected to the lens controller 311. The flash memory 314 can store control programs, parameters, and the like.

  The zoom lens position detector 313 acquires information regarding the zoom position of the zoom lens 303. Specifically, the zoom position indicates the position of the zoom lens 303 specified for each region obtained by dividing the movable range of the zoom lens 303 into a plurality of parts. The lens controller 311 periodically acquires information regarding the zoom position detected by the zoom lens position detector 313.

  The zoom lens position detector 313 is configured by a sliding resistance or the like, and detects information related to the zoom position of the zoom lens 303 with a voltage value. In addition, the lens controller 311 periodically reads out the voltage value detected by the zoom lens position detector 313, and AD-converts this voltage value to acquire information (digital data) regarding the 256 zoom positions. . In the present embodiment, information related to the zoom position divided into six parts is used in order to simplify the description.

1-4 Correspondence of Terms The digital camera 1 is an example of an imaging device or a camera system. The focus driving unit 306 is an example of a driving unit. The CPU 211 and the lens controller 311 are examples of setting means and control means. The power source 207 is an example of a supply unit. The combination of the CPU 211 and the body mount 208 is an example of a transmission unit.

2. Control in Camera Body and Interchangeable Lens Control of the camera system configured as described above will be described in detail below.

2-1. Control of CPU of Camera Body The camera system 1 of the present embodiment can be set as a control mode in a moving image shooting mode for shooting a moving image, a still image shooting mode for shooting a still image, a playback mode for reproducing an image, or the like. The power supply modes set for the interchangeable lens 3 include a standard mode and a power saving mode that reduces power consumption compared to the standard mode. FIG. 3A shows the correspondence between the control modes set in the camera body 2 and the power supply set in each control mode. In the standard mode, even when the focus lens 304 is not driven, the power supply to the focus driving unit 306 is continued. On the other hand, in the power saving mode, when the focus lens 304 is not driven, the supply of power to the focus driving unit 306 is stopped, thereby saving power.

  Based on the relationship shown in FIG. 3A, the CPU 211 of the camera body 2 determines whether or not the interchangeable lens 3 needs to be set in the power saving mode according to the control mode set in the camera body 2. . For example, when the CPU 211 determines that the interchangeable lens 3 needs to be set in the power saving mode, the CPU 211 transmits control information for controlling the power saving mode to the interchangeable lens 3.

  The control mode is selected by the user with the mode switching dial 221. When the mode selected by the mode switching dial 221 is the moving image shooting mode or the playback mode, the CPU 211 determines that it is necessary to set the power saving mode. This is because the moving image shooting mode or the playback mode does not require the accuracy of the stop position of the focus lens compared to the still image shooting mode. On the other hand, when the mode selected by the mode switching dial 221 is the still image shooting mode, the CPU 211 determines that it is necessary to set the standard mode.

  As described above, the CPU 211 transmits setting information indicating whether or not it is necessary to set the power saving mode to the lens controller 311. Specifically, when the CPU 211 determines that the power saving mode needs to be set, the CPU 211 transmits setting information indicating the power saving mode to the lens controller 311. On the other hand, when determining that it is not necessary to set the power saving mode, the CPU 211 transmits setting information indicating the standard mode to the lens controller 311. The lens controller 311 performs power control according to the setting information.

2-2. Control of Lens Controller of Interchangeable Lens In the interchangeable lens 3, the lens controller 311 receives setting information indicating the power saving mode or the standard mode from the CPU 211. In addition, the lens controller 311 sets the interchangeable lens 3 to the power saving mode or the standard mode according to the received setting information.

  Further, as shown in FIG. 4, the lens controller 311 has power for holding the position of the focus lens 304 in the focus driving unit 306 in accordance with the power setting (standard mode) (hereinafter referred to as “holding power”). Decide whether to supply.

  That is, when the standard mode is set, the lens controller 311 supplies holding power for holding the position of the focus lens 304 to the focus driving unit 306. On the other hand, when the power saving mode is set, the lens controller 311 determines whether to supply the holding power to the focus driving unit 306 according to the depth of field of the optical system when holding the focus lens 304 at the stopped position. To decide.

  When the lens controller 311 determines that the holding power is supplied to the focus driving unit 306, the lens controller 311 supplies the holding power to the focus driving unit 306 when the focus lens 304 is stopped to hold the position. At this time, the lens controller 311 supplies the power supplied from the body mount 208 to the focus driving unit 306 as holding power.

  The control of the lens controller 311 will be specifically described. When receiving the setting information indicating the power saving mode or the standard mode from the CPU 211 of the camera body 2, the lens controller 311 stores the setting information in the buffer memory 312. The lens controller 311 sets the interchangeable lens 3 to the power saving mode or the standard mode according to the setting information.

  The lens controller 311 supplies holding power to the focus driving unit 306 when the setting information stored in the buffer memory 312 indicates the standard mode. On the other hand, when the setting information stored in the buffer memory 312 indicates the power saving mode, the lens controller 311 determines supply / stop of holding power in consideration of the depth of field of the optical system. When the depth of field is deep, the holding power is not supplied, and even if the stop position of the focus lens 304 is slightly deviated, there is little influence on the in-focus state, so the image quality is not affected. However, when the depth of field is shallow, if the stop position of the focus lens 304 is shifted because no holding power is supplied, an in-focus state cannot be obtained immediately, and image quality deteriorates. As described above, when the depth of field is deep, there is no problem even if the holding power is not supplied. However, when the holding power is not supplied when the depth of field is shallow, the image quality may be deteriorated. Therefore, in the present embodiment, the supply / stop of the holding power is determined in consideration of the depth of field.

  Specifically, the lens controller 311 acquires information regarding the zoom position of the zoom lens 303 and the AV value of the diaphragm 307 as information regarding the depth of field of the optical system. Information regarding the zoom position can be acquired based on information output from the zoom lens position detector 313. Further, the AV value can be acquired based on information output from the aperture driving unit 308. The depth of field is obtained from the zoom position of the zoom lens 303 and the AV value of the aperture 307, and it is determined whether to hold power (ON) or stop (OFF) for each obtained depth of field. FIG. 5 shows table information indicating the relationship between the zoom position of the zoom lens 303, the AV value of the diaphragm 307, and the supply (ON) / stop (OFF) of the holding power.

  The lens controller 311 refers to the table information shown in FIG. 5 and determines whether to hold the holding power to the focus driving unit 306 based on the acquired information. For example, when the zoom position is “3” and the AV value is “2” (when the depth of field is shallow), the excitation is turned on and it is determined to supply the holding power to the focus driving unit 306.

  When the lens controller 311 determines that the holding power is supplied to the focus driving unit 306, the lens controller 311 supplies the holding power to the focus lens 304 when the focus lens 304 is put on standby at the stop position. On the other hand, when the lens controller 311 determines not to supply holding power to the focus driving unit 306, the lens controller 311 does not supply holding power to the focus lens 304 when waiting at the stop position of the focus lens 304. Note that not supplying holding power to the focus lens 304 means that continuous supply of holding power is stopped. That is, the lens controller 311 may supply temporary holding power while the focus lens 304 is stopped and then waited.

3. Operation The operation of the digital camera 1 configured as described above will be described with reference to the flowcharts of FIGS. In the following description, it is assumed that the interchangeable lens 3 is attached to the camera body 2. The camera body 2 starts the following operation when the power is turned on.

First, the operation of the camera body 2 will be described using the flowchart of FIG.
When the power source of the camera body 2 is turned on or the control mode is changed (S11), the CPU 211 determines whether or not the control mode is set to the moving image shooting mode or the playback mode (S12). When the power of the camera body 2 is turned on, the CPU 211 detects the control mode selected by the mode switching dial 221. Then, the CPU 211 stores the control mode detected by the mode switching dial 221 in the buffer memory 204 as information regarding the control mode. Thereby, the CPU 211 can control each part of the camera body 2 in accordance with the stored information regarding the control mode.

  Returning to FIG. 6, when the CPU 211 determines in step S12 that the moving image shooting mode or the playback mode is set, the CPU 211 transmits setting information indicating the power saving mode to the lens controller 311 (S13). On the other hand, if it is determined in step S12 that neither the moving image shooting mode nor the playback mode is set, the CPU 211 transmits setting information indicating the standard mode to the lens controller 311 (S14).

  Thereafter, when the control mode is changed by the mode switching dial 221, the above process is repeated.

Next, the operation of the interchangeable lens 3 will be described with reference to the flowcharts of FIGS.
The lens controller 311 determines whether setting information indicating the power saving mode or the standard mode has been acquired (S21).

  When receiving the setting information, the lens controller 311 stores the setting information in the buffer memory 312 (S22). Thereafter, the lens controller 311 determines whether or not the received setting information indicates a power saving mode (S23).

  If the received setting information indicates the power saving mode, the lens controller 311 determines whether or not to hold the holding power to the focus driving unit 306 according to the information related to the depth of field of the optical system (S24). The specific method for this determination is as described with reference to the table of FIG. If it is determined that the holding power is supplied, the lens controller 311 performs an operation setting (hereinafter referred to as “holding power ON setting”) for supplying the holding power to the focus driving unit 306 after driving the focus lens 304 (S25). On the other hand, when it is determined that the holding power is not supplied, the lens controller 311 performs an operation setting (hereinafter referred to as “holding power OFF setting”) in which the holding power is not supplied to the focus driving unit 306 after the focus lens 304 is driven (hereinafter referred to as “holding power OFF setting”). S26).

  On the other hand, when the received setting information indicates the standard mode in step S23, the lens controller 311 performs an operation setting (holding power ON setting) that supplies holding power to the focus driving unit 306 after driving the focus lens 304. (S27).

  FIG. 8 is a diagram illustrating the power supplied to the focus drive unit 306 when the holding power ON setting and the holding power OFF setting are made. When the holding power ON is set, as shown in FIG. 8A, not only when the focus lens 304 is driven, but also when the focus lens 304 is put on standby at the stop position after the focus lens 304 is driven. Holding power is supplied to the focus driving unit 306. On the other hand, when the holding power OFF is set, as shown in FIG. 8B, when the focus lens 304 is put on standby at the stop position after the focus lens 304 is driven, power is not supplied to the focus driving unit 306. . That is, power is supplied only when the focus lens 304 is driven.

  The operation when the holding power ON setting and the holding power OFF setting are made will be described with reference to the flowchart of FIG.

  First, the lens controller 311 determines whether or not the focus lens 304 needs to be driven (S31). Here, the case where the focus lens needs to be driven refers to the case where the zoom tracking operation is required in the interchangeable lens 3 or the case where the focus lens 304 needs to be driven in accordance with a control signal from the camera body 2. It is.

  When it is determined that the focus lens 304 needs to be driven, the lens controller 311 supplies driving power to the focus driving unit 306 to drive the focus lens 304 (S32). When the holding power is supplied, the driving power may be supplied continuously from the holding power. Note that the driving power and the holding power are distinguished from each other for clarity of explanation, but strict separation is not necessary.

  After completing the driving of the focus driving unit 306, the lens controller 311 determines whether or not the holding power ON setting has been made (S33). When the holding power is set to ON, the lens controller 311 supplies the holding power to the focus driving unit 306 (S34). By supplying the holding power, the focus driving unit 306 can stop the focus lens 304 at a desired position. On the other hand, when the holding power OFF is set, the lens controller 311 does not supply holding power to the focus driving unit 306 (S35). If the holding power is not supplied, the focus driving unit 306 may stop the focus lens 304 at a position shifted from a desired position.

  When the above series of processing is completed, the process returns to step S31 and the same processing is performed thereafter.

  In the camera system 1, when the zoom lens 303 and the diaphragm 307 are driven, the depth of field of the optical system changes. In this case, it is preferable that the interchangeable lens 3 performs an operation as shown in the flowchart of FIG. 10 in consideration of the depth of field.

  When the lens controller 311 detects that the zoom lens 303 or the diaphragm 307 has been adjusted (S41), the lens controller 311 reads the setting information stored in the buffer memory 312 and determines whether the power saving mode is set (step S41). S42). If the lens controller 311 determines that the power saving mode is set, the lens controller 311 performs the process of step S43. If the lens controller 311 determines that the power saving mode is not set, the process returns to step S41.

  In step S <b> 43, the lens controller 311 includes information regarding the zoom position based on information output from the zoom lens position detector 313 as information regarding the depth of field, and an AV value based on information output from the aperture driving unit 308. To get. This acquired information is based on information output after adjusting the zoom lens 303 or the aperture driving unit 308. Then, the lens controller 311 refers to the table information in FIG. 5 based on the zoom position and the AV value (depth of field), and determines whether or not it is necessary to supply holding power (S44). If the lens controller 311 determines that the holding power needs to be supplied, the lens controller 311 performs an operation setting (holding power ON setting) to supply the holding power to the focus driving unit 306 (S45). On the other hand, when the lens controller 311 determines not to supply the holding power, the lens controller 311 performs an operation setting (holding power OFF setting) so as not to supply the holding power to the focus driving unit 306 (S46).

  With the above configuration, it is possible to determine whether or not it is necessary to supply holding power with the interchangeable lens 3 itself. For this reason, the camera body 2 can reduce the power consumption in the interchangeable lens 3 while maintaining the in-focus state of the subject only by transmitting information indicating the power saving mode.

4). Summary The digital camera 1 includes a camera body 2 and an interchangeable lens 3 that can be attached to and detached from the camera body 2. The camera body 2 includes a CPU 211 that transmits an instruction to the interchangeable lens 3. The interchangeable lens 3 includes an optical system including a focus lens 304, a focus driving unit 306 that drives the focus lens 304, and a lens controller 311 that can set the own lens in a power saving mode in response to an instruction from the camera body 2. When the lens controller 311 is set to the power saving mode and the focus lens 304 is stopped and waited, the holding power for stopping and waiting the focus lens 304 is determined according to information on the depth of field of the optical system. A lens controller 311 that determines whether to supply to the focus driving unit 306 and a lens controller 311 that supplies holding power to the focus driving unit 306 according to the determination result of the lens controller 311 are provided.

  In this way, when the power saving mode is set and the focus lens is held at the stop position, it can be determined whether or not the holding power is supplied to the focus driving unit according to the depth of field. . Therefore, when the depth of field is shallow, the holding power is supplied to the focus driving unit. On the other hand, when the depth of field is deep, it can be controlled not to supply the holding power to the focus driving unit. Therefore, when the depth of field is shallow, priority can be given to maintaining a focused state with respect to the subject, and deterioration of image quality can be prevented. On the other hand, when the depth of field is deep, reduction of power consumption can be prioritized and power saving can be achieved.

(Other embodiments)
The first embodiment of the present invention has been described above. However, the present invention is not limited to the above-described embodiment, and can be realized in other embodiments. Therefore, other embodiments will be collectively described below.

  In the above embodiment, the image sensor is constituted by a CMOS sensor. However, the imaging device is not limited to this, and may be constituted by, for example, a CCD image sensor. That is, the image sensor may have any configuration as long as it can capture a subject image and generate image data (digital signal or electric signal). Note that power consumption can be reduced when the image sensor is formed of a CMOS sensor.

  The CPU 211 in the above embodiment determines whether or not the interchangeable lens 3 needs to be set in the power saving mode in accordance with the control mode set in the camera body 2. However, the present invention is not limited to this, and it may be determined whether or not the interchangeable lens 3 needs to be set in the power saving mode in consideration of the control state (operation state) of the camera body 2. For example, when the mode selected by the mode switching dial 221 is the still image shooting mode, the CPU 211 needs to set the power saving mode depending on whether or not the shutter switch 212 is held half-pressed. It may be determined whether or not there is (see FIG. 3B). The CPU 211 determines that it is not necessary to set the interchangeable lens 3 to the power saving mode when the shutter switch 212 is held in a half-pressed state. This is because in the still image shooting mode, when the shutter switch 212 is half-pressed, the digital camera 1 starts preparation for shooting start. That is, in preparation for the start of photographing, since autofocus control is generally performed, the accuracy of the stop position of the focus lens is required. On the other hand, when the shutter switch 212 is not half-pressed, the CPU 211 determines that the interchangeable lens 3 needs to be set in the power saving mode. Thereby, power consumption can be reduced.

  A specific operation of the camera body 2 will be described with reference to the flowchart of FIG. When the still image shooting mode is set, the CPU 211 transmits setting information indicating the power saving mode to the lens controller 311 (S51). Thereafter, the CPU 211 determines whether or not the shutter switch 212 is half-pressed (S52). When the shutter switch 212 is half pressed, the CPU 211 transmits setting information indicating the standard mode to the lens controller 311 (S53). Thereafter, the CPU 211 determines whether or not the half-press of the shutter switch 212 is released (S54). When determining that the half-press of the shutter switch 212 has been released, the CPU 211 returns to step S51 and performs the same processing as described above.

  Further, in the above embodiment, the table information shown in FIG. 5 is used to evaluate the depth of field according to the zoom position and the AV value, and determine whether to supply the holding power. However, the present invention is not limited to this, and information indicating the depth of field may be calculated based on the focal length according to the position of the zoom lens, the aperture value of the stop, and the like, and the determination may be made according to this information. Further, only the zoom position or the AV value may be used as information regarding the depth of field.

  Further, in the above-described embodiment, the description has been given using the information regarding the zoom position corresponding to the focal length and the AV value corresponding to the aperture value as the information regarding the depth of field. However, the information related to the depth of field is not limited to this, and information on the focus position focused by the focus lens and the diameter of the minimum scattering circle (allowable scattering circle) can be considered.

  In the above embodiment, the driving means is configured by the focus driving unit 306 provided with the stepping motor and the driver. However, the present invention is not limited to this, and the drive unit may have any configuration as long as the focus lens is stopped at a position with different accuracy and waits depending on whether the holding power is supplied or not. Absent. Therefore, a servo motor, a synchronous motor, etc. can be used for a drive means, for example.

  That is, the present invention is not limited to the above embodiment, and can be implemented with various configurations.

  The above embodiment can be applied to a digital still camera, a digital video camera, and the like. The present invention can also be applied to a camera system including a camera body and an interchangeable lens.

Claims (10)

An optical system including a focus lens;
Driving means for driving the focus lens;
Control means for controlling the supply of power to the drive means;
Setting means for setting a power supply mode that defines a method of supplying power to the drive means;
With
The control unit is configured to maintain the state of the focus lens according to the depth of field of the optical system when the focus lens is stopped when a predetermined power supply mode is set. Determining whether to hold power to be supplied to the driving means, and controlling the supply of holding power to the driving means according to the determination result;
Imaging device.   The imaging apparatus according to claim 1, wherein the driving unit has different accuracy for holding the position of the focus lens depending on whether the holding power is supplied from the supply unit or not. The driving means includes
When holding power is supplied from the supply means, the focus lens is continuously held at the stop position,
When the holding power is not supplied from the supply means, the focus lens can be held at a position within a predetermined range from a stop position.
The imaging device according to claim 2.   2. The imaging apparatus according to claim 1, wherein in a power supply mode other than the predetermined power supply mode, the control unit performs control to supply the holding power to the driving unit when the focus lens is stopped. The optical system further includes a zoom lens and a diaphragm,
The depth of field is determined according to the position of the zoom lens and / or the aperture state of the diaphragm.
The imaging device according to claim 1.   The imaging apparatus according to claim 1, wherein the predetermined power supply mode is a mode in which power consumption of the driving unit is further reduced as compared with other power supply modes.   The imaging apparatus according to claim 1, wherein the setting unit sets a power supply mode to the predetermined power supply mode when the imaging apparatus is at the time of moving image capturing or image reproduction. A camera system including an interchangeable lens and a camera body,
The camera body is
Supply means for supplying power to the interchangeable lens;
Setting means for setting a power supply mode that defines a power supply method;
Transmission means for transmitting setting information indicating the set power supply mode to the interchangeable lens,
The interchangeable lens is
An optical system including a focus lens;
Drive means for driving the focus lens in response to power from the supply means;
Control means for controlling the supply of power to the driving means,
When the predetermined power supply mode is set according to the setting information from the camera body, the control means is configured to adjust the focus according to the depth of field of the optical system when the focus lens is stopped. It is determined whether or not holding power for holding the state of the lens is supplied to the driving unit, and the supply of holding power to the driving unit is controlled according to the determination result.
Camera system.   The camera body can set a plurality of control modes related to image recording and playback, and the setting means temporarily switches the power supply mode according to the set control mode and the control state of the camera body. The camera system according to claim 8. An interchangeable lens that can be attached to the camera body,
An optical system including a focus lens;
Drive means for receiving power from the camera body and driving the focus lens;
Control means for controlling the supply of power to the drive means;
In accordance with control from the camera body, setting means for setting a power supply mode that defines a power supply method to the drive means, and
The control means determines the state of the focus lens according to the depth of field of the optical system when the focus lens is stopped when a predetermined power supply mode is set by the camera body. It is determined whether or not holding power for holding is supplied to the driving unit, and the supply of holding power to the driving unit is controlled according to the determination result.
interchangeable lens.

Images