JP2008067174A - Camera body - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To support an image-taking element unit in which an image-taking element unit equipped with image-taking elements is exchangeable and further image blurring can be corrected. <P>SOLUTION: The image-taking element unit is equipped with: a mounting portion 213 on which the image-taking element unit 300 including the image-taking elements 307 is detachably mounted; a contact portion 210 which is electrically conductive with the image-taking element unit 300 with the image-taking element unit 300 mounted by the mounting portion 213; and a checking unit 202 which checks on via the contact portion 210, whether the image-taking element unit 300 is equipped with an image blurring correction units 305, 309, 310, 312. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a camera body in which an image sensor unit including an image sensor can be attached and detached.

2. Description of the Related Art Conventionally, a camera having a blur correction function for reducing image blur due to camera shake due to camera shake or the like (hereinafter, correction of image blur is simply referred to as blur correction) has been put into practical use. As an example, Patent Document 1 discloses a technique for correcting image blur by arranging an image pickup device so as to be swingable.
JP 2003-110919 A

On the other hand, in recent years, the performance of image sensors has been greatly improved. Therefore, in the camera using the image sensor, the image sensor portion has become obsolete earlier than the other portions. In that case, if the performance of the obsolete image sensor was not satisfied, it was necessary to replace the camera.
Also in the device described in Patent Document 1, when the image pickup device itself becomes obsolete, it is necessary to take measures such as replacing the camera.
The subject of this invention is providing the camera main body which can respond to the obsolescence of an image pick-up element, implement | achieving an image blurring correction function.

The present invention solves the above problems by the following means. In addition, in order to make an understanding easy, although it attaches | subjects and demonstrates the code | symbol etc. corresponding to embodiment of this invention, it is not limited to this.
According to the first aspect of the present invention, the image pickup unit (300) including the image pickup element (307) is detachably mountable, and the image pickup unit is mounted in the state where the image pickup element unit is mounted by the mounting unit. A contact portion (210) that can be electrically connected to the element unit, and an image blur correction unit (305, 309, 310, 312) that corrects an image blur of an image captured by the image sensor unit. It is a camera body (200) provided with the confirmation part (202) which confirms whether it is through the said contact part.
According to a second aspect of the present invention, in the camera body according to the first aspect, information on the focal length of the photographing optical system (106) attached to the camera body or the photographing optical system attached to the camera body is attached. The camera body (200) is characterized by having a focal length information transmission unit (202) that transmits to the image sensor unit (300) via the contact point (210).
According to a third aspect of the present invention, in the camera body according to the first or second aspect, information on the shooting distance to the subject is transmitted to the mounted image sensor unit (300) via the contact portion (210). The camera body (200) is characterized by having an imaging distance information transmission unit (202) for transmission.
According to a fourth aspect of the present invention, in the camera body according to any one of the first to third aspects, the camera has a release button (201) that is operated when photographing, and the release button is operated. The camera body (200) is characterized in that the camera body (200) includes a release information transmission unit (202) that transmits the fact to the mounted image sensor unit (300) via the contact point (210).
According to a fifth aspect of the present invention, in the camera body according to any one of the first to fourth aspects, when the photographing preparation operation is started (half-pressed, S504: Yes, S603: Yes), the photographing optical system (106 ) When the first operation mode (blur correction mode 1) is transmitted to the image sensor (307) and the light that has passed through the imaging optical system is not transmitted to the image sensor during the shooting preparation operation. And an operation selection unit (202, S203) for selecting and executing a second operation mode (blur correction mode 2) for transmitting light that has passed through the imaging optical system to the image sensor. A camera body (200).
According to a sixth aspect of the present invention, in the camera main body according to the fifth aspect, the operation selection unit (202, S203) is configured such that the first operation mode (blur correction mode 1) and the second operation mode (blur correction). The camera body is characterized in that switching to mode 2) is performed according to a signal obtained from the image sensor unit (300).
According to a seventh aspect of the present invention, in the camera body according to the fifth or sixth aspect, the first push-in state (half-push) and the second push-in state (full push-down) further pushed from the first push-in state And a release button (201) capable of detecting two states of the camera body, and the photographing preparation operation is started in response to the release button being in a first depressed state. (200).
In addition, you may improve suitably the structure which attached | subjected the code | symbol. In addition, at least a part may be replaced with another component, and the configuration requirements that are not particularly limited with respect to the configuration are not limited to the configurations disclosed in the embodiments.

  According to the present invention, the image sensor unit can be exchanged, and the image sensor unit that can perform image blur correction can be mounted and used. Therefore, even if the image sensor itself becomes obsolete, it is possible to continue using the camera body.

  Hereinafter, embodiments of the present invention will be described in more detail with reference to the drawings.

(Embodiment)
FIG. 1 is a diagram showing an overview of the camera system of the present embodiment.
FIG. 2 is a block diagram of the camera system of this embodiment.
The camera system of the present embodiment includes an interchangeable lens 100, a camera body (body) 200, and an image sensor unit 300. The interchangeable lens 100 and the image sensor unit 300 are detachable from the camera body 200, and are interchangeable. System.
The interchangeable lens 100 includes a focal length encoder 101, an imaging distance encoder 102, a diaphragm 103, a lens CPU 104, a contact point 105 with the camera body, and an imaging optical system 106, and the camera body 200 via a mount unit (not shown). It is removable with respect to.
The focal length encoder 101 is an encoder that converts the focal length from position information of each lens group of the photographing optical system 106. The focal length encoder 101 encodes the focal length and outputs it to the lens CPU 104.

The shooting distance encoder 102 converts the distance (shooting distance) to a subject that can be focused at the position of the focus lens group from the position information of the focus lens group driven by an auto focus (AF) mechanism (not shown). Encoder. The shooting distance encoder 102 encodes the shooting distance and outputs it to the lens CPU 104.
The diaphragm 103 is an iris diaphragm that is driven by a stepping motor (STM) 107 and changes the amount of light passing therethrough.

  The lens CPU 104 is a part that controls the operation of the interchangeable lens 100, and is connected to a focal length encoder 101, an imaging distance encoder 102, a contact point 105, an STM 107, and the like. The lens CPU 104 has a communication function with the camera body and a control function of the interchangeable lens 100. The lens CPU 104 receives a focal length, a shooting distance, and the like, and outputs them to the body CPU 202 via the contact 105. Further, the lens CPU 104 receives release information, aperture amount information, and AF information from the body CPU 202 via the contact point 105, and controls the driving of the aperture by the STM 107 and controls the AF driving (not shown).

  A contact point 105 with the camera body 200 is a contact point that is in electrical contact with the contact point 209 of the camera body 200 and is provided with a plurality of contacts. Specifically, the contact 105 includes a contact for supplying power for driving the lens from the camera body 200, a contact for CPU power for driving the lens CPU 104, and a contact for digital communication. The drive system power supply and CPU power supply are supplied from the power supply of the camera body, and supply power for the lens CPU 104 and the drive system. In the digital communication contact, communication for inputting digital information such as focal length, photographing distance, and focus position information output from the lens CPU 104 to a body CPU 202 described later, and a focus position and an aperture amount output from the body CPU 202, etc. Communication for inputting the digital information to the lens CPU 104.

  The camera body 200 includes a release switch 201, a body CPU 202, a main mirror 203, a sub mirror 204, an AF sensor 205, a flash light emitting unit 206, a shutter unit 207, a digital processing circuit 208, a contact point 209 with the interchangeable lens 100, an image sensor unit 300, The interchangeable lens 100 and the image pickup device unit 300 are detachable camera body portions having a contact point 210, a display unit 211, a power source 212, and the like.

  The release switch 201 is a switch for operating shutter drive timing. The release switch 201 of the present embodiment can detect two states, a so-called half-pressed state that is turned on during the stroke, and a so-called full-pressed state that is further pushed from the half-pressed state and is turned on when the full stroke is pushed. is there. The release switch 201 outputs the state of the switch to the body CPU 202. Upon receipt of this, the body CPU 202 performs blur correction drive depending on the situation in addition to AF and AE (automatic exposure) when half-pressed, and mirrors when fully pressed. Up, shutter drive, etc. Further, the half-pressed state and the fully-pressed state transmitted to the body CPU 202 are transmitted to the image sensor unit CPU 313 via the contact point 210.

  The body CPU 202 has a communication function with the interchangeable lens 100 and the image sensor unit 300 and a control function of the camera body. The body CPU 202 communicates whether or not the mounting with the interchangeable lens 100 and the mounting with the imaging device unit 300 is complete, and information such as the focal length and the shooting distance input from the lens CPU 104 is received by the imaging device unit. The information is output to the CPU 313, and unit information (whether there is a shake correction function) and shake correction mode information (states of a shake correction switch 301 and a shake correction mode switch 302 described later) are input from the image sensor unit CPU 313. If the release switch 201 is half-pressed, the body CPU 202 outputs an instruction for a shooting preparation operation such as blur correction driving to the lens CPU 104 and the image sensor unit CPU 313 according to AE, AF, and the situation. When the release switch 201 is fully pressed, the body CPU 202 outputs instructions for driving the main mirror 203, driving the shutter unit 207, driving the diaphragm unit 103, and the like. The body CPU 202 performs image processing on the image information (information such as an image obtained by the image sensor) input from the digital processing circuit 208 and outputs the image information to the display unit 314.

The main mirror 203 is for guiding a subject image to an optical finder (not shown) at the time of composition determination, and is a so-called quick return mirror that is retracted from the photographing optical path during exposure of the image sensor 307 (hereinafter, exposure). Yes, and driven by a mirror driving unit (not shown) (for example, a DC motor).
The sub mirror 204 is a mirror for sending light to the AF sensor 205. A part of the main mirror 203 is a half mirror, and the light beam that has passed through the half mirror part is reflected and guided to the AF sensor 205. The sub mirror 204 is retracted from the photographing optical path when the main mirror 203 is retracted from the photographing optical path.

The AF sensor 205 is a sensor that detects a focused state of a subject image formed by a photographing optical system, and uses a CCD (Charge Coupled Devices).
The flash light emitting unit 206 is a part that instantaneously emits auxiliary illumination light at the time of photographing, and light emission is controlled by the body CPU 202.
The shutter unit 207 is located between the main mirror 203 and the image sensor 307 and is switched between a closed state that blocks subject light reaching the image sensor 307 and an open state that allows the subject light to pass through. This is a mechanism for controlling the exposure time. Information on the release switch 201 is input from the body CPU 202, and the shutter unit 207 is driven when fully pressed. The shutter unit 207 is driven by a shutter driving unit (not shown) (for example, a DC motor).
The digital processing circuit 208 is a circuit that performs A / D conversion on the image signal after analog processing input via the contact 210 and outputs the image signal to the body CPU 202.

  The contact point 209 with the interchangeable lens 100 is a contact point that is in electrical contact with the contact point 105 of the interchangeable lens 100 and is provided with a plurality of contact points. Specifically, the contact point 209 includes a contact point that supplies drive power for driving the drive system in the interchangeable lens 100, a contact point that supplies CPU power to drive the lens CPU 104, and a contact point for digital communication. Further, focal length information and shooting distance information are input from the lens CPU 104, and focus position information and aperture amount information are output from the body CPU 202 to the lens CPU 104.

The contact point 210 with the image sensor unit 300 is a contact point that is in electrical contact with the contact point 315 of the image sensor unit 300 and is provided with a plurality of contacts. Specifically, the contact 210 is provided with a contact for supplying a shake correction drive system power supply from the camera body 200, a contact for a CPU power supply for driving the image sensor unit CPU 313, and an analog communication from the analog processing circuit 306. And contacts for digital communication.
In the analog communication contact, the image signal output from the analog processing circuit 306 is communicated. In the digital communication contact, the focal length, the shooting distance, the state of the release switch 201, the flash light emitting unit signal, etc. output from the body CPU 202. Communication information for inputting the digital information to the image sensor unit CPU 313, digital information such as ON / OFF of the blur correction output from the image sensor unit CPU 313 and whether or not the image sensor unit 300 has a blur correction function, Communication for inputting to the body CPU 202 is performed.

The display unit 211 is a part that displays information such as shutter speed and aperture setting value. The display unit 211 mainly displays character information.
The power supply 212 is a part that supplies power to the camera system of the present embodiment, and for example, a rechargeable battery or the like is used.

  The image sensor unit 300 includes an image sensor and is a unit that is detachable from the camera body 200. There are two types of image sensor units that can be used in the camera system of the present embodiment: a unit having a blur correction function and a unit not having a blur correction function. First, the image sensor unit 300 having a blur correction function will be described.

(Image sensor unit with blur correction function)
An image sensor unit 300 with a shake correction function includes a shake correction switch 301, a shake correction mode switch 302, a gyro sensor 303, an EEPROM 304, a shake correction drive driver 305, an analog processing circuit 306, an image sensor 307, an image sensor drive circuit 308, It has a correction drive unit 309, a position detection unit 310, an image sensor holding unit 311, a shake correction follow-up control IC 312, an image sensor unit CPU 313, a display unit 314, and a contact point 315, which are provided in both the camera body 200 and the image sensor unit 300, respectively. This is an image sensor unit that can be attached to and detached from the camera body 200 using the mounted portions 213 and 319.

The shake correction switch 301 is a switch for selecting whether or not to perform a shake correction operation. The shake correction ON / OFF state selected by the shake correction switch 301 is output to the image sensor unit CPU 313.
The shake correction mode switch 302 is a switch for switching the shake correction mode, and the state of the shake correction mode selected by the shake correction mode switch 302 is output to the image sensor unit CPU 313. In the present embodiment, the blur correction mode 1 and the blur correction mode 2 are provided as the blur correction mode. In the blur correction mode 1, the blur correction function operates from when the release switch 201 is half-pressed to the end of exposure, and in the blur correction mode 2, the blur correction function operates from the full press to the end of exposure.

The gyro sensor 303 is an angular velocity sensor that detects the angular velocity of the shake generated in the image sensor unit 300, and outputs the detection result to the image sensor unit CPU 313.
An EEPROM (Electronically Erasable and Programmable Read Only Memory) 304 has information such as a gain value and an angle adjustment value of the gyro sensor 303, and outputs them to the image sensor unit CPU 313.
The shake correction drive driver 305 is a driver that controls the shake correction drive unit 309 and receives a drive amount input from the shake correction tracking control IC 312 to control the drive direction and drive amount of the shake correction drive unit 309.

The analog processing circuit 306 receives the output (image signal) of the image sensor 307 and performs processing such as improvement of the S / N ratio and level adjustment on the image signal, and then the processed image signal is sent to the contact 315. To the digital processing circuit 208.
The imaging element 307 is a photoelectric conversion element, and uses, for example, an image sensor such as a CCD or a CMOS (Complementary Metal Oxide Semiconductor). The image sensor 307 receives input from the image sensor drive circuit 308 and outputs image data to the analog processing circuit 306.
The image sensor drive circuit 308 receives an input such as a release timing from the image sensor unit CPU 313 and controls the image sensor 307 such as a data output timing.

FIG. 3 is a perspective view showing the periphery of the image sensor 307.
The image sensor 307 is attached to the image sensor holding unit 311. The imaging element holding unit 311 does not move with respect to the imaging element unit 300, that is, the imaging element light is applied to the imaging element back plate 316 and the imaging element front frame 317 arranged so as not to move with respect to the camera body 200. It is sandwiched in the axial direction. The imaging element back plate 316 is provided with steel balls 318 at three locations, and the imaging element holding unit 311 moves with respect to the camera body 200 in a direction parallel to the imaging surface of the imaging element 307 by the steel balls 318. It is free.

  Note that a lock hole (not shown) is formed in the image sensor holding unit 311, and a lock pin (not shown) is provided on the image sensor back plate 316. The lock pin can be moved by an actuator (not shown) between a position where the lock pin is fitted into the lock hole (lock position) and a position where the lock pin is retracted (lock release position), and the movement of the image sensor holding unit 311 is restricted. A locking mechanism is formed. When the shake correction operation for moving the image sensor holding unit 311 is not performed, the movement of the image sensor holding unit 311 is regulated by this lock mechanism.

The shake correction drive unit 309 is a mechanism for optically performing shake correction drive, and includes magnets 309a and 309b, a coil 309c, and yokes 309d and 309e. In addition, the blur correction driving unit 309 is provided with two sets for driving in two directions orthogonal to each other in a plane parallel to the imaging surface of the imaging element 307 together with the position detection unit 310 described later.
The magnet 309a and the yoke 309d are fixed to the imaging element front frame 317, and the magnet 309b and the yoke 309e are fixed to the imaging element back plate 316. The coil 309c is fixed at a position between the magnet 309a and the magnet 309b of the image sensor holding unit 311. A VCM (Voice Coil Motor) is formed by the magnets 309a and 309b, the coil 309c, and the yokes 309d and 309e. With such a configuration, the shake correction driving unit 309 receives the input from the shake correction drive driver 305 and energizes the coil 309c, thereby driving the image pickup device 307 with two axes along with the image pickup device holding unit 311. it can. In some cases, conversely, the drive actuator may be composed of a magnet and a yoke integrated with the image sensor 307 with the coil as the fixed side. Further, not only the VCM but also a piezoelectric element, STM or the like can perform the same function.

The position detection unit 310 is a part that detects the position of the image sensor holding unit 311 driven by the shake correction driving unit 309, and includes a Hall element 310a and a magnet 310b. The hall element 310 a is fixed to the image sensor front frame 317, and the magnet 310 b is fixed to the image sensor holding unit 311. The position detection unit 310 of the present embodiment uses a hall element 310a and a magnet 310b in pairs. Position detection using the Hall effect is performed by the magnetic flux of the magnet 310b fixed to the imaging element holding unit 311. A magnetic sensor other than the Hall element, such as an MR element, may be used, or an optical sensor such as a PSD (Position Sensitive Detector) may be used.
The position information detected by the position detector 310 is amplified and then output to the shake correction tracking control IC 312.

  Returning to FIG. 2, the shake correction tracking control IC 312 is an IC for performing shake correction control. The shake correction tracking control IC 312 calculates the shake correction drive unit movement amount from the shake correction drive unit target position input from the image sensor unit CPU 313 and the shake correction drive unit position information input from the position detection unit 310, and Output to the correction drive driver 305.

The image sensor unit CPU 313 includes a communication unit with the body CPU 202 and a shake correction processing unit. The shake correction processing unit calculates the shake correction drive unit target position from the information input from the EEPROM 304 and the shake angle, focal length information, and shooting distance information calculated in response to the output from the gyro sensor 303, and shake correction. The drive unit target position is output to the shake correction tracking control IC 312.
Here, the calculation performed by the shake correction processing unit of the image sensor unit CPU 313 will be described.
When performing the shake correction operation, the sensor output of the gyro sensor 303 is input to the image sensor unit CPU 313 via an amplifier (not shown). The image sensor unit CPU 313 obtains the shake angle by completely integrating the angular velocity.
Next, the focal length and shooting distance information of the interchangeable lens 100 are input to the image sensor unit CPU 313 via the body CPU 202.

FIG. 4 is a diagram illustrating the relationship among the photographing optical system, the subject, and the image sensor.
When the distance from the subject to the front principal point is a, the distance b from the rear principal point to the image plane, the shooting distance is R, and the shake angle is θ, the image blur amount L1 on the imaging plane by the angle θ at the time of proximity is Can be represented by the following formula (1).
L1 = βRtanθ (1)
However, lateral magnification β = b / a
In the case of infinity, R becomes ∞ and R≈a. In this case, the right side of the equation (1) is b tan θ, and b = f (focal length). Therefore, the image blur amount L2 on the imaging surface due to the angle θ at infinity is expressed by the following equation (2). be able to.
L2 = ftanθ (2)
As described above, the image blur amount (L1, L2) is obtained from the focal length and the photographing distance of the photographing optical system. This calculation process is performed by the image sensor unit CPU 313.

Returning to FIG. 2, the communication unit of the image sensor unit CPU 313 communicates with the body CPU 202 via the contact 315. At this time, whether or not the unit is completely mounted, unit information (whether or not there is a blur correction function), blur correction mode information, and the like are output to the body CPU 202.
The display unit 314 displays an image or the like obtained by the image sensor 307 in accordance with an instruction from the body CPU 202 via the contact point 315.

  A contact point 315 with the camera body 200 is a contact point that is in electrical contact with the contact point 210 of the camera body 200 and is provided with a plurality of contacts. Specifically, the contact point 315 is a contact point to which the camera shake correction driving system power is supplied from the camera body 200, the contact point of the CPU power source for driving the image sensor unit CPU 313, and the analog communication circuit 306 for analog communication. And contacts for digital communication.

  In the analog communication contact, the image signal output from the analog processing circuit 306 is communicated. In the digital communication contact, the focal length, the shooting distance, the state of the release switch 201, the flash light emitting unit signal, etc. output from the body CPU 202. For inputting the digital information of the image sensor to the image sensor unit CPU 313, ON / OFF of the blur correction output from the image sensor unit CPU 313, and whether the image sensor unit has a blur correction function or not. For inputting to the body CPU 202.

(Image sensor unit without blur correction function)
The image sensor unit without the blur correction function has a form in which the portion related to the blur correction function is removed from the image sensor unit 300 with the blur correction function, and will be described briefly without being illustrated.
The image sensor unit having no blur correction function includes an analog processing circuit, an image sensor, an image sensor drive circuit, and an image sensor unit CPU, and is an image sensor unit that can be attached to and detached from the camera body 200.

The analog processing circuit, the image sensor, and the image sensor drive circuit have functions similar to those of the analog processing circuit 306, the image sensor 307, and the image sensor drive circuit 308 included in the above-described image sensor unit 300 with the blur correction function.
The image sensor unit CPU has a communication function with the body CPU 202. The communication unit communicates with the body CPU 202 via a contact point with the image sensor unit. At that time, when the image sensor unit is mounted, whether or not the image sensor unit is completely mounted, and unit information (whether or not there is a blur correction function: an image sensor unit without a blur correction function. Etc.) to the body CPU.

The contact point of the image sensor unit without the blur correction function with the camera body 200 is a contact point of a CPU power source for driving the image sensor unit CPU from the camera body 200, a contact point for analog communication from the analog processing circuit, and a digital signal. There are communication contacts.
In the analog communication contact, the image signal output from the analog processing circuit is communicated, and in the digital communication contact, digital information such as the state of the release switch 201 output from the body CPU 202, the flash light emitting unit signal, and the like is obtained. Communication for inputting to the CPU 313 and communication for inputting to the body CPU digital information indicating that the image sensor unit output from the image sensor unit CPU has no blur correction function are performed.

  In the camera system of the present embodiment, the image sensor unit 300 with the blur correction function and the image sensor unit without the blur correction function can be used properly depending on the situation. When an image sensor unit with a blur correction function is used, a blur correction effect can be obtained, but there are disadvantages such as an increase in power consumption, an increase in the size of the entire camera, and an increase in weight. Therefore, when the blur correction function is not necessary, the above-described adverse effects can be eliminated by mounting the image sensor unit without the blur correction function.

Next, the operation of the camera system of this embodiment will be described.
FIG. 5 is a flowchart showing an operation flow of the camera system of the present embodiment.
In the following description, it is assumed that the image sensor unit 300 having the blur correction function is attached to the camera body 200 except for the subroutine B (the flow of FIG. 7) of S107 and S300.
When the power is turned on, in step (hereinafter referred to as S) 101, a battery check for checking the remaining amount of the power supply 212 is started.

In S102, if the remaining amount of the power supply 212 is equal to or greater than the specified value, the process proceeds to S103. On the other hand, if the remaining amount of the power supply 212 is less than the specified value, the process proceeds to S108, a warning is displayed on the display unit 211, and the operation is terminated.
In S103, the body CPU 202 starts communication with the lens CPU 104 and the image sensor unit CPU 313.
In S104, it is confirmed whether or not the interchangeable lens 100 and the image sensor unit 300 are completely attached. When both are completely mounted, the process proceeds to S105. On the other hand, if it is incomplete, the process proceeds to S109, a warning is displayed on the display unit 211, and the operation is terminated. This confirmation is determined based on whether or not communication can be performed reliably, but confirmation means such as a micro switch may be provided.

In S105, information such as focal length, photographing distance, autofocus driving method (whether driven by the motor in the interchangeable lens 100 or driven by the motor in the camera body 200) and the like are exchanged between the lens CPU 104 and the body CPU 202. I do.
In S106, information such as whether or not the image sensor unit 300 has a shake correction function is exchanged between the image sensor unit CPU 313 and the body CPU 202. Information about whether or not the image sensor unit 300 has a blur correction function is performed by the image sensor unit CPU 313 transmitting information stored in a storage unit (not shown) to the body CPU 202.

  In S107, the body CPU 202 determines whether or not the image sensor unit mounted on the camera body 200 is provided with the blur correction function, and the image sensor unit mounted on the camera body 200 is provided with the camera shake correction function. If YES in step S200, the flow advances to step S200 to execute subroutine A (FIG. 6). On the other hand, if the image sensor unit attached to the camera body 200 is not provided with the blur correction function, the process proceeds to S300, and the subroutine B (FIG. 7) is executed.

FIG. 6 is a flowchart showing a subroutine A of the S200 portion of the flow shown in FIG.
In S201, the image sensor unit CPU 313 reads information stored in the EEPROM 304.
In S <b> 202, information such as information obtained from the EEPROM 304, the state of the shake correction switch 301, and the selection state of the shake correction mode switch 302 is exchanged between the image sensor unit CPU 313 and the body CPU 202.

  In S203, the image sensor unit CPU 313 determines the state of the shake correction switch 301 and the selection state of the shake correction mode switch 302 (whether the shake correction mode 1 is selected or the shake correction mode 2 is selected). If the blur correction switch 301 is not performing blur correction (blur correction OFF), the process proceeds to S400, and the subroutine C (FIG. 8) is executed. When the shake correction switch 301 performs the shake correction (shake correction On) and the shake correction mode switch 302 selects the shake correction mode 1, the process proceeds to S500 and subroutine D (FIG. 9). Execute. When the shake correction switch 301 performs the shake correction (shake correction On) and the shake correction mode switch 302 selects the shake correction mode 2, the process proceeds to S600 and subroutine E (FIG. 10). Execute.

FIG. 7 is a flowchart showing a subroutine B of the S300 portion of the flow shown in FIG.
In S301, the half-press timer is reset. The half-press timer is a timer that counts the time from when the release switch 201 is half-pressed. If the half-press timer counts within the predetermined time, the half-press timer is turned on, the camera system is in the shooting preparation state, and when the predetermined time is exceeded, the half-press timer is turned off. Other than using the minimum necessary power, operations such as photometry and AF are suspended.

In S302, it is determined whether or not the half-press timer is ON. If the half-press timer is ON, the process proceeds to S303. If the half-press timer is OFF, the subroutine B is terminated and FIG. Return to the main flow.
In S303, it is determined whether or not the release switch 201 is half pressed. If the release switch 201 is half-pressed, the process proceeds to S304. If the release switch 201 is not half-pressed, the process returns to S302.
In S304, the half-press timer is reset.

In S305, the body CPU 202 performs distance measurement and photometry.
In step S <b> 306, the image sensor unit CPU 313 acquires focal length information of the interchangeable lens 200 from the lens CPU 104 via the body CPU 202.
In step S307, the lens CPU 104 performs AF driving in accordance with an instruction from the body CPU 202.
In S308, it is determined whether or not the release switch 201 is fully pressed. When the release switch 201 is fully pressed, the process proceeds to S309, and when the release switch 201 is not fully pressed, the process returns to S303.
In S309, the body CPU 202 retracts (mirrors up) the main mirror 203 from the photographing optical path.

In S310, the lens CPU 104 drives the diaphragm 103 in accordance with an instruction from the body CPU 202 to obtain an aperture diameter necessary for shooting.
In S311, the body CPU 202 drives the shutter unit 207 to the open position, and returns it to the closed position with a necessary exposure time (shutter speed).
In S <b> 312, electronic data of the subject image obtained by the image sensor 307 is taken from the image sensor unit 300 into the camera body 200.
In step S313, the lens CPU 104 drives the diaphragm unit 103 in accordance with an instruction from the body CPU 202 to set the diaphragm diameter to the open diameter.
In S314, the body CPU 202 returns the main mirror 203 to the photographing optical path (mirror down).
In S315, it is determined whether or not the half-press timer is ON. If the half-press timer is OFF, the operation returns to the main flow of FIG. 5 to end the operation. If the half-press timer is ON, , Return to S301.

FIG. 8 is a flowchart showing a subroutine C of the S400 portion of the flow shown in FIG.
Subroutine B in FIG. 7 is an operation in the case of an image sensor unit having no blur correction function, and subroutine C in FIG. 8 is an image sensor unit 300 having a blur correction function, but no blur correction operation is performed. These operations are substantially the same. Therefore, subroutine B in FIG. 7 and subroutine C in FIG. 8 are the same except that the operated image sensor unit is different and the operation in S415 is different, so here only subroutine B in FIG. In the description of FIG. 8, the description of the same part as in FIG. 7 is omitted, and only the operation of S415 is described.
In S415, it is determined whether or not the half-press timer is ON. If the half-press timer is OFF, the process returns to the flow of FIG. 6 to end the operation. If the half-press timer is ON, It returns to S203 of the flow of FIG.

FIG. 9 is a flowchart showing the subroutine D of the S500 portion of the flow shown in FIG.
In S501, the body CPU 202 causes the main mirror 203 to be mirrored up.
In S502, the half-press timer is reset.
In S503, it is determined whether or not the half-press timer is ON. If the half-press timer is ON, the process proceeds to S504. If the half-press timer is OFF, the process proceeds to S523.
In S504, it is determined whether or not the release switch 201 is half pressed. If the release switch 201 is half-pressed, the process proceeds to S505. If the release switch 201 is not half-pressed, the process returns to S503.

In S505, the half-press timer is reset.
In step S <b> 506, the image sensor unit CPU 313 activates the gyro sensor 303 in response to an instruction from the body CPU 202.
In S507, the body CPU 202 performs distance measurement and photometry.
In step S <b> 508, the body CPU 202 acquires focal length information and shooting distance information of the interchangeable lens 200 from the lens CPU 104, and transmits the acquired focal length information and shooting distance information to the image sensor unit CPU 313.
In S509, the lens CPU 104 performs AF driving in accordance with an instruction from the body CPU 202.

In S510, the image sensor unit CPU 313 releases the lock of the image sensor holding unit 311 by the lock mechanism in accordance with an instruction from the body CPU 202.
In step S <b> 511, the image sensor unit CPU 313 drives the shake correction driving unit 309 to move the image sensor holding unit 311 and center the image sensor 307. Here, the centering of the image sensor 307 is an operation of moving the image sensor 307 to a position where the optical axis of the imaging optical system 106 coincides with the center of the imaging surface of the image sensor.
In step S512, the image sensor unit CPU 313 starts blur correction driving.
In S513, it is determined whether or not the release switch 201 is fully pressed. If the release switch 201 is fully pressed, the process proceeds to S514 to start the photographing operation, and if the release switch 201 is not fully pressed, the process returns to S504.
In S514, the lens CPU 104 drives the diaphragm 103 in accordance with an instruction from the body CPU 202 so as to obtain an aperture diameter necessary for photographing.

In step S <b> 515, the image sensor unit CPU 313 drives the shake correction drive unit 309 to move the image sensor holding unit 311 and center the image sensor 307. This centering operation is called pre-exposure centering, and is performed in order to uniformly widen the blur correction possible range at the time of photographing.
In S516, the body CPU 202 drives the shutter unit 207 to the open position, and returns it to the closed position with a necessary exposure time (shutter speed).
In step S <b> 517, subject image data (image information) obtained by the image sensor 307 is captured from the image sensor unit 300 to the camera body 200.
In S518, the lens CPU 104 drives the diaphragm 103 in accordance with an instruction from the body CPU 202, and the diaphragm diameter is set to the open diameter.
In step S519, the image sensor unit CPU 313 stops the shake correction operation in accordance with an instruction from the body CPU 202.

In S520, the image sensor unit CPU 313 stops the angular velocity detection by the gyro sensor 303.
In S521, the image sensor unit CPU 313 restricts the movement of the image sensor holding unit 311 by setting the lock mechanism to the locked state.
In S522, it is determined whether or not the half-press timer is ON. If the half-press timer is OFF, the process returns to the flow of FIG. 6 to end the operation. If the half-press timer is ON, It returns to S203 of the flow of FIG.

In step S523, the image sensor unit CPU 313 stops the shake correction operation in accordance with an instruction from the body CPU 202.
In step S <b> 524, the image sensor unit CPU 313 stops the angular velocity detection by the gyro sensor 303.
In S525, the image sensor unit CPU 313 sets the lock mechanism to the locked state and restricts the movement of the image sensor holding unit 311.

FIG. 10 is a flowchart showing the subroutine E of the S600 portion of the flow shown in FIG.
In S601, the half-press timer is reset.
In S602, it is determined whether or not the half-press timer is ON. If the half-press timer is ON, the process proceeds to S603. If the half-press timer is OFF, the process returns to the flow of FIG. Exit.
In S603, it is determined whether or not the release switch 201 is half pressed. If the release switch 201 is half pressed, the process proceeds to S604, and if the release switch 201 is not half pressed, the process returns to S602.
In S604, the half-press timer is reset.

In step S <b> 605, the image sensor unit CPU 313 activates the gyro sensor 303 in response to an instruction from the body CPU 202.
In S606, the body CPU 202 performs distance measurement and photometry.
In step S <b> 607, the body CPU 202 acquires the focal length information and shooting distance information of the interchangeable lens 200 from the lens CPU 104, and transmits the acquired focal length information and shooting distance information to the image sensor unit CPU 313.
In S608, the lens CPU 104 performs AF driving in accordance with an instruction from the body CPU 202.
In S609, it is determined whether or not the release switch 201 has been fully pressed. If the release switch 201 is fully pressed, the process proceeds to S610 to start the photographing operation, and if the release switch 201 is not fully pressed, the process returns to S603.

In S610, the body CPU 202 mirrors the main mirror 203.
In S <b> 611, the lens CPU 104 drives the diaphragm unit 103 in accordance with an instruction from the body CPU 202, and sets the aperture diameter necessary for shooting.
In S612, the image sensor unit CPU 313 releases the lock of the image sensor holding unit 311 by the lock mechanism in accordance with an instruction from the body CPU 202.
In step S <b> 613, the image sensor unit CPU 313 drives the shake correction driving unit 309 to move the image sensor holding unit 311 and center the image sensor 307.
In S614, the image sensor unit CPU 313 starts blur correction driving.

In S615, the body CPU 202 drives the shutter unit 207 to the open position, and returns it to the closed position with a necessary exposure time (shutter speed).
In step S <b> 616, subject image data (image information) obtained by the image sensor 307 is captured from the image sensor unit 300 to the camera body 200.
In step S617, the lens CPU 104 drives the diaphragm unit 103 in accordance with an instruction from the body CPU 202 to set the diaphragm diameter to the open diameter.
In S618, the body CPU 202 mirrors the main mirror 203 down.
In step S619, the image sensor unit CPU 313 stops the shake correction operation in accordance with an instruction from the body CPU 202.

In S620, the image sensor unit CPU 313 stops the angular velocity detection by the gyro sensor 303.
In step S621, the image sensor unit CPU 313 restricts the movement of the image sensor holding unit 311 by setting the lock mechanism to the locked state.
In S622, it is determined whether or not the half-press timer is ON. If the half-press timer is OFF, the process returns to the flow of FIG. 6 to end the operation. If the half-press timer is ON, It returns to S203 of the flow of FIG.

  As described above, in the camera system according to the present embodiment, the body CPU 202 and the image sensor unit CPU 313 confirm whether the camera body 200 and the image sensor unit 300 are completely attached, and the image sensor unit 300 having the blur correction function. The sequence of the camera body CPU 202 is changed depending on whether or not there is. As a result, the image sensor unit having the blur correction function and the image sensor unit not having the blur correction function can be freely exchanged and used without any special setting when they are exchanged.

When there is a blur correction function, there are three types of operations: blur correction OFF, blur correction mode 1 and blur correction mode 2. In blur correction mode 1, camera shake correction driving is started by half-pressing release switch 201. In blur correction mode 2, blur correction driving is performed by fully pressing release switch 201.
First, in the case of the shake correction mode 1 with the shake correction function, the body CPU 202 immediately performs mirror up so that the subject is confirmed not by the finder but by the display unit 311. After half-pressing the release switch 201, the body CPU 202 requests the image sensor unit CPU 313 to turn on the gyro sensor 303. When the distance measurement and the photometry are completed, the focal length and the shooting distance information are transmitted in the order of the lens CPU 104 → the body CPU 202 → the image sensor unit CPU 313.

After the AF drive, the body CPU 202 requests the image sensor unit CPU 313 to release the lock. When unlocked, the image sensor unit CPU 313 performs centering of the image sensor 307 and starts blur correction.
When the release switch 201 is fully pressed, the body CPU 202 requests the image sensor unit CPU 313 to drive the blur correction drive unit 309 in order to center the image sensor 307 before exposure after aperture driving. After the shutter drive, the body CPU 202 requests the image sensor unit CPU 313 to move the image sensor drive circuit 308. When the aperture is opened, the body CPU 202 requests the image sensor unit CPU 313 to stop the blur correction drive. When the shake correction driving is stopped, the image sensor unit CPU 313 turns off the gyro sensor 303 and puts the lock mechanism into the locked state.

  Conventionally, as a demerit of the shake correction operation performed by moving the image sensor, there has been a case where the effect of the shake correction cannot be confirmed with a finder. However, in this embodiment, the blur correction mode 1 is provided, the body CPU 202 performs mirror-up, and the effect of the blur correction can be confirmed by a through image on the display unit 311 instead of checking the subject with the viewfinder.

Next, in the case of the blur correction mode 2 having the blur correction function, the blur correction operation is not performed before the start of the photographing operation that is started by fully pressing the release switch 201, and after the release switch 201 is fully pressed, Since the shake correction operation is performed, the subject cannot be confirmed on the display unit 311 after mirror-up as in the shake correction mode 1. For this reason, the mirror correction is not performed immediately after the image stabilization mode 2 is set.
As described above, in the blur correction mode 2, after the release switch 201 is pressed halfway, the body CPU 202 requests the image sensor unit CPU 313 to turn on the gyro sensor 303. When the distance measurement and the photometry are completed, the focal length and the photographing distance information are transmitted to the lens CPU 104 → the body CPU 202 → the image sensor unit CPU 313.

When the release switch 201 is fully pressed, the body CPU 202 requests the image sensor unit CPU 313 to release the lock after the aperture is driven. When the lock is released, the image sensor unit CPU 313 centers the image sensor 307 and starts a shake correction operation. After the shutter drive, the body CPU 202 requests the image sensor unit CPU 313 to move the image sensor drive circuit.
When the mirror is lowered, the body CPU 202 requests the image sensor unit CPU 313 to stop the blur correction drive. When the shake correction driving is stopped, the image sensor unit CPU 313 turns off the gyro sensor 303 and puts the lock mechanism in the locked state.

As described above, in the present embodiment, the blur correction mode 1 and the blur correction mode 2 can be properly used according to the intention of the photographer, and by selecting the blur correction mode 1, shooting is performed while checking the blur correction effect. It can be performed. Further, by selecting the blur correction mode 2, it is possible to perform shooting using a finder as in the conventional case.
In addition, according to the present embodiment, the image sensor unit can be removed from the main body. Therefore, even when foreign matter such as dust adheres to the imaging surface of the image sensor, the foreign object such as dust can be removed by removing the image sensor unit. There is also an effect that the removal operation can be easily performed.

(Deformation)
The present invention is not limited to the embodiment described above, and various modifications and changes can be made.
For example, in the present embodiment, an example in which image blur correction is performed by moving the image sensor has been described. However, the present invention is not limited thereto, and for example, an image sensor unit having a blur correction function using image processing calculation can be mounted. It may be a camera system.

It is a figure which shows the outline | summary of the camera system of this embodiment. It is a block diagram of the camera system of this embodiment. 2 is a perspective view showing the periphery of an image sensor 307. FIG. It is a figure which shows the relationship between an imaging optical system, a to-be-photographed object, and an image pick-up element. It is a flowchart which shows the flow of operation | movement of the camera system of this embodiment. It is a flowchart which shows the subroutine A of S200 part of the flow shown in FIG. It is a flowchart which shows the subroutine B of S300 part of the flow shown in FIG. It is a flowchart which shows the subroutine C of S400 part of the flow shown in FIG. It is a flowchart which shows the subroutine D of S500 part of the flow shown in FIG. It is a flowchart which shows the subroutine E of S600 part of the flow shown in FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 100: Interchangeable lens, 101: Focal length encoder, 102: Distance encoder, 103: Diaphragm part 103, 104: Lens CPU, 105: Contact, 106: Shooting optical system, 200: Camera main body, 201: Release switch, 202: Body CPU: 203: Main mirror, 204: Sub mirror, 205: AF sensor, 206: Flash emission unit, 207: Shutter unit, 208: Digital processing circuit, 209: Contact, 210: Contact, 211: Display unit, 212: Power supply, 300: Image sensor unit, 301: Shake correction switch, 302: Shake correction mode switch, 303: Gyro sensor, 304: EEPROM, 305: Shake correction drive driver, 306: Analog processing circuit, 307: Image sensor, 308: Image sensor Drive circuit 309: blur correction drive unit 310 Position detection unit, 311: pickup device holding portion, 312: shake correction tracking control IC, 313: image sensor unit CPU, 314: display unit, 315: contact

Claims (7)

A mounting portion on which an image sensor unit including the image sensor can be detachably mounted;
A contact portion capable of being electrically connected to the image sensor unit in a state where the image sensor unit is mounted by the mounting portion;
A confirmation unit that confirms whether or not the image sensor unit includes an image blur correction unit that corrects an image blur of an image captured by the image sensor, via the contact unit;
Camera body with The camera body according to claim 1,
A focal length information transmission unit that transmits information about a focal length of a photographing optical system included in the camera body or a photographing optical system mounted on the camera body to the mounted image sensor unit via the contact unit; ,
The camera body characterized by. In the camera body according to claim 1 or claim 2,
A shooting distance information transmission unit that transmits information about a shooting distance to a subject to the mounted image sensor unit via the contact unit;
The camera body characterized by. In the camera body according to any one of claims 1 to 3,
Has a release button to operate when shooting,
Having a release information transmission unit for notifying the mounted image sensor unit that the release button has been operated via the contact unit;
The camera body characterized by. In the camera body according to any one of claims 1 to 4,
A first operation mode for transmitting light that has passed through a photographing optical system to the image sensor when starting a photographing preparation operation;
A second operation mode in which the light that has passed through the photographing optical system is not transmitted to the image sensor during the photographing preparation operation, and the light that has passed through the photographing optical system is transmitted to the image sensor only when photographing is performed;
Having an operation selection section for selecting and executing
The camera body characterized by. The camera body according to claim 5,
The operation selection unit performs switching between the first operation mode and the second operation mode in accordance with a signal obtained from the image sensor unit;
The camera body characterized by. In the camera body according to claim 5 or 6,
A release button capable of detecting two states of a first pushed-in state and a second pushed-in state pushed further from the first pushed-in state;
The shooting preparation operation is started in response to the release button being in a first depressed state;
The camera body characterized by.

Images