The present invention relates to a photographing apparatus, and in particular relates to a photographing apparatus in which automatic tilt (automatic rotation) of an imaging plane (imaging surface of an image sensor) is possible.
In the related art, a method of using voice coil motors that use thin oblong-shaped drive coils is known in the art to be applied to a hand-shake correction device for correcting hand shake that occurs in an SLR (Single Lens Reflex) camera (Patent Literature 1). Furthermore, a hand-shake correction device is also known in the art in which hand-shake correction is possible in a total of six degrees of freedom (6DoF) by tilting an image sensor about two rotational axes, which are mutually orthogonal to each other in a plane that is orthogonal to an optical axis of a photographing lens; by rotating a reflection member that is provided at a midway position in a photographing optical system for folding (bending) an optical path about an axis that is parallel to the optical axis and tilting the reflection member about an axis that is orthogonal to the optical axis; and also by moving a lens group that is positioned midway within the photographing optical system in the optical axis direction (Patent Literature 2).
[Patent Literature 1] Japanese Unexamined Patent Publication No. 2012-226205
[Patent Literature 2] Japanese Unexamined Patent Publication No. 2008-035308
If an object (or object surface, parts of an object, or a plurality of objects positioned approximately on a plane) within a photographing area is tilted relative to the optical axis, an in-focus state can only be achieved on part of the object even if a focusing adjustment is carried out. For example, in a photographic view looking up at a tall building, sometimes the entire building cannot be brought into focus. Furthermore, in the case of photographing scenery at a relatively close distance, and, e.g., the object at a lower part of the picture frame is close and the object at a central to upper part, if the lower part of the picture frame is brought into focus, sometimes the upper part of the picture frame becomes out of focus; conversely, if the upper part of the picture frame is brought into focus, sometimes the lower part of the picture frame becomes out of focus.
Furthermore, in swing-and-tilt photography in which a conventional swing-and-tilt photography interchangeable lens is used, it is necessary for the photographer (user) to manually adjust the swing/tilt amount, which is a troublesome operation.
The hand-shake correcting device of Patent Literature 1 can only move an image sensor in a plane that is orthogonal to the optical axis, and hence, cannot perform swing-and-tilt photography.
In Patent Literature 2, an image sensor (which is included in a configuration of a hand-shake correcting device) is tilted to thereby enable swing-and-tilt photography. However, in the hand-shake correcting device in Patent Literature 2, since there are three members that are driven (controlled), namely, an image sensor, a lens group and a prism (reflection member), the assembly, positional adjustment and control thereof are complicated, so that it is difficult to carry out high-precision swing-and-tilt photography and a high-precision hand-shake correction.
The present invention has been devised in view of the above described problems, and the present invention provides a photographing apparatus which can bring an entire object into focus even if parts of the object have different object distances, such as an object (or a plane defined by the object) tilted (being inclined) relative to a plane orthogonal to the optical axis of the photographing apparatus, and similarly can bring a plurality of objects into focus even if such objects have different object distances, such as a plurality of objects positioned approximately on a plane that is tilted relative to a plane orthogonal to the optical axis of the photographing apparatus.
According to an aspect of the present invention, a photographing apparatus is provided, including an imaging-plane tilter configured to tilt an imaging plane, formed by a photographing optical system, relative to a plane that is orthogonal to an optical axis of the photographing optical system; a focus detector provided with a plurality of focus detection areas; and a tilt controller configured to control the imaging-plane tilter to tilt the imaging plane based on focus deviation amounts of the plurality of focus detection areas.
It is desirable for the photographing apparatus to include a focus deviation-amount detector configured to detect a focus deviation amount for each of the plurality of focus detection areas; and a focus adjuster configured to drive a focal adjustment optical element to an in-focus position based on at least one of the focus deviation amounts.
It is desirable for the photographing apparatus to include a calculator configured to calculate, based on the focus deviation amounts of the plurality of focus detection areas detected by the focus deviation-amount detector, a tilt correction amount for tilting the imaging plane so that each of the focus deviation amounts become minimum values.
It is desirable for the plurality of focus detection areas to include selection focus detection areas arranged in two mutually orthogonal directions, and selection focus detection areas arranged in at least one diagonal direction that is diagonal to each of the two mutually orthogonal directions. The calculator calculates the tilt correction amount based on focus deviation amounts detected at the selection focus detection areas of at least one the two mutually orthogonal directions and the diagonal direction.
It is desirable for the photographing apparatus to include a manual selector configured to select, via a manual operation, a focus detection area for detecting the focus deviation amount.
It is desirable for the photographing apparatus to include a priority mode selector configured to select one out of a plurality of priority modes, wherein each of the plurality of priority modes prioritize a group of focus detection areas for detecting the focus deviation amounts.
It is desirable for the imaging-plane tilter to include an image sensor, the image sensor provided with a rectangular imaging surface which receives the imaging plane. The priority mode selector is configured to select one priority mode out of at least one of: a horizontal-direction priority mode, which prioritizes the focus detection areas that are arranged in a horizontal direction of the imaging plane; a vertical-direction priority mode, which prioritizes the focus detection areas that are arranged in a vertical direction of the imaging plane; and a diagonal-direction priority mode, which prioritizes the focus detection areas that are arranged in a diagonal direction of the imaging plane that is diagonal to both the horizontal direction and the vertical direction.
It is desirable for the photographing apparatus to include an image sensor configured to capture an object image that is formed through the photographing optical system; and a touch panel display configured to display the object image that is captured by the image sensor. The manual selector selects a focus detection area for detecting the focus deviation amount upon the touch panel display receiving a corresponding touch operation.
It is desirable for the photographing apparatus to include an image sensor configured to capture an object image that is formed through the photographing optical system; and a touch panel display configured to display the object image that is captured by the image sensor. The priority mode selector selects a focus detection area for detecting the focus deviation amount upon the touch panel display receiving a corresponding touch operation.
It is desirable for the photographing apparatus to include an acceleration detector configured to detect a direction of swinging of the photographing apparatus, wherein the priority mode selector selects the priority mode based on a detected direction that is detected by the acceleration detector.
It is desirable for the photographing apparatus to include a finder for viewing an object image, formed through the photographing optical system; and a view-point detector configured to detect a view-point of a user that is viewing through the finder. The manual selector selects a focus detection area that aligns with the view-point detected by the view-point detector.
It is desirable for the photographing apparatus to include a finder for viewing an object image, formed through the photographing optical system; and a view-point detector configured to detect a line-of-vision of a user that is viewing through the finder. The manual selector selects focus detection areas that are arranged in a direction of movement of the view-point detected by the view-point detector.
It is desirable for the photographing apparatus to include a finder for viewing an object image, formed through the photographing optical system; and a view-point detector configured to detect a view-point of a user that is viewing through the finder. The priority mode selector selects a focus detection area that aligns with the view-point detected by the view-point detector.
It is desirable for the photographing apparatus to include a finder for viewing an object image, formed through the photographing optical system; and a view-point detector configured to detect a line-of-vision of a user that is viewing through the finder. The priority mode selector selects focus detection areas that are arranged in a direction of movement of the view-point detected by the view-point detector.
It is desirable for the imaging-plane tilter includes one of an image sensor; and at least one optical element of the photographing optical system. The tilt controller tilts the imaging plane by tilting the one of the image sensor and the optical element relative to a plane that is orthogonal to the optical axis.
It is desirable for the imaging-plane tilter to also be configured to translate the imaging plane in the optical axis direction, wherein the focus adjuster performs a focal adjustment by finely adjusting the imaging plane in the optical axis direction via the imaging-plane tilter.
It is desirable for the focus adjuster to drive the focal adjustment optical element to the in-focus position based on a focus deviation amount of a focus detection area that is located closest to the center of a photographing frame out of the plurality of focus deviation amounts.
It is desirable for the focus deviation-amount detector to include a focus detector that utilizes a phase-difference detection method, in which a focus deviation amount within a focus detection area is detected by detecting a phase difference between a pair of pupil-divided object-emanating light bundles.
According to the photographing apparatus of the present invention, since the imaging surface (imaging plane) can tilt in accordance to the inclination of the object (or object surface, parts of an object, or a plurality of objects positioned approximately on a plane), an entire inclined object (or object surface, parts of an object, or a plurality of objects positioned approximately on a plane) can be easily brought into focus.
The present disclosure relates to subject matter contained in Japanese Patent Application No. 2016-052361 (filed on Mar. 16, 2016) and Japanese Patent Application No. 2017-024754 (filed on Feb. 14, 2017) which are expressly incorporated herein by reference in their entireties.
The present invention will be described below in detail with reference to the accompanying drawings in which:
Embodiments of the present invention will be hereinafter discussed with reference to
The digital camera 10 is provided with a camera body 11 and a photographic lens 100 as a photographing optical system. The digital camera 10 is provided in the camera body 11 with a body CPU (tilt controller/calculator/priority mode selector) 20 and an imaging unit 30. The body CPU 20 controls the overall operations of the camera, performs computational and arithmetic operations, and controls driving of the camera 10. The imaging unit 30 is provided with an image sensor (image pickup device) 31 which captures an object image made incident thereon via the photographic lens 100. The body CPU 20 controls driving of the image sensor 31, processes image signals of captured object images at an image processor 32 to display the captured object images on an image display (monitor) 33, and writes data of the captured object images onto a memory card 34.
The digital camera 10 is provided with a contrast detector 35, a camera input device 21, an AF Unit (focus adjuster) 22, an exposure controller 23 and a lens communication circuit 24. The contrast detector 35 detects the contrast of an object image from the image signal processed by the image processor 32. The camera input device 21 includes, e.g., control switches, buttons, a dial (s) and/or a touchscreen, which are manually operated by the user to operate all the functions of the camera. The AF Unit 22 drives a focal adjustment lens group (focus adjustment optical element) FL, contained in the photographic lens 100, in the optical axis direction (the direction along the optical axis O) to adjust the focus. The exposure controller 23 controls opening and closing operations of a diaphragm, a shutter, etc., to adjust the quantity of light incident on the image sensor 31 and drives the image sensor 31 to control imaging operations. The lens communication circuit 24 performs communications with the photographic lens 100 to input lens information such as the focal length f, etc., of the photographic lens 100.
The digital camera 10 is provided with a roll detector GSα (which detects turning (rotation) about an imaginary axis in the Z-direction), a pitch detector GSβ (which detects tilt (rotation) about an imaginary axis in the X-direction), a yaw detector GSγ (which detects tilt (rotation) about an imaginary axis in the Y-direction), an X-direction acceleration detector GSX, a Y-direction acceleration detector GSY and a Z-direction acceleration detector GSZ as detectors for detecting shaking (vibrations) of the camera body 11 that is caused by hand shake; each of these six detectors are connected to a camera shake detecting circuit 44. These six detectors can be provided as a combined sensor, e.g., a six-axis sensor, a triple-axis gyro sensor, or a triple-axis acceleration sensor.
The imaging unit 30 is provided with a stage apparatus 60. The stage apparatus 60 is provided with a movable stage (imaging-plane rotator) 61, a front fixed yoke 62 and a rear fixed yoke 63. The image sensor 31 is fixedly mounted to the movable stage 61, and the front fixed yoke 62 and the rear fixed yoke 63 are positioned in front of and behind the movable stage 61, respectively. The stage apparatus 60 levitationally supports the movable stage 61 (so that the movable stage 61 is magnetically levitated) relative to the front fixed yoke 62 and the rear fixed yoke 63 at least when energized. The image sensor 31 constitutes a low-profile driven member having a flat front surface. In a levitational state, the movable stage 61 of the stage apparatus 60 can translate (linearly move) in the Z-direction (the first direction), translate in the X-direction (second direction) which is orthogonal to the Z-direction, translate in the Y-direction (third direction) which is orthogonal to both the X-direction and the Z-direction, tilt (rotate) about the X-direction (second direction), tilt (rotate) about the Y-direction (third direction), and turn (rotate) about the Z-direction (first direction) to thereby exhibit six axes of motion/motion with six degrees of freedom (6DoF) (see
The body CPU 20 inputs information on the focal length f from the photographic lens 100 via, e.g., the lens communication circuit 24, calculates the vibration direction, the vibration speed, etc., of the digital camera 10 based on detection signals input from the pitch (tilt (rotation) about an imaginary axis in the X-direction) detector GSβ, the yaw (tilt (rotation) about an imaginary axis in the Y-direction) detector GSγ, the roll (turn (rotation) about an imaginary axis in the Z-direction) detector GSα, the X-direction acceleration detector GSX, the Y-direction acceleration detector GSY and the Z-direction acceleration detector GSZ, calculates the driving direction, the driving speed and the driving amount of the image sensor 31 so that the object image projected onto the image sensor 31 via the photographic lens 100 does not move relative to the image sensor 31 and drives the movable stage 61 of the stage apparatus 60 in with six degrees of freedom (6DoF) (six-axis motion), i.e., translate (shift) the movable member in the X-direction, the Y-direction and/or the Z-direction, tilt (rotate) the movable member about the X-direction and/or the Y-axis, and/or turn (rotate) the movable member about the Z-direction, based on the calculation results. For example, the movable stage 61 can translate (shift), rotate (tilt or turn), translate (shift) while rotating, translate (shift) after rotating, and rotating after translation (shifting). The order of these movements is optional.
The stage apparatus 60 functions as a supporter which supports the movable stage 61, to which the image sensor 31 is fixed, in a manner to allow the movable stage 61 to translate and rotate (tilt or turn) with six degrees of freedom (6DoF) with respect to the front fixed yoke 62 and the rear fixed yoke 63. The movable stage 61 is a rectangular plate (frame) and greater in size than the image sensor 31 as viewed from the front. The front fixed yoke 62 and the rear fixed yoke 63 are rectangular plates (frames) of the same size and have slightly greater outer dimensions than those of the movable stage 61 in a plan view. The front fixed yoke 62 and the rear fixed yoke 63 are provided at the centers thereof with rectangular openings 62a and 63a, respectively, which have greater dimensions than the outer dimensions of the image sensor 31 as viewed from front (as viewed in the Z-direction). The front fixed yoke 62 and the rear fixed yoke 63 are connected and held in parallel with each other with a predetermined distance therebetween via a plurality of connecting columns (not shown) at positions not interfering with the movable stage 61 even when the movable stage 61 is moved (translated, tilted or turned) within a predetermined range.
The stage apparatus 60 is provided with a left pair of X-direction magnets (second-direction magnets/left and right X-direction magnets) MX1 and a right pair of X-direction magnets (second-direction magnets/left and right X-direction magnets) MX1, each pair being made of two permanent magnets identical in specification. The left pair of X-direction magnets MX1 and the right pair of X-direction magnets MX1 are fixed to the rear of the front fixed yoke 62 (the opposite side of the front fixed yoke 62 from the object side) to be positioned on either side of the opening 62a with respect to the leftward and rightward directions (on either side of the Z-axis with the Y-axis as a center line). Although the stage apparatus 60 is provided with the two pairs of X-direction magnets MX1 on either side of the opening 62a in the X-direction in the present embodiment of the stage apparatus, it is possible for the two pairs of X-direction magnets MX1 to be provided only on one side of the opening 62a with respect to the X-direction. The stage apparatus 60 is provided with a left pair of X-direction magnets MX2 and a right pair of X-direction magnets MX2 which are fixed to the front of the front fixed yoke 63 (the object side surface of the front fixed yoke 63) to face the left pair of X-direction magnets MX1 and the right pair of X-direction magnets MX1, respectively. Each pair of X-direction magnets MX2 is identical in specification to each pair of X-direction magnets MX1. Each X-direction magnet MX1 and MX2 is a plate-like magnet which is elongated in the Y-direction and thin in the Z-direction. The left and right X-direction magnets MX1 of each pair are arranged parallel to the Y-axis and spaced from each other in the X-direction; likewise, the left and right X-direction magnets MX2 of each pair are arranged parallel to the Y-axis and spaced from each other in the X-direction. In each pair of X-direction magnets MX1, the front and the rear sides of one X-direction magnet MX1 (the left X-direction magnet MX1 with respect to
The stage apparatus 60 is provided with a left pair of Y-direction magnets (upper and lower Y-direction magnets) MYA1 and a right pair of Y-direction magnets (upper and lower Y-direction magnets) MYB1, each pair being made of two permanent magnets identical in specification. The left pair of Y-direction magnets MYA1 and the right pair of Y-direction magnets MYB1 are fixed to the rear of the front fixed yoke 62 to be positioned below the opening 62a (to be spaced downward from the Z-axis with the Y-axis as a center line). The stage apparatus 60 is further provided with a left pair of Y-direction magnets (upper and lower Y-direction magnets) MYA2 and a right pair of Y-direction magnets (upper and lower Y-direction magnets) MYB2, each pair being made of two permanent magnets identical in specification. The left pair of Y-direction magnets MYA2 and the right pair of Y-direction magnets MYB2 are fixed to the front of the rear fixed yoke 63 to face the left pair of Y-direction magnets MYA1 and the right pair of Y-direction magnets MYB1, respectively. Each Y-direction magnet MYA1, MYB1, MYA2 and MYB2 is a plate-like magnet which is elongated in the X-direction and thin in the Z-direction. The upper and lower Y-direction magnets MYA1 are arranged parallel to the X-axis and spaced from each other in the Y-direction and the upper and lower Y-direction magnets MYB1 are arranged parallel to the X-axis and spaced from each other in the Y-direction. Likewise, the upper and lower Y-direction magnets MYA2 are arranged parallel to the X-axis and spaced from each other in the Y-direction and the upper and lower Y-direction magnets MYB2 are arranged parallel to the X-axis and spaced from each other in the Y-direction. In each pair of Y-direction magnets MYA1 and MYB1, the front and the rear of one Y-direction magnet MYA1 or MYB1 (the upper Y-direction magnet MYA1 or MYB1 with respect to
The stage apparatus 60 is further provided on the rear of the front fixed yoke 62 with three Z-direction magnets MZA1, MZB1 and MZC1 (see
Each Z-direction magnet MZA1, MZB1, MZC1, MZA2, MZB2 and MZC2 is a plate-like magnet which is rectangular (substantially square) in shape as viewed from the front. The Z-direction magnets MZA1, MZB1 and MZC1 are fixed to the rear side of the front fixed yoke 62 so that the front side (that is in contact with the front fixed yoke 62) and the rear side of each Z-direction magnet act as the south pole and the north pole, respectively (i.e., the south and north poles of each Z-direction magnet face forward and rearward, respectively), while the Z-direction magnets MZA2, MZB2 and MZC2 are fixed to the front of the rear fixed yoke 63 so that the same magnetic poles are placed face-to-face between each Z-direction magnet MZA2, MZB2 and MZC2 and the associated Z-direction magnet MZA1, MZB1 or MZC1. The Z-direction magnets MZA1, MZB1, MZC1, MZA2, MZB2 and MZC2 are identical in specification. In addition, the Z-direction magnets MZA1, MZB1 and MZC1 lie in a plane (first plane) orthogonal to the Z-axis and are arranged at substantially equi-angular intervals about the Z-axis. Likewise, the Z-direction magnets MZA2, MZB2 and MZC2 lie in a plane (second plane parallel to the aforementioned first plane) orthogonal to the Z-axis and are arranged at substantially equi-angular intervals about the Z-axis to face the Z-direction magnets MZA1, MZB1 and MZC1 in the Z-direction, respectively. With the passage of magnetic flux of each Z-direction magnet MZA1, MZB1 and MZC1 and the associated Z-direction magnet MZA2, MZB2 or MZC2 through the front fixed yoke 62 and the rear fixed yoke 63, a portion of a magnetic circuit which generates thrust in the Z-direction (the first direction) is formed between each Z-direction magnet MZA1, MZA2 and MZA3 and the associated Z-direction magnet MZB1, MZB2 or MZBC.
The movable stage 61, which is positioned between the front fixed yoke 62 and the rear fixed yoke 63, is a nonmagnetic member which is formed of a nonmagnetic material as a single-piece member by press-molding. The movable stage 61 is provided at a central portion thereof with an image sensor mounting hole 61a, having the shape of a rectangle as viewed from the front, and the image sensor 31 is fitted into the image sensor mounting hole 61a and fixed thereto. The image sensor 31 protrudes from the image sensor mounting hole 61a forwardly toward the front of the movable stage 61 in the optical axis direction.
When the movable stage 61 sits at the initial position (with the movable stage 61 magnetically levitated), the image sensor 31 is positioned so that the long sides of the image sensor 31 extend parallel to the X-axis and so that the short sides of the image sensor 31 extend parallel to the Y-axis. When the movable stage 61 sits at the initial position, the center of the imaging surface of the image sensor 31 is positioned on the optical axis O of the photographic lens 100, and the optical axis O and the Z-axis are aligned with each other. The Z-direction (the first direction), the X-direction (the second direction) and the Y-direction (the third direction) will be hereinafter described as fixed directions with respect to the camera body 11 and the photographic lens 100, with the Z-direction parallel to (including being aligned with) the optical axis O; however, the Z-direction (the first direction), the X-direction (the second direction) and the Y-direction (the third direction) can be fixed directions with respect to the image sensor 31.
The stage apparatus 60 is provided with a pair of X-drive coils (X-driver) CX which are fixed to the movable stage 61 on either side (left and right sides) of the image sensor 31 in the X-direction to be located to the left and right of the left and right sides (short sides) of the image sensor 31, respectively. The stage apparatus 60 is provided with a pair of Y-drive coils: a Y-drive coil (YA-driver) CYA and a Y-drive coil (YB-driver) CYB which are fixed to the movable stage 61 to be located below the lower side (long side) of the image sensor 31 and to be spaced from each other in the leftward and rightward directions (i.e., in the X-direction). The pair of X-drive coils (X-driver) CX are vertically elongated in the Y-direction and arranged at symmetrical positions with respect to the Y-axis (at equi-distant positions from the Y-axis) so that the longitudinal directions of the pair of X-drive coils CX extend parallel to the Y-direction and intersect the X-axis. The pair of Y-drive coils CYA and CYB are laterally elongated in the X-direction and arranged at symmetrical positions with respect to the Y-axis (at equi-distant positions from the Y-axis) so that the longitudinal directions of the pair of Y-drive coils CYA and CYB extend parallel to the X-direction. According to this arrangement, manufacture, adjustment and control of the stage apparatus 60 is facilitated.
The stage apparatus 60 is further provided with three circular coils: a Z-drive coil (ZA-driver) CZA, a Z-drive coil (ZB-driver) CZB and a Z-drive coil (ZC-driver) CZC which are fixed to the movable stage 61. The Z-drive coil CZA is fixed at a position (middle position) between the pair of Y-drive coils CYA and CYB, and the Z-drive coils CZB and CZC are fixed above the pair of X-drive coils CX, respectively. The Z-drive coil CZA is arranged on the Y-axis, and the Z-drive coils CZB and CZC are arranged to be symmetrical with respect to the Y-axis (at equi-distant positions from the Y-axis). The center of gravity (the center of gravity of the whole) of the Z-drive coils CZA, CZB and CZC is substantially coincident with the center of gravity of the movable stage 61. It is desirable that the Z-drive coils CZA, CZB and CZC be arranged so that a line which connects two of the three Z-drive coils CZA, CZB and CZC extends parallel to one of the X-axis and the Y-axis and so that a line which extends from the remaining one of the three Z-drive coils CZA, CZB and CZC and is orthogonal to the aforementioned connecting line extends parallel to (or aligns with) the other of the X-axis and the Y-axis. In the first embodiment of the stage apparatus, the Z-drive coils CZA, CZB and CZC are arranged so that a line which connects the two Z-drive coils CZB and CZC extends parallel to the X-axis and so that a line which extends from the Z-drive coil CZA and is orthogonal to the aforementioned connecting line aligns with the Y-axis as shown in
The pair of X-drive coils CX, the pair of Y-drive coils CYA and CYB and the three Z-drive coils CZA, CZB and CZC are flat (thin) coils which are arranged to be parallel to a plane (X-Y plane) orthogonal to the optical axis O. Each of these seven flat coils is made of a plurality of turns of a conductive wire wound in the X-Y plane which are in turn multi-layered in the thickness direction of the movable stage 61 (i.e., in the Z-direction).
The pair of X-drive coils CX are arranged so that the long portions (long sides) thereof extend parallel to the Y-axis and so that the front and rear surfaces of each X-drive coil CX face the pair of X-direction magnets MX1 and the pair of X-direction magnets MX2, respectively, while the pair of Y-drive coils CYA and CYB are arranged so that the long portions (long sides) thereof extend parallel to the X-axis, so that the front and rear surfaces of the Y-drive coil CYA face the pair of Y-direction magnets MYA1 and the pair of Y-direction magnets MYA2, respectively, and so that the front and rear surfaces of the Y-drive coil CYB face the pair of Y-direction magnets MYB1 and the pair of X-direction magnets MYB2, respectively.
The pair of X-drive coils (X-driver) CX, the Y-drive coil (YA-driver) CYA, the Y-drive coil (YB-driver) CYB, the Z-drive coil (ZA-driver) CZA, the Z-drive coil (ZB-driver) CZB and the Z-drive coil (ZC-driver) CZC are all connected to an actuator drive circuit 42 (see
Each X-drive coil CX and the associated front and rear pairs of X-direction magnets MX1 and MX2 constitute a second thrust generator which generates thrust in the X-direction (the second direction). The movable stage 61 can be translated in the X-direction by the thrust force in the X-direction which is generated by controlling the current through the pair of X-drive coils CX. Each X-drive coil CX and the associated X-direction magnets MX1 and MX2 also act (function) as a levitator which levitates and holds the movable stage 61 at a center position (initial position) regardless of the attitude of the camera body 11, e.g., when the camera is held in a vertical position in which the grip of the camera body 11 faces up or down, or at an inclined angle other than a horizontal position.
The Y-drive coil CYA and the associated front and rear pairs of Y-direction magnets MYA1 and MYA2, and the Y-drive coil CYB and the associated front and rear pairs of Y-direction magnets MYB1 and MYB2 constitute a pair of third thrust generators (thrust controllers), each of which generates thrust in the Y-direction (the third direction). The movable stage 61 can be translated in the Y-direction and turned (rotated) about an imaginary axis in the Z-direction by interaction of two thrust forces in the Y-direction which are generated by controlling the currents through the pair of Y-drive coils CYA and CYB, spaced from each other in the X-direction. The Y-drive coil CYA and the pair of Y-direction magnets MYA1 and MYA2, and the Y-drive coil CYB and the pair of Y-direction magnets MYB1 and MYB2 also act (function) as a levitator which levitates and holds the movable stage 61 at a center position (initial position) regardless of the attitude of the camera body 11, and especially when the camera is held in a normal position (horizontal position).
The three Z-drive coils CZA, CZB and CZC are arranged so that the front and rear surfaces of the Z-drive coil CZA face the front and rear Z-direction magnets MZA1 and MZA2, respectively, so that the front and rear surfaces of the Z-drive coil CZB face the front and rear Z-direction magnets MZB1 and MZB2, respectively, and so that the front and rear surfaces of the Z-drive coil CZC face the front and rear Z-direction magnets MZC1 and MZC2, respectively. The Z-drive coil CZA and the front and rear Z-direction magnets MZA1 and MZA2, the Z-drive coil CZB and the front and rear Z-direction magnets MZB1 and MZB2, and the Z-drive coil CZC and the front and rear Z-direction magnets MZC1 and MZC2 constitute three first thrust generators, each of which generates thrust in the Z-direction (the first direction). The movable stage 61 is levitated without contacting either the front fixed yoke 62 or the rear fixed yoke 63 (without contacting any of the three pairs of Z-direction magnets MZA1 and MZA2, MZB1 and MZB2, and MZC1 and MZC2), translated in the Z-direction, tilted about the X-direction and tilted about the Y-direction by interaction of three thrust forces in the Z-direction which are generated by controlling the currents through the three Z-drive coils CZA, CZB and CZC.
The Z-drive coils CZA, CZB and CZC and the pairs of Z-direction magnets MZA1 and MZA2, MZB1 and MZB2, and MZC1 and MZC2 also act (function) as a levitator which levitates and holds the movable stage 61 at an initial position relative to the optical axis direction and at an initial attitude (at an initial position in which the imaging surface of the image sensor 31 is orthogonal to the optical axis O).
The stage apparatus 60 is provided with two pairs of X-direction Hall elements (magnetic sensors), two pairs of Y-direction Hall elements (magnetic sensors) and three pairs of Z-direction Hall elements (magnetic sensors). More specifically, the stage apparatus 60 is provided with a left pair of X-direction Hall elements HX1 and HX2 (X-position detector HX), a right pair of X-direction Hall elements HX1 and HX2 (X-position detector HX), a left pair of Y-direction Hall elements HYA1 and HYA2 (YA-position detector HXA), a right pair of Y-direction Hall elements HYB1 and HYB2 (YA-position detector HXB), a pair of Z-direction Hall elements HZA1 and HZA2 (ZA-position detector), a pair of Z-direction Hall elements HZB1 and HZB2 (ZB-position detector) and a pair of Z-direction Hall elements HZC1 and HZC2 (ZC-position detector). These Hall elements HX1, HX2, HYA1, HYA2, HYB1, HYB2, HZA1, HZA2, HZB1, HZB2, HZC1 and HZC2 are all fixed to the movable stage 61. The left pair of X-direction Hall elements HX1 and HX2 are positioned in the air-core area of the left X-drive coil CX, and the right pair of X-direction Hall elements HX1 and HX2 are positioned in the air-core area of the right X-drive coil CX. The left pair of Y-direction Hall elements HYA1 and HYA2 are positioned in the air-core area of the left Y-drive coil CYA, and the right pair of Y-direction Hall elements HYB1 and HYB2 are positioned in the air-core area of the right Y-drive coil CYB. The pair of Z-direction Hall elements HZA1 and HZA2 are positioned in the air-core area of the Z-drive coil CZA, the pair of Z-direction Hall elements HZB1 and HZB2 are positioned in the air-core area of the Z-drive coil CZB, and the pair of Z-direction Hall elements HZC1 and HZC2 are positioned in the air-core area of the Z-drive coil CZC. Each pair of X-direction Hall elements HX1 and HX2 are positioned at an approximate center of the associated X-drive coil CX in the Y-direction (the short-side direction of the image sensor 31) and spaced from each other with a predetermined distance therebetween in the X-direction (the long-side direction of the image sensor 31). Each pair of Y-direction Hall elements HYA1 and HYA2, and HYB1 and HYB2 are positioned at an approximate center of the associated Y-drive coil CYA or CYB in the X-direction (the long-side direction of the image sensor 31) and spaced from each other with a predetermined distance therebetween in the Y-direction (the short-side direction of the image sensor 31). Each pair of Z-direction Hall elements HZA1 and HZA2, HZB1 and HZB2, and HZC1 and HZC2 are positioned to lie on the axis of the associated Z-drive coil CZA, CZB or CZC and spaced from each other with a predetermined distance therebetween in the Z-direction.
Each pair of X-direction Hall elements HX1 and HX2 (X-position detector HX), each pair of Y-direction Hall elements HYA1 and HYA2 (YA-position detector HXA) and HYB1 and HYB2 (YA-position detector HXB) and each pair of Z-direction Hall elements HZA1 and HZA2 (ZA-position detector HZA), HZB1 and HZB2 (ZB-position detector HZB) and HZC1 and HZC2 (ZC-position detector HZC) are all connected to a position detection circuit 43 (see
Each pair of X-direction Hall elements HX1 and HX2 constitute an X-direction position detector (translation-direction position detector) which detects the magnetic force (magnetic flux of an X-direction magnetic circuit) of the associated pairs of X-direction magnets MX1 and MX2 to detect the position of the movable stage 61 in the X-direction (the translation direction position in the X-direction) based on detection signals output from the X-direction Hall elements HX1 and HX2.
The pair of Y-direction Hall elements HYA1 and HYA2 detects the magnetic force of the associated pairs of Y-direction magnets MYA1 and MYA2 (magnetic flux of a Y-direction magnetic circuit), and the pair of Y-direction Hall elements HYB1 and HYB2 detects the magnetic force of the associated pairs of Y-direction magnets MYB1 and MYB2 (magnetic flux of a Y-direction magnetic circuit). Subsequently, the position of the movable stage 61 in the Y-direction and the turning position (rotational position) of the movable stage 61 about the Z-direction are detected based on detection signals output from the Y-direction Hall elements HYA1 and HYA2 and detection signals output from the Y-direction Hall elements HYB1 and HYB2. Accordingly, the pair of Y-direction Hall elements HYA1 and HYA2 and the pair of Y-direction Hall elements HYB1 and HYB2 each constitute a Y-direction position detector (translation direction position detector) which detects the position of the movable stage 61 in the Y-direction (the translation direction position of the movable stage 61 in the Y-direction) and a turning position (rotational position) detector which detects the turning position of the movable stage 61 about the Z-direction.
Each pair of Z-direction Hall elements HZA1 and HZA2, HZB1 and HZB2, and HZC1 and HZC2 detect the magnetic force of the associated pair of Z-direction magnets MZA1 and MZA2, MZB1 and MZB2, or MZC1 and MZC2 (magnetic flux of a Z-direction magnetic circuit) to detect the position of the movable stage 61 in the Z-direction (the translation direction position in the Z-direction), the tilting position of the movable stage 61 about the X-direction and the tilting position of the movable stage 61 about the Y-direction based on detection signals output from the three pairs of Z-direction Hall elements HZA1 and HZA2, HZB1 and HZB2, and HZC1 and HZC2. Accordingly, the three pairs of Z-direction Hall elements HZA1 and HZA2, HZB1 and HZB2, and HZC1 and HZC2 constitute both a Z-direction position detector (translation direction position detector) which detects the position of the movable stage 61 in the Z-direction (the translation direction position in the Z-direction), a tilting position detector which detects the tilting position of the movable stage 61 about the X-direction and a tilting position detector which detects the tilting position of the movable stage 61 about the Y-direction.
The X-drive coils CX, the Y-drive coils CYA and CYB and the Z-drive coils CZA, CZB and CZC, the X-direction Hall elements HX (H×1 and H×2), the Y-direction Hall elements HYA (HYA1 and HYA2) and HYB (HYB1 and HYB2), and the Z-direction Hall elements HZA (HZA1 and HZA2), HZB (HZB1 and HZB2) and HZC (HZC1 and HZC2) are all mounted on a flexible printed circuit (FPC) board (not shown) and are electrically connected to a circuit incorporated in the camera body 11 such as the actuator drive circuit 42 or the position detection circuit 43 via a flexible printed wiring board (flexible PWB) (not shown) which extends from the movable stage 61 (see
The actuator drive circuit 42 controls energization of the pair of X-drive coils CX, the pair of Y-drive coils CYA and CYB, and the three Z-drive coils CZA, CZB and CZC. The operation of the actuator drive circuit 42 is controlled by the body CPU 20 via an anti-shake/tilt control circuit 41 which is connected between the body CPU 20 and the actuator drive circuit 42 as shown in
The position detection circuit 43 detects the positions of the movable stage 61 in the X-direction, the Y-direction and the Z-direction, the tilting direction of the movable stage 61 about the X-direction (the tilting (rotating) angle/pitch angle about the X-direction), the tilting direction of the movable stage 61 about the Y-direction (the tilting (rotating) angle/yaw angle about an imaginary axis in the Y-direction) and the turning (rotation) direction of the movable stage 61 about the Z-direction (the turning (rotating) angle/roll angle about the Z-direction) from detection signals input from the X-direction Hall elements HX1 and HX2, the Y-direction Hall elements HYA1 and HYA2, and HYB1 and HYB2 and the Z-direction Hall elements HZA1 and HZA2, HZB1 and HZB2, and HZC1 and HZC2.
The digital camera 10 detects the positions of the movable stage 61 (i.e., the positions of the image sensor 31) in the X-direction, the Y-direction and the Z-direction, the rotational position (tilting position) of the movable stage 61 about the X-direction, the rotational position (tilting position) of the movable stage 61 about the Y-direction, and the rotational position of the movable stage 61 about the Z-direction in a manner which will be discussed thereinafter.
The position detection circuit 43 detects the position (the amount of movement) of the movable stage 61 in the X-direction by performing arithmetic computations based on the sum signal of the detection signals input from the pair of X-direction Hall elements HX1 and HX2.
The position detection circuit 43 detects the position of the pair (left pair) of Y-direction Hall elements HYA1 and HYA2 in the Y-direction by performing arithmetic computations based on the sum signal of the detection signals input from the pair of Y-direction Hall elements HYA1 and HYA2 and detects the position of the pair (right pair) of Y-direction Hall elements HYB1 and HYB2 in the Y-direction by performing arithmetic computations using the detection signals input the pair of Y-direction Hall elements HYB1 and HYB2, e.g., based on the sum signal of the detection signals input from the pair of Y-direction Hall elements HYB1 and HYB2. Based on these two positions in the Y-direction that are spaced from each other in the X-direction, the position detection circuit 43 detects the position (the amount of movement) of the movable stage 61 in the Y-direction and the turning position (the amount of rotation) of the movable stage 61 about the Z-direction.
In addition, the position detection circuit 43 detects the positions of the movable stage 61 in the Z-direction at three different points (detects the position of the movable stage 61 in the Z-direction, the tilting position of the movable stage 61 about the X-direction and the tilting position of the movable stage 61 about the Y-direction) by performing arithmetic computations using detection signals input from the three pairs of Z-direction Hall elements HZA1 and HZA2, HZB1 and HZB2, and HZC1 and HZC2 by performing arithmetic computations, e.g., based on the quotient of the sum of a pair of detection signals and the difference of this pair of detection signals. Thereupon, based on the positions of the movable stage 61 in the Z-direction at the three different points, the position detection circuit 43 detects the position (the amount of movement) of the movable stage in the Z-direction, the tilting position (rotation position) of the movable stage 61 about an imaginary axis in the X-direction and the tilting position (rotation position) of the movable stage 61 about an imaginary axis in the Y-direction.
In the above illustrated embodiment of the stage apparatus, the position detection accuracy in the X-direction and the Y-direction does not fluctuate even when the movable stage 61 moves in the Z-direction because the pair of X-direction Hall elements HX1 and HX2 that detect the position of the movable stage 61 in the X-direction are provided at a predetermined distance therebetween in the X-direction, because the pair of Y-direction Hall elements HYA1 and HYA2 that detect the position of the movable stage 61 in the Y-direction are provided at a predetermined distance therebetween in the Y-direction, and because the pair of Y-direction Hall elements HYB1 and HYB2 that detect the position of the movable stage 61 in the Y-direction are provided at a predetermined distance therebetween in the Y-direction.
The position detection accuracy in the Z-direction does not deteriorate even when the movable stage 61 translates in the X-direction or the Y-direction or tilts about the X-direction or the Y-direction because each of the three pairs of Z-direction Hall elements HZA1 and HZA2, HZB1 and HZB2, and HZC1 and HZC2 that detect the position of the movable stage 61 in the Z-direction are provided at a predetermined distance between the pair of Hall elements in the Z-direction.
Under control of the body CPU 20, the digital camera 10 levitates the movable stage 61 in between the front fixed yoke 62 and the rear fixed yoke 63 by controlling energization of the pair of X-drive coils CX, the pair of Y-drive coils CYA and CYB and the three Z-drive coils CZA, CZB and CZC via the actuator drive circuit 42 based on the positions calculated by the position detection circuits 43.
The digital camera 10 can carry out the below-described drive control with the movable stage 61 in a levitated state based on each position calculated by the body CPU 20 (position detection circuits 43).
The movable stage 61 can be translated in the Z-direction by interaction of three equal thrust forces in the Z-direction that are generated by controlling currents through the three Z-drive coils CZA, CZB and CZC by equal amounts. Furthermore, the movable stage 61 can be tilted (rotated) about the X-direction and can be tilted (rotated) about the Y-direction by interaction of three different thrust forces in the Z-direction that are generated by individually controlling currents through the three Z-drive coils CZA, CZB and CZC.
The movable stage 61 can be translated in the X-direction by a thrust force in the X-direction that is generated by controlling a current through each X-drive coil.
The movable stage 61 can be translated in the Y-direction by interaction of two thrust forces in the Y-direction that are generated by controlling currents through the Y-drive coils CYA and CYB by equal amounts. Furthermore, the movable stage 61 can be turned (rotated) about the Z-direction by interaction of two different thrust forces in the Y-direction that are generated by individually controlling currents through the Y-drive coils CYA and CYB.
Hence, the movable stage 61 can be translated, tilted/turned, tilted/turned while being translated, translated after being tilted/turned, and tilted/turned after being translated in all six directions with six degrees of freedom (6DoF) by interaction of thrust forces in the Z-direction, thrust forces in the X-direction and thrust forces in the Y-direction which are generated by controlling currents in the Z-drive coils CZA, CZB and CZC, the X-drive coil(s) CX and the Y-drive coils CYA and CYB.
The digital camera 10 (body CPU 20) can perform a hand-shake correction (shake reduction) operation by performing a drive-control of the above-described movable stage 61 in synchronization with hand shake (shake/vibration) of the camera body 11 and the photographic lens 100 that is detected by the camera shake detecting circuit 44.
In the digital camera 10, in addition to the shake-correction operation, special photography such as swing-and-tilt photography and compositional adjustment is possible by tilting (translating, tilting (rotating), or translating and tilting) the image sensor 31, and it is also possible to carry out an automatic tilting (automatic rotation) correction operation in which the image sensor 31 is translated and tilted in order to bring wide area of an object into focus in accordance with circumstances of the object (subject). The automatic tilt correction operation of the digital camera 10 will be described hereinbelow with reference to
1/f=1/a+1/b, and
M=a/b, wherein the focal length of the photographic lens 100 is designated as “f”, the distance (the object distance) between the principal plane LS and the object 200 is designated as “b”, and the distance (the image plane distance) between the principal plane LS and the imaging surface 31a (image surface center 31o) is designated as “a”, wherein “M” designates the magnification (optical magnification).
The image plane distance “a” is, for example, detected from the optical-axis position of the focal adjustment lens group FL of the photographic lens 100, and the object distance “b” is detected by the image plane distance “a” and the focal length “f” of the photographic lens 100.
Accordingly, in the composition of
As shown in
In this embodiment, in the initial state, the central focus detection area (2, 2) has been brought into focus.
Consequently, in order to achieve an in-focus state at all of the selected three focus detection areas (1, 2), (2, 2) and (3, 2), the image sensor 31 is tilted (rotated). Hence, the image sensor 31 is tilted about an axis in the Y-direction (short direction) that passes through the image surface center 310 so that the area of the imaging surface 31a onto which the left person 201 at a close distance is projected moves away from the principal plane LS by the focus deviation amount 1, and the area of the imaging surface 31a onto which the right person 203 at a far distance is projected moves closer to the principal plane LS by the focus deviation amount 2 (see
Since the digital camera 10 detects the focus deviation amounts of the three focus detection areas (1, 2), (2, 2) and (3, 2) and carries out a tilt adjustment operation on the image sensor 31 so that each focus deviation amount is 0, i.e., to be brought into focus, the three people 201 through 203 who are at different object distances can all be simultaneously be brought into focus.
An embodiment of an automatic tilt correction operation that is performed by the digital camera 10 will be hereinbelow described with reference to
The phase-shift detection circuit 70 is provided with a phase-difference sensor unit (a focus detector) 71 which can detect focus deviation amounts (defocus amounts) of the object(s) at the plurality of focus detection areas (1, 1) through (m, n) within the photographing frame 33a. The phase-difference sensor unit 71 is provided with photometering sensors (1, 1) through (m, n) which correspond to the focus detection areas (1, 1) through (m, n). Each of the photometering sensors (1, 1) through (m, n) is provided with a pair of sensor arrays which respectively receive a pair of pupil-divided object-emanating light bundles, and outputs a pair of image signals. Note that “m” and “n” are integers greater than 1, and may have the same or different value; in the embodiment shown in
Each of the photometering sensors (1, 1) through (m, n) outputs a pair of image signals to a focusing detector (a focus deviation-amount detector) 72 provided in the phase-shift detection circuit 70. The focusing detector 72 is provided with focusing detectors (1, 1) through (m, n) corresponding to photometer sensors (1, 1) through (m, n), and each of the focusing detectors (1, 1) through (m, n) detects a phase-difference between the corresponding pair of image signals, and outputs the result (phase-difference) to a focus deviation-amount detector 73 provided in the phase-shift detection circuit 70. The focus deviation-amount detector 73 calculates a focus deviation amount for each focusing detector (1, 1) through (m, n), and outputs the calculated results to the body CPU 20.
The body CPU 20 carries out an autofocusing adjusting operation, in which the focal adjustment lens group FL of the photographic lens 100 is driven (moved forwardly and rearwardly) in the optical axis direction by the AF Unit 22 so that the focus deviation amount of one focus detection area of the selected focus detection areas (selected from the plurality of focus detection areas (1, 1) through (m, n)) becomes 0 (becomes in focus), and carries out a tilt correction operation, in which the image sensor 31 is tilted (rotated) so that the focus deviation amounts of all of the selected focus detection areas becomes 0 or (the absolute value thereof) becomes a minimum value. In an embodiment, the autofocusing adjusting operation is performed based on the focus deviation amount of the focus detection area that is closest to the center of the photographing frame 33a out of the selected focus detection areas, or, e.g., is performed based on an intermediate (midway) value out of a plurality of focus deviation amounts; thereafter, a tilt correction operation is carried out so that the focus deviation amounts of the other remaining selected focus detection areas become 0.
Details of an automatic tilt (rotation) correction operation that is performed by the digital camera 10 will be described hereinbelow with reference to the flowchart of
The digital camera 10 decides the focus detection areas, namely, decides (selected/designates) which focus detection areas out of the focus detection areas (1, 1) through (3, 3) to use for a tilt correction operation (S11).
An initial tilt amount (rotational amount) is stored in a RAM 20a (S13). Although the initial tilt amount is 0 at the initial state, if the image sensor 31 is already tilted, the tilting amount thereof is input via the position detection circuit 43 and is stored in the RAM 20a.
The body CPU 20 calculates the magnification M from the focal length f, the object distance “b” and the image distance “a”, and stores the magnification M in the RAM 20a (S15).
Thereafter, the focus deviation amounts of the selected focus detection areas are detected (S17), and the difference between each focus deviation amount thereof is calculated (S19).
Thereafter, a tilt correction amount is calculated in order to minimalize the focus deviation amounts at the selected focus detection areas (S21). For example, in
Based on the calculated tilt correction amount, a tilt correction operation is carried out on the image sensor 31 via the stage apparatus 60 (S23).
Upon the tilt correction operation being carried out, the focus deviation amounts of the selected focus detection areas are detected, and if focus deviation amounts still occur, the image sensor 31 is finely adjusted (is linearly driven (translated) forwardly or rearwardly) in the optical axis direction via the stage apparatus 60 to perform a focusing correction (focal adjustment) operation (S25), and thereafter the automatic tilt correction operation ends (S27).
According to the above-described tilt correction operation, when the digital camera 10 detects different focus deviation amounts within the designated or selected focus detection areas (designated or selected from within the focus detection areas (1, 1) through (3, 3)), since a tilt correction operation is carried out on the image sensor 31 so that all of the focus deviation amounts become 0, i.e., so that the object (or object surface, parts of an object, or a plurality of objects positioned approximately on a plane) at each selected focus detection area of the imaging surface 31a is brought into focus, the entire object (entire object area, etc.) can be brought into focus. Accordingly, the photographer (user) does not need to carry out a manual tilt correction operation, thereby enabling the photographer to easily carry out a special photographing operation such as swing-and-tilt photography.
The digital camera 10 performs a still photographing operation upon the automatic tilt correction operation ending (S27), thereby obtaining a high-quality image in which the entire object(s) is brought into focus.
In the embodiment shown in
Step S25 may be omitted, thereby reducing the risk of missing out on a photographic opportunity in the case where a shutter-priority mode is in operation.
The above-described contrast detection and storing of contrast values are repeatedly carried out while moving the focal adjustment lens group FL, via the AF Unit 22, in a direction from a position at the minimum photographing distance to a position at the infinite photographing distance, or vice versa in the opposite direction thereto. Hence, at each focus detection area (1, 1) through (m, n), the focus deviation-amount detector 83 detects the position of the focal adjustment lens group FL at which a contrast peak of obtained as an in-focus position. Thereupon, each difference between a reference in-focus position (e.g., the in-focus position at the center focus detection area) and the other in-focus positions are calculated, and the respective calculated results are set as focus deviation amounts.
Similar to the embodiment shown in
Thereafter, the image sensor 31 is finely adjusted (translated) in the optical axis (O) direction (S16-1), and the contrasts of the selected focus detection areas are detected by the contrast detection circuit 80 (S16-2). At this step (S16-2), the operation of finely adjusting the image sensor 31 in the optical axis (O) direction, via the stage apparatus 60, and detecting the contrasts of the selected focus detection areas is carried out by repeatedly finely adjusting (moving) the image sensor 31 forwardly or rearwardly in the optical axis direction via the stage apparatus 60 to obtain contrast peaks, and the position in the optical axis direction of the image sensor 31 is detected when each contrast peak is obtained. Thereafter, each difference of the optical axis position of the image sensor 31, at which each contrast peak was attained at the selected focus detection areas, is calculated.
The contrast peaks obtained in the selected focus detection areas and the optical-axis positions of the image sensor 31 at which the contrast peak were obtained are stored in the RAM 20a (S16-3).
Thereafter, a tilt amount at which the contrast at a designated focus detection area is maximum (at which the focus deviation amount is 0, or as close to 0 as possible) is calculated (S16-4).
Subsequently, a tilt correction operation is carried out on the image sensor 31 via the stage apparatus 60 based on the calculated tilt correction amount (S23).
Upon the tilt correction operation being carried out, the focus deviation amounts of the selected focus detection areas are detected, and if focus deviation amounts still occur, the image sensor 31 is finely adjusted (is linearly driven forwardly or rearwardly) in the optical axis direction via the stage apparatus 60 to perform a focusing correction (focal adjustment) operation (S25), and thereafter the automatic tilt correction operation ends (S27). In the case where the focus deviation amount detected in step S25 is greater than the translatable amount of the image sensor 31 in the optical axis (O) direction via the stage apparatus 60, the focal adjustment lens group FL may be driven to perform a focus correction operation.
Accordingly, the digital camera 10 can bring into focus the entire object (or the entire object area) that is within the selected or designated focus detection areas via the above-described automatic tilt correction operation.
In the automatic tilt correction operation, the focus detection areas to be brought into focus can be configured to be selected or designated in groups from predetermined groups of focus detection areas, or the user may separately designate the focus detection areas to be brought into focus. The focus detection areas can be, for example, grouped as a plurality of focus detection areas in the horizontal direction, the vertical direction, or in a diagonal direction, and priority modes are set which prioritize the groups of focus detection areas. The priority modes include a horizontal-direction priority mode, a vertical-direction priority mode, and a diagonal-direction priority mode.
Furthermore, there also can be a collective priority mode (which results in all of the focus deviation amounts becoming minimum amounts) in which a tilt correction operation is carried out so that the absolute values of the focus deviation amounts in all or a plurality of focus detection areas become minimum (so that a total or an average absolute value becomes a minimum value).
The horizontal-direction priority mode is a tilt-correction operation mode which detects inclination (perspective difference) of an object (or object surface, parts of an object, or a plurality of objects positioned approximately on a plane) in a horizontal direction by detecting the focus deviation amounts of the object at each of the selected focus detection areas (
The vertical-direction priority mode is a tilt-correction operation mode which detects inclination (perspective difference) of an object (or object surface, parts of an object, or a plurality of objects positioned approximately on a plane) in a vertical direction by detecting the focus deviation amounts of the object at each of the selected focus detection areas (
The diagonal-direction priority mode is a tilt-correction operation mode which detects inclination (perspective difference) of an object (or object surface, parts of an object, or a plurality of objects positioned approximately on a plane) in a diagonal direction by detecting the focus deviation amounts of the object at each of the selected focus detection areas (
The collective priority mode is a tilt-correction operation mode which detects the focus deviation amounts within all or a plurality of focus detection areas, and tilts (rotates) the image sensor 31 about the horizontal direction and about the vertical direction, and translates the image sensor 31 in the optical axis direction, via the stage apparatus 60, so that the total or average value of the focal deviation amounts (absolute values) become a minimum value.
The above-described collective priority mode can be selected by a configuration in which the tilt setting circuit 46 sets the collective priority mode upon receiving a command from a tilt operation switch(es), provided on the digital camera 10.
In an alternative configuration for selecting focus detection areas, the photographer (user) commands or selects a plurality of focus detection areas or a plurality of locations on an object that the photographer wishes to bring into focus (for use in the tilt correction operation). Furthermore, a configuration is possible in which focus detection areas displayed on the image display 33 can be selected by tilt operation switches (manual selector) 45, and in the case where the image display 33 is a touch panel (touch screen), a configuration is possible in which commands (touch/contact operations) are performed by touching, tapping or sliding, etc., the user's finger on the image display 33. In the case where a touch panel display is used as the image display 33, a priority portion(s) (focus detection area(s)) of the object (subject) to be photographed that have priority over other portions of the object for being brought into focus can be selected by the user using his/her finger to trace such a priority portion(s).
Furthermore, in an alternative configuration for selecting focus detection areas, the photographer (user) swings the digital camera 10 in a direction in which the photographer wants to prioritize the tilting (of the image sensor 31). For example, the digital camera 10 can be configured so that if the digital camera 10, starting at an initial erect position, is swung in a horizontal direction, the horizontal-direction priority mode is selected (which prioritizes the focus detection areas that are arranged in the horizontal direction), or if the digital camera 10 is swung in a vertical direction, the vertical-direction priority mode is selected (which prioritizes the focus detection areas that are arranged in the vertical direction). The swinging direction of the digital camera 10 can be detected by utilizing detection results of the X-direction acceleration detector GSX, the Y-direction acceleration detector GSY and the Z-direction acceleration detector GSZ.
In the case where the digital camera 10 is a single-lens reflex (SLR) digital camera provided with an optical finder, in which the focus detection areas are displayed within the field-of-view of the optical finder, the photographer (user) may decide on the photographic composition with respect to the object that the photographer wants to photograph while viewing the object through the optical finder, and determine a plurality of focusing locations (out of the displayed focus detection areas) by operating switch (es), etc. During such an operation, the focusing locations are stored in memory via image positions and coordinates. Thereafter, a tilt correction operation of the image sensor 31 and an autofocusing adjusting operation are carried out so that the focal points at the determined focusing locations are optimum at the moment a shutter-release operation is performed. Furthermore, a view-point (line-of-vision) detector can be provided on the optical finder, whereby an object area (focus detection area) that aligns with the line-of-vision of the photographer (user) can be selected, a focus detection area (s) in a movement direction of the photographer's line-of-vision can be selected, or the priority mode corresponding to the direction of the photographer's line-of-vision can be selected. Furthermore, the optical finder may be an electronic view finder, in which a display that displays an object image that is captured by the image sensor (31) can be viewed via an eyepiece.
Although the stage apparatus 60 of the illustrated embodiment includes a moving coil configuration in which permanent magnets are fixed to front and rear yokes, and drive coils and hall sensors are fixed to the movable stage (61), however, the stage apparatus 60 may alternatively include a moving magnet configuration in which permanent magnets are fixed to the movable stage (61), and drive coils and hall sensors are fixed to front and rear yokes. If such a moving magnet configuration is applied, the number of flexible printed circuit boards drawn from the movable stage (61) can be reduced, the load on the movable stage (61) can be reduced, and the movable stage (61) can be more rapidly and accurately driven.
The stage apparatus according to the present invention can be applied to various photographing apparatuses and optical apparatuses such as an interchangeable lens and a camera-integrated lens, in addition to a so-called mirrorless digital camera, an SLR (single lens reflex) digital camera, a compact digital camera, a digital video camera, drive recorder, action camera, a digital camera installed in a portable terminal (mobile phone, smartphone), etc.
Furthermore, the present invention can also be applied to a projector (image projector apparatus) which projects images (still/moving images) and data, etc., or a laser scanner. In the case where the present invention is applied to a projector, the projector can be provided at an approximate center of the movable stage 61 with an image-forming element (LCD panel) which allows projection light to be incident thereon from one side (the rear) of the LCD panel in the thickness direction of the movable stage 61 (the first direction/the Z-direction) and to emerge from the LCD panel to travel toward an projector optical system provided on the other side (the front) of the movable stage, or the projector can be provided at an approximate center of the movable stage 61 with a DMD (digital mirror device/digital micro mirror device) panel (projection panel) which reflects the incident projection light, which is incident thereon from a direction different from the first direction (the Z-direction), in the first direction (toward the projector optical system). Alternatively, a projector optical system can be mounted on the movable stage 61 instead of the image-forming element.
Note that the projector may be provided with a focal detector for detecting a focal shift amount and/or a, e.g., a trapezoidal distortion detector for detecting trapezoidal distortion in the projected image; these detectors are used when focusing and when correcting trapezoidal distortion. In regard to trapezoidal distortion in particular, by providing a trapezoidal distortion detector, a trapezoidal distortion amount can be detected and automatically corrected by tilting the projected image with an image tilter based on a focal shift amount.
Furthermore, the projector of the present embodiment can also be applied to digital signage technology. Specifically, the projector of the present embodiment can be utilized for shake correction in the case where the projector is installed in transportation such as inside a train or an automobile. Alternatively, the projector of the present embodiment can be utilized for shake correction in the case where the projector is installed in a movable robot. Furthermore, by installing the shake-correction device of the present invention in a hand-held miniature projector, hand-shake can be effectively corrected. It should be noted that the projector of the present embodiment can be generally installed in a photographing apparatus. In the case where a miniature projector is installed onto a photographing apparatus body, or a display thereof, photographing shake-correction may be carried out, during a photographing operation, by translating and/or rotating (tilting/turning) a movable stage that holds an image sensor or an optical element (lens group, etc.) of a photographing optical system; and a shake-correction may be carried out, during a projecting operation of a photographing image, by translating and/or rotating (tilting/turning) a movable stage that holds an image-forming element so that the projected image does not shake. In the case where the shake-correction device of the present invention is installed a projector, although it is possible to achieve a higher resolution by a pixel shifting method in which the number of pixels that are displayed are increased by shifting the image-forming element by a half pixel or by one pixel, it is also possible to achieve a higher resolution by rotating the movable stage on which the image-forming element is mounted instead of, or in addition to, performing a pixel shifting method.
The stage apparatus of the present invention can also be applied to a lens barrel (e.g., a lens barrel disclosed in Japanese Unexamined Patent Publication No. 2015-4769) provided with an image-correction optical system in which one optical element of a photographing optical system is driven. For example, in the photographic lens 100, one or a plurality of optical elements of the photographing optical system can serve as a correction optical element (driven member). In this alternative embodiment shown in
Furthermore, the digital camera 10, to which the present invention is applied, can carry out hand-shake correction (image stabilization) and/or a special photographic effect by a combined operation of a hand-shake correction device provided in the photographing lens 100 and a hand-shake correction device provided in the camera body 11.
Obvious changes may be made in the specific embodiments of the present invention described herein, such modifications being within the spirit and scope of the invention claimed. It is indicated that all matter contained herein is illustrative and does not limit the scope of the present invention.
Number | Date | Country | Kind |
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2016-052361 | Mar 2016 | JP | national |
2017-024754 | Feb 2017 | JP | national |
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