Abstract: A method and system for hiding objectionable frames during autofocusing are disclosed. A personal electronic device such as a cameral telephone can have two cameras that have overlapping fields of view. One camera can provide imaging. The other camera can facilitate autofocusing in a manner wherein images produced thereby are not viewed by a user. Because the autofocus frames are hidden, the user is not distracted or annoying thereby.

Abstract: A digital photographing apparatus with a display unit on a front surface thereof and a method of controlling the same. The method includes setting a self photographing mode; generating countdown information for self photographing; determining a subject distance; and displaying the countdown information together with a captured image on the display unit when the subject distance is shorter than a reference distance. Thereby, a photographer may see a preview along with the countdown information so that a desired self-photographed image may be acquired.

Abstract: An image pickup apparatus includes a detector configured to detect an in-focus direction based on a focus signal that results from an output signal of an image pickup device by reciprocating a focus lens in an optical axis direction, and a focus controller configured to provide focusing by moving the focus lens in the in-focus direction. The focus controller is configured to set an amplitude of the focus lens when moving a center of a reciprocation of the focus lens, to be less than that of the focus lens when the center of the reciprocation of the focus lens is not moved.

Abstract: An imaging apparatus includes: a supplying section configured to supply a driving command for driving at least a portion of a lens in a specific direction to a focal-point adjustment device for changing or adjusting a focal-point distance in accordance with power supplied to the focal-point adjustment device; and an inference section configured to infer a position, at which the lens is located after being driven in accordance with the driving command in the specific direction, on the basis of the driving command supplied to the focal-point adjustment device and on the basis of error information serving as information on an error of a driving quantity by which the lens driven by the focal-point adjustment device is moved.

Abstract: A camera module includes a lens system, an image sensor, and an actuator. The actuator is fixed relative to the image sensor, and the actuator moves the lens system relative to the image sensor to achieve focus. Components that move relative to each other result in gaps or spaces between the components, an in particular there is a gap between the lens system and the actuator. Such a gap provides a traveling path for foreign material, or particulates, to enter the camera module and reach the image sensor, or other intermediate optical components between the lens system and the image sensor. A camera contamination reduction apparatus is implemented as a protective membrane that prevents foreign material from reaching the internal optical components through the traveling path.

Abstract: A camera system (1) includes an interchangeable lens (200) and a camera body (100). The camera body (100) includes a body controller (140) configured to generate a command, and a sending unit (150) configured to send the generated command to the interchangeable lens. The interchangeable lens (200) includes a movable member (230, 260), a driving unit (233, 261) configured to drive the movable member, a receiving unit (250) configured to receive a command from the camera body, and a lens controller (240) configured to control the driving unit according to the received command. Further, a prediction unit (140, 240) is provided in either one of the camera body and the interchangeable lens, which predicts whether an operation of the driving unit of the interchangeable lens according to the received command will be completed within a predetermined time.

Abstract: An image pickup apparatus which is capable of accurately acquiring evaluation values at target positions for contrast evaluation value acquisition to thereby suppress degradation of accuracy of autofocus due to skipping the reading of a contrast evaluation value at an in-focus position and an increase in autofocus time. The image pickup apparatus acquires from an interchangeable lens at least one of a drivable defocus amount of the interchangeable lens, and a driving speed in driving of a focus lens to focus adjustment positions. The image pickup apparatus changes a lens driving method for focus detection, based on at least one of the drivable defocus amount, the driving speed, and a charge storage interval for charge storage in an image pickup element for acquiring a signal for use in focus detection.

Abstract: A remote communication apparatus for receiving the image of a remote user captured by an imaging device to show the image to another user includes a zoom controller for controlling a zoom ratio defining the angle of view of the imaging device, and an estimator for estimating a distance between the imaging device and the remote user on the basis of the zoom ratio of the imaging device.

Abstract: An imaging apparatus that adjusts focus based on frequency components extracted from an image signal is provided. The apparatus includes a 1st order Infinite Impulse Response (IIR)-filter including a plurality of sample delayers having a plurality of line buffers for buffering and delaying a plurality of samples to sequentially read pixels of the image signal through raster scanning and extracting frequency components of the image signal from the read pixels by using the plurality of sample delayers; and a delay sample number controller for controlling the IIR-filter to match the number of horizontal pixels sequentially read from the image signal through raster scanning to the number of the plurality of samples buffered by the plurality of line buffers.

Abstract: Provided are a lens driving motor and an elastic member of the lens driving motor. The elastic member of a lens driving motor, the elastic member includes a first spring and a second spring. The second spring is different from the first spring and disposed together with the first spring on one side of a carrier to support the carrier. A first lead line of a coil and a first external power source are connected to the first spring, and a second lead line of the coil and a second external power source are connected to the second spring to supply power to the coil. Since the carrier can be assembled to other part after a (+) lead line and a (?) lead line of the coil are connected to the first and second springs, respectively, using solder, a process is simple and convenient.

Abstract: A remote communication apparatus for receiving the image of a remote user captured by an imaging device to show the image to another user includes a zoom controller for controlling a zoom ratio defining the angle of view of the imaging device, and an estimator for estimating a distance between the imaging device and the remote user on the basis of the zoom ratio of the imaging device.

Abstract: An image pickup apparatus includes an image pickup unit including two-dimensionally arranged photoelectric conversion elements, the image pickup unit being configured to perform an photoelectric conversion of an object image formed on an image pickup plane and to output an image signal, a detector configured to detect a focus signal based on the image signal obtained by moving a focus lens, and a controller configured to find an in-focus direction based on the focus signal and to provide a control so that the focus lens can be moved in the in-focus direction. The controller selects one of a plurality of interruption timings that occur in a synchronization signal in moving the focus lens, and starts moving the focus lens with a selected interruption timing.

Abstract: Methods and apparatus for capturing and rendering images with focused plenoptic cameras employing different filtering at different microlenses. In a focused plenoptic camera, the main lens creates an image at the focal plane. That image is re-imaged on the sensor multiple times by an array of microlenses. Different filters that provide different levels and/or types of filtering may be combined with different ones of the microlenses. A flat captured with the camera includes multiple microimages captured according to the different filters. Multiple images may be assembled from the microimages, with each image assembled from microimages captured using a different filter. A final image may be generated by appropriately combining the images assembled from the microimages. Alternatively, a final image, or multiple images, may be assembled from the microimages by first combining the microimages and then assembling the combined microimages to produce one or more output images.

Abstract: Systems and methods are directed to acquiring, generating, manipulating and/or editing refocusable video data/frames. The refocusable video frames may be light field video frames that may be focused and/or refocused after acquisition or recording of such video frames. In one aspect, a method comprises: selecting a first key frame, wherein the first key frame corresponds to one of a plurality of refocusable light field video frames; selecting a second key frame, wherein the second key frame corresponds to one of the plurality of refocusable light field video frames which is temporally spaced apart from the first key frame such that a plurality of refocusable light field video frames are temporally disposed between the first and the second key frames; determining virtual focus parameters for the first key frame and the second key frame; and generating video data.

Abstract: A method of using an image capture device to identify range information for objects in a scene includes providing an image capture device having an image sensor, at least two coded apertures, and a lens; storing in a memory a set of blur parameters derived from range calibration data for each coded aperture; capturing images of the scene having a plurality of objects using each of the coded apertures; providing a set of deblurred images using the captured images from each coded aperture and each of the blur parameters from the stored set; and using the set of deblurred images to determine the range information for the objects in the scene.

Abstract: There is disclosed stereographic camera system including a left and a right camera including respective lenses, plural mechanisms to synchronously set a focal length of the lenses, to synchronously set a focal distance of the lenses, to set a convergence angle between the left and right cameras, and to set an intraocular distance between the left and right cameras. A distance measuring device may be used to measure the distance to an extreme object. A controller may cause an interocular distance and a convergence angle between the left and right cameras to be set based on a maximum allowable disparity, the focal length of the lenses, and a convergence distance.

Abstract: An image pickup apparatus includes an image sensor and a photographing optical system. An imaging surface of the image sensor includes an effective light-receiving area having a rectangular shape that is defined by short sides and long sides. An optical surface of a lens that is provided closest to the image plane within the photographing optical system and which possesses an imaging function has a non-circular shape in a front elevational view. A boundary of the non-circular optical surface of the lens that is provided closest to the image plane includes two pairs of mutually parallel sides so that, when the lens that is provided closest to the image plane is rotated about the optical axis relative to the imaging surface, an image area formed by the non-circular optical surface covers the rectangular effective light-receiving area of the imaging surface before and after rotation.

Abstract: Position detection unit detecting absolute positions without moving an object to be detected. The detection unit having a first sensor for outputting a monotone signal, that changes in response to displacement of an object to be detected; a second sensor for outputting two sinusoidal signals in response to displacement of the object to be detected; a first memory for storing a monotone signal relative to the position of the object to; a second memory for storing max and min values for each sinusoidal signal; and a position calculator for identifying the cycle of the sinusoidal signal in which the object to be detected is positioned based on the detected monotone signal and stored monotone signal data, and for calculating the position of the object to be detected within the identified cycle and obtaining an absolute position, based on the detected sinusoidal signal and the stored max/min data.

Abstract: An automatic focusing method for a camera, including scanning in a macro mode, scanning in a normal mode, and additional scanning. In the scanning in the macro mode, a region within a first distance is scanned if the macro mode is set by a user. In the scanning in the normal mode, a region beyond the first distance is scanned if the normal mode is set by the user. In the additional scanning, the scanning in the normal mode is performed additionally if it is determined that the position of the focus lens found in the scanning in the macro mode does not have the largest focus value, and the scanning in the macro mode is performed additionally if it is determined that the position of the focus lens found in the scanning in the normal mode does not have the largest focus value.

Abstract: Methods for automatic focus in a stereographic imaging device that includes two imaging sensor systems are provided. Focus searches are executed on both imaging sensor systems to determine optimal focused lens positions for each. The focus searches may be executed currently or sequentially, and may be at differing lens position granularities. Focal scores and spatial locations, i.e., the locations of focus regions, may be shared between the imaging sensor systems to coordinate the focus searches. Touchscreen coordinates may also be used to coordinate the focus searches.

Abstract: A camera lens actuation apparatus for driving motion of a camera lens supported on a support structure by a suspension system. The apparatus incorporates a subassembly comprising SMA wire connected to at least one mounting member which is mounted to the support structure. At least one pair of lengths of SMA wire are held in tension between the camera lens element and the support structure at respective acute angles to the optical axis applying a tensional force having a component along the optical axis. The lengths of SMA wire in the pair are held at angle as viewed along the optical axis. There may be plural pairs with a balanced arrangement in which the forces generated have no net component perpendicular to the optical axis and generate no net torque around any axis perpendicular to the optical axis. A control circuit controls heating of the SMA wire in response to a measure of its resistance.

Abstract: Methods and apparatus for rich image capture using focused plenoptic camera technology. A radiance camera employs focused plenoptic camera technology and includes sets of modulating elements that may be used to modulate the sampling of different aspects of the range of plenoptic data. The radiance camera, via the modulating elements, may capture a particular property of light, such as luminance, color, polarization, etc., differently in different microimages or in different portions of microimages. With the focused plenoptic camera technology, the microimages are captured at the same time in a single image. Thus, multiple microimages of the same image of a scene may be captured at different exposures, different colors, different polarities, and so on, in a single image at the same time. Captured images may be used, for example, in High Dynamic Range (HDR) imaging, spectral imaging, polarization imaging, 3D imaging, and other imaging applications.

Abstract: An apparatus for removing motion blur of an image is disclosed. The apparatus includes a motion-blur-function-estimation unit that estimates the motion-blur function of an input image, an image-restoration unit that restores the input image using the estimated motion-blur function, a cost-calculation unit that calculates the blur cost of the restored image, and a control unit that determines the re-estimation of the motion-blur function depending on the calculated blur cost.

Abstract: In an example embodiment, a method for focusing a miniature camera includes applying a signal to an actuator in the camera, moving a MEMS stage movably supported by one or more flexures in response to the application of the signal, moving a lens in response to the moving of the MEMS stage, and limiting movement of the MEMS stage to substantially one degree of freedom corresponding to an optical axis of the lens.

Abstract: An image processing apparatus includes: a blur removing processing section configured to carry out a blur removing process for an input image using a plurality of blur removal coefficients for removing blur of a plurality of different blur amounts to produce a plurality of different blur removal result images; a feature detection section configured to detect a feature from each of the different blur removal result images; a blur amount class determination section configured to determine blur amount classes representative of classes of the blur amounts from the features; and a prediction processing section configured to carry out mathematic operation of pixel values of predetermined pixels of the input image and prediction coefficients learned in advance and corresponding to the blur amount classes to produce an output image from which the blur is removed.

Abstract: An imaging apparatus includes an apparatus body having an outer casing, at least a shutter mechanism and an imaging device placed inside the outer casing, an opening formed in the outer casing, and a storage space and a placement space defined inside the outer casing and communicating with the opening and the storage space, respectively, a strobe unit having a lid part and a light-emitting part and connected to the apparatus body so as to be movable between close and open positions, a sensor unit placed in the placement space and having an autofocus sensor and a sensor adjusting part having plural adjusting screws, and a mirror placed inside the outer casing to reflect part of incident light toward the autofocus sensor. When the strobe unit is moved to the open position, the storage space is defined as an adjustment space into which an adjustment jig can be inserted.

Abstract: An image-capturing system includes: an image-capturing device that captures an image of a subject; and an illumination device that illuminates the subject. The image-capturing device includes a control unit that calculates a light quantity needed to illuminate the subject based upon at least, either an exposure time or an aperture value and image-capturing sensitivity. The illumination device includes a current-controlled light emission unit that emits light used to illuminate the subject and a light emission control unit that controls the light emission unit so as to emit light in the light quantity calculated by the control unit.

Abstract: Provided are a lens driving motor and an elastic member of the lens driving motor. The elastic member of a lens driving motor, the elastic member includes a first spring and a second spring. The second spring is different from the first spring and disposed together with the first spring on one side of a carrier to support the carrier. A first lead line of a coil and a first external power source are connected to the first spring, and a second lead line of the coil and a second external power source are connected to the second spring to supply power to the coil. Since the carrier can be assembled to other part after a (+) lead line and a (?) lead line of the coil are connected to the first and second springs, respectively, using solder, a process is simple and convenient.

Abstract: Example methods and apparatus to perform multi-focal plane image acquisition and compression are disclosed. A disclosed example method includes capturing a first image of a portion of an object at a first focal plane and at a first resolution, computing a contrast metric for the captured first image, comparing the contrast metric to a threshold to determine whether to capture a second image of the portion of the object at the first focal plane and at a second resolution, wherein the second resolution is different from the first resolution, capturing the second image of the portion of the object at the first focal plane and at the second resolution, and storing a first representation of the second image in a file, the file containing a second representation of the portion of the object at a second focal plane, wherein the second representation is at the first resolution.

Abstract: A digital camera comprises an imaging/focus detection element, in which focus detection pixel rows are incorporated in a two-dimensional array of a plurality of imaging pixels, that outputs image signals and focus detection signals, a focus detection unit that detects a state of focal adjustment at a photographic optical system based upon the focus detection signal, an image blur detection unit that detects an image blur quantity, a reliability judgment unit that judges, based upon the blur quantity, whether or not the state of focal adjustment detected in correspondence to a focus detection pixel row disposed along a direction different from a rolling shutter scanning direction among the focus detection pixel rows is reliable, and a focal adjustment unit that executes focal adjustment for the photographic optical system based upon the state of focal adjustment judged to be reliable by the reliability judgment unit.

Abstract: Systems and methods directed to acquiring, generating, manipulating and/or editing refocusable video data/frames. The refocusable video frames may be light field video frames that may be focused and/or re-focused after acquisition or recording of such video frames. In one aspect, method comprises: selecting a first key frame, wherein the first key frame corresponds to one of a plurality of refocusable light field video frames, selecting a second key frame, wherein the second key frame corresponds to one of the plurality of refocusable light field video frames which is temporally spaced apart from the first key frame such that a plurality of refocusable light field video frames are temporally disposed between the first and the second key frames, determining a virtual focus parameters for the first key frame and the second key frame, and generating first video data.

Abstract: An image capturing apparatus performs autofocus control that uses a face detection function. The image capturing apparatus sets a face region as an AF frame if face detection is successful. However, if a state in which face detection is successful transitions to a state in which face detection has failed, and furthermore a variation between subject distances is less than or equal to a threshold value, the image capturing apparatus maintains the previous AF frame setting instead of changing the AF frame setting. If the variation in subject distances is greater than the threshold value, the image capturing apparatus sets the AF frame to a predetermined region that does not follow a face region.

Abstract: A camera module includes a lens system, an image sensor, and an actuator. The actuator is fixed relative to the image sensor, and the actuator moves the lens system relative to the image sensor to achieve focus. Components that move relative to each other result in gaps or spaces between the components, an in particular there is a gap between the lens system and the actuator. Such a gap provides a traveling path for foreign material, or particulates, to enter the camera module and reach the image sensor, or other intermediate optical components between the lens system and the image sensor. A camera contamination reduction apparatus is implemented as a protective membrane that prevents foreign material from reaching the internal optical components through the traveling path.

Abstract: Methods and apparatus for capturing and rendering images with focused plenoptic cameras employing different filtering at different microlenses. In a focused plenoptic camera, the main lens creates an image at the focal plane. That image is re-imaged on the sensor multiple times by an array of microlenses. Different filters that provide different levels and/or types of filtering may be combined with different ones of the microlenses. A flat captured with the camera includes multiple microimages captured according to the different filters. Multiple images may be assembled from the microimages, with each image assembled from microimages captured using a different filter. A final image may be generated by appropriately combining the images assembled from the microimages. Alternatively, a final image, or multiple images, may be assembled from the microimages by first combining the microimages and then assembling the combined microimages to produce one or more output images.

Abstract: Provided are a focusing position determining apparatus, an imaging apparatus, and a focusing position determining method, the method including setting an aperture to a first aperture value; driving a focus lens through a first range of positions as a first drive; during the first drive, obtaining images periodically, and calculating a first sampling of contrast values from the obtained images; calculating a first focus position from the first sampling of contrast values; setting the aperture to a second aperture value; driving a focus lens through a second range of positions as a second drive, the second range of positions being based on the first focus position; during the second drive, obtaining images periodically, and calculating a second sampling of contrast values from the obtained images; calculating a focusing position from the second sampling of contrast values; and driving the focus lens to the calculated focusing position.

Abstract: An automatic focusing apparatus includes: plural focus detection units detecting focus states in plural areas independently; a unit measuring detection time of the focus detection units; a unit calculating a maximum focus detection time; a unit calculating defocus amounts based on outputs from the focus detection units; a unit driving a focus lens based on the defocus amounts; and a unit calculating an object predicted position. When the focus detection time exceeds the maximum focus detection time, all detections by the focus detection units are completed, defocus amounts corresponding to the respective plural areas are calculated based on the focus states in the areas detected by the focus detection units, and the focus lens is driven according to an output of the focus detection unit corresponding to a focus target position where a difference between the focus target position and the object predicted position is within an allowable range.

Abstract: An image pickup apparatus includes: an in-focus operation section configured to drive a focus lens to move over a predetermined driving range in order to detect evaluation values each representing the strength of the contrast of an image signal generated based on a subject of an image pickup operation from a plurality of predetermined positions and find an in-focus position of the focus lens based on the evaluation values; a detector configured to acquire first evaluation values obtained for the predetermined positions during a first period of driving the focus lens to move over the predetermined driving range, and second evaluation values obtained for at least one of the predetermined positions during a second period between the end of the first period and a process to find the in-focus position based on the first evaluation values; and a change measurement section configured to measure a change of the evaluation value.

Abstract: A back focus adjustment apparatus of a camera includes a casing, an adjusting module and an image capturing device. The adjusting module includes a fixed support, a movable support and a drive module. The drive module includes an adjustment wheel and two drive wheels. The lens module is mounted on a bottom surface of the casing. The fixed support is fixed in the casing and opposite to the bottom surface thereof. The image capturing device is mounted on the movable support. The drive module is defined on the fixed support. The drive module is connected to the movable support through worm gears defined on drive wheels. The drive wheels and the adjustment wheel are gearingly engaged. The image capturing device moves back and forth according to the adjustment of the adjusting wheel of the adjusting module.

Abstract: An imaging apparatus includes an imaging device receiving light from an object through an imaging lens at a predetermined imaging plane and performing photoelectric conversion of an object image to generate a captured image; a phase-difference detector for receiving the light from the object and generating a phase-difference detection signal corresponding to a focus level of the object image; an evaluation-value calculator for calculating a predetermined evaluation value corresponding to a contrast of the object image on the basis of the captured image; and a determining unit for selecting an optimum AF method from among a plurality of AF methods in which the phase-difference detection signal obtained by the phase-difference detecting unit and the predetermined evaluation value based on the captured image are used selectively or in combination, the optimum AF method being selected in accordance with image-capturing conditions of the object.

Abstract: A camera auto-focuses using computed blur differences between images of a three-dimensional scene. The camera computes the blur difference between two images of the scene acquired at two different picture numbers. The camera uses the computed blur difference to predict a third picture number, where the camera uses the third picture number to auto-focus a camera lens on the scene.

Abstract: An electronic camera includes a menu providing section that provides a focus area selection menu that allows a user to select a focus area, a characterizing portion detecting section that detects a characterizing portion of an object, and an area setting section that sets a focus area based on the characterizing portion detected by the characterizing portion detecting section. The focus area selection menu that is provided by the menu providing section to the user includes, as a selection item, a focus area to be set by the area setting section.

Abstract: Disclosed are a focus detecting apparatus capable detection in various light illumination conditions and an image acquiring apparatus having the same. The focus detecting apparatus may include a mark disposed on a primary image plane. A pair of images of the mark is detected by a sensor, the distance between which images is used to determine the main wavelength of the light received from a subject. The main wavelength is used in determining the chromatic aberration correction by which the defocus amount may be adjusted.

Abstract: A lens barrel assembly for a camera is disclosed. The lens barrel assembly comprises a lens barrel, at least one optical element disposed within the lens barrel, and an actuator configured to move the optical element. The actuator can be disposed entirely or partially within the lens barrel. The actuator can be a MEMS actuator, such as a MEMS actuator that is formed at least partially of silicon. The optical element can be a lens.

Abstract: An imaging apparatus includes an imaging sensor, a reticle, a focus detection unit, a spectroscopic member, and a diffusion coefficient controller. The imaging sensor is configured to receive light from a lens unit. The reticle is capable of changing a diffusion coefficient. The focus detection unit is configured to detect a focus state of an imaging surface based on a signal from the imaging sensor. The spectroscopic member is configured to split the light from the lens unit to the reticle and the focus detection unit. The diffusion coefficient controller is configured to change the diffusion coefficient of the reticle. The diffusion coefficient controller controls a diffusion coefficient of a portion of the reticle corresponding to a defocus range to be higher than a diffusion coefficient of a portion of the reticle corresponding to a focusing range according to the focus state detected by the focus detection unit.

Abstract: Disclosed are an optical system for infinite image formation and a method for fabricating a camera module using the optical system. The optical system includes a first lens unit including at least one lens; a projection chart capable of partially allowing light to pass therethrough; a backlight unit capable of emitting light; and a first holder coupled with the first lens unit, the projection chart and the backlight unit. The first lens unit is exposed through an opening of the first holder. The method includes coupling the optical system with a camera module including a first lens unit, an image sensor and a printed circuit board, where the optical system is coupled to the first lens unit; and adjusting an effective focal length between the first lens unit and the image sensor by rotating the optical system and the first lens unit of the camera module.

Abstract: An imaging apparatus includes: a supplying section configured to supply a driving command for driving at least a portion of a lens in a specific direction to a focal-point adjustment device for changing or adjusting a focal-point distance in accordance with power supplied to the focal-point adjustment device; and an inference section configured to infer a position, at which the lens is located after being driven in accordance with the driving command in the specific direction, on the basis of the driving command supplied to the focal-point adjustment device and on the basis of error information serving as information on an error of a driving quantity by which the lens driven by the focal-point adjustment device is moved.

Abstract: A driving device is adapted to drive a driven member, and includes a driving member, and a linear shape memory alloy (SMA) actuator. The driving member has a displacement output portion which is movable in a first axis direction, and a displacement input portion for moving the displacement output portion in the first axis direction in response to an application of a moving force in a second axis direction orthogonal to the first axis direction. The driving member is engaged with the driven member at the displacement output portion. The SMA actuator is disposed in contact with the driving member at least at the displacement input portion to apply the moving force to the displacement input portion.

Abstract: An image pickup apparatus includes an image pickup device configured to capture an image regarding an object image; an object detector detecting a specific object in the captured image; an image-capturing-information obtaining unit obtaining image capturing information from a predetermined area set in an image capturing area; a determiner determining whether or not the image capturing information regarding the specific object is obtainable from the predetermined area; and a display controller controlling a position display shown on a display unit, the position display indicating a position of the specific object. The display controller changes a display mode of the position display in accordance with the result of the determination performed by the determiner.

Abstract: An image pickup apparatus with an AF sensor unit fixed thereto promptly with high precision by a parallax adjustment method. The image pickup apparatus with the AF sensor has a stationary cylinder. The stationary cylinder constitutes an image pickup lens barrel with a first axis and a second axis that are perpendicular to an optical axis of the lens barrel and are perpendicular to each other. An AF sensor holder is configured to hold said AF sensor. An AF sensor holder-mounting unit is mounted on the stationary cylinder through a first axis rotation-adjusting mechanism rotatably with respect to the first axis, and configured to support said AF sensor holder through a second axis rotation-adjusting mechanism rotatably with respect to the second axis. The first axis rotation-adjusting mechanism and the second axis rotation-adjusting mechanism are directed in the same direction at operation sides thereof, respectively.

Abstract: An auto focus image system that includes a pixel array coupled to a focus signal generator. The pixel array captures an image that has at least one edge with a width. The focus signal generator may generate a focus signal that is a function of the edge width and/or statistics of edge widths. A processor receives the focus signal and/or the statistics of edge widths and adjusts a focus position of a focus lens. The edge width can be determined by various techniques including the use of gradients. A histogram of edge widths may be used to determine whether a particular image is focused or unfocused. A histogram with a large population of thin edge widths is indicative of a focused image. The generator may eliminate an edge having an asymmetry of a gradient profile of an image signal. The generator may also eliminate an edge that fails a template for an associated peaking of the gradient.