Abstract: An image processing device includes: a detection unit detecting a movement amount of an image between first image data constituting image data generated by an image capturing element provided with a plurality of image generating pixels generating pixel values for generating an image and a plurality of pairs of phase difference detecting pixels generating pixel values for performing focusing determination by phase difference detection, and second image data subsequent to the first image data on a time axis, wherein the movement amount is a movement amount of one phase difference detecting pixel when a defective pixel included in the pair of phase difference detecting pixels is one of the pair; and a correction unit correcting the pixel value of the defective pixel in the second image data on the basis of the detected movement amount and the pixel value of one phase difference detecting pixel in the first image data.

Abstract: A method is for monitoring the electrical integrity of lines of photosites of an imaging device with matrix array of photosites. The control lines of photosites may include for each line of photosites an emission of elementary electrical control signals for the photosites of the line. The method may include diagnosis of the elementary electrical control signals emitted.

Abstract: The optical apparatus including a motor to move an optical element, a position detector configured to detect a position of the optical element, a controller configured to control drive of the motor by using a position detection signal from the position detector, and a memory configured to store a reference movement amount of the optical element corresponding to a moving speed and a moving time period of the optical element moved by the motor. The controller is configured to acquire a correction value for reducing a difference between (a) an actual movement amount of the optical element obtained by using the position detection signal when the optical element is moved by the motor and (b) the reference movement amount, and then to control the drive of the motor by using the correction value.

Abstract: At least certain embodiments described herein provide a continuous autofocus mechanism for an image capturing device. The continuous autofocus mechanism can perform an autofocus scan for a lens of the image capturing device and obtain focus scores associated with the autofocus scan. The continuous autofocus mechanism can determine an acceptable band of focus scores based on the obtained focus scores. Next, the continuous autofocus mechanism can determine whether a current focus score is within the acceptable band of focus scores. A refocus scan may be performed if the current focus score is outside of the acceptable band of focus scores.

Abstract: A solid-state imaging device includes a semiconductor substrate having a principal surface, and three or more pixel regions formed in at least one direction of two different directions along the principal surface of the semiconductor substrate. Each pixel region includes a plurality of photoelectric conversion regions having different sensitivities. The photoelectric conversion region having the highest sensitivity in peripheral pixel regions of the pixel regions has a higher sensitivity than the photoelectric conversion region having the highest sensitivity in a central pixel region of the pixel regions.

Abstract: An image processing apparatus includes an imaging unit which captures an image, and a focal range control unit which changes a focal position and a depth of field of a captured image by controlling an imaging device or a focus lens in the imaging unit. Further, the image processing apparatus includes a distance measurement unit which measures a distance to a subject, from a degree of blur in each of n images (where n ?2) captured by the imaging unit controlled by the focal range control unit and having focal ranges different from each other.

Abstract: A digital photographing apparatus includes a focus lens, a focus detection unit that detects focus in a contrast auto focusing (AF) method by moving the focus lens, and a controller that calculates a velocity of a subject from a first focus detection result and a second focus detection result in a continuous shooting operation. The controller restricts a U-turn driving for correcting backlash of the focus lens when the calculated velocity of the subject is equal to or greater than a predetermined value. An AF initiating location and a final correction operation are adaptively adjusted based on the velocity of the subject in each process of the continuous shooting, thereby improving an AF performance and the continuous photographing speed.

Abstract: An imaging apparatus includes a first imaging unit, a second imaging unit, a light measurement calculator, a holding unit, a detection unit, a recognition unit, a selection unit, and a focus adjustment controller. The second imaging unit is configured to acquire first image information, second image information, and third image information. The selection unit is configured to select the at least one of focus detection areas using a recognition result of the recognition unit. The focus adjustment controller is connected to the selection unit and is configured to perform a focus adjustment control using a focus adjustment state in a focus detection area selected by the selection unit. The changing unit is connected to the recognition unit and is configured to change the predetermined range based on the first determination and the second determination.

Abstract: In a method for correcting shading effects in an image sensor including a plurality of pixels, shading effects on at least one readout pixel of the image sensor are modeled based on a parametric component, and the shading effects on the at least one readout pixel are corrected based on the modeled shading effects. The parametric component is dependent on at least one of a color channel corresponding to the readout pixel and a color correlated temperature of light incident on the at least one readout pixel.

Abstract: An image processing apparatus according to the present invention, comprises: a motion detection unit that detects a motion vector from an input image; a determination unit that determines whether an image is moving in each pixel in use of the detected motion vector, and determines whether a motion pixel, about which determination has been made that the image is moving therein, exists in a predetermined range from a still pixel about which determination has been made that the image is not moving therein; and a correction unit that performs correction processing to decrease at least one of high frequency components, contrast, and luminance for the still pixel about which determination has been made that a motion pixel exists in the predetermined range.

Abstract: An imaging apparatus includes an imaging unit configured to capture an image, a subject detector configured to detect a subject from the image captured by the imaging unit, a setting unit configured to set, in accordance with a change of a position of the subject detected by the subject detector, an image region to be focused on for the changed position of the subject, a focus unit configured to perform a focus operation to the subject included in the set image region, and a controller configured to control a speed of the focus operation according to a moving speed of the subject detected by the subject detector.

Abstract: An imaging control unit includes: a detecting unit that detects a focused-status of a focus detecting range set to an image data of each frame; a setting unit that sets, at a position of a distinctive-region including a distinctive points of an object detected from an processed image data, a focus detecting range of an image data of a subsequent frame; and a control unit that performs, when the focus detecting range is not in focused-status, a focal length control to change a focal length of a imaging lens so that the focus detecting range is in focused-status. When a displacement amount from the focus detecting range set to the imaged image data to the distinctive-region detected in the processed image data based on the imaged image data is large, the control unit aborts performing the focal length control even when the focus detecting range is not in focused-status.

Abstract: An image-pickup apparatus includes an image-pickup section that picks up images to obtain picked-up-image-data items, a temporarily retaining section that temporarily retains the picked-up-image-data items, a storage-process section that performs a storage process on the picked-up-image-data items, a movement-detecting section that detects a movement of the image-pickup apparatus, an operation section that performs a shutter operation, and a control section that causes the temporarily retaining section to retain picked-up-image-data items in a shutter-operation period, that selects, on the basis of detection results obtained by the movement-detecting section in the shutter-operation period, a picked-up-image-data item from among the retained picked-up-image-data items, and that causes the storage-process section to perform the storage process on the selected picked-up-image-data item.

Abstract: An image capturing apparatus capable of switching between an optical viewfinder and live view which involves periodically reading out an image signal out of an image sensor and sequentially displaying the image signal on a display unit, comprises a phase difference focus control unit that performs auto focus control using a phase difference detection method; a selection unit that selects one of a plurality of focus detection areas used for the auto focus control; an electronic zoom unit that changes an angle of view; and a control unit that causes the phase difference focus control unit to perform auto focus control by the phase difference detection method using the selected focus detection area if the selected focus detection area is located within the changed angle of view, otherwise not to perform auto focus control by the phase difference detection method using the selected focus detection area.

Abstract: An image pickup apparatus capable of performing proper image evaluation in photographing a moving image by changing the exposure condition. An image pickup unit picks up an image of an object and a driving unit drives a focus lens in an optical axis direction. A control circuit controls a focus state of the object by causing the driving unit to move the focus lens in the optical axis direction. A focus evaluation value is acquired from each image. The control circuit causes the image pickup unit to pick up images of a multistage exposure image group by changing exposure time, selects an image according to exposure time, updates a direction of driving the focus lens using the focus evaluation value acquired from the selected image, and causes the driving unit to move the focus lens in the updated driving direction.

Abstract: A shift amount between a plurality of image signals that is obtained from pixels in each of which a plurality of photoelectric conversion units are provided is computed from an amount of correlation based on a difference value between the plurality of image signals. Also, if the difference value that is used for computing the amount of correlation is not less than a predetermined upper limit, a predetermined value that is not more than the upper limit is used as the difference value.

Abstract: Disclosed herein are an image capturing apparatus and a method of controlling the same, by which images may be captured without direct contact with a main body of the image capturing apparatus and without purchasing and carrying an additional remote controller. The method of controlling the image capturing apparatus includes generating a first detection signal and a second detection signal in response to motion of an object within a detection region of an ocular sensor, controlling a focusing module to bring a subject into focus in response to the generation of the first detection signal, and controlling a shutter and an imaging device to capture an image of the subject in response to the generation of the second detection signal.

Abstract: A digital image acquisition system having no photographic film comprises a portable apparatus for capturing digital images and a digital processing component for reducing camera motion blur in an image captured by the apparatus. The digital processing component operates by comparing the image with at least one other image, for example a preview image, of approximately the same scene taken outside the exposure period of the main image. In one embodiment the digital processing component identifies at least one feature which is relatively less blurred than the corresponding feature in the main image, and/or calculates a trajectory of at least one feature in a plurality of preview images and extrapolates such feature onto the main image, and calculates a PSF in respect of the feature, and de-convolves the main image using the PSF.

Abstract: An image capturing apparatus includes an image sensor provided in the neighborhood of an image plane of a photographing optical system for forming the image of a subject; pupil dividing member for forming images of a pair of light beams that have passed through different pupil regions of the photographing optical system; focus detection sensors arranged two-dimensionally for photoelectrically converting images of the pupil dividing member; and a correlation calculation unit which, in order to obtain one focus measurement value from one pair of two-dimensional images generated by the focus detection sensors and extending in the pupil dividing direction of the pupil dividing member and in a direction perpendicular to the pupil dividing direction, calculates the correlation between the pair of two-dimensional images while shifting the pair of two-dimensional images in the pupil dividing direction.

Abstract: An imaging device includes: a first imaging unit which does not include a phase difference detecting pixel on an imaging element; a second imaging unit which includes a phase difference detecting pixel on an imaging element; a pixel comparing unit which compares first obtained image obtained by the first imaging unit with a second obtained image obtained by the second imaging unit; a correcting unit which corrects phase difference information obtained by the second imaging unit based on a comparison result by the image comparing unit; a phase difference applying unit which applies the phase difference information corrected by the correcting unit to the first obtained image; and a recording unit which records image information.

Abstract: A mobile multimedia device may be operable to crop a series of image samples received during an autofocus operation. Each of the cropped image samples may be scaled by the mobile multimedia device to fit a display unit in the mobile multimedia device. Each of the scaled image samples may then be displayed on the display unit for viewing during the autofocus operation. The received image samples may be cropped based on an operating mode in which the mobile multimedia device is currently operating. The autofocus operation may be initiated utilizing a shutter button in the mobile multimedia device. The autofocus operation may be terminated when a desired focus is achieved. After the autofocus operation is terminated, the mobile multimedia device may be operable to display one or more image samples received after the termination of the autofocus operation for continuous viewing, with or without further cropping and scaling.

Abstract: An imaging apparatus that determines in-focus conditions according to a user's taste by using auto-focus (AF). The imaging apparatus including an AF unit, that allows the user to input an in-focus operation start command, and that allows the user to input a main photographing start command. The imaging apparatus includes a photographing environment storing unit that stores photographing stop and start data, an assumed in-focus condition group generating unit that generates an assumed in-focus condition group based on at least the photographing stop data, an assumption confirming unit that confirms the assumed in-focus condition group, and an in-focus condition group changing unit that, if an in-focus success rate for the assumed in-focus condition group is higher than for the default in-focus condition group, changes the default in-focus condition group to the assumed in-focus condition group.

Abstract: A portable electronic device and an autofocus control method of a camera of the portable electronic device are disclosed. The portable electronic device provides a G-sensor to detect the orientation of the portable electronic device, and provides a storage unit to store autofocus lookup tables for different orientations of the portable electronic device, respectively. According to orientation information from the G-sensor, the central processing unit of the portable electronic device selects one autofocus lookup table from the storage unit and thereby generates an actuating signal for a focus model. The focus model of the portable electronic device is actuated by the actuating signal to adjust an image distance between a lens module and an image sensor of the camera.

Abstract: An imaging apparatus includes an optical system including a focus lens, an imaging unit operable to capture a subject image formed by the optical system to generate image data, a driver operable to drive the focus lens along an optical axis of the optical system, and an autofocus adjusting unit operable to adjust a subject image formed on the imaging unit to be in focus by evaluating the image data generated by the imaging unit and by controlling the driver to drive the focus lens. When adjusting the subject image to be in focus anew after previously adjusting the subject image to be in focus, the autofocus adjusting unit estimates a focus position and controls the driver to drive the focus lens according to a driving method used for evaluating the image data generated by the imaging unit, and different driving methods are used for different results of the estimation.

Abstract: An electronic device may have a digital image sensor for capturing an image and may have storage and processing circuitry for processing the image to produce a corresponding enhanced depth-of-field image. Multiple image areas, within a given image may be processed. As each image area is processed, a signal-to-noise ratio may be computed. A kernel parameter characteristic curve may be used to select values to be used for kernel parameters for each image area based on the computed signal-to-noise ratio for that image area. Kernels may be generated for each image area and the generated kernels may be convolved with their respective image areas to modify the image areas. This allows each image area to be selectively sharpened or smoothed based on its signal-to-noise ratio. Image areas with low and high signal-to-noise ratios may be sharpened less those with moderate signal-to-noise ratios to enhance depth of field in the image.

Abstract: An image capturing apparatus capable of switching between an optical viewfinder and live view which involves periodically reading out an image signal out of an image sensor and sequentially displaying the image signal on a display unit, comprises a phase difference focus control unit that performs auto focus control using a phase difference detection method; a selection unit that selects one of a plurality of focus detection areas used for the auto focus control; an electronic zoom unit that changes an angle of view; and a control unit that causes the phase difference focus control unit to perform auto focus control by the phase difference detection method using the selected focus detection area if the selected focus detection area is located within the changed angle of view, otherwise not to perform auto focus control by the phase difference detection method using the selected focus detection area.

Abstract: An image capture device of the present invention includes: a first image capture element 10A and a second image capture element 10B; and an optical system which is capable of forming a first image which is in focus on an image capture plane of the first image capture element 10A and forming a second image which is out of focus on an image capture plane of the second image capture element 10B. An image processing section 220 processes a signal obtained from the first image capture element 10A and a signal obtained from the second image capture element 10B and produces a restored image from an image obtained by the second image capture element 10B, the restored image having reduced camera shake blur and reduced out-of-focus blur.

Abstract: In one embodiment, a solid-state imaging device includes: an imaging optical system including: a first and second surfaces facing each other; a flat reflector provided on the first surface and having an aperture in an outer circumferential portion; and a plurality of reflectors provided on the second surface and located in a plurality of ring-like areas, each of the reflectors being inclined in a radial direction, the reflectors having different diameters from one another; and an imaging element module including: an imaging element including an imaging area having a plurality of pixel blocks each including a plurality of pixels, and receiving and converting light from the imaging optical system into image data; a visible light transmission substrate provided between the imaging optical system and the imaging element; a microlens array provided on a surface of the visible light transmission substrate on the imaging element side; and an image processing unit processing the image data obtained by the imaging ele

Abstract: A captured image processing system includes a portable terminal apparatus and an image output apparatus. The portable terminal apparatus captures images consecutively while detecting a change in position of the portable terminal apparatus during the image capture, and transmits, to the image output apparatus, (i) a plurality of captured image data and (ii) motion information on the change in position detected for each of the plurality of captured image data. The output apparatus receives, from the portable terminal apparatus, the plurality of captured image data and the motion information, carries out, in accordance with the motion information, a positioning process in which the plurality of captured image data are positionally adjusted, prepares, by use of the plurality of captured image data subjected to the positioning process, high resolution image data, and outputs the high resolution image data prepared or an image displayed based on the high resolution image data.

Abstract: Among other things, one or more techniques and/or systems are provided for quantifying blur of an image. Blur may result due to motion of a camera while the image is captured. Accordingly, motion measurement data corresponding to motion of the camera during an exposure event may be used to create a camera rotation matrix. A camera intrinsic matrix may be obtained based upon a focal length and principle point of the camera. A transformation matrix may be estimated based upon the camera rotation matrix and/or the camera intrinsic matrix. The transformation matrix may be applied to pixels within the image to determine a blur metric for the image. In this way, blur of an image may be quantified offline and/or in real-time during operation of the camera (e.g., so that the image may be re-acquired (e.g., on the fly) if the image is regarded as being overly blurry).

Abstract: An imaging apparatus includes an optical system including a focus lens, an imaging unit operable to capture a subject image formed by the optical system to generate image data, a driver operable to drive the focus lens along an optical axis of the optical system, and an autofocus adjusting unit operable to adjust a subject image formed on the imaging unit to be in focus by evaluating the image data generated by the imaging unit and by controlling the driver to drive the focus lens. When adjusting the subject image to be in focus anew after previously adjusting the subject image to be in focus, the autofocus adjusting unit estimates a focus position and controls the driver to drive the focus lens according to a driving method used for evaluating the image data generated by the imaging unit, and different driving methods are used for different results of the estimation.

Abstract: A method for selecting a focus setting for a digital image acquisition appliance, the method comprising: acquiring a first image (350) with a first focus setting (100), acquiring a second image with a second focus setting (102), the second image being acquired sequentially with the first image, dividing the first image (350) into a first grid (104) of macroblocks (352), dividing the second image (106) into a second grid of macroblocks, determining a first zone (354) in the first grid of macroblocks and a second zone in the second grid of macroblocks (108) using a first predetermined selection criteria, calculating a macroblock shift (110) of the first zone with respect to the second zone to a sub-macroblock precision, calculating a first value of a figure-of-merit for the first image and a second value of the figure-of-merit for the second image (112), the first value being calculated using focus metric data obtained from macroblocks belonging to the first grid of macroblocks, the second value being calculate

Abstract: An aspect of the present invention provides an image pickup apparatus, comprising: an image pickup optical system which forms an image of a subject; an imaging device which obtains an image by picking up the image of the subject via the image pickup optical system; a target detection device which detects a size of a target in the image; a first control device which controls a focus position of the image pickup optical system according to the size of the target detected by the target detection device; and a second control device which performs continuous AF that detects a focusing position where a contrast in the image reaches a local maximum by moving the focus position of the image pickup optical system, moves the focus position of the image pickup optical system to the focusing position and keeps an in-focus state.

Abstract: A motion vector calculation unit calculates inter-frame movement amounts. A masked region specification unit separates the entire edge image of frame feature data into (i) an edge image showing relatively large movement amounts and (ii) an edge image showing relatively small movement amounts. The masked region specification unit then specifies the edge image showing relatively large movement amounts as a region to be masked. This way, a correction parameter is detected from a region other than the masked region. When the correction parameter is a slang angle, a slant correction unit performs slant correction on a frame picture obtained by an image sensor.

Abstract: Subject matter disclosed herein may relate to lens actuators used, for example, in auto-focus and/or vibration compensation systems of digital cameras.

Abstract: System and methods are provided for configuring operation of a remote control by a display device. In one embodiment a method includes detecting user selection of an input of the display device and determining a command for the remote control based on the user selection of the input, wherein the command identifies a configuration for the remote control. The method further includes transmitting the command to the remote control, by the display device, for configuration of the remote control, wherein the configuration specifies operation of the remote control with one or more devices associated with the input.

Abstract: An image recognition device includes a detection unit which is configured to detect a first difference between at least a part of the first image information and the reference information, a second difference between at least a part of the second image information and the reference information, and a third difference between at least a part of the third image information and the reference information. A recognition unit is configured to make a first determination whether the first difference is within a predetermined range, and to make a second determination whether the second difference is within the predetermined range. A changing unit is configured to change the predetermined range based on the first and second determinations. The recognition unit is configured to recognize an area corresponding to the reference image in the third image information based on the third difference and the predetermined range which has been changed.

Abstract: Apparatuses and methods for recording and reproducing RAW image data to more precisely correct for hand tremble in response to an electronic hand tremble correction when an image is recorded. The recording apparatus includes an image developing processor performing an image developing process on raw data sequentially output from an image sensor in frames and generating completely developed image data in frames, an electronic hand tremble correction unit performing an electronic hand tremble correction process on the completely developed image data and generating completely electronic hand tremble correction processed image data, a moving quantity data obtaining unit obtaining data of moving quantity in frames used for the electronic hand tremble correction process performed by the electronic hand tremble correction unit, and a storage medium recorder sequentially recording in frames the RAW data, the completely developed image data, and the data of moving quantity to a storage medium per frame.

Abstract: A method operable in a digital image acquisition system having no photographic film is provided. The method comprises receiving a relatively low resolution image of a scene from an image stream, wherein the scene potentially includes one or more faces. At least one high quality face classifier is applied to the image to identify relatively large and medium sized face regions and at least one relaxed face classifier is applied to the image to identify relatively small sized face regions. A relatively high resolution image of nominally the same scene is received and at least one high quality face classifier is applied to the identified small sized face regions in the higher resolution version of said image.

Abstract: Certain aspects of a method and system for inverse telecine and scene change detection of progressive video may include determining a cadence, for example, 3:2 or 2:2 pulldown, and phase of received progressive input pictures. A difference between two or more consecutive received progressive input pictures may be determined. The motion compensation of a plurality of output pictures may be controlled based on the determined cadence, phase and difference between two or more consecutive received progressive input pictures. The system may be enabled to determine repeated pictures and scene changes. The motion compensation of output pictures may be stopped during detected scene changes.

Abstract: When a face is detected from image signals, stability determination time is set for determining if the face is recognized in a stable manner, and a period of time for which the face is consecutively detected starts to be measured. Until the measured period of time exceeds the stability determination time, an AF evaluation value acquired from a normal frame set to include a face frame corresponding to the face is used to exercise TV-AF control. Once the measured time exceeds the stability determination time, TV-AF control is exercised based on AF evaluation values acquired from each of the face frame and the normal frame.

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: A control method of detecting an object image to be focused from a sensed image, setting a focus detection area in detecting an in-focus state of a photographing optical system, and exercising control such that the photographing optical system is moved based on a signal output in the focus detection area to carry out focus control, wherein, in the setting of the focus detection area, a first focus detection area corresponding to an object to be focused detected from the sensed image and a second focus detection area which is larger than the first focus detection area are set, and in the focus control, control is exercised such that the photographing optical system is moved based on output signals in the set first and second focus detection areas.

Abstract: A method (300) and image capture device (100) are provided for determining whether an image incident upon an image sensor (101) is sufficiently stable prior to executing an auto-focus process. An image stability mechanism (104) compares attribute data—such as luminance or frequency spectrum—from successive images to determine whether a change between the attribute data from image to image is within a predetermined range (710). The image stability mechanism (104) can also be configured to determine whether a scene incident upon the image sensor (101) has changed. Where the image is sufficiently stable, an indicator module (107) provides an image stability indication to a control circuit (102). The control circuit (102) can then be configured to execute the auto-focus operation when the image is sufficiently stable, or when both the scene has changed and the image is sufficiently stable.

Abstract: An auto-focusing apparatus detects a speed of a moving object accurately even in a system in which backlash exists in focusing control by performing moving object prediction auto-focusing (AF).

Abstract: An aspect of the present invention provides an image pickup apparatus, comprising: an image pickup optical system which forms an image of a subject; an imaging device which obtains an image by picking up the image of the subject via the image pickup optical system; a target detection device which detects a size of a target in the image; a first control device which controls a focus position of the image pickup optical system according to the size of the target detected by the target detection device; and a second control device which performs continuous AF that detects a focusing position where a contrast in the image reaches a local maximum by moving the focus position of the image pickup optical system, moves the focus position of the image pickup optical system to the focusing position and keeps an in-focus state.

Abstract: A method of processing a digital image using face detection within the image achieves one or more desired image processing parameters. A group of pixels is identified that correspond to an image of a face within the digital image. Default values are determined of one or more parameters of at least some portion of the digital image. Values are adjusted of the one or more parameters within the digitally-detected image based upon an analysis of the digital image including the image of the face and the default values.

Abstract: This invention makes it possible to produce a high quality synthesized panoramic image when it is difficult to highly precisely shift the image pickup direction.

Abstract: A digital camera includes: an imaging unit that receives and images a light from a subject transmitted a photographing optical system; a recognition unit that recognizes a feature region of the subject using an image obtained by imaging with the imaging unit; a detection unit that detects a size of the feature region that is recognized with the recognition unit; and a control unit that predicts a distance to the subject after a predetermined period of time according to the size of the feature region, and controls the photographing optical system so as to focus on the subject.

Abstract: A method and apparatus for determining a shaken image by using auto focusing. The method includes calculating a maximum AF value of a preview image and a maximum AF value of a captured image that is down-sampled according to the preview image and comparing the maximum AF value of the preview with the maximum AF value of the captured image to determine whether the captured image is shaken or not.