Abstract: An image capturing apparatus includes an image capturing unit, a motion vector detection unit, a shake detection unit, a shake calculation unit configured to calculate a shake amount of the image capturing apparatus between the two images, an image blurring conversion unit configured to convert an output from the shake calculation unit into an image blurring amount of an image, a correction amount calculation unit configured to calculate, by using at least one of an output from the motion vector detection unit and an output from the image blurring conversion unit, a correction amount for electronically correcting the image blurring amount of the image, and a correction unit configured to electronically correct image blurring of the image based on an output from the correction amount calculation unit.

Abstract: A camera lens assembly is provided. The camera lens includes a movable Auto Focusing (AF) unit configured to move back and forth in a direction of an optical axis of an image sensor, and a movable Optical Image Stabilization (OIS) unit installed on the movable AF unit and configured to move back and forth in the direction of the optical axis together with the movable AF unit. The movable OIS unit floats in a direction orthogonal to the optical axis on the movable AF unit. The camera lens assembly simplifies the construction while implementing both the auto focus function and the optical image stabilization function. As a result, the camera lens assembly is advantageous for miniaturization and may improve reliability.

Abstract: An image processing system includes a hardware block and a central processing unit (CPU). The hardware block receives a first image and generates a first feature value and a first segmented image from the first image. The CPU generates a first transformation matrix based on the first segmented image and the first feature value. The hardware block also generates a first transformed image by applying the first transformation matrix to the first image.

Abstract: There are provided a device and method that correct a false color occurring in a locally highlighted region in an image. A false color pixel is detected in data conversion processing of generating an RGB array image from an RGBW array image, low-band signals corresponding to respective RGBW colors that are different according to whether a pixel is a false color pixel, and the RGBW array is converted by interpolation processing to which the calculated low-band signals are applied to generate the RGB array image. The interpolation processing is performed using the low-band signals on an assumption that a W low-band signal mW, and RGB respective low-band signals mR, mG, and mB have a proportional relation in a local region. When a pixel of interest is a false color pixel, the low-band signal is calculated by an application of a low-pass filter having a coefficient in which a contribute rate of pixel values in the vicinity of the pixel of interest is made relatively lower than that of separated pixels.

Abstract: To provide an anti-vibration actuator capable of smooth transition to image-blur prevention control. The present invention is an actuator (10) furnished with a locking mechanism, including: a fixed portion (12); a movable portion (14) with an image-blur prevention lens (16); a movable portion support means (18); a drive means for driving the movable portion; a movable portion locking mechanism (42) for locking a movable portion by limiting the range over which the movable portion can move to be within a predetermined locked movable range; a memory section (36a), within which is stored the movable portion initial position to which the movable portion is moved upon startup of image-blur prevention control; and a control section (36) for moving the movable portion to the initial position and releasing the lock upon startup of control; whereby the predetermined position in the locked movable range is stored as an initial position.

Abstract: Provided is a method generates an edge index of a current sample, and applies an edge offset corresponding to the edge index to the current sample. The edge index is generated using the differences between a current sample and two neighboring samples determined by an edge offset type. Accordingly, the difference between original samples and reconstructed samples are effectively reduced by generating the optimum edge index. Also, the quantity of bits required for reducing the differences are reduced by fixing the sign of offset to positive or negative.

Abstract: A measurement method capable of measuring a motion blur amount of an image with a high accuracy is provided. The measurement method fixes a camera on a vibratory table of a vibratory apparatus; selects one of a plurality of pieces of vibration data in accordance with the mass of the camera; shakes the vibratory table of the vibratory apparatus in accordance with the selected vibration data; acquires an evaluation image by imaging a subject by the camera while the vibratory table is being shaken; and measures a motion blur amount of an image based on the acquired evaluation image. In this case, the vibration data may be obtained by performing statistic processing for measured data.

Abstract: The lens barrel comprises a drive frame, a guide frame, and a moving frame. The moving frame includes a moving frame main body, a second cam mechanism portion, and a guide protrusion. The moving frame main body is configured to move between the drive frame and the guide frame. The second cam mechanism portion is configured to be accommodated in the first accommodation portion of the drive frame and engage to the first cam mechanism portion of the drive frame. The guide protrusion is configured to be accommodated in the second accommodation portion of the drive frame and engage to the guide groove of the guide frame.

Abstract: An imaging device of the present invention comprises a photographing lens for forming a subject image, an imaging section for converting the subject image to image signals and outputting the image signals, a storage section for storing image data obtained based on the image signals output from the storage section, an attitude detection section for detecting an attitude of the imaging device, an image detection section for detecting a face image contained in the image signals, and a storage control section for determining storage start and storage end for the image data, based on detection results of the attitude detection section and detection results of the image detection section.

Abstract: An optical unit with a shake correcting function may include a movable body configured to hold an optical element; a fixed body which covers at least a side face part of the movable body; a spring member which is connected with the movable body and the fixed body; a shake correction drive mechanism configured to generate a drive force for swinging the movable body with respect to the fixed body; and a stopper mechanism which is provided between the spring member and a swing center of the movable body in an optical axis direction, and configured to determine a movable range of the movable body in a direction perpendicular to the optical axis direction.

Abstract: Methods and devices for controlling the number of consecutive images captured in a burst operating mode are described. In one example embodiment, the present disclosure describes a method implemented by a processor of an electronic device. The electronic device has a camera module. The camera module is configured to temporarily capture a number of consecutive images to an image buffer when operation of the camera module is triggered. The method includes: obtaining motion data from a motion sensor on the electronic device; and based on the motion data, controlling the number of consecutive images captured by the camera module when operation of the camera module is triggered.

Abstract: The image processing apparatus includes a memory configured to store information on a specific image pickup condition under which a specific blur component is generated in an input image produced by image capturing using an optical system, the specific blur component being caused by the optical system; an image pickup condition acquirer configured to acquire information on an actual image pickup condition when capturing the input image; and a processor configured to perform, when the actual image pickup condition coincides with the specific image pickup condition, a blur detection process to detect the specific blur component included in the input image.

Abstract: A gain may be applied to a short-exposure image to form a virtual long-exposure image. The short-exposure image may have been captured using a short total exposure time (TET), the virtual long-exposure image may have a virtual long TET, and the virtual long TET may be greater than the short TET. A true long-exposure image may be captured using a true long TET. The true long TET may be substantially equal to the virtual long TET. Color values of at least some pixels of the true long-exposure image may be copied to corresponding pixels of the virtual long-exposure image.

Abstract: A video stabilization method includes: measuring an inter-frame camera motion based on a difference angle of a relative camera view direction in comparison with a reference camera view direction in each frame of a frame sequence of a video; generating a camera motion path of the frame sequence by using the inter-frame camera motion and determining a camera view direction adjustment angle based on a user's view direction by using the camera motion path; and compensating for the camera view direction by using the camera view direction adjustment angle in each frame.

Abstract: Provided is an optical unit comprising a shake detecting sensor which is less likely to unnecessarily vibrate even with the optical unit being designed to have a thinner profile. At a first step in the assembly of an optical unit provided with a shake correction mechanism, a module cover is mounted on a fixed body with a spring member therebetween and a movable module driving mechanism is provided between the module cover and the fixed body. At a second step, an image-capturing unit is inserted into the interior of the module cover by way of a fixed-body-side opening portion and a module-cover-side opening portion, and at a third step, a holding member is attached to a module cover.

Abstract: An image capturing method includes: continuously generating, using a processor, one or more OFF images in which the subject is captured with the illumination turned OFF, for a first number of times; continuously generating, using the processor, ON images in which the subject is captured with the illumination turned ON, for a second number of times; continuously generating, using the processor, one or more OFF images in which the subject is captured with the illumination turned OFF, for the first number of times; computing, using the processor, a difference image between each of the generated ON images and the OFF image corresponding to the ON image among the generated OFF images; and integrating, using the processor, the computed difference images.

Abstract: A system is operable to correct for distortion in an image. The distortion in the image was caused by rotation of an image capture device while the image was being captured by the image capture device. The system includes an orientation sensor configured to perform a first measurement concurrently with the image capture device capturing the image. The system further includes a rotation module configured to generate, based on the first measurement, a rotation matrix. The system further includes a correction module configured to, based on the rotation matrix, correct the distortion in the image caused by the rotation of the image capture device. The system further includes a restoration module configured to selectively reverse the correction of the distortion in the image based on (i) the image as corrected by the correction module and (ii) the rotation matrix.

Abstract: The present disclosure relates to an image capture apparatus and a control method for the same, with which a moving picture captured for a specific length of time before or after the capture of a still picture can be recorded during still picture capture. The image capture apparatus has a first image stabilization mode and a second image stabilization mode in which a shake component not corrected in the first image stabilization mode can be corrected, and has an image stabilization function that performs image stabilization on the basis of shake of the image capture apparatus. The image stabilization function performs image stabilization without using the second image stabilization mode when the moving picture is buffered, which allows stable image stabilization to be utilized during the capture of a recorded moving picture.

Abstract: Stereo image reconstruction techniques are described. An image from a root viewpoint is translated to an image from another viewpoint. Homography fitting is used to translate the image between viewpoints. Inverse compositional image alignment is used to determine a homography matrix and determine a pixel in the translated image.

Abstract: An image shake correcting device includes a shake detecting unit configured to detect a shake of an image pickup apparatus; a first optical correcting unit and a second optical correcting unit configured to correct optically an image shake by using a shake signal output from the shake detecting unit; a first position detecting unit configured to detect a position of the first optical correcting unit and output a first position detection signal; and a calculating unit configured to calculate a target position signal for controlling the first optical correcting unit based on the shake signal. The calculating unit calculates a target position signal for controlling the second optical correcting unit by using the signal that is obtained by subtracting the first position detection signal for detecting the position of the first optical correcting unit controlled by the target position signal from the target position signal.

Abstract: An image pickup apparatus includes a shake detecting unit configured to detect a shake of the image pickup apparatus; a first and a second optical correcting unit configured to move in a direction different from an optical axis so as to correct optically an image shake; a first position detecting unit configured to detect a position of the first optical correcting unit and output a first position detection signal; a second position detecting unit configured to detect a position of the second optical correcting unit and output a second position detection signal; and a controlling unit configured to control the first optical correcting unit and the second optical correcting unit. A range for detecting a position of the first position detecting unit is different from that of the second position detecting unit.

Abstract: A method of determining stability of a camera comprises capturing an image with the camera and then (A) determining a magnitude of motion for each region of a current sub-division of the image. A step (B) then determines a number of the magnitudes of motion not larger than a magnitude threshold associated with the current sub-division, and where the determined number is greater than or equal to a region threshold associated with the number of regions in the current sub-division, (i) determining the camera to be stable, or otherwise (ii) dividing the current sub-division of the image into a further sub-division and repeating steps (A) and (B) upon the further sub-division.

Abstract: A Digital Image Stabilization apparatus and method applies a Principal transform including a rotational motion component to a source frame and interpolates and outputs the image data of each pixel of an entire row of the destination frame in raster order. A first step identification the diagonally oriented meta-rows of source frame data that correspond to the pixels of an entire row of the destination frame, based on the principal transform coefficients. A second step is to horizontalize the source frame data of the meta-rows that correspond to the pixels of an entire row of the destination frame, by storing each meta-row of source frame data into one row of a memory buffer, such as a multi-line buffer. Then, a moving-window interpolation step sequentially interpolates based on the principal transform coefficients and outputs the image data of an entire row of the destination frame in raster order.

Abstract: There is provided an image processing device including a weight calculation unit that calculates a weight corresponding to each of a plurality of pixel values centering on a pixel of interest of an input image based on a feature amount calculated based on the plurality of pixel values centering on the pixel of interest, a regression coefficient reading unit that reads a regression coefficient stored for each class code determined based on a plurality of pixel values corresponding to the pixel of interest of the input image, and a pixel value calculation unit that calculates a pixel value of a pixel of interest of an output image by performing calculation using the plurality of pixel values, the weights, and the regression coefficients centering on the pixel of interest of the input image.

Abstract: This image capture device includes an image capturing section 100 which captures two images in mutually different exposure times, and an image processing section 220 which performs restoration processing on the images that have been captured by the image capturing section 100. The image processing section 220 includes a blur kernel determining section which determines a blur kernel that defines the camera-shake-induced motion blur of the image captured; and an image restoration section which generates the restored image. The blur kernel determining section changes the size of the blur kernel according to the exposure time in which the image is captured.

Abstract: A Digital Image Stabilization method including selecting a Principal transform representing a stationary/background object in the scene of a video frame, based on scoring each of a plurality of transforms of tile motion vector (Tile MV) groups and of feature point motion vector (FP MV) groups, and excluding large moving objects based on the history of the stationary (background) group and the history of each of the plurality motion vector groups.

Abstract: Provided are a digital image processing apparatus which corrects a position of each of a plurality of template motion vectors of an image frame of a captured image by considering relative positions of neighboring motion vectors respectively similar to each of the template motion vectors, calculates a score of each of the template motion vectors by considering a number of the neighboring motion vectors, and selects a global motion vector representing the image frame based on the score, and a method of estimating a global motion of an image to stabilize the captured image using the global motion.

Abstract: An image processing apparatus divides image data captured while a flash light is not emitted into a plurality of areas, calculates color evaluation value for each of the divided areas. The apparatus divides image data captured while the flash light is emitted into a plurality of areas and to calculate color evaluation value for each of the divided areas. The apparatus determines a movement for each of the plurality of areas in accordance with the calculated color evaluation value and the calculated color evaluation value. The apparatus performs white balance processing into image data in accordance with the determined movement.

Abstract: An image capturing apparatus comprises: an image sensor configured to capture an image; a vibration detection unit configured to detect a vibration; a vector detection unit configured to detect a motion vector from images; a first correction unit configured to optically correct an image blur; a second correction unit configured to electrically correct the image blur; a first calculation unit configured to calculate, on the basis of the vibration, a first vibration correction amount for controlling the first correction unit; a second calculation unit configured to calculate, on the basis of the motion vector, a second vibration correction amount for controlling the second correction unit; and a control unit configured to control the first and second calculation units so that the first and second vibration correction amounts are suppressed when a vibration amount is greater than a first threshold.

Abstract: This invention provides an image free from camera shake by using a plurality of images captured by a camera array image capturing apparatus. A determination unit determines whether to execute a camera shake correction processing. A memory unit temporarily stores only a group of images determined by a determination unit to be camera shake corrected. A camera shake correcting unit synthesizes images to correct blurs in the images. A matching point searching unit determines matching pixels by checking pixel value similarity between images. A moving amount calculating unit, based on the result acquired by the matching point searching unit, calculates a moving amount of each pixel between images. A position correcting unit, based on the moving amount of each pixel calculated by the moving amount calculating unit, corrects the positions of the images. An image synthesizing unit synthesizes a group of images that are position-corrected by the position correcting unit.

Abstract: A rifle scope includes an image sensor configured to capture visual data corresponding to a view area, a display, and a controller coupled to the display and the image sensor. The controller is configured to apply a first stabilization parameter to at least a portion of the visual data to produce a stabilized view, to provide the stabilized view and a reticle to the display, and to apply a second stabilization parameter to stabilize the reticle relative to the stabilized view in response to motion.

Abstract: An exemplary embodiment of the present disclosure includes a position detection unit detecting a position of the camera apparatus, a controller outputting a control signal, in a case the position of the camera apparatus detected by the detection unit is a condition for dropping the camera apparatus, and an OIS (Optical Image Stabilization) driving unit receiving the control signal outputted by the controller and being driven to cushion an inner structure of the camera apparatus.

Abstract: There is provided a camera module including: a housing; a lens unit mounted in the housing; a hand shake correction unit correcting a movement of the lens unit with respect to the housing; and a damping member disposed between the housing and the lens unit to thereby reduce the movement of the lens unit through the hand shake correction unit.

Abstract: Disclosed herein is a camera lens module. The camera lens module in accordance with an embodiment of the present invention includes a vibration correction carrier, a rolling unit disposed in parallel to a direction vertical to an optical axis and configured to support the vibration correction carrier, a lens barrel carrier disposed on a side opposite the vibration correction carrier based on the rolling unit, and a base configured to mount the vibration correction carrier and the lens barrel carrier on the base.

Abstract: An image pickup apparatus that reduces a camera shake and a motion blur during close-up shooting performed by increasing shooting magnification and depth of field. A control unit determines an aperture value and a shutter speed based on information on shooting magnification and a photometry result. In a situation where luminance information based on photometry result is the same, the aperture value is set larger when the shooting magnification is larger than a first value than when not larger than the same, and in a situation where the shooting magnification is larger than the first value and the luminance information is the same, the aperture value is set larger and the shutter speed is set lower when neither a camera shake nor a motion of an object within an imaging screen has occurred than when either has occurred.

Abstract: It is arranged so that a camera user can recognize presence of camera shake in a case where the user is looking at a subject through an optical viewfinder. A portion of the image of a subject captured by a solid-state electronic image sensing device is displayed in an electronic viewfinder constituted by a liquid crystal display unit. An image of a subject optically formed via an objective window of the optical viewfinder and the portion of the image of the subject displayed in the electronic viewfinder are superimposed. If camera shake is taking place, the portion of the image of the subject in the superimposed images will appear blurry. By viewing this portion of the image of the subject, therefore, the user can tell whether camera shake is taking place.

Abstract: An image creation device includes an acquisition unit that acquires an image to be processed, a region information acquisition unit that acquires region information specifying an object region where an object to be processed is shown in the image to be processed, a setting unit that sets a fixed control point, a vibration control point and a vibration direction based on a shape of the object region by referring to a storage unit storing a shape of the object in association with a fixed control point, a vibration control point and a vibration direction when the object vibrates, a creation unit that creates a video to be displayed with the object vibrating in accordance with the fixed control point, the vibration control point and the vibration direction, and an output unit that outputs the image to be processed where the video is superimposed.

Abstract: In one embodiment of the present invention, a method is provided for providing border handling in motion compensated interpolation, wherein a camera model is used to detect areas of predominant movements in a displayable output, and for each reveal or conceal area: it is determined whether the reveal or conceal areas is due to a camera movement or an object movement. If the reveal or conceal areas is due to a camera movement. The camera model is used to arrive at interpolated pixel values for pixels within the corresponding area. If the reveal or conceal areas is not due to a camera movement, arriving at interpolated pixel values for pixels within the corresponding area without using the camera model.

Abstract: Methods and apparatus for correcting digital image blur caused by motion of imaging device or subject. A method comprising displaying an image in a viewfinder, designating by a processor or by the user a main subject in the displayed image, capturing multiple images of the main subject, combining multiple images. Combining the multiple images may include calculating pixel values for the corrected image based on pixel values in the combined multiple images. Method may include shifting the multiple images to align the main subject in each of the images.

Abstract: In one embodiment, a method includes determining one or more motions of a camera, where the motions correspond to movements of the camera during recording of a multimedia clip. The method also includes determining one or more amounts of light present during the recording, and from the determined motions and amounts of light, determining a motion-blur metric for the multimedia clip. The method further includes determining whether to apply a video-stabilization routine to the multimedia clip based on the motion-blur metric.

Abstract: An apparatus and a method of controlling the apparatus are provided that can realize high-accuracy correction of image shake due to shift shake. Rotation radiuses at a plurality of frequencies among the frequency components of the shift shake are obtained. Correction amount is determined based on a result of assigning a respective weight to the rotation radius at each of the plurality of the frequencies based on information regarding at least one of an angular velocity and acceleration.

Abstract: Provided is a lens barrel having, in order from an object side to an image side, a first to a third group lens, the lens barrel including: a fixed frame; a cam frame supported by the fixed frame so as to be rotationally movable in a optical axis direction between a forward and a backward movement ends; and a shutter frame which moves in the optical axis direction in a rotation restricted state, through the rotation of the cam frame, in which: a third group frame is fixed to the shutter frame so that the object side of the third group lens is arranged on an inner peripheral side of the shutter frame; and the second frame is configured so that the image side of the frame is stored on the inner peripheral side of the shutter frame when the cam frame is positioned at the backward movement end.

Abstract: A compact camera module has an EMI housing configured to shield camera module components from electromagnetic interference and having defined therein a focus-adjustment aperture to permit an optical train to extend to at one end of an auto-focus range, and a light leak baffle partially overlaps the focus-adjustment aperture along the optical path outside the auto-focus range.

Abstract: An image stabilization control apparatus including a mechanism which causes a vibration when the mechanism moves is disclosed. The apparatus comprises a vibration correction unit configured to correct image shake occurring due to vibration applied to the image stabilization control apparatus. A correction value of an angular velocity of the vibration is calculated based on signals based on the angular velocity and an acceleration of the vibration, frequency bands of the signals are narrowed. During the mechanism is moving, the image shake is corrected by driving the vibration correction unit based on the angular velocity of the vibration which is corrected by the corrected value calculated before the mechanism moves.

Abstract: An image capture apparatus comprises a first shake detection unit configured to detect a shake of the image capture apparatus, a rotational shake calculation unit configured to calculate a rotational shake amount, a second shake detection unit configured to detect the shake of the image capture apparatus, a translational shake calculation unit configured to calculate a translational shake amount, a correction amount calculation unit configured to calculate, based on the rotational shake amount and the translational shake amount, a correction amount for correcting image blurring, and a correction unit configured to correct the image blurring, wherein the rotational shake calculation unit calculates a first translational motion component and perspective component, and wherein the correction amount calculation unit calculates a second translational motion component.

Abstract: Methods and apparatus for correcting blurred images captured by an imaging device. A method comprising recording image data and recording motion information, transmitting a portion of the image data and/or a portion of the motion information to a computer for processing. The computer may calculate an inverse filter from at least the motion information, and the computer may generate a corrected image by applying an inverse filter to the image data.

Abstract: An amount of change between images is calculated based on a motion vector between images obtained by an image sensor and on shake information related to a shake in a rotational direction around at least an axis perpendicular to an optical axis of an imaging optical system. Then, based on a shake correction amount determined based on the shake information and the amount of change, an image obtained by the image sensor is geometrically deformed. The amount of change is a shake component of the image capture apparatus in a direction perpendicular to the optical axis, and is calculated after cancelling at least one of a change between images caused by the shake in the rotational direction included in the shake information and a change between images caused by an influence of a difference between exposure periods of the image sensor.

Abstract: A scanning method and apparatus. The method comprising the steps of: measuring an ambient video level using an area sensor under the control of a processor means; and calculating a gain and/or a exposure time and/or light source power for an actual flash video level using a stored reference flash video level and the measured ambient video level such that a summation of the actual flash video level and the ambient video level yields a desired video level in a scan image of the document using the calculated gain and/or exposure time and/or light source power.

Abstract: A motion sensor includes a sensor element that outputs a sense signal in response to a motion applied thereto and a sensor circuit that senses the motion based on the sense signal. The sensor circuit includes a sensor-element-signal amplifier that receives the sense signal. The sensor-element-signal amplifier operates switchably between at a normal mode and at a low-noise mode that consumes a larger electric power and produces a smaller noise than the normal mode. This motion sensor senses a small motion and a large motion accurately.

Abstract: An imaging apparatus includes an imaging unit configured to capture an image by using a rolling shutter method, a movement detection unit configured to detect a movement amount of the imaging apparatus relative to an object, an in-focus detection unit configured to detect an in-focus degree to the object, a distortion correction unit configured to correct a distortion in the image generated due to the rolling shutter method by changing a reading position of each line in the image, and a control unit configured to determine a correction amount of the distortion generated due to the rolling shutter method from the movement amount detected by the movement detection unit and the in-focus degree detected by the in-focus detection unit.