Abstract: The present disclosure relates to methods and systems that may reduce pixel noise due to defective sensor elements in optical imaging systems. Namely, a camera may capture a burst of images with an image sensor while adjusting a focus distance setting of an optical element. For example, the image burst may be captured during an autofocus process. The plurality of images may be averaged or otherwise merged to provide a single, aggregate image frame. Such an aggregate image frame may appear blurry. In such a scenario, “hot” pixels, “dead” pixels, or otherwise defective pixels may be more easily recognized and/or corrected. As an example, a defective pixel may be removed from a target image or otherwise corrected by replacing a value of the defective pixel with an average value of neighboring pixels.

Abstract: An imaging module (camera module 50) includes a movable portion (holder 4 and coil 5) which fixes a first lens group (1) and is displaced in an optical axis direction thereof, and a non-movable portion (magnet 6, yoke 7, and base 8) which fixes a second lens group (2) and is not displaced in the optical axis direction, and includes a focus adjustment mechanism (actuator 20A) fixed to the substrate.

Abstract: Provided are an imaging device and a focusing control method capable of preventing a focusing error even in a case where still image capturing is consecutively performed to enhance imaging quality. A digital camera performs a correlation operation of two images captured by a pixel pair P1 after performing an imaging process of an N-th frame, and determines a reliability of a correlation operation result based on the result of the correlation operation. In a case where the reliability is low, the digital camera performs a focusing control based on a contrast AF method in each time of imaging subsequent to an (N+1)-th frame, and in a case where the reliability is low, the digital camera performs a focusing control based on a phase difference AF method in an imaging process of the (N+1)-th frame.

Abstract: A method for determining at least one characteristic relating to the posture of the head (10) of a person (1) wearing spectacles (100) including a frame (110) and two lenses (150G, 150D), using a determining device including an image sensor, at least one light source and a computation unit, the method includes steps of: a) acquiring an image (301) of at least part of the wearer's head, in which the spectacles are illuminated by the light source; b) in the image, locating reflections (160D, 160G, 161D, 161G) from the light source, reflected by the two lenses of the spectacles; and c) deducing the wearer's head posture characteristic in relation to the image sensor, as a function of the position of the reflections in the image.

Abstract: A focus adjustment control apparatus is provided which includes: a focus detection unit that calculates an evaluation value with regard to contrast of an image via an optical system to detect a focus adjustment state of the optical system; an acquisition unit that acquires from a lens barrel at least one of a maximum value and a minimum value of an image plane movement coefficient that represents correspondence relationship between a movement amount of a focus adjustment lens included in the optical system and a movement amount of an image plane; and a control unit that uses at least one of the maximum value and the minimum value of the image plane movement coefficient to determine a drive speed for the focus adjustment lens when the focus detection unit detects the focus adjustment state.

Abstract: The present disclosure provides an image acquisition method, an electronic apparatus, an electronic device, and a storage medium. The method includes: receiving an image function enabling instruction and controlling, according to the image function enabling instruction, a touch display apparatus to enter an image acquisition interface; receiving a touch action on a screen of the image acquisition interface; determining whether image acquisition duration of the touch action on one same area of the screen of the image acquisition interface is greater than or equal to a preset image acquisition preparation time; and controlling an image sensing apparatus to acquire a corresponding image if the image acquisition duration of the touch action on the screen of the image acquisition interface is greater than or equal to the image acquisition preparation time.

Abstract: A distance measurement apparatus includes: an imaging element that images an object by performing exposure and readout of electric charges sequentially for each row or column; an optical system that has a controllable in-focus position; an imaging control unit that moves the in-focus position at constant speed, and causes the imaging element to image the object sequentially while the in-focus position is being moved, to obtain blurred images; a distance measurement unit that measures a distance from a reference position in the optical system to the object using the blurred images and a point spread function dependent on object distance; and a correction unit that performs a correction process on the distance for each row or column according to a movement range of the in-focus position in which the in-focus position is moved during the exposure for each row or column when the blurred images are obtained.

Abstract: A focus detecting apparatus includes: a lens; a light-transmitting unit; a light-receiving unit; and an optical film that transmits a beam of light passing through the lens and includes a holographic optical element, a diffractive optical element, or a pellicle mirror, wherein a beam of light from the light-transmitting unit is reflected on a reflection mirror including the optical film, passes through a first exit pupil area on one side of an optical axis, and is transmitted to the subject, a beam of reflected light of light irradiated onto the subject passes through a second exit pupil area on another side of the optical axis, is reflected on the reflection mirror and received by the light-receiving unit, and a focal position is obtained using position information of the beam of light received by the light-receiving unit. Autofocusing can be continuously performed during continuous photographing operation and in low brightness environment.

Abstract: Methods, apparatuses and a computer program are provided. An apparatus comprises: one or more optical elements, a first actuator and a second actuator. The first actuator may be configured to drive the one or more optical elements from a rest position across a first displacement, and configured to drive the one or more optical elements from the rest position across a second displacement. The second actuator may be configured to assist the first actuator in controlling movement of the one or more optical elements across a portion, and not all, of the first displacement, and configured to assist the first actuator in controlling movement of the one or more optical elements in the second direction across a portion, and not all, of the second displacement. The first and second actuators may be biased such that, when no electrical power is supplied to the first and second actuators, they bring the one or more optical elements to a rest position from which the one or more optical elements are driven.

Abstract: A method for calibrating a focus point for a camera lens may include capturing a reflection of a focus point measuring device that is affixed to the camera. The method may include evaluating a captured image of the reflection to measure a calibration amount for a focus point, and adjusting a focus point of a lens of the camera by the calibration amount. The focus point measuring device may include a substantially planar target surface defining a plane, and a ruled target surface inclined at substantially 45° to the substantially planar target and extending through the plane thereof, marked to indicate respective distances in front of and behind the plane. The device may further include a fixture for holding the substantially planar target surface and the ruled target surface in a defined orientation to the camera, enabling performance of the method.

Abstract: A camera module for a vision system of a vehicle includes a housing, a circuit element and a lens. The housing has a base portion and a lens portion. The circuit element includes CMOS imaging sensor and associated circuitry. The CMOS imaging sensor has a dynamic range of greater than approximately 100 dB. The dynamic range of the imaging sensor may follow, at least in part, a non-linear response curve. The base portion and the lens portion are welded or sealed together to substantially limit water intrusion into the camera module and the camera module may include shielding to limit or reduce electronic noise. The camera module is configured for mounting at a rear portion of the vehicle so that the imaging sensor has a rearward field of view.

Abstract: Video conversion technology, in which a first stream of video content is accessed and multiple, different layers are extracted from the first stream of the video content. Each of the multiple, different layers are separately processed to convert the multiple, different layers into modified layers that each have a higher resolution. The modified layers are reassembled into a second stream of the video content that has a higher resolution than the first stream of the video content.

Abstract: A lens barrel (3) includes a local maximum outer diameter section (3e) and a maximum outer diameter section (3a). The maximum outer diameter section (3a) is provided in a portion of an area of the local maximum outer diameter section (3e) which portion includes an area corresponding to an outer periphery of an image pickup lens (2m) which is the largest in lens diameter. This achieves a further size reduction while achieving a high-accuracy installation of a lens barrel.

Abstract: Methods and apparatus for performing zoom in and zoom out operations are described using multiple optical chains in a camera device. At least one optical chain in the camera device includes a moveable light redirection device, said light redirection device being one of a substantially plane mirror or a prism. Different zoom focal length settings correspond to different scene capture areas for the optical chain with the moveable light redirection device. Overlap between scene areas captured by different optical chains increases during zoom in and decreases during zoom out. Images captured by different optical chains are combined and/or cropped to generate a composite image corresponding to a zoom focal length setting.

Abstract: A method for adjusting focus position and an electronic apparatus are provided. Herein, a depth map is obtained according to a first image and a second image which are captured by a first lens and a second lens, respectively. A plurality of depth values included in the depth map is compared with a depth of field (DOF) table for obtaining a plurality of focus distances. An All-in-Focus (AIF) image is generated according to a plurality of focus images captured by the first lens with the focus distances, respectively. A blur process is executed for a plurality of pixels excluding a focus selected location in the AIF image, so as to obtain an adjusting image.

Abstract: A vehicle camera assembly includes a pedestal, a bracket, a camera and an emblem. The pedestal has an interior surface and an exterior surface with a lens receiving opening extending from the interior surface to the exterior surface. The interior surface includes a bracket attachment structure having at least one projection extending from the interior surface such that a recess is defined between a portion of the interior surface and the at least one projection. The bracket is attached to the bracket attachment structure with one edge of the bracket being retained within the recess. The camera is retained between the bracket and the pedestal. The camera has a lens portion that is aligned with the lens receiving opening of the pedestal. The emblem is attached to the exterior surface of the pedestal and is spaced apart from the lens receiving opening.

Abstract: An autofocus device is provided that includes a lens drive system, an imager, a contrast detector, first and second peak detectors, and a backlash detector. The lens drive system translates a lens. The imager captures an image through the lens. The contrast detector detects the contrast of an image captured by the imager. The first peak detector detects a first contrast peak of images captured at different lens positions when the lens is translated in a forward direction. The second peak detector detects a second contrast peak of images captured at different lens positions when the lens is translated in a backward direction. The detection of the second peak is carried out after detection of the first contrast peak. The backlash detector detects the backlash in the lens drive system according to the positions of the first and second contrast peaks.

Abstract: An image capturing apparatus, includes: an image capturing element configured to capture an image of a subject; and a focusing control unit configured to perform a focusing control by a phase difference AF method using detection signals of first signal detection units and second signal detection units; a matching degree generation unit configured to generate a first matching degree which corresponds to a matching degree of two images captured by a first pair using the detection signals of the respective signal detection units of the first pair, and a second matching degree which corresponds to a matching degree of two images captured by a second pair using the detection signals of the respective signal detection units of the second pair; and a credibility determination unit configured to determine credibility of the focusing control by the phase difference AF method based on the first matching degree and the second matching degree.

Abstract: Technologies for dynamically implementing an image protection policy include a camera device with a camera to capture an image of at least one person. The camera device determines a location in the image of at least one person in the image, determines a location of at least one personal computing device, and maps the personal computing devices to the persons captured in the image based on the determined device and image locations. The camera device may broadcast an announcement of the creation of the image to the personal computing devices, negotiate an image protection policy with each of the personal computing devices, and implement the negotiated image protection policy.

Abstract: A method for aligning an image capture device for a print device includes providing a capture stage on which an object to be imaged by the capture device is placed. The capture stage includes a plurality of reference markers spaced apart by a predetermined distance. The reference markers are imaged with the capture device. A distance between the reference markers is measured. A correction difference between the measured distance of the reference markers and the predetermined distance is computed. An angular correction value based on the correction difference is computed. The angular position of the capture device relative to the capture stage is adjusted based upon the angular correction value.

Abstract: A computation & control unit defines, as first and second voltages, A+B_signal voltages at distances which give the maximum and minimum voltages of an S_signal voltage, respectively. The unit further defines the higher one of the first and second voltages as an S_signal validity determination voltage and defines a distance at which the S_signal voltage takes on an in-focus determination voltage. The unit defines first and second lower limit voltages, defines the higher one of the first and second lower limit voltages as a lower limit voltage, and defines, as an upper limit voltage, an A+B_signal voltage at a distance which gives an in-focus determination voltage between the maximum and minimum positions of the S_signal voltage. An input and output unit outputs the upper and lower limit voltages as the upper and lower limit values of a settable range of the S_signal validity determination voltage.

Abstract: A camera includes a lens assembly and a stereoscopic display for displaying an image captured by the camera, and automatically determines a correct focus for the camera using the stereoscopic display to show an icon on the image appearing to move perpendicularly, relative to a first plane corresponding to a surface of the stereoscopic display, from different perceived depths corresponding to different planes parallel to the first plane.

Abstract: A reliable and repeatable accuracy of focus measurement device to measure the focus accuracy of cameras. The measurement device includes a frame having a substantially planar front face with a focusing target located thereon, and at least one depth-of-field ruler coupled to the frame with a transverse axis falling within a front face plane and a long axis that is angularly adjustable with respect to the front face plane.

Abstract: A camera includes: a taking lens forming an image of a subject; an image pickup unit; a subject brightness acquisition unit acquiring the brightness information of the subject on the basis of the output of the image pickup unit; a control unit controlling the exposure according to the brightness information acquired by the subject brightness acquisition unit; and a storage unit storing the information indicating the optical state of the taking lens before the subject brightness acquisition unit acquires the brightness information. The control unit determines whether or not the brightness information is acquired again by the subject brightness acquisition unit according to the information about the optical state of the taking lens stored in the storage unit when the subject brightness acquisition unit previously acquired the brightness information, and the information about the optical state of the taking lens when the latest brightness information is acquired.

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: The present invention relates to a method for measuring a time delay between two output signals measured by two adjacent optical sensors, the time delay resulting from a movement of an object moving in a given direction. The method comprises the steps: carrying out a spatial filtering of the signals Ph1 and Ph2 delivered by a first and a second optical sensor; calculating a first order derivative and carrying out a temporal low-pass filtering of the signals; calculating the second order derivative of the signals; measuring the delay between the signals; and is characterized in that the step of measuring the delay is a feedback loop based on an estimated delay between the temporally filtered signals. Device and set of devices for measuring the angular velocity of a luminance transition zone and steering aid system for fixation and tracking a target comprising at least one such luminance transition zone.

Abstract: The present invention relates to a focusing device comprising: a lens, a lens plate, an image sensor, an image sensor plate, at least two rotatable structures, and at least two strips, wherein the lens is connected to the lens plate, the image sensor is connected to the image sensor plate, wherein each strip is arranged to be wound onto one of the rotatable structures, respectively, the rotatable structures and the strips are arranged between the lens plate and the image sensor plate, the rotatable structures and/or the strips are arranged in contact with the lens plate and the image sensor plate, and wherein a distance between the lens and the image sensor is adjusted by winding the strips onto or off the rotatable structures.

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: The image pickup apparatus of the present invention includes: an optical imaging system for forming an object image; an image pickup device including a plurality of pixels that photoelectrically converts the object image; a defocus quantity calculation section for calculating a defocus quantity based on a phase difference between a plurality of signals for focus detection obtained from a plurality of pixels for focus detection that respectively receive a light flux that passes through a different pupil region of the optical imaging system; a focusing section for driving the optical imaging system so as to achieve an in-focus state, in accordance with the defocus quantity calculated at the defocus quantity calculation section; an addition practicability determination section for determining a practicability of performing inter-frame addition on a plurality of signals for focus detection before calculating the defocus quantity, based on an analysis result of a signal component of the object image; and an inter-

Abstract: An apparatus and method for auto focusing camera module includes a DFoV value measurer measuring a DFoV value of a lens; storage stored with a designed DFoV value of a lens, a controller comparing the DFoV value of a lens measured by the DFoV value measurer with the designed DFoV value of a lens stored in the storage to recognize an initial position of a lens, and a lens mover focusing the lens by winding the lens or by unwinding the lens in response to the initial position of the lens recognized by the controller.

Abstract: Provided is an imaging apparatus including an imaging unit that performs imaging with an image sensor having pixels of first, second, and third colors, a luminance ratio calculation unit that integrates luminance of each of the first, second, and third colors within a focus determination region of an imaging signal output by the imaging unit and calculates a ratio of the luminance between the integrated values of the colors, a luminance normalization unit that normalizes the integrated value of the luminance of the first color within the focus determination region of the imaging signal output by the imaging unit at the ratio of the luminance between the integrated values calculated by the luminance ratio calculation unit, and a display processing unit that performs display corresponding to the integrated value of the luminance normalized by the luminance normalization unit.

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: A method, apparatus and computer program product are provided for displaying first media content item with a second media content item inserted within the display of the first media content item. In particular, the second media content item can be displayed with the first media content item when location information associated with the second media content item describes a location with a capture zone of the first media content item.

Abstract: An auto-focus (AF) method adapted for an image capturing device includes following steps. When a first press signal generated by a user pressing a button of the image capturing device is detected, a local peak searching method is applied to perform an AF procedure. It is determined whether a second press signal generated by the user pressing the button is detected. If not, it is determined whether a first released signal generated by the user releasing the button is detected. The continuous pressing count is calculated according to the first released signal and the first press signal that are continuously generated. Whether the continuous pressing count is greater than a first threshold is determined. If yes, a global peak searching method is applied to perform the AF procedure. If not, the local peak searching method is still applied to perform the AF procedure.

Abstract: The present invention provides a method for automatically focusing applied to a camera module. The method comprises the following steps: (a). determining a value of a modulation transfer function of an image at a center area and four corner areas of a lens by a processing unit; (b). determining whether the number of times of decreased or unchanged of the value of the modulation transfer function at the center area is over a predetermined value; and (c). if over the predetermined vale, then determining the average of the value of the modulation transfer function at the four corner areas by the processing unit, to determine the maximum of the value of the modulation transfer function at the center area.

Abstract: The image pickup apparatus includes a first detector detecting a first in-focus position by a phase difference detection method using paired image signals, a controller controlling position of a focus lens a basis of the first in-focus position to perform focusing, a second detector detecting a second in-focus position by a contrast detection method, a calculating part calculating a correction value for correcting the first in-focus position in image capturing on a basis of difference between the first and second in-focus positions, and a determining part determining a level of reliability of the first in-focus position. The controller calculates the correction value when the level of reliability is a first level, and to restrict the calculation of the correction value when the level of reliability is a second level lower than the first level.

Abstract: The invention provides a measuring instrument, comprising a telescope, a distance measuring unit, an image pickup unit, angle detecting units for detecting a vertical and horizontal angle in the sighting direction, an automatic sighting unit, an arithmetic unit, and a storage unit. The arithmetic unit makes the telescope rotate in horizontal and vertical direction and perform scanning over a predetermined range so that a plurality of objects to be measured are included and makes the image pickup unit acquire digital images during the scanning process. The arithmetic unit detects the objects in the digital images, calculates a vertical and horizontal angle of the objects based on the angle detector and a deviation of each of the objects from sighting axis, associates the calculated angles with each of the objects, and makes the storage unit store the vertical and horizontal angles of the objects as target values for automatic sighting.

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: 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: A method for calibrating a focus point for a camera lens may include capturing a reflection of a focus point measuring device that is affixed to the camera. The method may include evaluating a captured image of the reflection to measure a calibration amount for a focus point, and adjusting a focus point of a lens of the camera by the calibration amount. The focus point measuring device may include a substantially planar target surface defining a plane, and a ruled target surface inclined at substantially 45° to the substantially planar target and extending through the plane thereof, marked to indicate respective distances in front of and behind the plane. The device may further include a fixture for holding the substantially planar target surface and the ruled target surface in a defined orientation to the camera, enabling performance of the method.

Abstract: A stereographic camera system and method of operating a stereographic camera system are disclosed. The stereographic camera system may include a left camera and a right camera including respective lenses having a focal length and a focus distance, an interocular distance mechanism to set an intraocular distance between the left and right cameras, and a controller. The controller may receive inputs indicating the focal length and the focus distance of the lenses. The controller may control the intraocular distance mechanism, based on the focal length and focus distance of the lenses and one or both of a distance to a nearest foreground object and a distance to a furthest background object, to automatically set the interocular distance such that a maximum disparity of a stereographic image captured by the left and right cameras does not exceed a predetermined maximum disparity.

Abstract: An imaging device includes: an optical system which obtains an optical image of a photographic subject; an image sensor which converts the optical image to an electric signal; a digital signal processor which produces image data based on the electric signal; a display section which displays a photographic subject image expressed by the image data; and an operating section which performs a necessary setting regarding imaging, the digital signal processor including: an autofocus operation section which performs an autofocus operation based on data of an autofocus area set in the photographic subject image; a main area setting section which sets a main area in the photographic subject image; and a blurring operation section which performs a blurring operation on an area other than the main area in the photographic subject image, wherein the autofocus area is set automatically to overlap with at least a part of the main area.

Abstract: A system, method, and computer program product are provided for automatically progressively determining focus depth estimates for an imaging device from defocused images. After a depth-from-defocus (DFD) system generates sometimes-noisy estimates for focus depth and optionally a confidence level that the focus depth estimate is correct, embodiments of the present invention process a sequence of such input DFD measures to iteratively decrease the likelihood of focus depth ambiguity and to increase an overall focus depth estimate confidence level. Automatic focus systems for imaging devices may use the outputs of the embodiments to operate more quickly and accurately, either directly or in combination with other focus depth estimation methods, such as calculated sharpness measures. A depth map of a 3D scene may be estimated for creating a pair of images based on a single image.

Abstract: A camera module and method for focusing a tunable lens configured to continuously vary its optical power in response to a drive signal. A drive circuit generates the drive signal so that the tunable lens performs a continuous scan of its optical power. An image sensor is configured to acquire light images passing through the tunable lens, and to convert the light images to image signals during the continuous scan. A processor is configured to generate focus scores of the acquired light images using the image signals during the continuous scan. The processor is configured to determine from the focus scores a peak focus score achieved or achievable, and to instruct the drive circuit to adjust the drive signal so that the tunable lens settles at a value of the optical power that corresponds to the peak focus score.

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: Systems and methods are directed to acquiring, generating, manipulating and/or editing video data/frames. The video frames may be light field video frames having virtual aperture parameters that may be adjusted 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 light field video frames; selecting a second key frame, wherein the second key frame corresponds to one of the plurality of light field video frames which is temporally spaced apart from the first key frame such that a plurality of light field video frames are temporally disposed between the first and the second key frames; determining virtual aperture parameters for the first key frame and the second key frame; and generating video data.

Abstract: A digital camera of the present invention comprises: an imaging section, a read out section for reading out first image data for still picture storage from the imaging section, a storage section subjecting the first image data to image processing and storing the resultant data, an image data generating section for generating second image data that has fewer pixel data than the first image data, from the first image data, and a detection section for detecting at least one evaluation value based on the second image data, wherein a detection operation of the evaluation value by the detection section is executed in parallel to a still picture storage operation by the storage section.

Abstract: A focusing device for a beam projector including a casing, a body tube having at least one lens, the body tube being advanced or retracted in a direction of an optical axis in the casing, a movable member provided at a side of the body tube, the movable member moving in parallel with the direction of the optical axis, a bridge fixed to the body tube and coupled with the movable member to cover at least a part of the movable member, and a drive motor fixed in the casing and provided at a side of the body tube, in which the movable member linearly reciprocates as the drive motor operates, whereby the body tube is advanced or retracted.

Abstract: The present invention provides an autofocus module including: a supporting base, an electrical focusing element and an conductive element, wherein the supporting base at least accommodates one lens element, the electrical focusing element is disposed at one end of the supporting base so that the electrical focusing element and the lens element are positioned along a common optical lens, and the conductive element is embedded in the supporting base and connected to the electrical focusing element and an external power source respectively. The electrical focusing element obtains power through the conductive element, and by controlling the power magnitude supplied to the electrical focusing element, the focal length thereof can be changed accordingly, thereby carrying out the autofocus operation.

Abstract: An imaging device includes a detector that repeatedly carries out a series of operation of generating an evaluation value to evaluate the degree of focusing of a position after driving of a lens toward one end part in the drive range of the lens, and detects the evaluation value of a position that is closer to the end part than the position of the evaluation value of the highest degree of focusing and is immediately adjacent or adjacent across a predetermined number of positions to the position of the evaluation value of the highest degree of focusing. The imaging device further includes a drive controller that makes the series of operation be repeatedly carried out toward the other end part in the drive range of the lens, and drives the lens to a position of a degree of focusing not smaller than the detected evaluation value.