Abstract: A shakiness correcting method includes: generating, based on motion sensing data, first filtering data to be applied to a first mode; generating, based on the motion sensing data, second filtering data to be applied to a second mode; and selectively performing shakiness correction on one of the first filtering data and the second filtering data according to mode selection information, wherein the generating of the first filtering data and the generating of the second filtering data are performed in a mutually parallel manner.

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: Multichannel device controllers are disclosed. In one embodiment, a multichannel device controller includes a plurality of user selectable control modes for controlling a multichannel device and a plurality of user configurable settings for adjusting parameters associated with the plurality of user selectable control modes. A touchscreen displays a user interface corresponding to a selected one of plurality of user selectable control modes and receives user input indicative of a command to send to the multichannel device. A processor generates the command to send to the multichannel device based at least in part on the user input and the plurality of user configurable settings.

Abstract: An auto-focusing method for use in a device, includes: after performing a manual focusing on a target object through receiving a user operation on the target object in a viewfinder of the device, acquiring first spatial data of the target object; when detecting a change of contents of a view in the viewfinder, acquiring position variation data of the target object; acquiring second spatial data of the target object according to the first spatial data and the position variation data; and performing an auto-focusing on the target object according to the second spatial data.

Abstract: Techniques and architectures for video stabilization can transform a shaky video to a steady-looking video. A path smoothing process can generate an optimized camera path for video stabilization. With a large smoothing kernel, a path smoothing process can remove both high frequency jitters and low frequency bounces, and at the same time can preserve discontinuous camera motions (such as quick panning or scene transition) to avoid excessive cropping or geometry distortion. A sliding window based implementation includes a path smoothing process that can be used for real-time video stabilization.

Abstract: An imaging apparatus has one of the interchangeable lens and the camera body acting as a master and the other acting as a slave. The master has a shake detection unit configured to detect a shake of the camera body and/or the interchangeable lens; and a shake correction processing unit configured to calculate an amount of shake correction for the correction lens and the imaging device based on an output from the shake detection unit. The shake correction processing unit performs arithmetic processing for calculating a shake correction signal and separates the shake correction signal into a low frequency domain and a high frequency domain. One of the lens driving unit and the device driving unit performs the image blur correction based on the shake correction signal of the high frequency domain, and the other performs the image blur correction based on the shake correction signal of the low frequency domain.

Abstract: An optical image anti-shake device, defined with an X-axis, a Y-axis and a Z-axis, includes a casing, a movable member and a base. A suspension mechanism furnished inside the optical image anti-shake device includes a movable-member support and a suspension module. A first surface of the movable-member support is connected to the movable member. The suspension module suspends the movable-member support together with the movable member inside an inner compartment formed between the casing and the base.

Abstract: In the case of a camera system for recording images consisting of at least one single camera, a solution is intended to be provided which allows a good sharp image to be recorded. This is achieved by virtue of the single cameras (1) each being arranged in different directions such that they record a continuous overall image, with the overall image comprising the frames from the single cameras (1), and are being a central control unit (3) which can be used to capture the motion profile of the camera system by means of at least one sensor (2) and to ascertain the trigger times of the single cameras (1) on the basis of a prescribed target function, said camera system moving autonomously over the entire time progression.

Abstract: An imaging apparatus includes a follow shot control unit and a blur correction unit. The follow shot control unit calculates a panning angular velocity and a tilting angular velocity based on a first or second angular velocity for an image pickup device on the basis of magnitude correlation between the first and second angular velocities for image pickup device and on the basis of an inclination angle immediately before exposure and a ratio between the first and second angular velocities, when a state is a following shot state. The blur correction unit calculates an image blur correction amount on the basis of a difference between the first angular velocity and the panning angular velocity and a difference between the second angular velocity and the tilting angular velocity.

Abstract: Embodiments of the invention provide an apparatus for driving an actuator of a camera module in a mobile device. The apparatus includes a proportional-integral-derivative (PID) controller configured to compare an output of a gyro sensor with an output of a hall sensor configured to sense a position of an actuator to output a digital signal of plural bits, and a differential current digital-to-analog converter configured to convert the digital signal output from the PID controller into an analog current signal.

Abstract: Provided are an image stabilizing method and apparatus, which are capable of performing robust operations in a moving environment. The image stabilizing apparatus includes: an image pre-processor configured to receive a current image and a reference image corresponding to the current image; a feature point selector configured to select at least one feature point corresponding to a background from a plurality of feature points, comprising the background and at least one moving object, in the reference image; a motion estimator configured to estimate a motion of a current image, based on the selected feature point in the reference image and at least one corresponding feature point, corresponding to the selected feature point in the reference image, in the current image; and an image corrector configured to generate a stabilized current image by converting the current image by using the estimated motion.

Abstract: An image stabilizing device and system for a binocular telescope having a pair of telescopic optical systems each comprising an objective lens, a gimbal mounted erecting prism and an eyepiece lens which is capable of compensating for deterioration in quality of an observed image due to user hand shake or other external vibrations.

Abstract: A blur correction device according to this disclosure includes: a movable frame which supports a correction optical system, the movable frame having a through hole formed along an optical axis; a base part which holds the movable frame; and a base frame which forms a space, where the movable frame moves, between the base frame and the base part; a guide shaft being disposed inside the through hole formed in the movable frame; a locking member which is movably supported by the guide shaft, the locking member being configured to move into the through hole formed in the movable frame to come into contact with a part of the movable frame for restricting movement of the movable frame in a direction intersecting the optical axis of the movable frame; and a drive unit which drives the locking member along the guide shaft.

Abstract: An optical image-stabilizing apparatus includes: an optical image-stabilizing unit including a movement frame and a support frame supporting the movement frame to be movable in a direction perpendicular to an optical axis; and a locking unit capable of locking the movement frame to not be moved in the direction perpendicular to the optical axis, wherein the locking unit includes: a locking barrel movable in a direction parallel to the optical axis and configured to limit movement of the movement frame according to a position in the direction parallel to the optical axis; a driving barrel rotatable and configured to transfer a driving force to the locking barrel so that the locking barrel is moved in the direction parallel to the optical axis; and a guide barrel between the locking barrel and the driving barrel and including rectilinear guide portions that extend in the direction parallel to the optical axis so that the locking barrel is moved in the direction parallel to the optical axis.

Abstract: A stage apparatus includes a stationary support plate, magnetic force generators immovable relative to the stationary support plate, a stage member, an image sensor fixed to the stage member, a control circuit board connected to a side of the stage member, and coils which produce a driving force upon a supply of electric current thereto, the coils being fixed to the stage member at an opposite side of the center of the stage member with respect to the control circuit board, and a FPC board between the stationary support plate and the stage member. The stationary support plate is recessed, from a lateral edge of the stationary support plate at which the control circuit board is provided, in a direction toward the coils and includes an FPC board escape recess, in which said FPC board is partially positioned.

Abstract: An image capturing apparatus determines the target position of a shake correction lens in accordance with a shake signal corresponding to an acting shake, and performs feedback control to converge the position of the shake correction lens to the target position. A division unit divides the shake signal into low- and high-frequency components. A first low-pass filter integrates the high-frequency component, and a second low-pass filter integrates the low-frequency component. A synthesis unit synthesizes output signals from the first and second low-pass filters, and outputs the synthetic signal as the target position. When the apparatus is being panned or tilted, the cutoff frequency of the second low-pass filter is set to be a value larger than that of a cutoff frequency when the apparatus is neither being panned nor tilted.

Abstract: An evaluation method for evaluating the performance of an image stabilization function of an imaging apparatus includes: a first imaging step of imaging an object, with the image stabilization function being ON and the imaging apparatus being vibrated; a second imaging step of imaging the object, with the imaging apparatus being static; a first calculation step of calculating a first shutter speed based on the image taken in the first imaging step, and calculating a first evaluation value based on the first shutter speed and a reference shutter speed; a second calculation step of calculating a second evaluation value based on the images taken in the first and second imaging steps; and an evaluation step of calculating an evaluation value of the performance of the image stabilization function of the imaging apparatus, based on a result of subtraction of the second evaluation value from the first evaluation value.

Abstract: A method for stabilizing a line of sight of an imaging system on board a satellite uses windows selected within an image sensor. Variations of the line of sight can be characterized at a frequency that is greater than that of a sequential mode of image acquisition by the sensor. The stabilization method can be implemented at the same time as the full-frame acquisition of images by means of the imaging system.

Abstract: A method of receiving input from a user includes sensing a first trajectory of a center of mass of a hand of the user during a gesture made by the hand. A second trajectory of a finger tip of the hand of the user during the gesture made by the hand is also sensed. An alphanumeric character represented by the gesture made by the hand is determined dependent upon both the first trajectory and the second trajectory.

Abstract: A camera system including an imaging optical system including a focus lens, a driving device which drives the focus lens, a moving speed command value input device which inputs a moving speed command value of the focus lens, a wobble amount calculating device which calculates a wobble amount for wobbling the focus lens, a moving amount command value calculating device which calculates a command value of an amount of movement of the focus lens per unit time based on the inputted moving speed command value, a moving amount maximum value calculating device which calculates a maximum value of the amount of movement of the focus lens per unit time in consideration of the wobble amount, a moving amount determining device which sets, when the command value is larger than or equal to the maximum value, the maximum value as the amount of movement of the focus lens per unit time.

Abstract: An optical image stabilizer for a camera lens assembly, which includes: a main frame; a drive frame moving on the main frame in at least one direction; a camera element mounted to the drive frame; a pair of driving permanent magnets installed at one of the main frame and the drive frame; and a pair of coils installed at the other of the main frame and the drive frame and opposite to the driving permanent magnets, wherein the camera element is moved in its entirety via motion of the drive frame by interactions of the electromagnetic forces generated when currents are applied to the coils.

Abstract: A lock mechanism for a stage apparatus, includes a stationary support board; a movable stage; a leaf spring supported by the stationary support board; a press portion and a pressed portion provided on the leaf spring and the movable stage, respectively, a frictional contacting member being fixed to at least one of opposed surfaces of the press portion and the pressed portion; an electromagnet for resiliently deforming the leaf spring in a lock releasing direction to disengage the frictional contacting member from the one of opposed surfaces of the press portion and the pressed portion; and a permanent magnet, fixed to the stationary support board, which magnetically attracts the leaf spring to hold the frictional contacting member and the one of opposed surfaces of the press portion and the pressed portion in a disengaged state when the leaf spring is resiliently deformed by the electromagnet.