A control apparatus comprising at least one processor or circuit configured to execute a plurality of tasks includes a first acquisition task configured to acquire information on image shift sensitivity relative to decentering of an image stabilizing optical system, the information being associated with an image point position of an image pickup optical system, the image pickup optical system including the image stabilizing optical system configured to perform image stabilization, and a second acquisition task configured to acquire a first image stabilizing driving amount of the image stabilizing optical system during the image stabilization. The second acquisition task is configured to acquire the first image stabilizing driving amount associated with a predetermined image point position by using the information on the image shift sensitivity associated with the predetermined image point position.

Actuators for rotating or tilting an optical element, for example an optical path folding element, comprising a voice coil motor (VCM) and a curved ball-guided mechanism operative to create a rotation or tilt movement of the optical element around a rotation axis upon actuation by the VCM. In some embodiments, an actuator includes two, first and second VCMs, and two curved ball-guided mechanisms operative to create rotation or tilt around respective first and second rotation axes.

Systems and methods are disclosed for image capture. For example, systems may include an image capture module including an image sensor configured to capture images, a connector, and an integrated mechanical stabilization system configured to control an orientation of the image sensor relative to the connector; an aerial vehicle configured to be removably attached to the image capture module by the connector and to fly while carrying the image capture module; and a handheld module configured to be removably attached to the image capture module by the connector, wherein the handheld module includes a battery and an integrated display configured to display images received from the image sensor.

An image evaluation apparatus comprises an image capturing device configured to include a blur correction function, a vibration control unit configured to vibrate the image capturing device based on an input waveform, a vibration detection unit that detects the vibration of the image capturing unit, a memory storing instructions, and a processor executing the instructions causing the image evaluation apparatus to compare the input waveform with the waveform of the vibration detection result that was detected by the vibration detection unit, and perform a captured image evaluation that is an evaluation of the blur correction function based on a captured image result of a subject by the image capturing device, wherein the processor performs captured image evaluation in a case in which it has been determined that the difference of the waveform of the vibration detection result with respect to the input waveform is within a predetermined range.

Visual content is captured by an image capture device during a capture duration. The image capture devices experiences motion during the capture duration. The intentionality of the motion of the image capture device is determined based on angular acceleration of the image capture device during the capture duration. A punchout of the visual content is determined based on the intentionality of the motion of the image capture device. The punchout of the visual content is used to generate stabilized visual content.

An imaging apparatus includes: an image sensor that captures a subject image to generate image data; a controller that controls an image shooting operation, based on image data resulting from a plurality of times of imaging by the image sensor, the image shooting operation generating image data indicating a synthetic image into which a plurality of captured images is synthesized; a shake detector that detects a shaking state of the imaging apparatus; and a display that displays information, wherein the controller controls the display to display shaking state information including a plurality of shaking states detected by the shake detector during the plurality of times of imaging by the image sensor in the image shooting operation for the synthetic image.

An agricultural monitoring system, the agricultural monitoring system comprising: an imaging sensor, configured and operable to acquire image data at submillimetric image resolution of parts of an agricultural area in which crops grow, when the imaging sensor is airborne; a communication module, configured and operable to transmit to an external system image data content which is based on the image data acquired by the airborne imaging sensor; and a connector operable to connect the imaging sensor and the communication module to an airborne platform.

This application discloses a communication circuit, a control method, and an electronic device. The circuit includes a plurality of optical image stabilizers OIS, a gyroscope, and a control circuit, where an input terminal of the control circuit is connected to a power terminal, an output terminal of the control circuit is connected to the plurality of OISs separately, and the plurality of OISs are all connected to the gyroscope; and the control circuit controls one of the plurality of OISs to conductively connect to the gyroscope and establish a communication connection.

An electronic device includes: a motion sensor for outputting motion data corresponding to motion of the electronic device; a camera module for performing an OIS function within a operation range when the motion data has a first size; and a processor electrically connected to the motion sensor and the camera module. The processor acquires motion data from the motion sensor while continuously acquiring image frames through the camera module, determines, based on the motion data, a parameter associated with the OIS function such that the camera module performs the OIS function within the operation range using the parameter based on determination that the motion data has the second size lager than the first size, and acquire image frames for which the OIS function has been performed within the operation range using the determined parameter.

In an optical unit with a shake correction function, a first circuit board, which is pulled out from a camera module, and a second circuit board, on which a first drive coil and a second drive coil are mounted, are electrically connected by a first connection portion and a second connection portion, which are electrically connected while overlapping each other. Moreover, in the optical unit with a shake correction function, a drawer portion of the first circuit board is pulled out toward an outer peripheral side of the optical unit with a shake correction function.