Abstract: Systems and methods are described for replacing a background portion of an image. An illustrative method includes receiving a first image, identifying a background portion of the first image and a subject portion of the first image, identifying a geographic location corresponding to the background portion of the first image, identifying a landmark associated with the geographic location of the object, retrieving a second image depicting the landmark, and generating for display a third image comprising the subject portion of the first image placed over the second image.

Abstract: A method includes: receiving light at an image sensor of a digital camera; generating an image based on the received light; detecting an artifact in the image; determining a blocking area of the sensor based on the detecting the artifact; blocking the light at the blocking area; determining whether the artifact is present in the image after the blocking; in response to determining that the artifact is present after the blocking, determining a new blocking area and repeating the blocking and the determining using the new blocking area; and in response to determining that the artifact is not present after the blocking, saving the image in memory.

Abstract: An electronic device includes an device body, where an opening is formed on the surface of the device body and a rotating shaft is provided within the device body; and a functional module rotatable around the rotating shaft, where the functional module is configured to be able to rotate into the device body or rotate out from the device body through the opening.

Abstract: An information processing apparatus that is capable of reducing deviation of cycles of modules having independent clock supply sources. A processor controls a first module to operate in synchronization with a first synchronizing signal supplied from a first timing controller, controls a second module to operate in synchronization with a second synchronizing signal supplied from a second timing controller, measures times of supplying the synchronizing signals to the modules, calculates a time difference between the times when the first timing controller is switched to a second mode where the first synchronizing signal is supplied to the first module based on a setting period after synchronizing the synchronizing signals in a first mode where the first synchronizing signal is supplied to the first module in synchronization with the second synchronizing signal, and changes the setting period when the time difference is more than a threshold.

Abstract: Embodiments include devices and methods for processing an image captured by an image sensor of an unmanned autonomous vehicle (UAV). A processor of the UAV may determine a body coordinate matrix of the UAV. The processor may determine an estimated rotation of the image sensor of the UAV. The processor may determine an estimated rotation of the UAV. The processor may transform an image captured by the image sensor based on the body coordinate matrix, the estimated rotation of the image sensor, and the estimated rotation of the UAV.

Abstract: An optical apparatus including a first operation portion operable to adjust a first optical parameter, a second operation portion operable to adjust the first optical parameter and a second optical parameter different from the first optical parameter. In the optical apparatus, an adjustment amount of the first optical parameter per unit rotation angle of the first operation portion and an adjustment amount of the first optical parameter per unit rotation angle of the second operation portion are different from each other.

Abstract: Police officers and others carry multiple electronic devices with the ability to communicate between each other and with remote devices. Unintentional communications may occur between the devices carried by other police officers, for example, which may cause a device carried by one officer to be controlled by a device carried by a different officer. A method of dynamic pairing between electronic devices, based on the time and proximity of the devices, reduces the possibility for unintentional communications.

Abstract: A control apparatus includes a calculation unit configured to perform a focus detection by a phase difference detection method based on an image signal output from an image sensor, and to calculate a defocus amount, and a focus control unit configured to control a focus lens based on the defocus amount. When a predetermined condition is satisfied, the focus control unit changes a driving speed of the focus lens based on information on a luminance or contrast of the image signal. At least one processor or circuit is configured to perform a function of at least one of the units.

Abstract: An image magnification ratio indicating device of the invention includes a processor having hardware, and the processor is configured to: magnify, or not, an image at a predetermined magnification ratio and transmit the image; switch an image transmission destination; instruct change of an image as a transmission target, and change a first magnification ratio to a second magnification ratio according to the change of the image as the transmission target or the switching of the image transmission destination and indicate the magnification ratio.

Abstract: An image capturing apparatus comprises a pixel unit, a driver that drives the pixel unit, a memory that stores image data output from the pixel unit, and at least one image processor that performs a first operation which uses a first image data and a second operation for obtaining an image using the image data, and a controller that controls transfer of the image data to the memory and the image processor. The controller controls so that after the first image data is transferred to the image processor, second image data of the image data is transferred to the image processor, and the driver drives the pixel unit so as to output the image data in a predetermined order which is different from an order of transferring the first image data and the second image data to the image processor.

Abstract: A photographing method includes entering a slow shutter photographing mode, dividing each frame of image of the photographed object into a light trail region, a background light source region, and a non-light-source region, merging the light trail regions of the frames of images, setting a merged light trail region as a light trail region of a target image, setting the background light source regions of one or more of the frames of images as a background light source region of the target image to avoid overexposure, merging the non-light-source regions of one or more of the frames of images, setting a merged non-light-source region as a non-light-source region of the target image to enhance brightness of the non-light-source region, and storing the target image after obtaining a photographing instruction.

Abstract: An image sensor capable of performing satisfactory distortion aberration correction on an imaging result, regardless of a combination of a lens module and an imaging module being used, is provided. A main body module of an image sensor acquires form information of each module from an imaging module and a lens module which are mounted thereon, acquires size information indicating a number of pixels and/or a pixel size of an imaging element within the imaging module and distortion aberration characteristic information indicating distortion aberration characteristics of an optical system within the lens module from a predetermined device on the basis of the acquired form information, and performs distortion aberration correction using the acquired information.

Abstract: A drive unit configured to pan-tilt drive an optical imaging system, and a system control unit configured to control a correction amount of the image stabilization by driving the drive unit are provided in the imaging apparatus, wherein the system control unit changes the correction amount depending on at least one of total power of the imaging apparatus, an amplitude of a motion of the imaging apparatus, a frequency of the motion, a shutter speed, and the number of drive times of the drive unit.

Abstract: The present disclosure provides a circuit for detecting light including a photoelectric conversion circuit, a reset circuit, a voltage amplifying circuit, and a current amplifying circuit, where the reset circuit writes a reset voltage provided by the reset power end to the first node in response to a reset control signal provided by the reset control signal line; the photoelectric conversion circuit collects incident light and generates a corresponding electrical signal according to the collected incident light; the voltage amplifying circuit performs voltage amplification processing on an electrical signal at the first node and writes the electrical signal after the voltage amplification processing to the second node, in response to an turn-on control signal provided by the turn-on control signal line; and the current amplifying circuit performs current amplification processing on the electrical signal at the second node and writes it to a signal reading line.

Abstract: A communication apparatus which includes a communication unit that communicates with an external apparatus, records connection information for connecting to the external apparatus using the communication unit, and subjects, upon activation of the communication apparatus, the communication unit to communication connection to the external apparatus based on the connection information. The communication apparatus inhibits the communication connection to the external apparatus based on an activation factor, which is a factor in the activation of the communication apparatus.

Abstract: An image pickup apparatus capable of compositing a plurality of continuously captured images is provided that includes a first detection unit configured to detect shake of the image pickup apparatus; a second detection unit configured to detect a moving amount of a captured image captured by an imaging unit; a correction unit configured to correct image blur of an image caused by shake of the image pickup apparatus; a control unit configured to calculate a blur amount of a background in the captured image from a shake detection signal detected by the first detection unit and the moving amount detected by the second detection unit and to control image blur correction performed by the correction unit; and a combining unit configured to combine a plurality of captured images with corrected image blur.

Abstract: Various embodiments include a camera voice coil motor (VCM) actuator configured to shift an image sensor along multiple axes. Some embodiments include a magnet and coil arrangement. Some embodiments include a position sensing arrangement. Some embodiments include a flexure arrangement. Some embodiments include a coil structure and coil carrier assembly.

Abstract: A light field imaging system placed under a display and used as a front-facing camera in a portable electronic apparatus is provided. The light field imaging system includes a lens unit, an optical metasurface and an image sensor. The lens unit is configured to collect input light from a scene and output a light signal. The optical metasurface, disposed in an optical path of the light signal, is configured to produce an optical signal in response to the light signal. The optical metasurface has a spatially varying optical response to the light signal. The image sensor is configured to sense the optical signal to generate light field image data.

Abstract: A camera controller is configured to control a camera through voice commands. The camera controller includes drain mechanisms that allow the camera controller to be used in environments in which the camera controller is exposed to fluids. The camera controller device comprises a housing body with an outer surface including a first opening and a second opening. A first channel extends from the first opening into the housing body and to a cavity in which a microphone is located, enabling audio signals entering the first opening to be captured by the microphone. A membrane is located between the first channel and the microphone to create a waterproof seal over the microphone. A second channel extends from the first channel to the second opening to create a drain such that fluid entering from the first opening can flow from the first channel through the second channel and out the second opening.

Abstract: An image sensor in which a pixel array and a memory cell array are merged includes a first semiconductor chip including the pixel array and the memory cell array in a same semiconductor chip, and a second semiconductor chip overlapping the first semiconductor chip in a vertical direction. The second semiconductor chip includes a first logic circuit that controls the pixel array, an analog-to-digital converter (ADC) that converts an analog signal output from the pixel array under control of the first logic circuit to a digital signal, and a second logic circuit that stores data that is output from the ADC circuit based on the digital signal to the memory cell array of the first semiconductor chip.