An image capture device includes electronic components and a body. The electronic components include an image sensor and a processing apparatus. The body defines an internal compartment containing the electronic components. The body includes a rear housing and a chassis. The rear housing extends around a top side, a right side, a bottom side, and a left side of the body. The chassis includes an upright portion and a lateral portion extending rearward from the upright portion. The rear housing and the chassis are coupled to each other to cooperatively form the internal compartment with the upright portion of the chassis being coupled to a front end of the rear housing and the lateral portion being positioned outside of and below the internal compartment.

Provided are a vision sensor, an image processing device including the same, and an operating method of the vision sensor. The vision sensor includes a pixel array including a plurality of pixels, a synchronization control module configured to receive a synchronization signal from an external image sensor and generate an internal trigger signal based on the synchronization signal, an event detection circuit configured to receive the internal trigger signal and detect whether an event has occurred in the plurality of pixels and generate event signals corresponding to pixels in which the event has occurred, and an interface circuit configured to receive the event signals and transmit to an external processor vision sensor data based on the trigger signal and at least one of the event signals, where the vision sensor data includes matching information for timing image frame information generated by the image sensor and the event signals generated by the vision sensor.

A camera identification method comprises identifying a to-be-identified camera using a light sensitivity deviation of each pixel in the to-be-identified camera; generating corresponding identification data; identifying a target camera using a light sensitivity deviation of each pixel in the target camera; and identifying the target camera by comparing a similarity between data that identifies the target camera and identification data of a known camera.

A signal processing device includes: a processor including at least one or more pieces of hardware, the processor being configured to: switch to one of a first state in which an input of a clock signal for operating an imager to the imager is permitted and a second state in which the input of the clock signal to the imager is prohibited, and temporarily switch from the first state to the second state when a first synchronization signal output from a first synchronization signal generation circuit and a second synchronization signal output from a second synchronization signal generation circuit are not synchronized.

A method may include obtaining sensor data from one or more LiDAR units and determining a point-cloud corresponding to the sensor data obtained from each respective LiDAR unit. The method may include aggregating the point-clouds as an aggregated point-cloud. A number of data points included in the aggregated point-cloud may be decreased by filtering out one or more of the data points according to one or more heuristic rules to generate a reduced point-cloud. The method may include determining an operational granularity level for the reduced point-cloud. An array of existence-based objects may be generated based on the reduced point-cloud and the operational granularity level.

An imaging apparatus including: an image sensor unit; and a camera unit from which the image sensor unit is detachable, in which the image sensor unit includes at least an image sensor and a first storage unit in which first correction data are stored, the camera unit includes at least a control unit, and the control unit performs an update determination process for determining whether or not the first correction data stored in the first storage unit have been updated.

The disclosure relates to an apparatus and a method for controlling an image sensor, a storage medium, and a movable object. The apparatus for controlling an image sensor includes: a data obtaining unit configured to obtain parameter data related to one or more moving scenarios; and an instruction generation unit configured to generate, based on the parameter data, an instruction for controlling operation modes of the image sensor, where the moving scenarios are scenarios in which a movable object with the image sensor is located; and the operation modes correspond to setting manners of active pixels of the image sensor. According to the solutions of one or more embodiments of the disclosure, different operation modes are set for the image sensor in different scenarios, so that while sensing requirements in different scenarios are met, the power consumption can be reduced and requirements for a system can be lowered as far as possible.

A head mounted display device including a first image capturing unit and a second image capturing unit different from the first image capturing unit comprises a first generation unit configured to generate, based on a signal representing an image output timing of the first image capturing unit, a first signal for controlling a start of exposure of the second image capturing unit, and supply the generated first signal to the second image capturing unit, and a second generation unit configured to generate, based on the signal representing the image output timing of the first image capturing unit, a second signal for controlling a start of measurement of a sensor that measures a position and orientation of the sensor, and supply the generated second signal to the sensor.

Disclosed are systems, methods, and structures for monocentric multiscale gigapixel imaging systems and cameras employing a Galilean architecture wherein adjacent subimages do not overlap while advantageously producing a reduced system volume, improved relative illumination and image quality as compared with prior art systems.

An imaging device includes a pixel array part having a plurality of pixels that perform photoelectric conversion, a converter that converts an analog pixel signal output from the pixel array part into digital pixel data, a first signal processing unit that performs first signal processing on the digital pixel data, a second signal processing unit that performs second signal processing that is at least partly shared by the first signal processing on the digital pixel data or data that has been subjected to at least a part of the first signal processing, a recognition processing unit that performs predetermined recognition processing on the basis of output data of the second signal processing unit, and an output interface unit that outputs at least one of output data of the first signal processing unit and the output data of the recognition processing unit.