This disclosure provides methods, devices, and systems for controlling motion-activated switches. The present implementations more specifically relate to relay controller that prevent motion-activated switches from turning off devices associated with an environment in which people are present. In some aspects, a motion-activated switch may include a relay controller coupled to a motion sensor, a camera, and a relay. The motion sensor outputs a motion trigger to the relay controller responsive to detecting motion in an environment. The motion trigger may cause the relay controller to acquire one or more images of the environment, via the camera, and selectively toggle the relay based on the acquired images. For example, the relay controller may close the relay responsive to identifying an image that includes an object of interest or may open the relay controller may open the relay responsive to identifying an image that does not include an object of interest.

An imaging apparatus includes: a first display panel unit for executing display toward a user side; a second display panel unit for executing display toward a subject side; an imaging processing unit for subjecting incident light from the subject side to photoelectric conversion to obtain a captured image signal; a recording processing unit for executing a recording process to a recording medium regarding the captured image signal obtained at the imaging processing unit; and a control unit for controlling the display states of the first display panel unit and the second display panel unit for each of a plurality of various types of operation periods changing along with the operation of the imaging processing unit or the recording processing unit, and executing display control wherein the first display panel unit and the second display panel unit can have different display content during at least a single operation period.

A device includes a processor that is configured to detect that a first image is captured by the device; configure the device to capture images in a first resolution after detecting that the first image was captured; start a timer; restart the timer when a second image is captured before the timer expires; detect an event indicative of a second resolution that is lower than the first resolution; and configure the device to capture images in the second resolution after detecting the event indicative of the second resolution.

A device includes a processor that is configured to detect that a first image is captured by the device; configure the device to capture images in a first resolution after detecting that the first image was captured; start a timer; restart the timer when a second image is captured before the timer expires; detect an event indicative of a second resolution that is lower than the first resolution; and configure the device to capture images in the second resolution after detecting the event indicative of the second resolution.

An acquisition imaging system is described herein that acquires multiple images from multiple imagers where each are sent to a single processor/controller, resulting in a single, resultant image providing a detailed field of view. The system is comprised of multiple sets of images taken by multiple sensors, strategically placed to acquire multiple perspectives of an image field. Each sensor is packaged with digitization, compression and communication components in an imager to allow for the transfer of the image to a processor/controller system controller. The system's controller acts as the network interface, power supply and centralized management for processing information, specifically the analytics. The present invention has applications in surveillance, event classification systems, indexed archival storage, real-time and post facto image content analytics, future filtering vectors; ad hoc querying, automatic queries, and multiple query languages.

Methods, systems, and apparatus, for performing low-power vision sensing. One computing device includes a vision sensor configured to generate vision sensor data and an ambient computing system configured to repeatedly process the vision sensor data generated by the vision sensor according to a low-power detection process. If a detection is indicated by the low-power detection process, the ambient computing system wakes one or more other components of the computing device to perform a high-power detection process using the vision sensor data.

A control device includes: a power source configured to supply a predetermined power-supply voltage to an imaging element; a voltage detector configured to detect an output voltage value of the power-supply voltage supplied by the power source; and a processor comprising hardware, the processor being configured to supply an adjusted voltage value from the power source to the imaging element based on a voltage value of the power-supply voltage detected in the imaging element and on the output voltage value detected by the voltage detector, calculate a delay time from timing when the voltage value of the power-supply voltage is detected in the imaging element until timing when the power source supplies the adjusted voltage value to the imaging element, and control supply timing when the power source supplies the adjusted voltage value based on the delay time.

An induction-powered camera may be capable of being installed external to a building without any building alterations. The induction-powered camera may include a continuous power source. The induction-powered camera may transmit one or more images to a control panel associated with security and/or automation systems. The induction-powered camera may be movable and/or removable with undue burden. In one example, an apparatus for a security and/or automation system is described. The apparatus may include a first half of the apparatus and an electricity transmission unit positioned within the first half. An electricity receiving unit may be positioned a predetermined distance away from the electricity transmission unit. The electricity receiving unit proximate a second half of the apparatus and a camera may be proximate the second half of the apparatus, the camera powered by the electricity receiving unit.

An electronic device detects a first operation for enabling burst shooting; obtains, in response to the first operation, at least two groups of raw data collected by the camera, where each group of raw data corresponds to one image; sends the at least two groups of raw data to the cloud server, so that the cloud server generates, based on each group of raw data, a corresponding thumbnail and an image corresponding to the thumbnail; receives at least one thumbnail from the cloud server; displays the at least one thumbnail on a display; sends a request message to the cloud server after detecting a second operation for selecting a first thumbnail included in the at least one thumbnail, where the request message is used to request a first image corresponding to the first thumbnail; receives the first image from the cloud server; and displays the first image on the display.

A vehicle image control apparatus for an image of a vehicle camera equipped with no image signal processor (ISP) and a method thereof, includes a first image controller equipped with a first ISP that performs image processing, supplies power to a camera device provided in a vehicle and equipped with no ISP, and the camera device obtains a surrounding image of the vehicle and transmits the surrounding image to the first image controller. The first image controller selectively shares the surrounding image with a second image controller equipped with a second ISP that performs image processing. Accordingly, it is possible to implement an efficient vehicle image-related system such that a plurality of controllers share one or more cameras equipped with no ISP.