An example computing device is provided. The computing device includes a video camera, a privacy shutter, and a processor communicatively coupled to the video camera. The video camera is to capture an image of a user. The privacy shutter is movably coupled to the video camera to move between an open position and a closed position. The processor is to activate the video camera when a video conference call application is executed, detect that the privacy shutter is in the closed position when the video camera is activated, and replace a blank screen caused by the privacy shutter in the closed position with a background image in response to detection of the privacy shutter in the closed position.

An example computing device is provided. The computing device includes a video camera, a privacy shutter, and a processor communicatively coupled to the video camera. The video camera is to capture an image of a user. The privacy shutter is movably coupled to the video camera to move between an open position and a closed position. The processor is to activate the video camera when a video conference call application is executed, detect that the privacy shutter is in the closed position when the video camera is activated, and replace a blank screen caused by the privacy shutter in the closed position with a background image in response to detection of the privacy shutter in the closed position.

In certain embodiments, an imaging system includes an enclosure with an objective aperture opening into an interior space of the enclosure, an optical assembly optically coupling the objective aperture to an imaging sensor within the enclosure, a shutter mounted to the objective aperture for selectively blocking and admitting illumination through the objective aperture into the interior space, and an illuminator mounted to illuminate the interior space of the enclosure.

In certain embodiments, an imaging system includes an enclosure with an objective aperture opening into an interior space of the enclosure, an optical assembly optically coupling the objective aperture to an imaging sensor within the enclosure, a shutter mounted to the objective aperture for selectively blocking and admitting illumination through the objective aperture into the interior space, and an illuminator mounted to illuminate the interior space of the enclosure.

An optical component driving mechanism is provided. The optical component driving mechanism includes a first movable portion, a fixed portion, and a first driving assembly. The fixed portion includes a first opening. The first movable portion is movable relative to the fixed portion. The first driving assembly is configured to drive the first movable portion to move relative to the fixed portion.

To enable correction or adjustment of a curtain travel curve in a case of driving an opening and closing blade by a power source in which a motor mechanism and a spring mechanism are combined. Provided are the motor mechanism that generates a traveling torque of the opening and closing blade of a mechanical shutter provided in an incident light path to an imaging element by electric conduction to a coil, and the spring mechanism that generates the traveling torque of the opening and closing blade together with the motor mechanism. In this case, a control unit capable of individually controlling a time length from the start of the electric conduction to the coil to the start of traveling of the opening and closing blade, and a value of a current to be supplied to the coil is provided.

Disclosed are aspects of a camera assembly, including a sensor for sampling image data in a sampling step. A lens is provided for focussing light onto the sensor. A window is supported in front of the lens. The window includes a transparency changing material for varying the transmittance of light through the window in response to an input signal. The camera assembly is configured to thereby increase the transmittance of light through the window during the sampling step of the sensor.

This disclosure pertains to techniques for dynamically adapting image capturing techniques, e.g., based on shutter activation frequency, to improve camera responsiveness. One such technique is a method, comprising: receiving a first capture request; in response to receiving the first capture request, using a first capturing technique to capture a first set of images based on an image capture sequence, the image capture sequence comprising one or more images; generating a first image based on the captured first set of images; receiving a second capture request within a first time window from the first capture request, wherein a duration of the first time window is based, at least in part, on a length of time needed to capture the one or more images of the image capture sequence using the first capturing technique; in response to the received second capture request, using a second capturing technique to capture a second set of images, wherein the second capturing technique is different from the first capturing technique; and generating a second image based on the captured second set of images.

This disclosure pertains to techniques for dynamically adapting image capturing techniques, e.g., based on shutter activation frequency, to improve camera responsiveness. One such technique is a method, comprising: receiving a first capture request; in response to receiving the first capture request, using a first capturing technique to capture a first set of images based on an image capture sequence, the image capture sequence comprising one or more images; generating a first image based on the captured first set of images; receiving a second capture request within a first time window from the first capture request, wherein a duration of the first time window is based, at least in part, on a length of time needed to capture the one or more images of the image capture sequence using the first capturing technique; in response to the received second capture request, using a second capturing technique to capture a second set of images, wherein the second capturing technique is different from the first capturing technique; and generating a second image based on the captured second set of images.

Embodiments of the present disclosure include an apparatus with a camera. A shutter is positioned horizontally in front of the lens of the camera. The shutter is configured to move in front of a lens of the camera and is further configured to move orthogonally to the horizontal axis so as to at least partially obscure the lens of first camera in a closed shutter position. The apparatus further includes a motor positioned horizontally behind the front of the lens of the camera. The motor is configured to move the shutter orthogonally to the horizontal axis between the closed shutter position and an open shutter position.