A camera assembly can include a housing that includes a front side that includes a front side perimeter, a back side that includes a back side perimeter, and a surface that extends between the front side and the back side; a camera that includes a front side aperture; a front side illumination light; and a status light.

A camera assembly can include a housing that includes a front side that includes a front side perimeter, a back side that includes a back side perimeter, and a surface that extends between the front side and the back side; a camera that includes a front side aperture; a front side illumination light; and a status light.

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.

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.

A system and method for controlling characteristics of collected image data are disclosed. The system and method include performing pre-processing of an image using GPUs, configuring an optic based on the pre-processing, the configuring being designed to account for features of the pre-processed image, acquiring an image using the configured optic, processing the acquired image using GPUs, and determining if the processed acquired image accounts for feature of the pre-processed image, and the determination is affirmative, outputting the image, wherein if the determination is negative repeating the configuring of the optic and re-acquiring the image.

A system and method for controlling characteristics of collected image data are disclosed. The system and method include performing pre-processing of an image using GPUs, configuring an optic based on the pre-processing, the configuring being designed to account for features of the pre-processed image, acquiring an image using the configured optic, processing the acquired image using GPUs, and determining if the processed acquired image accounts for feature of the pre-processed image, and the determination is affirmative, outputting the image, wherein if the determination is negative repeating the configuring of the optic and re-acquiring the image.

Embodiments of systems and methods for operating an electro-optical shutter with variable transmissivity are described. In some embodiments, an Information Handling System (IHS) may include a processor and a memory coupled to the processor, the memory having program instructions stored thereon that, upon execution, cause the IHS to: receive context information, and control a transmissivity of the electro-optical shutter of a camera coupled to the IHS, at least in part, based upon the context information.

Embodiments of systems and methods for operating an electro-optical shutter with variable transmissivity are described. In some embodiments, an Information Handling System (IHS) may include a processor and a memory coupled to the processor, the memory having program instructions stored thereon that, upon execution, cause the IHS to: receive context information, and control a transmissivity of the electro-optical shutter of a camera coupled to the IHS, at least in part, based upon the context information.

An example shutter assembly for protecting cameras, such as webcams, integrated into computing devices is disclosed. The shutter assembly includes an actuator element and shutter element. The actuator element can rotate an axis to pivot the shutter element into and out of the field of view of the camera assembly. The actuator can extend through or be otherwise accessible through the housing of the computing device so that the shutter can move in a plane parallel to the front surface or bezel of the computing device. Because the shutter element operated from a surface other than the front facing surface, the bezel can include a single surface with a window to protect the camera assembly and allow for a touch control capabilities. The shutter element can be disposed between the bezel and the camera assembly to provide privacy from the camera being inadvertently or maliciously activated.

An example shutter assembly for protecting cameras, such as webcams, integrated into computing devices is disclosed. The shutter assembly includes an actuator element and shutter element. The actuator element can rotate an axis to pivot the shutter element into and out of the field of view of the camera assembly. The actuator can extend through or be otherwise accessible through the housing of the computing device so that the shutter can move in a plane parallel to the front surface or bezel of the computing device. Because the shutter element operated from a surface other than the front facing surface, the bezel can include a single surface with a window to protect the camera assembly and allow for a touch control capabilities. The shutter element can be disposed between the bezel and the camera assembly to provide privacy from the camera being inadvertently or maliciously activated.