Abstract: An imaging system including a front aperture, two or more refractive lens elements mounted in a lens barrel, and a photosensor. One or more of the components of the imaging system (e.g., the aperture, lenses, lens groups, and/or photosensor) are tilted with respect to each other and/or with respect to a center (or mechanical) axis of the imaging system to compensate for effects including but not limited to keystone distortion, resolution non-uniformity, and gradient blur that result from tilt of an object in the field of view of the camera with respect to the center axis of the camera.

Abstract: An imaging system including a front aperture, two or more refractive lens elements mounted in a lens barrel, and a photosensor. One or more of the components of the imaging system (e.g., the aperture, lenses, lens groups, and/or photosensor) are tilted with respect to each other and/or with respect to a center (or mechanical) axis of the imaging system to compensate for effects including but not limited to keystone distortion, resolution non-uniformity, and gradient blur that result from tilt of an object in the field of view of the camera with respect to the center axis of the camera.

Abstract: One or more embodiments are directed to a device comprising: a body having a cavity, an opaque structure, and an aperture in the body that places the cavity in fluid communication with an environment external to the body. A photon emitter is located in the cavity below the aperture and configured to emit photons through the aperture to the environment external to the body. A photon receiver is located in the cavity below the opaque structure of the body and configured to receive photons that are each reflected from both an object that is spaced apart from the body in the environment external to the body and from a surface of the opaque structure.

Abstract: A proximity sensor includes a radiation source configured to emit a primary radiation beam and a primary detector configured to pick up a reflected primary radiation beam. The radiation source is further configured to emit stray radiation. The sensor further includes a reference detector arranged to receive the stray radiation. The stray radiation may, for example, be emitted from either a side of the radiation source or a bottom of the radiation source.

Abstract: A proximity sensor includes a radiation source configured to emit a primary radiation beam and a primary detector configured to pick up a reflected primary radiation beam. The radiation source is further configured to emit stray radiation. The sensor further includes a reference detector arranged to receive the stray radiation. The stray radiation may, for example, be emitted from either a side of the radiation source or a bottom of the radiation source.

Abstract: A device including a photon emitter, a photon receiver, and a screen opaque to photons following a direct path from the outside of the device to the photon receiver.

Abstract: A camera module characterization method is presented. An object is imaged with the camera module. The object may be a test chart including a pattern that defines edges and markers. A resolution metric is measured from the obtained image, and at least one point where the resolution metric is maximized is identified (indicative of a measured in-focus position). The measured in-focus position is then used to derive optical aberration parameters. With respect to the test chart, the markers in the image are located and compared with known theoretical marker positions. A difference between the theoretical and actual marker positions is calculated and used to determine edge locations. A measurement of a resolution metric is then made from the obtained image at the determined edge locations.