Methods and apparatus for controlling the read out of rows of pixel values from sensors corresponding to different optical chains used to capture portions of the same image area are described. The readout is controlled based on user input and/or determinations with regard to the rate of motion in captured images or portions of captured images. For a low rate of motion i, the readout rate of a sensor corresponding to a small focal length is slowed down while the pixel row readout rate of one or more sensors corresponding to one or more optical chains have larger focal lengths are allowed to proceed at a normal rate. For a high rate of motion, the read out rate of the sensor corresponding to the optical chain having the smaller focal length is allowed to proceed at the normal rate.

Methods and apparatus for controlling the read out of rows of pixel values from sensors corresponding to different optical chains used to capture portions of the same image area are described. The readout is controlled based on user input and/or determinations with regard to the rate of motion in captured images or portions of captured images. For a low rate of motion i, the readout rate of a sensor corresponding to a small focal length is slowed down while the pixel row readout rate of one or more sensors corresponding to one or more optical chains have larger focal lengths are allowed to proceed at a normal rate. For a high rate of motion, the read out rate of the sensor corresponding to the optical chain having the smaller focal length is allowed to proceed at the normal rate.

An optical system including at least one liquid crystal lens and an imaging lens module is provided. The optical system is configured to form an image of an object. The at least one liquid crystal lens and the imaging lens module is disposed on a path of light from the object. The at least one liquid crystal lens includes a first substrate, a second substrate, and a liquid crystal layer. The second substrate is opposite to the first substrate. The liquid crystal layer is disposed between the first substrate and the second substrate. An effective refractive index of each position on the liquid crystal layer is related to an voltage applied, and the at least one liquid crystal lens is configured to change an optical axis of the at least one liquid crystal lens by changing distribution of orientations of liquid crystal molecules of the liquid crystal layer.

Systems and methods for adjusting a focal length of a mirror are provided. Some systems can include an adjustment device having an slot, a mirror that is rotatable about an axis, and a drive coupled to the mirror and configured to engage the slot, wherein movement of the adjustment device can cause the drive to move within the slot upwards or downwards in accordance with a slope of the slot, thereby rotating the mirror about the axis.

Systems and methods for adjusting a focal length of a mirror are provided. Some systems can include an adjustment device having an slot, a mirror that is rotatable about an axis, and a drive coupled to the mirror and configured to engage the slot, wherein movement of the adjustment device can cause the drive to move within the slot upwards or downwards in accordance with a slope of the slot, thereby rotating the mirror about the axis.

A zoom apparatus for a camera of a game system is disclosed. The zoom apparatus has a body structure formed to fit over the camera. The zoom apparatus includes a zoom lens disposed within the body structure so as to be positioned in front of a lens of the camera when the body structure is attached to the camera. The zoom apparatus also includes an optical waveguide disposed within the body structure. The optical waveguide is formed to have an optical input and an optical output. The optical waveguide is formed to receive light into the optical input from a light source on the camera when the body structure is attached to the camera. The optical waveguide is formed to emit light from the optical output into a designated area within a field of view of the lens of the camera when the body structure is attached to the camera.

A zoom apparatus for a camera of a game system is disclosed. The zoom apparatus has a body structure formed to fit over the camera. The zoom apparatus includes a zoom lens disposed within the body structure so as to be positioned in front of a lens of the camera when the body structure is attached to the camera. The zoom apparatus also includes an optical waveguide disposed within the body structure. The optical waveguide is formed to have an optical input and an optical output. The optical waveguide is formed to receive light into the optical input from a light source on the camera when the body structure is attached to the camera. The optical waveguide is formed to emit light from the optical output into a designated area within a field of view of the lens of the camera when the body structure is attached to the camera.

An autofocus lens system includes no conventional moving parts and has excellent speed and low power consumption. The system includes a small electronically-controlled focusing-module lens. The focusing-module lens includes two adjustable polymeric surfaces (e.g., two adjustable-surface lenses in a back-to-back configuration). The curvature of the surfaces can be adjusted to change focus. The performance of the autofocus lens system is extended by adding a conventional first and second lens, or lens group, on either side of the focusing-module lens. What results is an autofocus lens system with excellent near field and far field performance.

An autofocus lens system includes no conventional moving parts and has excellent speed and low power consumption. The system includes a small electronically-controlled focusing-module lens. The focusing-module lens includes two adjustable polymeric surfaces (e.g., two adjustable-surface lenses in a back-to-back configuration). The curvature of the surfaces can be adjusted to change focus. The performance of the autofocus lens system is extended by adding a conventional first and second lens, or lens group, on either side of the focusing-module lens. What results is an autofocus lens system with excellent near field and far field performance.

An optics system includes at least one emitting fiber tip that transmits a divergent beam. The divergent beam includes a global maximum intensify of radiation centered with an output optical axis. The divergent beam includes central beams for collimating and periphery beams for disposing. The periphery beams include parasitic radiation of the divergent beam. The optics system includes at least one collimating lens having an output size, output shape, and output optical axis centered thereto and configured to redirect the central beams to a target and redirect the periphery beams into free-space; and at least one redirecting element positioned in between the at least one emitting fiber tip and the at least one collimating lens. The redirecting element includes a first area having an interior size and interior shape to transmit the central beams, and at least one second area outside of the first area to transmit the periphery beams.