Abstract: Embodiments provide systems and methods for providing a dynamically variable focal plane in a waveguide-based display. Generally speaking, embodiments described herein provide an optical system that allows variable control of the focal length of the image emerging from the display engine into the waveguide. This can be a dynamic system that is controlled based upon the content being projected on the display. For a stereoscopic system, individual control of each eye can be provided. More specifically, embodiments comprise an electrically tunable lens element interposed between the output of the projection engine and the optical waveguide and a control unit to dynamically the tunable lens element to vary the focal length of the images provided to the waveguide display.

Abstract: Embodiments of the disclosure provide systems and methods for providing a dynamically variable focal plane in a waveguide-based display. Generally speaking, embodiments described herein provide an optical system that allows variable control of the focal length of the image emerging from the display engine into the waveguide. This can be a dynamic system that is controlled based upon the content being projected on the display. For a stereoscopic system, individual control of each eye can be provided. More specifically, embodiments comprise an electrically tunable lens element interposed between the output of the projection engine and the optical waveguide and a control unit to dynamically the tunable lens element to vary the focal length of the images provided to the waveguide display.

Abstract: Embodiments of the disclosure provide systems and methods for providing a dynamically variable focal plane in a waveguide-based display. Generally speaking, embodiments described herein provide an optical system that allows variable control of the focal length of the image emerging from the display engine into the waveguide. This can be a dynamic system that is controlled based upon the content being projected on the display. For a stereoscopic system, individual control of each eye can be provided. More specifically, embodiments comprise an electrically tunable lens element interposed between the output of the projection engine and the optical waveguide and a control unit to dynamically the tunable lens element to vary the focal length of the images provided to the waveguide display.

Abstract: Devices and systems of a near eye system are provided. In particular, the near eye system may include a digital light processor, a first prism optically coupled to the digital light processor, a lens assembly optically coupled to the first prism, a second prism optically coupled to the lens assembly, and a waveguide configured to direct optical energy received from the second prism into an eye of a user.

Abstract: Techniques for charging and communication with electronic devices, such as headphones, are provided. Specifically, systems and methods to provide charging of, and communication with, audio devices, such as by photovoltaic (PV) cells, infrared (IR) illumination, audio signals, and LEDs such as laser LEDs, are disclosed.

Abstract: Techniques for fiber optic light sensing and communication are provided. Specifically, systems and methods to provide diffusive optical fiber sensors and communication devices and methods of use are disclosed.

Abstract: Techniques for charging and optical communication with electronic devices are provided. Specifically, systems and methods to provide charging through laser or optical means and to provide optical communications are presented. Even more specifically, in one embodiment, the systems and methods comprise standard USB interfaces, USB protocols and USB connectors.

Abstract: Techniques for remote interactions with devices, such as charging, communications, and user interaction, are provided. Specifically, systems and methods to provide charging of devices, such as, remote charging by photovoltaic (PV) cells, infrared (IR) illumination, audio signals, and LEDs such as laser LEDs to charge devices such as watches, jewelry, car panels, headphones and phones, are presented.

Abstract: According to one embodiment, a multi-layer force sensor can comprise two or more Force Sensitive Resistors (FSRs), Force Sensitive Capacitors (FSCs), or other force sensitive devices. Each of these force sensitive devices can comprise a different layer of the multi-layer force sensor. Additionally, each of these different layers can be constructed of a different material providing different responses, i.e., different resistance, conductance, etc., over the same range of pressure or force. As a force is applied to the multi-layer sensor, this difference in response to the force between the layers can be used to determine a value for the force. The multi-layer force sensor can be implemented in a bridge circuit. The bridge circuit can be used to measure the differences in resistance, conductance, etc. between the different layers of the multi-layer sensor.

Abstract: Techniques for charging and optical communication with electronic devices are provided. Specifically, systems and methods to provide charging through laser or optical means and to provide optical communications are presented. Even more specifically, in one embodiment, the systems and methods comprise standard USB interfaces, USB protocols and USB connectors.

Abstract: Techniques for light coupling are provided. Specifically, systems and methods to provide coupling of light emitted from one or more LEDs with light received by an optical fiber are presented.

Abstract: Techniques for fiber optic light sensing and communication are provided. Specifically, systems and methods to provide diffusive optical fiber sensors and communication devices and methods of use are disclosed.

Abstract: Techniques for remote interactions with devices, such as charging, communications, and user interaction, are provided. Specifically, systems and methods to provide charging of devices, such as, remote charging by photovoltaic (PV) cells, infrared (IR) illumination, audio signals, and LEDs such as laser LEDs to charge devices such as watches, jewelry, car panels, headphones and phones, are presented.

Abstract: Techniques for charging and communication with electronic devices, such as headphones, are provided. Specifically, systems and methods to provide charging of, and communication with, audio devices, such as by photovoltaic (PV) cells, infrared (IR) illumination, audio signals, and LEDs such as laser LEDs, are disclosed.

Abstract: An optical waveguide assembly includes a plurality of separate body sections each having a coupling cavity for receiving an LED element and a light extraction feature spaced from the coupling cavity, and a mounting structure surrounding the plurality of body sections that maintains the plurality of body sections in assembled relationship. The waveguide assembly may be incorporated into a light engine.

Abstract: An optical waveguide includes a body of optically transmissive material defined by outer edges and having a width substantially greater than an overall thickness thereof. The body of optically transmissive material includes a first side and a second side opposite the first side. An interior coupling cavity is defined by a surface intersecting the second side and extends from the second side toward the first side. The interior coupling cavity is disposed remote from edges of the body and is configured to receive an LED element. The body of optically transmissive material further includes a first array of light mixing cavities surrounding the interior coupling cavity and an extraction feature disposed on one of the first and second sides. The light extraction feature at least partially surrounds the interior coupling cavity.

Abstract: An optical waveguide includes a body of optically transmissive material defined by outer edges and having a width substantially greater than an overall thickness thereof. The body of optically transmissive material includes a first side and a second side opposite the first side. An interior coupling cavity is defined by a surface intersecting the second side and extends from the second side toward the first side. The interior coupling cavity is disposed remote from edges of the body and is configured to receive an LED element. The body of optically transmissive material further includes a first array of light mixing cavities surrounding the interior coupling cavity and an extraction feature disposed on one of the first and second sides. The light extraction feature at least partially surrounds the interior coupling cavity.

Abstract: An optical waveguide assembly includes a plurality of separate body sections each having a coupling cavity for receiving an LED element and a light extraction feature spaced from the coupling cavity, and a mounting structure surrounding the plurality of body sections that maintains the plurality of body sections in assembled relationship. The waveguide assembly may be incorporated into a light engine.

Abstract: A device, system and method integrating forward and panoramic fields is disclosed, comprising: a primary reflector, comprising a convex surface in relation to the forward field, reflective on at least part of the convex surface; a secondary reflector, forward of the primary reflector relative to the forward field, reflective on at least part a surface thereof facing rearward toward the primary reflector; a primary reflector hole in the primary reflector, substantially centered about an optical axis of the apparatus; and a secondary reflector hole in the secondary reflector, substantially centered about the optical axis.

Abstract: A device, system and method integrating forward and panoramic fields is disclosed, comprising: a primary reflector, comprising a convex surface in relation to the forward field, reflective on at least part of the convex surface; a secondary reflector, forward of the primary reflector relative to the forward field, reflective on at least part a surface thereof facing rearward toward the primary reflector; a primary reflector hole in the primary reflector, substantially centered about an optical axis of the apparatus; and a secondary reflector hole in the secondary reflector, substantially centered about the optical axis.