The present invention relates to a smart vest for use by railyard personnel at a railyard. The smart vest utilizes many safety features, such as improved visibility, a real-time camera, an environmental monitor, high-accuracy location tracking, tracking the state of the railyard crew member, real-time communication, and mobile power. Each of these features may be incorporated with the smart vest.

Techniques are disclosed for enabling a wind-sensing optical scope to communicate with external components to provide for a ballistic solution. Techniques may further incorporate cost saving features such as the utilization of a photo diode and/or other features. The wind-sensing optical scope may include various sensors to collect data for the ballistic solution, and/or data from external sensors may be used. Techniques may further incorporate range finding in the wind-sensing optical scope, depending on desired functionality.

A method of augmenting a human face with projected light is disclosed. The method includes determining a blend of component attributes to define visual characteristics of the human face, modifying an input image based, at least in part, on an image of the human face, wherein the modified input image defines an augmented visual characteristic of the human face, determining a present location of one or more landmarks on the human face based, at least in part, on the image of the human face, predicting a future location of the one or more landmarks, deforming a model of the human face based on the future location of the one or more landmarks, generating an augmentation image based on the deformed model and the modified input image, and transmitting for projection the augmentation image.

Imaging systems and method of optical imaging. One example of an imaging system includes an optical scanning subsystem including an optical source and a waveguide, the waveguide being configured to direct optical radiation generated by the optical source over an area of a scene, a detection subsystem including an optical sensor configured to collect reflected optical radiation from the area of the scene, and a fused fiber focusing assembly including a fused fiber bundle, a plurality of lenses coupled together and positioned to receive and focus the reflected optical radiation from the area of the scene directly onto the fused fiber bundle, a microlens array interposed between the fused fiber bundle and the optical sensor and positioned to receive the reflected optical radiation from the fused fiber bundle, and a focusing lens positioned to direct the reflected optical radiation from the microlens array onto the optical sensor.

Provided is an information processing system including at least a reflection member, and an information processing apparatus capable of image processing. The reflection member is a retro reflecting material. The information processing apparatus includes an imaging section that captures an image, a first light emitting section, a second light emitting section, and a light source detecting section. The first light emitting section and the second light emitting section each emit light. At least one of a half-power angle and an entrance angle of the second light emitting section is different from that of the first light emitting section. The light source detecting section detects, in the image captured by the imaging section, a light source image including an image of the retro reflecting material.

Aspects of the present disclosure relate to eye tracking systems and methods which track eyes by illuminating the eyes using a light source and detecting the eye illuminations using a sensor. Implementations of the present disclosure may utilize wide angle lighting via a plurality of individual light sources which are each oriented in different orientations. A wide area may be illuminated by the different light sources, and these light sources may be selectively turned on and off based on a current location of a user.

The methods and apparatus for repetitive iris recognition include an apparatus for repetitively imaging an iris. The apparatus comprises a housing defining a substantially planar outer surface, a first axis normal to the substantially planar outer surface, and a curved outer surface, opposite the substantially planar outer surface, defined by a curve rotated about the first axis. The apparatus further comprises an infrared sensor array, disposed within the housing, to acquire an infrared image of an iris via at least one first aperture in the substantially planar outer surface. The apparatus further comprises at least one infrared illuminator, disposed within the housing, to illuminate the iris during acquisition of the infrared image of the iris via at least one second aperture in the substantially planar outer surface.

The various implementations disclosed herein include a camera assembly configured for communication over multiple communication protocols. The camera assembly includes: (1) an enclosed housing; (2) a lens module positioned within the enclosed housing and configured to receive light; (3) circuit board(s) positioned within the enclosed housing; (4) communication circuitry coupled to the circuit board(s) and configured to wirelessly communicate over a plurality of different communication protocols, the communication circuitry including one or more transceivers configured for communication over a first communication protocol and a second communication protocol; (5) a first antenna arranged at a first location on the circuit board(s), the first antenna configured for communication over the first communication protocol; and (6) a second antenna arranged at a second location on the circuit board(s), the second antenna configured for communication over the second communication protocol.

In one embodiment, an infrared (IR) imaging system for determining a concentration of a target species in an object is disclosed. The imaging system can include an optical system including an optical focal plane array (FPA) unit. The optical system can have components defining at least two optical channels thereof, said at least two optical channels being spatially and spectrally different from one another. Each of the at least two optical channels can be positioned to transfer IR radiation incident on the optical system towards the optical FPA. The system can include a processing unit containing a processor that can be configured to acquire multispectral optical data representing said target species from the IR radiation received at the optical FPA. Said optical system and said processing unit can be contained together in a data acquisition and processing module configured to be worn or carried by a person.

A system includes a depth sensing device that includes a depth sensor. The depth sensor includes an infrared projector and an infrared camera. The system includes a processor coupled to the depth sensor and a memory accessible to the processor, and programming in the memory. Execution of the programming by the processor configures the system to perform functions, including functions to project, via the infrared projector, a pattern of infrared light on a plurality of objects located in a space that are reached by the projected infrared light. The plurality of objects includes objects of interest and light fixtures in the space. The execution of the programming by the processor further configures the system to determine light fixture location coordinates for each of the light fixtures based on computed distances between the objects of interest and each of the light fixtures based on distortions of the projected infrared light.