An electronic device is provided which includes a housing, a first camera module disposed on a first portion of the housing to face in a first direction, and having a first lens cover protruding in a convex shape from an outer surface of the housing, and a second camera module disposed on a second portion of the housing, which is positioned to be opposite to the first portion of the housing, to face in a second direction that is opposite to the first direction, and having a second lens cover protruding in a convex shape from an outer surface of the housing.

An omnidirectional lens is disclosed of the type which captures light from virtually all angles of incidence, and also emits light in all directions. Embodiments are specifically disclosed as a two-way lens that receives light beams from all directions of the compass and directs those light beams to a photosensor. The same two-way lens acts in a beacon mode to produce light beams from one or more LEDs, and to emit such light beams (again) in all directions of the compass. The emitted light beams can also be used to signal various functions as visible signals to users on a jobsite.

A sensor module for a lighting fixture includes a housing configured to be mounted to a lighting fixture, a light sensor mounted in the housing, and a sensor cover over the light sensor. The sensor cover includes a parallel surface and an angled surface. The parallel surface is parallel to a task surface within an area of interest, and includes a first number of lens sections, each of which are configured to focus light from a different portion of a first subset of the task surface to the light sensor. The angled surface includes a second number of lens sections, each of which extend from an edge of the parallel surface to form a facet of the angled surface and are configured to focus light from a different portion of a second subset of the task surface to the light sensor.

The subject invention includes a biomimetic integrated optical sensor system, based on the integration of a wide field-of-view (WFOV) miniature staring multi-aperture compound eye with a high-speed, low-cost, polarization and spectral selective liquid crystal (LC) filter array, a MWIR focal plane array (FPA), and a neural network processor.

An omnidirectional lens is disclosed of the type which captures light from virtually all angles of incidence, and also emits light in all directions. Embodiments are specifically disclosed as a two-way lens that receives light beams from all directions of the compass and directs those light beams to a photosensor. The same two-way lens acts in a beacon mode to produce light beams from one or more LEDs, and to emit such light beams (again) in all directions of the compass. The emitted light beams can also be used to signal various functions as visible signals to users on a jobsite.

An electronic device is provided which includes a housing, a first camera module disposed on a first portion of the housing to face in a first direction, and having a first lens cover protruding in a convex shape from an outer surface of the housing, and a second camera module disposed on a second portion of the housing, which is positioned to be opposite to the first portion of the housing, to face in a second direction that is opposite to the first direction, and having a second lens cover protruding in a convex shape from an outer surface of the housing.

A rotationally shift invariant and multi-layered array system for full-field of view and/or photon collection by 4 pi steradian field of view. In the system, all of the incoming light (i.e., light from all directions), in a solid angle of 4 pi steradians, is focused inside the optics. The optics have a spherically shift invariant structure, providing rotational shift invariance. The system comprises a nontraditional use of the Gabor Superlen and is a configuration of multiple microlens array shell structures with concentrically arranged bulk optical components. Examples of such bulk optical components include Luneburg lenses, micro-structured surfaces, a single lens, a plurality of single lenses, ball lenses, metalenses, diffractive optical elements, and magnetic lenses. In an embodiment, the Gabor Superlens (i.e., microlens array) is planar. In an embodiment, no moving parts are required for the system to achieve truly full-field of view imaging and/or photon collection by 4 pi steradian field of view.

A LIDAR system architecture which transmits light via an optical phased array and receives the reflected signal with a spherically shift invariant sensor. Phased arrays offer the ability to quickly scan a desired area by manipulating the electrical, or in this case-thermal, properties of an array of sensors. Similarly spherically shift invariant systems offer the ability to bring light into focus at the same location regardless of its angle of arrival.

The subject invention includes a biomimetic integrated optical sensor system, based on the integration of a wide field-of-view (WFOV) miniature staring multi-aperture compound eye with a high-speed, low-cost, polarization and spectral selective liquid crystal (LC) filter array, a MWIR focal plane array (FPA), and a neural network processor.