A tunable optic includes a hexagonal-shaped housing, a polar liquid, a first electrode, a second electrode, a third electrode, a fourth electrode, a fifth electrode, a sixth electrode, and a grounding electrode. The hexagonal-shaped housing includes first, second, third, fourth, fifth, and sixth side walls and first and second light transmissive end walls, and the first, second, third, fourth, fifth and sixth side walls and the first and second light transmissive end walls define a hexagonal-shaped inner cavity. The polar liquid is disposed within the hexagonal-shaped inner cavity. The polar liquid has a surface, and the surface has a curvature and a two-dimensional tilt angle that is variable in response to voltages supplied to each of the first, second, third, fourth, fifth, and sixth electrodes, whereby lens characteristics and light deflection characteristics of the tunable optic are varied.

A working vehicle includes a vehicle body, an obstacle detector to detect an obstacle in a vicinity of the vehicle body, at least one lamp to be lighted on a peripheral portion of the vehicle body, and an attachment bracket attached to the vehicle body. The attachment bracket includes an attachment body including a detector-attaching portion to which the obstacle detector is attached, and at least one lamp-attaching portion to which the at least one lamp is attached.

A lighting system includes a plurality of lights, and a control mechanism configured to automatically adjust at least a first light of the plurality of lights based on one of a desired position and a desired direction. Each light of the plurality of lights is adjustable to project a light beam.

A spotlight system including a spotlight continuously rotatable about a spotlight pan axis and tiltable about a spotlight tilt axis. The system includes a spotlight controller including a housing continuously rotatable about a controller pan axis. The housing has a circumferential lip that engages with a fixed based and a hub engaged with a handle. The handle rotates about a controller tilt axis perpendicular to the controller pan axis. A controller board is electrically connected to a slip ring that penetrates the base, with a pan input sensor, a tilt input sensor, and a microprocessor. The pan input sensor measures the position of the housing relative to the base, the tilt input sensor measures the position of the handle relative to the housing, and the microcontroller interprets the positions and generates control signals corresponding to the direction of a spotlight.

A light assembly attaches to a surface of a vehicle with a power source. The light assembly includes a light head including a light, a light head terminal in electrical communication with the light, and a first mounting structure. The light assembly further includes a first base configured to be coupled to the surface of the vehicle. The first base includes a second mounting structure configured to mate with the first mounting structure. The first base also includes a conductor configured to couple to the power source of the vehicle and a first base terminal in electrical communication with the conductor. The light assembly further includes a second base configured to be coupled to the surface of the vehicle. The second base includes a third mounting structure configured to mate with the first mounting structure and a battery and a second base terminal in electrical communication with the battery.

This disclosure introduces methods and devices for robotic police officer assistance, incorporating an articulating spotlight, removable camera, spike strip delivery, and chemical agent dispenser, aiming to enhance officer safety during common police activities by allowing remote operation and minimizing the need for officers to be physically present in dangerous situations. Presented herein are methods and devices for robotic police officer assistance. The device comprises an articulating spotlight, a removeable camera, a spike strip delivery mechanism, and a chemical agent dispenser. The robot is controlled by a police officer so that the actions of the robot can be controlled from a position that is safe for the officer. By directing the robotic device, it is not necessary for an officer to be placed in in a dangerous position to conduct some of the most common police activities. When an officer is not required to put their personal safety on the line during common police activities, serious injury to police officers can be avoided. Also disclosed herein are methods of using the robotic device during police activities or emergencies that would otherwise require an officer to be put in harm's way.

A lighting system of a vehicle is provided herein and includes an external lighting device, one or more sensors configured to detect an object approaching the vehicle, and a controller configured to identify the object and assess a threat level thereof based on input from the one or more sensors. If the controller determines that the object is high threat, the controller operates the external lighting device to produce an illumination sequence in the direction of the object.

Provided is a beam-steering mechanism, comprising a lens and a light source positioned in a focal plane of the lens. One of the light source and the lens moves relative to the other of the light source and the lens. The light source outputs a light beam at the lens which forms an illumination spot on a surface from the light beam. The illumination spot moves in a direction in response to a movement of one of the light source and the lens.

A vehicle illumination system for illuminating a path to a vehicle may include a light mechanism arranged on the vehicle, at least one antenna configured to detect a unique device of an approaching user; and at least one controller. The controller may be configured to determine a user location based on the detected unique device, predict the path based at least in part on the user location, and instruct the light mechanism to illuminate an area along the path.

A light diverting system for diverting light from a headlamp assembly of a vehicle includes a processor and a user input device communicatively coupled to the processor. A light diverting apparatus includes an actuator communicatively coupled to the processor and a light diverting member comprising a reflective surface configured to reflect light from a light source. A memory module is communicatively coupled to the processor that stores logic that, when executed by the processor, causes the system to receive user instructions from the user input device and adjust a position of the light diverting member using the light diverting apparatus based on the user instructions.