The present disclosure sets forth a motion sensing outdoor security light with the flexibility of being mounted to either a wall structure or to an eave or ceiling structure. An adjustable spherical motion sensor housing may be provided with the rotationally adjustable outdoor security light, allowing easy adjustment of motion detection ranges under different mounting schemes without comprising the aesthetic design of the light. The adjustable spherical motion sensor housing may also provide an enlarged horizontal field of view for better performance.

The present disclosure sets forth an outdoor security light with the flexibility of being mounted to either a wall structure or to an eave or ceiling structure. The security light can be adjusted for each installation without the necessity of changing hardware elements of the security luminaire. Various embodiments allow for both a vertical installation wall mount, and a horizontal installation ceiling or eave mount, while maintaining appropriate outward orientation of the lamp heads while also allowing for appropriate positioning of a motion or other sensors.

The present disclosure sets forth an outdoor security light with the flexibility of being mounted to either a wall structure or to an eave or ceiling structure. The security light can be adjusted for each installation without the necessity of changing hardware elements of the security luminaire. Disclosed designs include a luminaire housing having a housing mount which is removably received within a housing mount attached to a structure. The mechanical and electrical interface between the two may allow a removable engagement with a lock mechanism for an easy installation, while providing electrical power to the luminaire housing and communication therebetween.

The present disclosure sets forth an outdoor security light with the flexibility of being mounted to either a wall structure or to an eave or ceiling structure. The security light can be adjusted for each installation without the necessity of changing hardware elements of the security luminaire. Disclosed designs include a luminaire housing having a housing mount which is removably received within a housing mount attached to a structure. The mechanical and electrical interface between the two may allow a removable engagement with a lock mechanism for an easy installation, while providing electrical power to the luminaire housing and communication therebetween.

A light includes a housing with a front face, a first face oriented at a first oblique angle with respect to the front face, and a second face oriented at a second oblique angle with respect to the front face. The light also includes a light source with a plurality of LEDs arranged to emit light from the front face, and a power source configured to provide power to the light source. The second oblique angle is different than the first oblique angle. The first face and the second face each define a surface configured to support the light. The first face includes two legs spaced from one another, and the second face includes two legs spaced from one another.

A lighting appliance includes a housing, a lighting element disposed in the housing is capable of displaying multiple color temperatures, a control unit disposed in the housing, an electrical communication system in communication with the lighting element and the control unit, and a sensor disposed on a portion of the housing, where the sensor is in communication with the lighting element and the control unit via the electrical communication system, and when a motion signal is detected by the sensor, the control unit is configured to instruct the lighting element to illuminate in a predetermined light mode for a predetermined time.

A light includes a housing including a front face, a first face, a second face, and a first surface arranged adjacent the first face. A lens is coupled to the front face. A light source is covered by the lens. A power source is configured to provide power to the light source. The first face is angled at a first oblique angle with respect to the front face, the second face is angled at a second oblique angle with respect to the front face, and the first surface is angled at a third oblique angle with respect to the front face. The first face, the second face, and the first surface each define a surface configured to support the light. The first face includes two legs spaced from one another and extending away from the first surface.

A light includes a housing having a top face, a bottom face, a first side face, a second side face, and a surface arranged adjacent to the bottom face. The top face, the bottom face, the first side face, the second side face, and the surface are each configured to support the light. The light further includes a head pivotally coupled to the housing. The head includes a lens and a plurality of LEDs configured to emit light through the lens. The light additionally includes a power source configured to provide power to the plurality of LEDs. The head is positioned between the top face, the bottom face, and the first and second side faces in a first position of the head. The surface is obliquely oriented relative to the lens when the head is in the first position.

Systems and methods for an auto-land system for a rotorcraft are provided. The system includes, a search light (SL) assembly configured to receive user input directing the SL to a point of interest (POI) and determine an actual SL orientation and an actual SL range to the POI; and, a searchlight controller operationally coupled to the search light assembly, and configured to: responsive to receiving a command to auto-land at the POI, begin (i) generating a desired trajectory from the rotorcraft actual orientation and rotorcraft actual range to the POI; (ii) generating guidance commands for navigating the rotorcraft in accordance with the desired trajectory; (iii) monitoring an actual SL range and an actual SL orientation; and (iv) generating controlling commands for the searchlight assembly in accordance with the coordinates of the POI.

A light includes a housing including a front face, a first face, a second face, and a first surface arranged adjacent the first face. A lens is coupled to the front face. A light source is covered by the lens. A power source is configured to provide power to the light source. The first face is angled at a first oblique angle with respect to the front face, the second face is angled at a second oblique angle with respect to the front face, and the first surface is angled at a third oblique angle with respect to the front face. The first face, the second face, and the first surface each define a surface configured to support the light. The first face includes two legs spaced from one another and extending away from the first surface.