Directional lighting system and method

We claim: 1 . A method of connected lightbulb operation, the method comprising: determining a lightbulb orientation relative to an external reference point; concurrently operating an invisible light emitting element of the connected lightbulb in a high emission mode and operating a plurality of visible light emitting elements of the connected lightbulb in a low emission mode; detecting user presence within a monitored space based on signals sampled by an external camera separate from the connected lightbulb, wherein the signals are sampled using invisible light emitted by the invisible light emitting element; identifying a visible light emitting element, from the plurality of visible light emitting elements, based on the lightbulb orientation and a position of the external reference point relative to the monitored space; and selectively operating the identified visible light emitting element in a high emission mode while operating a remainder of the plurality of visible light emitting elements in a low emission mode in response to detecting the user presence. 2 . The method of claim 1 , wherein determining the lightbulb orientation comprises: progressing the plurality of visible light emitting elements through an orientation emission pattern, comprising sequentially transitioning individual light emitting elements of the connected lightbulb from a low emission mode, to a high emission mode, to the low emission mode; and determining the lightbulb orientation based on measurements of signals emitted by the plurality of visible light emitting elements while progressing through the orientation emission pattern. 3 . A method of connected lightbulb operation, the method comprising: operating an invisible light emitting element of the connected lightbulb in a high emission mode while operating a visible light emitting element of the connected lightbulb in a low emission mode; detecting a trigger event; and selectively operating the visible light emitting element in a high emission mode in response to detection of the trigger event. 4 . The method of claim 3 , wherein detecting the trigger event comprises detecting user presence within a monitored space, wherein the connected lightbulb illuminates the monitored space. 5 . The method of claim 4 , wherein detecting user presence within the monitored space comprises detecting user presence based on signals sampled by an external camera separate from the connected lightbulb. 6 . The method of claim 3 , further comprising selectively operating light emitting elements of a second connected lightbulb in response to detection of the trigger event. 7 . The method of claim 6 , further comprising connecting the connected lightbulb to a local WiFi network, wherein the second connected lightbulb is connected to the local WiFi network. 8 . The method of claim 6 , wherein selectively operating the light emitting elements of the second connected lightbulb comprises: operating an infrared light emitting element of the second connected lightbulb in a high emission mode, and operating a visible light emitting element of the second connected lightbulb in a low emission mode. 9 . The method of claim 3 , wherein the visible light emitting element is one of a plurality of individually indexed light emitting elements of the connected lightbulb, the method further comprising: progressing the plurality of light emitting elements through an orientation emission pattern; and determining a lightbulb orientation relative to an external reference point based on the orientation emission pattern. 10 . The method of claim 9 , wherein determining the lightbulb orientation comprises determining the lightbulb orientation based on external device measurements of signals emitted by the plurality of light emitting elements while progressing through the orientation emission pattern. 11 . The method of claim 10 , wherein progressing the plurality of light emitting elements through the orientation emission pattern comprises sequentially transitioning individual light emitting elements of the connected lightbulb from a low emission mode, to a high emission mode, to the low emission mode. 12 . The method of claim 9 , wherein selectively operating the visible light emitting element in the high emission mode comprises: identifying the visible light emitting element from the plurality of light emitting elements, the visible light emitting element having a predetermined position relative to the external reference point; and selectively operating the visible light emitting element in the high emission mode while operating a remainder of the plurality of the visible light emitting elements in the low emission mode. 13 . A lighting system comprising: a substrate; a set of individually indexed light emitting elements mounted to the substrate, the set of light emitting elements comprising: a visible light emitting element configured to emit visible light; and an invisible light emitting element configured to emit invisible light; a processor electrically connected to the set of individually indexed light emitting elements, the processor configured to independently operate the invisible light emitting element from the visible light emitting element; a wireless communication module electrically connected to the processor; and a diffuser mounted to the housing, the diffuser cooperatively encapsulating the visible and invisible light emitting element within the lighting system. 14 . The lighting system of claim 12 , wherein the wireless communication module comprises a WiFi radio. 15 . The lighting system of claim 14 , further comprising a second wireless communication module. 16 . The lighting system of claim 15 , wherein the second wireless communication module comprises an IR transceiver. 17 . The lighting system of claim 12 , wherein the invisible light emitting element comprises an infrared light emitting element. 18 . The lighting system of claim 17 , wherein the visible light emitting element comprises a white light emitting element. 19 . The lighting system of claim 12 , wherein the processor is configured to selectively operate the invisible light emitting element in a high emission mode in response to occurrence of a contextual event. 20 . The lighting system of claim 19 , further comprising an external camera defining a field of view overlapping a monitored space, wherein the contextual event comprises detecting user entry into the monitored space based on signals sampled by the external camera.