A lighting apparatus includes a light source module, a light passing cover, a prism plate and a surface rim. The light source module includes a light source plate and multiple LED modules mounted on the light source plate. The light passing cover has a first side facing to the multiple LED modules for receiving a light from the multiple LED modules. The prism plate is disposed with more than 50 prism units for diffusing the light passing through the light passing cover from a second side of the light passing cover. The surface rim has a light opening for the light diffused by the prism units to escape from the lighting apparatus.

A vehicle interior component comprising a cover with a surface providing a display region is disclosed. The component may comprise a composite layer/structure and light source to provide light at a first and a second visible color/wavelength. The composite layer may comprise light-transmissive segments with color and light-transmissive transparent/translucent segments; light at the first wavelength is transmitted through a first segment and transparent/translucent segment to present a first image/visual effect at the display region; light at the second wavelength is transmitted through a second segment and transparent/translucent segment to present a second image/visual effect at the display region; light at the first wavelength is obstructed by the second segment; light at the second wavelength is obstructed by the first segment; transparent/translucent segments transmit light at first and second wavelengths. The composite layer may comprise a multi-layer form on the cover.

A vehicle interior component comprising a cover with a surface providing a display region is disclosed. The component may comprise a composite layer/structure and light source to provide light at a first and a second visible color/wavelength. The composite layer may comprise light-transmissive segments with color and light-transmissive transparent/translucent segments; light at the first wavelength is transmitted through a first segment and transparent/translucent segment to present a first image/visual effect at the display region; light at the second wavelength is transmitted through a second segment and transparent/translucent segment to present a second image/visual effect at the display region; light at the first wavelength is obstructed by the second segment; light at the second wavelength is obstructed by the first segment; transparent/translucent segments transmit light at first and second wavelengths. The composite layer may comprise a multi-layer form on the cover.

A lighting device includes a housing, a power supply, a first light source such as a LED, a variable focus lens adapted to vary the focus of light from the first light source, a switch and a controller having circuitry, The circuitry is adapted to control the current to the first light source based upon a voltage of the power supply, and is adapted to control variability of the variable focus lens.

A lighting device includes a housing, a power supply, a first light source such as a LED, a variable focus lens adapted to vary the focus of light from the first light source, a switch and a controller having circuitry, The circuitry is adapted to control the current to the first light source based upon a voltage of the power supply, and is adapted to control variability of the variable focus lens.

A lighting apparatus including an enclosure, a printed circuit board mounted to the enclosure, and an upwardly directed primary light emitting diode in electrical communication with the printed circuit board. The lighting apparatus additionally includes a power source for supplying electrical power to the printed circuit board. The lighting apparatus further includes a transparent dome situated atop the enclosure and covering the printed circuit board, wherein the transparent dome includes an optically unobstructed region in vertical alignment with the primary light emitting diode for passage of an upwardly directed light beam emitted from the primary light emitting diode when powered.

A lighting apparatus including an enclosure, a printed circuit board mounted to the enclosure, and an upwardly directed primary light emitting diode in electrical communication with the printed circuit board. The lighting apparatus additionally includes a power source for supplying electrical power to the printed circuit board. The lighting apparatus further includes a transparent dome situated atop the enclosure and covering the printed circuit board, wherein the transparent dome includes an optically unobstructed region in vertical alignment with the primary light emitting diode for passage of an upwardly directed light beam emitted from the primary light emitting diode when powered.

A light emitting module includes: a substrate; a first light source mounted on the substrate, the first light source comprising a first light emitting element configured to emit first light, a light reflecting member surrounding lateral faces of the first light emitting element, and a first wavelength conversion member configured to convert a wavelength of a portion of the first light and to emit second light, such that the first light source is configured to output light that includes the first light and the second light, the first wavelength conversion member covering the first light emitting element and extending out from the lateral faces of the first light emitting element when viewed from above; and a first lens on which the light output from the first light source is incident.

Systems for apparatuses formed of light emitting devices. Solutions for controlling the off-state appearance of lighting system designs is disclosed. Thermochromic materials are selected in accordance with a desired off-state of an LED device. The thermochromic materials are applied to a structure that is in a light path of light emitted by the LED device. In the off-state the LED device produces a desired off-state colored appearance. When the LED device is in the on-state, the thermochromic materials heat up and become more and more transparent. The light emitted from the device in its on-state does not suffer from color shifting due to the presence of the thermochromic materials. Furthermore, light emitted from the LED device in its on-state does not suffer from attenuation due to the presence of the thermochromic materials. Techniques to select and position thermochromic materials in or around LED apparatuses are presented.

Systems for apparatuses formed of light emitting devices. Solutions for controlling the off-state appearance of lighting system designs is disclosed. Thermochromic materials are selected in accordance with a desired off-state of an LED device. The thermochromic materials are applied to a structure that is in a light path of light emitted by the LED device. In the off-state the LED device produces a desired off-state colored appearance. When the LED device is in the on-state, the thermochromic materials heat up and become more and more transparent. The light emitted from the device in its on-state does not suffer from color shifting due to the presence of the thermochromic materials. Furthermore, light emitted from the LED device in its on-state does not suffer from attenuation due to the presence of the thermochromic materials. Techniques to select and position thermochromic materials in or around LED apparatuses are presented.