초록 ▼

A system to provide radiant energy of selectable spectral characteristic (e.g. a selectable color combination of light) uses an optical integrating cavity to combine energy of different wavelengths from different sources. Sources of radiant energy of different wavelengths, typically different-color

A system to provide radiant energy of selectable spectral characteristic (e.g. a selectable color combination of light) uses an optical integrating cavity to combine energy of different wavelengths from different sources. Sources of radiant energy of different wavelengths, typically different-color LEDs, supply radiant energy into the interior of the cavity. The cavity has a diffusely reflective interior surface and an aperture for allowing emission of combined radiant energy. Control of the intensity of emission of the sources sets the amount of each wavelength of energy in the combined output and thus determines a spectral characteristic of the radiant energy output through the aperture. A variety of different elements may optically process the combined light output, such a deflector, a variable iris, a lens, a variable focusing lens system, a collimator, a holographic diffuser and combinations thereof. Such systems are useful in various luminous applications as well as various illumination applications.

대표청구항 ▼

What is claimed is: 1. A lighting system, comprising: a dome having a reflective surface; and a plate having a substantially flat reflective surface facing the reflective surface of the dome, coupled to the dome so as to form a reflective chamber between the reflective surfaces of the dome and plat

What is claimed is: 1. A lighting system, comprising: a dome having a reflective surface; and a plate having a substantially flat reflective surface facing the reflective surface of the dome, coupled to the dome so as to form a reflective chamber between the reflective surfaces of the dome and plate, at least a portion of one of the reflective surfaces of the dome and plate being diffusely reflective; an aperture for emission of light from the chamber; a plurality of light emitting diodes (LEDs), each respective one of the LEDs being coupled to emit light into the chamber in a direction toward a reflective surface of the dome or plate so that light emissions from the respective LED reflect at least once within the chamber before emission through the aperture, wherein reflections of light from the LEDs within the chamber combines light from the LEDs for the emission through the aperture toward a region intended for humanly perceptible lighting by emitted combined light. 2. The lighting system as in claim 1, wherein at least portions of both the reflective surface of the dome and the reflective surface of the plate are diffusely reflective. 3. The lighting system as in claim 2, wherein the aperture extends through the plate. 4. The lighting system as in claim 2, wherein the reflective surface of the dome has a shape corresponding to a substantial segment of a sphere. 5. The lighting system as in claim 4, wherein: the plate is circular; and the LEDs are coupled to emit light into the chamber and toward the reflective surface of the dome from points around the circular plate. 6. The lighting system as in claim 2, wherein the reflective surface of the dome has a shape corresponding to a substantial segment of a cylinder. 7. The lighting system of claim 2, wherein the reflective surfaces of the dome and plate form the chamber so as to have a substantially rectangular cross-section. 8. The lighting system of claim 2, wherein the dome and plate are formed as parts of an extruded member. 9. The lighting system as in claim 1, further comprising control circuitry coupled to first and second ones of the LEDs emitting light of first and second different colors for establishing respective amounts of light output from the first and second LEDs, so as to set a color characteristic of the combined light emitted through the aperture. 10. The lighting system as in claim 9, wherein the control circuitry comprises: a memory storing a plurality of color settings; and a controller, for selecting one of the stored color settings from memory and establishing respective amounts of light output from the first and second LEDs so as to set the color characteristic of the combined light emitted through the aperture, in accordance with the selected one of the stored color settings. 11. The lighting system as in claim 9, further comprising: a sensor for sensing a characteristic relating to operation of the lighting system; wherein the control circuitry establishes the respective amounts of light output from the LEDs based at least in part on the sensed characteristic. 12. The lighting system as in claim 11, wherein: the sensor is for sensing a characteristic of the combined light; and the control circuitry establishes the respective amounts of light output from the LEDs based at least in part on the sensed characteristic of the combined light. 13. The lighting system as in claim 12, wherein the sensed characteristic of the combined light relates to color of the combined light. 14. The lighting system as in claim 13, wherein the sensor is coupled to sense the combined light within the chamber. 15. The lighting system as in claim 11, further comprising: at least one, initially inactive LED; wherein the control circuitry is responsive to the sensed characteristic to activate the initially inactive LED to maintain the set color characteristic of the combined light emitted through the aperture. 16. The lighting system as in claim 1, wherein the plurality of LEDs include respective color LEDs for emission of a plurality of respective primary colors. 17. The lighting system as in claim 16, respective color LEDs comprise: at least one red (R) LED; at least one green (G) LED; and at least one blue (B) LED. 18. The lighting system as in claim 1, further comprising a white light source supplying white light to the chamber. 19. The lighting system as in claim 18, wherein the white light source is coupled to emit white light into the chamber in a direction toward a reflective surface of the dome or plate, for reflection in the chamber, to integrate the white light from the white light source into the combined light for emission through the aperture. 20. The lighting system as in claim 18, wherein the white light source is arranged so that at least a substantial portion of the white light from the white light source passes directly through the aperture. 21. A down light, comprising: a dome having a reflective surface facing downward; a plate extending across an open area of the surface of the dome and having a substantially flat reflective surface facing toward the reflective surface of the dome; wherein the reflective surfaces of the dome and plate form a chamber therebetween; an aperture extending downward through the plate; a plurality of light emitting diodes coupled to emit light from points on the reflective surface of the plate toward the reflective surface of the dome; wherein at least a portion of one of the reflective surfaces has a diffuse reflectively such that reflections within the chamber combine light from the LEDs for combined light emission downward through the aperture. 22. The down light of claim 21, wherein the reflective surface of the dome has a shape corresponding to a substantial segment of a sphere. 23. The down light of claim 22, wherein: the plate is circular; and the LEDs are coupled to emit light upward into the chamber toward the reflective surface of the dome from points around the circular plate. 24. The down light of claim 21, wherein the reflective surface of the dome has a shape corresponding to a substantial segment of a cylinder. 25. The down light of claim 21, wherein the reflective surfaces of the dome and plate form the chamber so as to have a substantially rectangular cross-section. 26. The down light of claim 21, wherein the dome and plate are formed as parts of an extruded member. 27. The down light of claim 21, further comprising control circuitry coupled to first and second ones of the LEDs emitting lights of different colors for establishing respective amounts of light outputs from the first and second LEDs, so as to set a color characteristic of the combined light emitted through the aperture. 28. The down light of claim 27, wherein the control is configured to set the characteristic of the combined light to a temperature of substantially white light. 29. The down light of claim 21, further comprising a white light source supplying white light to the chamber. 30. The down light of claim 29, wherein the white light source is coupled to emit white light into the chamber in a direction toward a reflective surface of the dome or plate, for reflection in the chamber, to integrate the white light from the white light source into the combined light for emission through the aperture. 31. The down light of claim 29, wherein the white light source is arranged so that at least a substantial portion of the white light from the white light source passes directly through the aperture. 32. A system providing down lighting, comprising: a dome having a diffusely reflective surface facing downward, the diffusely reflective surface of the dome having a shape corresponding to a substantial segment of a sphere; a plate extending across an circular open area of the surface of the dome and having a substantially flat diffusely reflective circular surface facing toward the reflective surface of the dome; wherein the reflective surfaces of the dome and plate form a chamber therebetween; an aperture extending downward through the plate; a plurality of light emitting diodes coupled to emit light from points on the circular reflective surface of the plate upward into the chamber toward the reflective surface of the dome; wherein reflections within the chamber combine light from the LEDs for combined light emission downward through the aperture; control circuitry coupled to first and second ones of the LEDs emitting lights of different colors for establishing respective amounts of light outputs from the first and second LEDs, so as to set a color characteristic of the combined light emitted through the aperture; and a white light source supplying white light to the chamber, the white light source being arranged so that at least a substantial portion of the white light from the white light source passes directly through the aperture.