Interference-resistant compensation for illumination devices
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H05B-037/02
H05B-033/08
출원번호
US-0510243
(2014-10-09)
등록번호
US-9247605
(2016-01-26)
발명자
/ 주소
Ho, Horace C.
Frank, Rebecca
출원인 / 주소
Ketra, Inc.
대리인 / 주소
Daffer, Kevin L.
인용정보
피인용 횟수 :
0인용 특허 :
132
초록▼
A method and illumination device are provided for interference-resistant compensation in light emitting diode (LED) devices. In one embodiment, the method includes monitoring a detection photocurrent within a lamp during multiple detection intervals interspersed with periods of illumination, applyin
A method and illumination device are provided for interference-resistant compensation in light emitting diode (LED) devices. In one embodiment, the method includes monitoring a detection photocurrent within a lamp during multiple detection intervals interspersed with periods of illumination, applying a drive current sufficient to produce illumination to one of multiple emission LED elements within the lamp during a subsequent measurement interval, and monitoring a measurement photocurrent within the lamp while the drive current is applied. An embodiment of an illumination device comprising a lamp includes multiple emission LED elements, one or more photodetectors, and a lamp control circuit, where the lamp control circuit is adapted to perform steps of the method.
대표청구항▼
1. A method for controlling a lamp comprising multiple emission light emitting diode (LED) elements, the method comprising: operating one or more of the multiple emission LED elements to produce illumination substantially continuously by supplying a respective drive current at an operative drive cur
1. A method for controlling a lamp comprising multiple emission light emitting diode (LED) elements, the method comprising: operating one or more of the multiple emission LED elements to produce illumination substantially continuously by supplying a respective drive current at an operative drive current level to each of the one or more of the multiple emission LED elements;bringing the respective drive current of each of the emission LED elements within the lamp to a non-operative drive current level, which is insufficient to produce illumination, for the duration of each of multiple detection intervals interspersed with periods of said illumination;monitoring a detection photocurrent induced in a detection interval photodetector within the lamp during at least a portion of each of the multiple detection intervals;bringing the respective drive current of all except a first one of the emission LED elements within the lamp to a non-operative drive current level which is insufficient to produce illumination, for the duration of a first measurement interval occurring subsequent to the multiple detection intervals and after a period of said illumination, wherein during said first measurement interval, the method comprises: applying a first drive current at an operative drive current level, which is sufficient to produce illumination, to the first one of the emission LED elements; andmonitoring a measurement photocurrent induced in a first measurement photodetector within the lamp during said applying a first drive current. 2. The method of claim 1, further comprising: bringing the respective drive current of all except a second one of the emission LED elements within the lamp to a non-operative drive current level, which is insufficient to produce illumination, for the duration of a second measurement interval occurring subsequent to the multiple detection intervals and after a period of said illumination wherein during said second measurement interval, the method further comprises: applying a second drive current at an operative drive current level, which is sufficient to produce illumination, to the second one of the emission LED elements; andmonitoring a measurement photocurrent induced in a second measurement photodetector within the lamp during said applying a second drive current. 3. The method of claim 2, wherein the first measurement photodetector and second measurement photodetector are the same photodetector. 4. The method of claim 1, wherein said multiple detection intervals and said first measurement interval are within a first periodic series of intervals separated by a first offset from a periodic timing reference. 5. The method of claim 1, wherein: said multiple detection intervals are within a first periodic series of intervals separated by a first offset from a periodic timing reference; andsaid first measurement interval is within a second periodic series of intervals separated by a second offset from the periodic timing reference. 6. The method of claim 1, further comprising determining, for at least one of the multiple detection intervals, that a magnitude of the monitored detection photocurrent does not vary substantially with time during the at least a portion of the detection interval. 7. The method of claim 6, further comprising determining that a predetermined number of free detection intervals has occurred, wherein: a determination that the magnitude of the detection photocurrent monitored in a detection interval does not vary substantially with time indicates that the detection interval is a free detection interval; andsaid applying the first drive current during the first measurement interval is in response to a determination that the predetermined number of free detection intervals has occurred. 8. The method of claim 1, further comprising: determining, for at least one of the multiple detection intervals, that a magnitude of the monitored detection photocurrent varies substantially with time; andin response to a determination that the magnitude of the monitored detection photocurrent varies substantially with time, repeating the steps of: bringing the respective drive current of each of the emission LED elements to a non-operative drive current level, which is insufficient to produce illumination, the duration of each of multiple detection intervals, andmonitoring the photocurrent induced in the detection interval photodetector during at least a portion of each of the multiple detection intervals. 9. The method of claim 8, further comprising waiting for a delay time prior to said repeating the step of bringing the respective drive current of each of the emission LED elements to a non-operative drive current level, which is insufficient to produce illumination. 10. The method of claim 9, wherein the delay time comprises a randomized delay time. 11. The method as recited in claim 8, wherein the multiple detection intervals are within a series of periodic intervals, and further comprising, prior to said repeating the step of bringing the respective drive current of each of the emission LED elements to a non-operative drive current level, which is insufficient to produce illumination, shifting a phase of the series of periodic intervals relative to a timing reference. 12. The method of claim 11, further comprising determining that a predetermined number of collisions has occurred, wherein: a collision comprises a determination that a magnitude of the monitored detection photocurrent varies substantially with time; andsaid shifting a phase of the series of periodic intervals is in response to a determination that the predetermined number of collisions has occurred. 13. An illumination device comprising a lamp, wherein the lamp comprises: multiple emission light emitting diode (LED) elements;one or more photodetectors; anda lamp control circuit operably coupled to the multiple emission LED elements and the one or more photodetectors, wherein the lamp control circuit is adapted to: operate one or more of the multiple emission LED elements to produce illumination substantially continuously by supplying a respective drive current at an operative drive current level to each of the one or more of the multiple emission LED elements;bring the respective drive current of each of the emission LED elements to a non-operative drive current level, which is insufficient to produce illumination, for the duration of each of multiple detection intervals interspersed with periods of said illumination;monitor a detection photocurrent induced in a detection interval photodetector of the one or more photodetectors during at least a portion of each of the multiple detection intervals;bring the respective drive current of all except a first one of the emission LED elements to a non-operative drive current level, which is insufficient to produce illumination, for the duration of a first measurement interval occurring subsequent to the multiple detection intervals and after a period of said illumination, wherein during said first measurement interval, the lamp control circuit is further adapted to: apply a first drive current at an operative drive current level, which is sufficient to produce illumination to the first one of the emission LED elements; andwhile applying the first drive current, monitor a measurement photocurrent induced in a first measurement photodetector of the one or more photodetectors. 14. The illumination device of claim 13, wherein the detection interval photodetector and the first measurement photodetector comprise the same photodetector. 15. The illumination device of claim 13, wherein the first measurement photodetector comprises an LED configured for detection. 16. The illumination device of claim 13, wherein the lamp control circuit is further adapted to determine whether a magnitude of the monitored detection photocurrent varies substantially with time. 17. The illumination device of claim 16, wherein a determination that the magnitude of the monitored detection photocurrent does not vary substantially with time indicates that the detection interval is a free detection interval, and wherein the lamp control circuit is further adapted to: determine whether a predetermined number of free detection intervals has occurred; andapply the first drive current during the first measurement interval in response to a determination that the predetermined number of free detection intervals has occurred. 18. The illumination device of claim 16, wherein, in response to a determination that the magnitude of the monitored detection photocurrent varies substantially with time, the lamp control circuit is further adapted to: again bring the respective drive current of each of the emission LED elements to a non-operative drive current level, which is insufficient to produce illumination, for the duration of each of multiple detection intervals; andagain monitor the detection photocurrent induced in the detection interval photodetector during at least a portion of each of the multiple detection intervals. 19. The illumination device of claim 18, further comprising a delay generator operably coupled to the lamp control circuit and adapted to generate a delay time, and wherein the lamp control circuit is further adapted to wait for a delay time prior to again bringing the respective drive current of each of the emission LED elements to the non-operative drive current level. 20. The illumination device of claim 19, wherein the delay generator is further adapted to generate a randomized delay time. 21. The illumination device of claim 18, further comprising a timing reference generator operatively coupled to the lamp control circuit and adapted to generate a periodic timing reference, and wherein the lamp control circuit is further adapted to: generate the multiple detection intervals within a series of periodic intervals synchronized to the timing reference; andshift a phase of the series of periodic intervals relative to the timing reference, prior to again bringing respective drive current of each of the emission LED elements to the non-operative drive current level. 22. The illumination device of claim 21, wherein a collision comprises a determination that the magnitude of the monitored detection photocurrent varies substantially with time, and wherein the lamp control circuit is further adapted to: determine whether a predetermined number of collisions has occurred; andshift the phase of the series of periodic intervals in response to a determination that the predetermined number of collisions has occurred.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (132)
Kretz, Thierry; Lebrun, Hugues; Chuiton, Elisabeth, Active matrix of an organic light-emitting diode display screen.
Dai, Ming-Ji; Liu, Chun-Kai; Chien, Heng-Chieh; Yu, Chih-Kuang; Li, Sheng-Liang, Apparatus and method for measuring characteristic and chip temperature of LED.
Bucks Marcel J. M.,NLX ; Nijhof Engbert B. G.,NLX ; Algra Johannes E.,NLX ; De Clercq John E. K. G.,NLX ; Habing Pieter W.,NLX ; Roijers Stefan E.,NLX, Circuit arrangement and signalling light provided with the circuit arrangement.
Gfeller Fritz R. (Adliswil CHX) Mueller Hans R. (Langnau CHX), Communication system in which data are transferred between terminal stations and satellite stations by infrared signals.
Cho, Jong-Whan; Park, Sang-Jin; Park, Jong-Woung; Lee, Myung-Woo; Uh, Kee-Han; Kim, Hyung-Guel; Choi, Young-Jun; Jung, Young-Bae, Image display system with light pen.
May, Dexter; Schlanger, Steven; Trotter, Matthew; Walters, Alex; Potenzone, Vincent; Cross-Szymanek, Lillian, LED light source with multiple independent control inputs and interoperability.
Borner Herbert Friedrich,DEX ; Busselt Wolfgang,DEX ; Justel Thomas,DEX ; Nikol Hans,DEX ; Ronda Cornelis R.,DEX, LED lighting system for producing white light.
Selvan,Maniam; Boay,Yoke Peng; Kang,Hooi Choo, Light source having more than three LEDs in which the color points are maintained using a three channel color sensor.
Marshall Roger N. (Solana Beach CA) Hauck Lane T. (San Diego CA) Shapiro Leonid (Lakeside CA) Busch Jeffrey W. (San Diego CA) Stevens Eric S. (El Cajon CA), Method and apparatus for calibrating an optical computer input system.
Zilan Shen ; Dennis Lee Matthies ; James H. Atherton ; Roger Green Stewart, Method and apparatus for calibrating display devices and automatically compensating for loss in their efficiency over time.
Gilliland Patrick B. ; Anguelov Evgueniy, Optoelectronic transmitter having an improved power control circuit for rapidly enabling a semiconductor laser.
Michael J. Bernstein ; Michael E. Fein ; William L. Shea ; Willem A. Crone ; Paul D. Mannheimer ; Bradford Chew ; Adnan Merchant, Oximeter sensor with encoded temperature characteristic.
Porter David R. (Roanoke VA) Bowen James H. (Salem VA) Holland John M. (Shawsville VA), Synchronous, asynchronous, data rate transparent fiber optic communications link.
Tymes LaRoy (4032 Campana Dr. Palo Alto CA 94306), System for converting a received modulated light into both power for the system and image data displayed by the system.
Chobot, Joseph Paul, Systems and methods for controlling solid state lighting devices and lighting apparatus incorporating such systems and/or methods.
Ducharme,Alfred D.; Morgan,Frederick M.; Lys,Ihor A.; Dowling,Kevin J.; Mueller,George G., Systems and methods for generating and modulating illumination conditions.
Haggerty, Joseph P.; Shah, Chinmay M.; Milbar, Marek; Stekas, James C., Systems and methods for transmitting and receiving large objects via digital radio broadcast.
Beuk Leonardus G.M.,NLX ; Kohler Hans E.P.,NLX ; Jansen Robertus C.J.,NLX ; Van Gerwen Adrianus H.,NLX, Wireless communication system for reliable communication between a group of apparatuses.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.