Overlapping measurement sequences for interference-resistant compensation in light emitting diode devices
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H05B-037/02
H05B-033/08
출원번호
US-0510212
(2014-10-09)
등록번호
US-9155155
(2015-10-06)
발명자
/ 주소
Ho, Horace C.
Frank, Rebecca
출원인 / 주소
Ketra, Inc.
대리인 / 주소
Daffer, Kevin L.
인용정보
피인용 횟수 :
0인용 특허 :
117
초록▼
A method and illumination device are provided for interference-resistant compensation in light emitting diode (LED) devices. In one embodiment, the method includes initiating a sequence of measurements during multiple measurement intervals interspersed with periods of illumination. The sequence of m
A method and illumination device are provided for interference-resistant compensation in light emitting diode (LED) devices. In one embodiment, the method includes initiating a sequence of measurements during multiple measurement intervals interspersed with periods of illumination. The sequence of measurements includes sensitive measurements performed during measurement intervals when a non-constant external illumination is not present, and at least one non-sensitive measurement performed during an interval when non-constant external illumination is present. An embodiment of an illumination device comprising a lamp includes multiple emission LED elements, one or more photodetectors, a storage medium adapted for storing configuration information, and a lamp control circuit. The configuration information includes ordering of sensitive and non-sensitive measurements within a sequence of compensation measurements that the lamp is configured to perform, and ordering of interfering and non-interfering measurements within an additional sequence of measurements that an additional lamp is configured to perform.
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 at a respective substantially continuous drive current sufficient to produce illumination;bringing to a level insuff
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 at a respective substantially continuous drive current sufficient to produce illumination;bringing to a level insufficient to produce illumination the respective drive current of each of the emission LED elements within the lamp for the duration of each of multiple detection intervals interspersed with periods of said operating;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;detecting, for at least one of the multiple detection intervals, that the monitored detection photocurrent varies substantially with time; andsubsequent to said detecting, initiating a sequence of measurements, wherein: the sequence comprises multiple measurements taken during multiple corresponding measurement intervals, one measurement per interval;the sequence comprises one or more sensitive measurements in which photocurrent is detected and one or more non-sensitive measurements in which photocurrent is not detected;the sensitive measurements in the sequence are performed during measurement intervals during which external illumination sufficient to induce a detection photocurrent that varies substantially with time is not incident upon the lamp; andat least one non-sensitive measurement in the sequence is performed during a measurement interval during which external illumination sufficient to induce a detection photocurrent that varies substantially with time is incident upon the lamp. 2. The method of claim 1, wherein said initiating a sequence of measurements further comprises: bringing the respective drive current of each of the LED elements within the lamp to a level insufficient to produce illumination for the duration of each measurement interval in which a non-sensitive measurement is performed; andbringing the respective drive current of each of the LED elements within the lamp, except for a single LED element subject to a photocurrent measurement, to a level insufficient to produce illumination for the duration of each measurement interval in which a sensitive measurement is performed. 3. The method of claim 1, wherein: the monitored detection photocurrent varies substantially with time in response to external illumination incident upon the lamp;the external illumination sufficient to induce within the lamp a detection photocurrent that varies substantially with time is produced by a measurement within an additional sequence of measurements performed by an additional lamp; andthe additional sequence comprises one or more interfering measurements producing illumination sufficient to induce within the lamp a detection photocurrent that varies substantially with time and one or more non-interfering measurements not producing illumination sufficient to induce within the lamp a detection photocurrent that varies substantially with time. 4. The method of claim 3, wherein said initiating a sequence of measurements comprises performing a first measurement in the sequence during an initial measurement interval, and further comprising selecting the initial measurement interval such that the sensitive measurements in the sequence are performed during measurement intervals in which external illumination sufficient to induce a detection photocurrent that varies substantially with time is not incident upon the lamp. 5. The method of claim 4, wherein said selecting the initial measurement interval comprises: determining an order of interfering and non-interfering measurements in the additional sequence of measurements; andpredicting which upcoming measurement intervals will contain interfering measurements from among the additional sequence of measurements. 6. The method of claim 5, wherein: said determining an order of interfering and non-interfering measurements comprises referencing a data structure stored within the lamp; andthe data structure stores configuration information for the additional lamp. 7. The method of claim 6, wherein said determining an order of interfering and non-interfering measurements further comprises taking into account a number of detection intervals in which the monitored detection photocurrent has varied substantially with time during a current detection sequence. 8. The method of claim 7, wherein said taking into account a number of detection intervals in which the monitored detection photocurrent has varied substantially with time comprises referencing a collision counter stored within the lamp. 9. The method of claim 7, wherein said determining an order of interfering and non-interfering measurements further comprises taking into account a number of detection intervals in which the monitored detection photocurrent has not varied substantially with time during a current detection sequence. 10. The method of claim 9, wherein said taking into account a number of detection intervals in which the monitored detection photocurrent has not varied substantially with time comprises referencing a free interval counter stored within the lamp. 11. The method of claim 9, wherein said determining an order of interfering and non-interfering measurements further comprises taking into account a number of consecutive detection intervals in which the monitored detection photocurrent has not varied substantially with time since the most recent detection interval in which the monitored detection photocurrent did vary substantially with time. 12. The method of claim 11, wherein said taking into account a number of consecutive detection intervals in which the monitored detection photocurrent has not varied substantially with time comprises referencing a contiguous free interval counter stored within the lamp. 13. The method of claim 11, wherein said determining an order of interfering and non-interfering measurements further comprises: repeating said monitoring a detection photocurrent induced in a detection interval photodetector within the lamp during at least a portion of an additional detection interval; andtaking into account any changes in the numbers of detection intervals in which the monitored detection photocurrent has or has not varied substantially with time and in the number of consecutive detection intervals in which the monitored detection photocurrent has not varied substantially with time. 14. The method of claim 4, wherein the sequence of measurements comprises a default measurement order, and further comprising altering an order of measurements in the sequence from the default measurement order to a revised measurement order prior to initiating the sequence of measurements. 15. An illumination device comprising a lamp, wherein the lamp comprises: multiple emission light emitting diode (LED) elements;one or more photodetectors;a storage medium adapted for storing a data structure containing configuration information, wherein the configuration information comprises: ordering of sensitive and non-sensitive measurements within a sequence of compensation measurements that the lamp is configured to perform; andordering of interfering and non-interfering measurements within an additional sequence of measurements that an additional lamp is configured to perform; anda lamp control circuit operably coupled to the multiple emission LED elements, the one or more photodetectors, and the storage medium, wherein the lamp control circuit is adapted to initiate the sequence of compensation measurements. 16. The illumination device of claim 15, wherein: said sensitive measurements comprise measurements in which photocurrent is detected; andsaid interfering measurements comprise measurements producing illumination. 17. The illumination device of claim 15, wherein the lamp control circuit is further adapted to, prior to initiating the sequence of compensation measurements: operate one or more of the multiple emission LED elements at a respective substantially continuous drive current to produce illumination;bring to a level insufficient to produce illumination the respective drive current of each of the emission LED elements 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 during at least a portion of each of the multiple detection intervals; anddetermine whether the monitored detection photocurrent varies substantially with time. 18. The illumination device of claim 17, wherein the storage medium further comprises: a collision counter configured to store a number of detection intervals in which the monitored detection photocurrent has varied substantially with time during a current detection sequence;a free interval counter configured to store a number of detection intervals in which the monitored detection photocurrent has not varied substantially with time during a current detection sequence; anda contiguous free interval counter configured to store a number of consecutive detection intervals in which the monitored detection photocurrent has not varied substantially with time since the most recent detection interval in which the monitored detection photocurrent did vary substantially with time. 19. 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 at a respective substantially continuous drive current to produce illumination;bring to a level insufficient to produce illumination the respective drive current of each of the emission LED elements 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 during at least a portion of each of the multiple detection intervals;determine whether the monitored detection current varies substantially with time; andin the event that the monitored detection current does vary substantially with time for at least one of the multiple detection intervals, initiate a sequence of measurements, wherein: the sequence comprises multiple measurements taken during multiple corresponding measurement intervals, one measurement per interval;the sequence comprises one or more sensitive measurements in which photocurrent is detected and one or more non-sensitive measurements in which photocurrent is not detected;the sensitive measurements in the sequence are performed during measurement intervals during which external illumination sufficient to induce a detection photocurrent that varies substantially with time is not incident upon the lamp; andat least one non-sensitive measurement in the sequence is performed during a measurement interval during which external illumination sufficient to induce a detection photocurrent that varies substantially with time is incident upon the lamp. 20. The illumination device of claim 19, wherein the lamp control circuit is further adapted to: perform a first measurement in the sequence during an initial measurement interval; andselect the initial measurement interval such that the sensitive measurements in the sequence are performed during measurement intervals in which external illumination sufficient to induce a detection photocurrent that varies substantially with time is not incident upon the lamp. 21. The illumination device of claim 20, wherein: the external illumination sufficient to induce a detection photocurrent that varies substantially with time is produced by a measurement within an additional sequence of measurements performed by an additional lamp;the additional sequence comprises one or more interfering measurements producing illumination sufficient to induce within the lamp a detection photocurrent that varies substantially with time and one or more non-interfering measurements not producing illumination sufficient to induce within the lamp a detection photocurrent that varies substantially with time; andthe lamp control circuit is further adapted to select the initial measurement interval such that the sensitive measurements in the sequence are performed during measurement intervals in which interfering measurements are not performed by the additional device. 22. The illumination device of claim 21, wherein the lamp control circuit is further adapted to: determine an order of interfering and non-interfering measurements in the additional sequence of measurements; andpredict which upcoming measurement intervals will contain interfering measurements from the additional sequence of measurements. 23. The illumination device of claim 22, further comprising a storage medium operably coupled to the lamp control circuit and configured to store a data structure containing configuration information, wherein: the configuration information comprises ordering of interfering and non-interfering measurements within the additional sequence of measurements that the additional lamp is configured to perform; andthe lamp control circuit is further adapted to reference the configuration information.
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