Method, apparatus, and system for occupancy sensing
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06F-017/00
G05B-011/01
G05B-011/32
G01C-017/38
G06M-011/04
F21V-023/04
출원번호
US-0289492
(2011-11-04)
등록번호
US-9014829
(2015-04-21)
발명자
/ 주소
Chemel, Brian
Piepgras, Colin N.
Morgan, Frederick
출원인 / 주소
Digital Lumens, Inc.
대리인 / 주소
Cooley LLP
인용정보
피인용 횟수 :
29인용 특허 :
319
초록▼
Embodiments of the present invention include an occupancy sensing unit configured to monitor an environment illuminated by a lighting fixture. An inventive occupancy sensing unit may include an occupancy sensor to detect radiation indicative of at least one occupancy event in the environment illumin
Embodiments of the present invention include an occupancy sensing unit configured to monitor an environment illuminated by a lighting fixture. An inventive occupancy sensing unit may include an occupancy sensor to detect radiation indicative of at least one occupancy event in the environment illuminated by the lighting fixture according to sensing parameters. The occupancy sensor can be coupled to a memory that logs sensor data, which represent the occupancy events, provided by the occupancy sensor. A processor coupled to the memory performs an analysis of the sensor data logged in the memory and adjusts the sensing parameters of the occupancy sensor based on the analysis.
대표청구항▼
1. An occupancy sensing unit to monitor an environment illuminated by a lighting fixture, the occupancy sensing unit comprising: A) at least one occupancy sensor to detect radiation indicative of at least one occupancy event, in the environment illuminated by the lighting fixture, according to sensi
1. An occupancy sensing unit to monitor an environment illuminated by a lighting fixture, the occupancy sensing unit comprising: A) at least one occupancy sensor to detect radiation indicative of at least one occupancy event, in the environment illuminated by the lighting fixture, according to sensing parameters;B) a memory, operatively coupled to the at least one occupancy sensor, to log sensor data, representing the at least one occupancy event, provided by the at least one occupancy sensor; andC) a processor, operatively coupled to the memory, to: C1) perform an analysis of the sensor data logged in the memory, the analysis comprising forming a representation of the sensor data logged in the memory based on at least one of a frequency, an amplitude, a duration, or a rate of change of the sensor data logged in the memory,C2) perform a classification of the sensor data according to the representation of the sensor data logged in the memory performed in C1),C3) store, in the memory, results of the classification performed in C2) for analysis of future sensor data from the at least one occupancy sensor, andC4) adjust at least one of a gain, a threshold, an offset, a timeout, or a sensitivity of the at least one occupancy sensor based on the results stored in the memory in C3). 2. The occupancy sensing unit of claim 1, wherein the at least one occupancy sensor provides an analog signal representative of the at least one occupancy event, and wherein the occupancy sensing unit further comprises: an analog-to-digital converter, operatively coupled to the at least one occupancy sensor, to provide a digital representation of the analog signal at one of a plurality of digital levels,wherein different levels among the plurality of digital levels represent different types of occupancy events. 3. The occupancy sensing unit of claim 1, wherein the at least one occupancy sensor comprises: two or more sensing elements to provide at least one of one or more signals indicative of a velocity or a trajectory associated with the at least one occupancy event, andwherein the sensor data represents the velocity associated with the at least one occupancy event. 4. The occupancy sensing unit of claim 3, wherein the analysis comprises determination of a frequency with which at least one of a particular velocity or a particular trajectory appears in the sensor data. 5. The occupancy sensing unit of claim 1, wherein the sensing parameters comprise the at least one of the gain, the threshold, the offset, the timeout, or the sensitivity of the at least one occupancy sensor. 6. The occupancy sensing unit of claim 1, wherein the lighting fixture remains in an active state after the at least one occupancy sensor stops sensing the radiation indicative of the at least one occupancy event for a sensor delay. 7. The occupancy sensing unit of claim 6, wherein the processor adjusts the sensor delay based on the analysis of the sensor data logged in the memory. 8. The occupancy sensing unit of claim 1, wherein the analysis performed by the processor comprises creating an n-dimensional array of the sensor data logged in the memory, wherein each dimension of the array corresponds to a parameter associated with the at least one occupancy event. 9. The occupancy sensing unit of claim 8, wherein the analysis performed by the processor further comprises partitioning the n-dimensional array into clusters corresponding to different types of occupancy events. 10. The occupancy sensing unit of claim 8, wherein the dimensions of the array comprise at least one of a frequency, amplitude, duration, rate of change, duty cycle, time of day, day of the week, month of the year, ambient light level, or ambient temperature associated with the sensor data logged in the memory. 11. The occupancy sensing unit of claim 1, wherein the analysis performed by the processor comprises determining a distribution of a frequency with which the at least one occupancy sensor detects occupancy events. 12. The occupancy sensing unit of claim 11, wherein the processor adjusts a duration of a sensor delay based on the distribution of the frequency with which the at least one occupancy sensor detects occupancy events. 13. The occupancy sensing unit of claim 1, further comprising: a communications interface to provide at least one of sensor data or a signal indicative of the at least one occupancy event to at least one of a controller of a lighting fixture, a lighting management system, or another occupancy sensing unit. 14. The occupancy sensing unit of claim 1, in combination with a light-emitting diode (LED) lighting fixture comprising: D) at least one LED to illuminate the environment; andE) a controller, operatively coupled to the at least one LED and to the occupancy sensing unit, to place the at least one LED in an active state in response to a signal indicative of the at least one occupancy event and to place the at least one LED in an inactive state after an elapse of a sensor delay. 15. The occupancy sensing unit of claim 14, wherein the controller: E1) sets the at least one LED to a first lighting level in response to a signal indicative of a first type of occupancy event, andE2) sets the at least one LED to a second lighting level in response to a signal indicative of a second type of occupancy event. 16. The occupancy sensing unit of claim 14, wherein the controller: E3) changes a light level of the at least one LED after a first elapsed time in response to a signal indicative of a first type of occupancy event, andE4) changes the light level of the at least one LED after a second elapsed time in response to a signal indicative of a second type of occupancy event. 17. A method of monitoring an environment illuminated by a lighting fixture, the method comprising: A) providing, with an occupancy sensor having sensing parameters, sensor data representative of at least one occupancy event in the environment illuminated by the lighting fixture according to sensing parameters;B) logging the sensor data in a memory;C) performing an analysis of the sensor data logged in the memory in B), the analysis comprising forming a representation of the sensor data logged in the memory based on at least one of a frequency, an amplitude, a duration, or a rate of change of the sensor data logged in the memory,D) performing a classification of the sensor data according to the representation of the sensor data logged in the memory performed in C),E) store, in the memory, results of the classification performed in D) for analysis of future sensor data from the occupancy sensor, andF) adjusting at least one of a gain, a threshold, an offset, a timeout, or a sensitivity of the occupancy sensor based on the results stored in the memory in E). 18. The method of claim 17, wherein A) further comprises: A1) providing, with the occupancy sensor, an analog signal representative of the at least one occupancy event; andA2) digitizing the analog signal at one of a plurality of digital levels to provide the sensor data, wherein different levels in the plurality of digital levels represent different types of occupancy events. 19. The method of claim 17, wherein the sensor data represents at least one of a velocity or a trajectory associated with the at least one occupancy event. 20. The method of claim 19, wherein C) comprises determining a frequency with which at least one of a particular velocity or a particular trajectory appears in the sensor data. 21. The method of claim 17, wherein C) comprises creating an n-dimensional array of the sensor data logged in the memory, wherein each dimension of the array is a parameter associated with the at least one occupancy event. 22. The method of claim 21, wherein C) further comprises partitioning the n-dimensional array into clusters corresponding to different types of occupancy events. 23. The method of claim 21, wherein the dimensions of the array comprise at least one of a frequency, amplitude, duration, rate of change, duty cycle, time of day, day of the week, month of the year, ambient light level, or ambient temperature associated with the sensor data logged in the memory. 24. The method of claim 17, wherein C) comprises determining a distribution of a frequency with which the at least one occupancy sensor detects occupancy events. 25. The method of claim 24, wherein F) comprises changing a duration of a sensor delay after detection of the at least one occupancy event based on the distribution of the frequency with which the at least one occupancy sensor detects occupancy events. 26. The method of claim 17, further comprising: changing a sensor delay after an end of the at least one occupancy event based on the analysis in C). 27. The method of claim 17, further comprising: providing at least one of the sensor data or a signal indicative of the at least one occupancy event to at least one of a controller of a lighting fixture, a lighting management system, or another occupancy sensing unit. 28. The method of claim 17, fixture comprising: changing an illumination level of the environment in response to a signal indicative of the at least one occupancy event. 29. The method of claim 28, wherein changing the illumination level of the environment comprises: setting the illumination level to a first level in response to a signal indicative of a first type of occupancy event, andsetting the illumination level to a second level in response to a signal indicative of a second type of occupancy event. 30. The method of claim 28, wherein changing the illumination level of the environment comprises: changing the illumination level after a first elapsed time in response to a signal indicative of a first type of occupancy event, andchanging the illumination level after a second elapsed time in response to a signal indicative of a second type of occupancy event. 31. A lighting system to provide variable occupancy-based illumination of an environment, the lighting system comprising: a plurality of lighting fixtures, wherein each lighting fixture in the plurality of lighting fixtures comprises:A) at least one occupancy sensor to provide a first occupancy signal representing at least one occupancy event;B) a communications interface to transmit the first occupancy signal to at least one other lighting fixture in the plurality of lighting fixtures and to receive a second occupancy signal from another lighting fixture in the plurality of lighting fixtures;C) a memory, operatively coupled to the communications interface, to store sensor data representing the first and second occupancy signals; andD) at least one light source to illuminate the environment in response to at least one of the first occupancy signal or the second occupancy signal;E) a controller, operatively coupled to the light source, the communications interface, and the memory, to: E1) place the at least one light source in an inactive state after elapse of a predetermined delay period following an end of the at least one occupancy event,E2) perform an analysis of the sensor data logged in the memory, the analysis comprising forming a representation of the sensor data logged in the memory based on at least one of a frequency, an amplitude, a duration, or a rate of change of the sensor data logged in the memory,E3) perform a classification of the sensor data according to the representation of the sensor data logged in the memory performed in E2),E4) store, in the memory, results of the classification performed in E3) for analysis of future sensor data from the at least one occupancy sensor, andE5) adjust the predetermined delay period of the at least one occupancy sensor based on the results stored in the memory in E4). 32. The lighting system of claim 31, wherein the controller controls a light level of the at least one light source based at least in part on the first and second occupancy signals. 33. The lighting system of claim 31, wherein the at least two of the plurality of lighting fixtures are configured to provide respective signals indicative of at least one of a velocity or a trajectory associated with the at least one occupancy event.
Verfuerth, Neal R.; Potts, Michael J., Apparatus and method for comparison of electric power efficiency of lighting sources to in effect be a virtual power plant.
Verfuerth, Neal R.; Potts, Michael J., Apparatus for and method of metering separate lighting circuits for comparative electric power usage to provide a virtual power plant in electric power savings.
Creutzmann Edmund (Munich DEX) Maier Manfred (Munich DEX), Electrophotographic printer comprising an exposure energy correcting means for the optical character generator.
Verfuerth,Neal R.; Potts,Michael J., Female electric connector plug apparatus for and method of attachment to flourescent tube luminaire fixture assembly.
Chemel, Brian J.; Piepgras, Colin; Kondo, Steve T.; Johnston, Scott D., LED lighting methods, apparatus, and systems including historic sensor data logging.
Chemel, Brian; Piepgras, Colin N.; Kondo, Steve T.; Johnston, Scott D., LED lighting methods, apparatus, and systems including rules-based sensor data logging.
Chemel, Brian J.; Piepgras, Colin; Kondo, Steve T.; Johnston, Scott D., LED-based lighting methods, apparatus, and systems employing LED light bars, occupancy sensing, and local state machine.
Chemel, Brian J.; Piepgras, Colin; Kondo, Steve T.; Johnston, Scott D., LED-based lighting methods, apparatus, and systems employing LED light bars, occupancy sensing, local state machine, and meter circuit.
Chemel, Brian J.; Piepgras, Colin; Kondo, Steve T.; Johnston, Scott D., LED-based lighting methods, apparatus, and systems employing LED light bars, occupancy sensing, local state machine, and time-based tracking of operational modes.
Walters, Jeff D.; Darnell, Charles J.; Gibler, Zachary S.; Henderson, David A.; Minarczyk, Michael M.; Holland, William Eric, Light management system having networked intelligent luminaire managers.
Walters, Jeff D.; Darnell, Charles J.; Gibler, Zachary S.; Henderson, David A.; Minarczyk, Michael M.; Holland, William Eric, Light management system having networked intelligent luminaire managers.
Walters, Jeff D.; Darnell, Charles J.; Gibler, Zachary S.; Henderson, David A.; Minarczyk, Michael M.; Holland, William Eric, Light management system having networked intelligent luminaire managers.
Walters, Jeff D.; Darnell, Charles J.; Gibler, Zachary S.; Henderson, David A., Light management system having networked intelligent luminaire managers that support third-party applications.
Walters, Jeff D.; Darnell, Charles J.; Gibler, Zachary S.; Henderson, David A.; Minarczyk, Michael M.; Holland, William Eric, Light management system having networked intelligent luminaire managers with enhanced diagnostics capabilities.
Howell, Donald W.; Vinson, Mark W.; Blevins, Frank O.; Tamagni, Jr., Armand J.; Campbell, Michael L., Lighting performance power monitoring system and method with optional integrated light control.
Blackwell,Michael K.; Lys,Ihor A.; Warwick,John; Morgan,Frederick M.; Mincheva,Adriana, Method and apparatus for authoring and playing back lighting sequences.
Ducharme, Alfred D.; Morgan, Frederick M.; Lys, Ihor A.; Dowling, Kevin J.; Mueller, George G., Methods and apparatus for controlling a color temperature of lighting conditions.
Morgan, Frederick M.; Lys, Ihor A.; Mueller, George G.; Dowling, Kevin J.; Holmes, Timothy; Warwick, John, Methods and apparatus for controlling illumination.
Ducharme,Alfred D.; Morgan,Frederick M.; Lys,Ihor A.; Dowling,Kevin J.; Mueller,George G., Methods and apparatus for generating and modulating illumination conditions.
Mueller, George G.; Ducharme, Alfred D.; Dowling, Kevin J.; Lys, Ihor A.; Morgan, Frederick M.; Cella, Charles H., Methods and apparatus for generating and modulating white light illumination conditions.
Mueller, George G.; Ducharme, Alfred D.; Dowling, Kevin J.; Lys, Ihor A.; Morgan, Frederick M.; Cella, Charles H., Methods and apparatus for generating and modulating white light illumination conditions.
Ducharme,Alfred D.; Morgan,Frederick M.; Lys,Ihor A.; Dowling,Kevin J.; Mueller,George G., Methods and apparatus for generating prescribed spectrums of light.
Piepgras, Colin; Mollnow, Tomas; Morgan, Frederick M.; Dowling, Kevin J., Methods and apparatus for providing lighting via a grid system of a suspended ceiling.
Morgan, Frederick M.; Lys, Ihor A.; Mueller, George G.; Dowling, Kevin J.; Holmes, Timothy; Warwick, John, Methods and apparatus for remotely controlled illumination of liquids.
Chemel, Brian J.; Piepgras, Colin; Kondo, Steve T.; Johnston, Scott D., Methods, systems, and apparatus for commissioning an LED lighting fixture with remote reporting.
Chemel, Brian J.; Piepgras, Colin; Kondo, Steve T.; Johnston, Scott D., Methods, systems, and apparatus for mapping a network of lighting fixtures with light module identification.
Verfuerth, Neal R.; Wetenkamp, Kenneth J.; Ernst, Ronald E.; Johnson, Troy M.; Heimerman, Donald C., Modular light fixture with power pack and deployable sensor.
Verfuerth, Neal R.; Bartol, Anthony J.; Wetenkamp, Kenneth J., Modular light fixture with power pack and radiative, conductive, and convective cooling.
David P. Eckel ; Selin Tansi-Glickman ; Gaetano Bonasia ; Stephen P. Hebeisen ; James A. Porter, Network based electrical control system with distributed sensing and control.
Walters, Jeff D.; Darnell, Charles J.; Gibler, Zachary S.; Henderson, David A., Network operation center for a light management system having networked intelligent luminaire managers.
Douglas D. Myron ; Vadim A. Konradi ; Bruce G. Williams ; John J. Fowler ; Timothy W. Woytek ; Jonathan D. Williams ; Gerard L. Cullen, Occupancy sensor and method of operating same.
Walters, Jeff D.; Darnell, Charles J.; Gibler, Zachary S.; Henderson, David A., Owner/operator control of a light management system using networked intelligent luminaire managers.
Crooks Cynthia A. (Houston TX) Ambrose Michael W. (Cypress TX) Mato ; Jr. Stephan A. (Katy TX) Bhagat Gopal C. (Houston TX), Pointing device for a portable computer.
Cmar Gregory (379 Namant Rd. Namant MA 01908), Process for identifying patterns of electric energy effects of proposed changes, and implementing such changes in the fa.
Ference Jonathan H. (Riegelsville PA) Lind ; III Frederick J. (Macungie PA), Programmable lighting control system with normalized dimming for different light sources.
Verfuerth, Neal R.; Potts, Michael J.; Wang, Jun, System and method for reducing peak and off-peak electricity demand by monitoring, controlling and metering high intensity fluorescent lighting in a facility.
Ducharme,Alfred D.; Morgan,Frederick M.; Lys,Ihor A.; Dowling,Kevin J.; Mueller,George G., Systems and methods for generating and modulating illumination conditions.
Dowling,Kevin J.; Morgan,Frederick M.; Lys,Ihor A.; Chemel,Brian; Blackwell,Michael K.; Warwick,John; Ducharme,Alfred D., Systems and methods of controlling light systems.
Dowling,Kevin J.; Morgan,Frederick M.; Lys,Ihor A.; Chemel,Brian; Blackwell,Michael K.; Warwick,John, Systems and methods of generating control signals.
Mueller, George G.; Lys, Ihor A.; Dowling, Kevin J.; Morgan, Frederick M.; Blackwell, Michael K.; Ducharme, Alfred D.; Osterhout, Ralph; Piepgras, Colin; Geary, Dawn; Holmes, Timothy, Wireless lighting control methods and apparatus.
Leinen, Richard A.; Hick, Robert L., Advanced networked lighting control system including improved systems and methods for automated self-grouping of lighting fixtures.
Leinen, Richard A.; Hick, Robert L., Advanced networked lighting control system including improved systems and methods for automated self-grouping of lighting fixtures.
Fadell, Anthony Michael; Rogers, Matthew Lee; Matsuoka, Yoky; Sloo, David; Honjo, Shigefumi; McGaraghan, Scott A.; Plitkins, Michael; Veron, Maxime; Guenette, Isabel, Environmental sensing with a doorbell at a smart-home.
Fadell, Anthony Michael; Rogers, Matthew Lee; Matsuoka, Yoky; Sloo, David; Honjo, Shigefumi; McGaraghan, Scott A.; Plitkins, Michael; Veron, Maxime; Guenette, Isabel, Handling visitor interaction at a smart-home in a do not disturb mode.
Fadell, Anthony Michael; Rogers, Matthew Lee; Matsuoka, Yoky; Sloo, David; Honjo, Shigefumi; McGaraghan, Scott A.; Plitkins, Michael; Veron, Maxime; Guenette, Isabel, Initially detecting a visitor at a smart-home.
Fadell, Anthony Michael; Rogers, Matthew Lee; Matsuoka, Yoky; Sloo, David; Honjo, Shigefumi; McGaraghan, Scott A.; Plitkins, Michael; Veron, Maxime; Guenette, Isabel, Interacting with a detected visitor at an entryway to a smart-home.
Fadell, Anthony Michael; Rogers, Matthew Lee; Matsuoka, Yoky; Sloo, David; Honjo, Shigefumi; McGaraghan, Scott A.; Plitkins, Michael; Veron, Maxime; Guenette, Isabel, Leveraging neighborhood to handle potential visitor at a smart-home.
Chemel, Brian J.; Piepgras, Colin; Kondo, Steve T.; Johnston, Scott D., Lighting fixtures and methods via a wireless network having a mesh network topology.
Johnston, Scott D.; Elledge, Christopher; Medal, Hugh; Morgan, Frederick M.; Egan, John F., Methods, apparatuses, and systems for operating light emitting diodes at low temperature.
Chemel, Brian; Egan, John F.; Johnston, Scott D.; Kondo, Steve T.; Kuhn, Jesse F.; Massicotte, Matthew W.; Morgan, Frederick M.; Piepgras, Colin N.; Sick, Henry B.; Elledge, Christopher L., Methods, systems, and apparatus for intelligent lighting.
Fadell, Anthony Michael; Rogers, Matthew Lee; Matsuoka, Yoky; Sloo, David; Honjo, Shigefumi; McGaraghan, Scott A.; Plitkins, Michael; Veron, Maxime; Guenette, Isabel, Occupant notification of visitor interaction with a doorbell at a smart-home.
Fadell, Anthony Michael; Rogers, Matthew Lee; Matsuoka, Yoky; Sloo, David; Honjo, Shigefumi; McGaraghan, Scott A.; Plitkins, Michael; Veron, Maxime; Guenette, Isabel, Secure handling of unsupervised package drop off at a smart-home.
Fadell, Anthony Michael; Rogers, Matthew Lee; Matsuoka, Yoky; Sloo, David; Honjo, Shigefumi; McGaraghan, Scott A.; Plitkins, Michael; Veron, Maxime; Guenette, Isabel, Visitor feedback to visitor interaction with a doorbell at a smart-home.
Fadell, Anthony Michael; Rogers, Matthew Lee; Matsuoka, Yoky; Sloo, David; Honjo, Shigefumi; McGaraghan, Scott A.; Plitkins, Michael; Veron, Maxime; Guenette, Isabel, Visitor options at an entryway to a smart-home.
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