Patent Application
20210041520
Aspects of the present invention generally relate to sensors of building management systems and, more particularly, systems and methods for time correction of motion sensors for building management systems.
Building management systems provide the capability of managing many building management components from a central front-end interface or group of interfaces. These building management components include building equipment for lighting, power, heating, ventilation, air conditioning, fire safety, and security. The building management systems offer operational and sustainability benefits for building developers, managers, and occupants.
Advanced building management systems may determine the quantity and location of people located in a building or a particular area of the building. For example, a lighting system of the building management system may include motion sensors positioned near ceiling light fixtures to detect proximal motion. The sensors of the lighting system may deliver timing data corresponding to the detected motion to a central server. The central server will need precise timing data in order to track people accurately.
Some motion sensors of lighting systems do not provide precise timing data. Each motion sensor may include an on-board clock but the clock of one motion sensor may be misaligned in time relative to another motion sensor of the lighting system. Existing lighting systems may address the misalignment in time of motion sensors, but they do so at the expense of added cost and/or insufficient precision. For example, the time of an on-board clock for a particular sensor may be set periodically through a broadcast message provided to the sensor or an external tool but additional components and complexity are added to the lighting system. For another example, the central server may store the time when timing data is received as well as the sensor time, but errors in transmit timing may still exist. Thus, existing lighting systems do not adequately address the problem of insufficient precision of timing data received from motions sensors.
A building management system requires accurate timing data in order to determine occupancy within a room or an area within its managed facility. Unfortunately, the time clocks of one or more of its sensors may not be accurate, thus making the determination of occupancy difficult. Thus, the building management system may perform time correlation of the raw data received for its sensors and make the appropriate time adjustments. In this manner, the building management system may adjust the sensor timing data to compensate for the sensor time errors so that all sensor data are based on the same time base before determining occupancy of its managed facility.
One aspect is a building management system for sensor time correction comprising multiple sensors, such as motion sensors, and an energy manager communicating directly or indirectly with the sensors. The sensors are distributed within a particular area in which each pair of the sensors has a distance between the pair of sensors. The sensors provide multiple time measurements in response to detecting an object traversing among the sensors in which the time measurements are associated with unsynchronized time. The energy manager identifies a predicted time for traversing among the sensors based on one or more distances between pairs of sensors and an average velocity of the object to traverse among the sensors. The energy manager determines a sensor time error for each sensor of the sensors by cross-correlating the time measurements with the predicted time.
Another aspect is a method of a building management system for sensor time correction. A predicted time for traversing among multiple sensors is identified based on one or more distances between pairs of sensors and an average velocity of an object to traverse among the sensors. The time measurements are received from the sensors in response to detecting the object traversing among the sensors in which the time measurements are associated with unsynchronized time. A sensor time error is determined for each sensor of the sensors by cross-correlating the time measurements with the predicted time.
Yet another aspect is another method a building management system for sensor time correction. A predicted time for traversing between a first sensor and a second sensors is identified based on a distance between the first and second sensors and an average velocity of an object to traverse between the first and second sensors. A first time measurement is received from the first sensor and a second time measurement is received from the second sensor in response to the object traversing between the first and second sensors. The first and second time measurements are associated with a common time period but unsynchronized time. A non-corrected time for traversing between the first sensor and the second sensor is determined based on the first and second time measurements. A sensor time error is determined based on a cross-correlation of the predicted time and the non-corrected time.
For a more complete understanding of the present disclosure, and the advantages thereof, reference is now made to the following descriptions taken in conjunction with the accompanying drawings, wherein like numbers designate like objects.
To facilitate an understanding of embodiments, principles, and features of the present invention, they are explained hereinafter with reference to implementation in illustrative embodiments. In particular, they are described in the context of a building management system for sensor time correction. Embodiments of the present invention, however, are not limited to use in the described devices or methods.
The components and materials described hereinafter as making up the various embodiments are intended to be illustrative and not restrictive. Many suitable components and materials that would perform the same or a similar function as the materials described herein are intended to be embraced within the scope of embodiments of the present invention.
A building management system may determine occupancy, such as the number of people in a room or an area, within its managed facility. The building management system utilizes precise timing data for each of its sensors in order to determine occupancy accurately throughout the managed facility. The building management system performs sensor time correction for the sensors located within its building environment or environments to address any, and preferably all, sensor time errors. The system may detect and correct errors for sensor timing data, whether the timing data is generated in real time or historically.
A sensor of the building management system senses an increase in signal level when an object, such as a person, traverses in proximity to the sensor. For some embodiments, the building management may save this sensor timing data to generate historical data. Thus, when an object traverses a set of sensors, the building management system may receive or collect the sensor timing data from the set of sensors and identify a trail corresponding to movement of the object based on the real time or historical data. When the timing of one or more of the sensors is misaligned relative to the timing of other sensors, then the misaligned time causes the corresponding sensor or sensors to operate out-of-sync and/or out-of-order. By observing the time correlation of the sensors and making the appropriate time adjustments, the building management system may determine the proper timing and order of operation of the sensors based on the non-corrected sensor timing data. For some embodiments, the building management system may determine the sensor time error based on historical data, after the sensors have detected sensor timing data for a period of time, and update the sensor time error whenever a new set of non-corrected sensor timing data is received. The building management system may identify the time error for each sensor, determine a time base from the time error, and set all sensors to the determined time base so that all sensors are on the same time base.
Referring to
In accordance with the floor plan, the building management system 100 comprises multiple sensors 132-180 in which the various pathways 124-130 of an object, such as a person, may be detected by one or more of the sensors. For the embodiment shown in
In addition to the sensors 132-180, the building management system 100 may further include an energy manager 182 that communicates directly or indirectly with the sensors. The energy manager 182 may be co-located with the sensors 132-180, located remote from the sensors and within the same facility as the sensors, or located remote from the sensors and the facility. Also, the building management system 100 may include one or more intervening devices to communicating between the energy manager 182 and the sensors 132-180. For example, one or more gateways may be co-located with a group of sensors and facilitate communication and/or control between the energy manager 182 and the group of sensors.
The building management system 100 performs sensor time correction based on object movement, such as those represented by the pathways 124-130. For example, each pathway shown in
An object, such as a person, may also travel in a non-linear manner whether aligned or offset from one or more sensors. The object may traverse in the non-linear manner to, at least in part, maneuver around any structures 112 or items 116-122 in or near a particular pathway. For some embodiments, an object may travel in a non-linear manner offset from the position of one or more sensors to avoid various workstations 116 and a cubical 118. For example, the pathway 128 may represent a non-linear pathway offset from sensors 144, 146, 148, 150 and/or 154, 156, 158, 160. The sensors 144, 146, 148, 150 and/or 154, 156, 158, 160 are positioned in proximity to the pathway 128 having a boundary or obstruction on one or more sides of the pathway. For some other embodiments, an object may traverse in a non-linear manner aligned with some sensors, but offset from other sensors, to avoid an obstacle such as an appliance 122 or to move toward a target such as a portal. For example, the pathway 130 may represent a non-linear pathway detected by sensors 132, 142, 152. The sensors 170, 172, 174, 176 are positioned in proximity to the pathway 124, 126 having a boundary or obstruction on one or more sides of the pathway. Whether aligned or offset, the object is likely to traverse in a non-linear manner if the pathway is bounded on at least one side by a boundary or obstructions, such as structure 112 or an item 116-122. For example, as illustrated by pathway 130, a person is likely to traverse the area 102 in a non-linear manner to avoid the appliance 122 or head toward the portal 112.
The building management system 100 may include an energy manager 182 to communicate directly or indirectly with the sensors and received data from the sensors. The energy manager 182 may receive data associated with objects traversing through areas 102-108 and paths 110 over a period of time and analyze the data to perform sensor time correction. The energy manager 182 may take into consideration the fact that objects, particularly people, do not necessarily walk in a straight line. Thus, an analysis of the data by the energy manager 182 may be based on a mean, median, or mode of the data, and a larger sampling of data would be preferable over a smaller sampling of data. The analysis of the data by the energy manager 182 may also be filtered, such as removing or de-emphasizing extremes from consideration. The analysis of the data by the energy manager 182 may further apply weightings to the data based on location or type. For example, a hallway may motivate people to walk in a substantially straight line so data associated with a hallway may be given more significance than data associated with a more open area.
The person 208 may walk in proximity to the sensors 202-206 in certain directions 214-218 to traverse to various locations 220-226 along the pathway. For example, the first sensor 202 may detect the person 208 traversing from a first position 220 to a second position 222 in a first direction 214. Likewise, the second sensor 204 may detect movement from the second position 222 to a third position 224 in a second direction 216, and the third sensor 206 may detect movement from the third position 224 to a fourth position 226 in a third direction 218. The sensors provide time measurements in response to detecting that an object, such as the person 208, has traversed among the sensors.
Referring to
Referring specifically to
For cross-correlation, the energy manager 182 may determine a sensor time error of one or more time measurements relative to one or more other time measurements. For example, for the time measurements shown in
For another example, in view of the time measurements shown in
The controller 408 may execute code and process data received other components of the device components 400, such as information received at the communication component 404 or stored at the memory component 410. The code associated with the building management system 100 and stored by the memory component 410 may include, but is not limited to, operating systems, applications, modules, drivers, and the like. An operating system includes executable code that controls basic functions of the energy manager 104, such as interactions among the various components of the device components 400, communi cad on with external devices via the communication component 404, and storage and retrieval of code and data to and from the memory component 410. Each application includes executable code to provide specific functionality for the controller 408 and/or remaining components of the energy manager 104. Examples of applications executable by the controller 408 include, but are not limited to, building management applications, such as an error determination application 412 to determine the sensor time error for each sensor, a prediction module 414 to determine the predicted time for traversing among the sensors, and a cross-correlation module 416 to perform cross-correlation of time measurements with predicted time. Data is information that may be referenced and/or manipulated by an operating system or application for performing functions of the energy manager 104. Examples of data associated with the building management system 100 and stored by the memory component 410 may include, but are not limited to, sensor distances 418 identifying distances between pairs of sensors, object velocity 420 identifying the average velocity of the object to traverse among the sensors, and the like.
The device components 400 of each energy manager 104 may further comprise one or more input and/or output components (I/O interfaces) 422. The I/O interfaces 422 of the device components 400 may include a variety of video, audio, and/or mechanical components. The I/O interfaces 422 of each energy manager 182 may comprise a user interface 424 for interaction with a user, such as a technician, of the energy manager. The user interface 424 may include a combination of hardware and software to provide a user with a desired user experience. For example, the user interface 424 may include one or more input components to allow the user to enter information and one or more output components to provide information to the user. Although the user interface 424 may include all input components and all output components of the I/O interface 422, the user interface may also be directed to a specific subset of input components and/or output components. The I/O interfaces 422 may further include one or more controllers 426-432 to manage sensor data received directly or indirectly from the sensors 132-180. Examples of the sensor data managed by the controller or controllers 426-432 include, but are not limited to, lighting, motion, temperature, imaging, and air quality data associated with each sensor. For some embodiments, a controller 426 of the I/O interfaces 422 may receive data originating from a motion sensor such as a passive infrared motion detection sensor.
The device components 400 may further comprise a power source 434, such as a power supply or a portable battery, for providing power to the other device components 400 of each energy manager 182 of the building management system 100.
It is to be understood that
The building management system 100, such as the energy manager 182, may identify 504 a predicted time for traversing among sensors based on at least one distance between pairs of sensors and an average velocity of an object to traverse among the sensors. The distances 418 between the pairs of sensors and the velocity 420 may be stored at the memory component 410 of an energy manager 182 communicating directly or indirectly with the first and second sensors. For example, the object may be a person, the average velocity of the object may be an average walking speed of the person, and the predicted time may be determined by dividing the distance between two given sensors by an average walking speed of a person. Each pair of sensors may be adjacent sensors or non-adjacent sensors, and the average walking speed may be dependent on the environmental conditions of the sensors. Although the energy manager 182 may identify 504 the predicted time before or during positioning 502 the sensors, the energy manager may identify the predicted time after positioning the sensors when the distances between sensors are more firmly established.
The building management system 100, such as the energy manager 182, may receive or collect 506 time measurements from the sensors in response to detecting the object traversing among the sensors. The building management system 100 may receive 506 time measurements from the sensors any time after positioning 502 the sensors regardless of when the system identifies 504 the predicted time. Accordingly, the received or collect data may be subsequently processed by the system in real time or as historical data. The time measurements are associated with unsynchronized time, thus recognizing that the timing of one or more sensors may be misaligned relative to the timing of other sensors and causing the sensors to operate out-of-sync and/or out-of-order.
After identifying 504 the predicted time period and receiving/collecting 506 the time measurements, the building management system, such as the energy manager 182, may determine a sensor time error for each sensor. For example, the system 100 may determine 508 the sensor time error by cross-correlating 510 the time measurements with the predicted time. For some embodiments, the system 100 may determine a degree to which the time measurements with the predicted time are correlated based on their respective correlated peaks. In response to determining 508 the sensor time error, the building management system 100 may establish 512 a common base clock for the sensors at the energy manager 182 based on the sensor time error.
The building management system 100, such as the energy manager 182, may store 604 the distance 418 between sensors, the velocity 420 of the object, or both at the memory component 410. The energy manager 182 may store 604 the distance before or during positioning 602 the sensors, but the energy manager may store this data after positioning the sensors when the distance is more firmly established.
After storing 604 the distance and velocity of the object, the building management system 100, such as the energy manager 182, may identify 606 a predicted time for traversing between a first sensor and a second sensors. The predicted time may be identified 606 based on a distance 418 between the first and second sensors and the velocity 420 of the object to traverse between the first and second sensors. For example, the object may be a person, the average velocity of the object may be an average walking speed of the person, and the predicted time may be determined by dividing the distance between the first and second sensors by an average walking speed of the person.
The building management system 100, such as the energy manager 182, may receive 608 a first time measurement from the first sensor and a second time measurement from the second sensor in response to the object traversing between the first and second sensors. The building management system 100 may receive 608 time measurements from the sensors any time after positioning 502 the sensors regardless of when the system stores 604 the distance and/or velocity or when the system identifies 606 the predicted time. Similar to the embodiments of
After identifying 606 the predicted time period and receiving 608 the time measurements, the building management system 100, such as the energy manager 182, may determine 610 a non-corrected time for traversing between the first sensor and the second sensor based on the first and second time measurements. The non-corrected time is based on raw data received from the sensor, such as the received signals 302-306, 352-356 shown in
Those skilled in the art will recognize that, for simplicity and clarity, the full structure and operation of all systems suitable for use with the present disclosure are not being depicted or described herein. Also, none of the various features or processes described herein should be considered essential to any or all embodiments, except as described herein. Various features may be omitted or duplicated in various embodiments. Various processes described may be omitted, repeated, performed sequentially, concurrently, or in a different order. Various features and processes described herein can be combined in still other embodiments as may be described in the claims.
It is important to note that while the disclosure includes a description in the context of fully functional systems, those skilled in the art will appreciate that at least portions of the mechanism of the present disclosure are capable of being distributed in the form of instructions contained within a machine-usable, computer-usable, or computer-readable medium in any of a variety of forms, and that the present disclosure applies equally regardless of the particular type of instruction or signal bearing medium or storage medium utilized to actually carry out the distribution. Examples of machine usable/readable or computer usable/readable mediums include: nonvolatile, hard-coded type mediums such as read only memories (ROMs) or erasable, electrically programmable read only memories (EEPROMs), and user-recordable type mediums such as floppy disks, hard disk drives and compact disk read only memories (CD-ROMs) or digital versatile disks (DVDs).
Although an example embodiment of the present disclosure has been described in detail, those skilled in the art will understand that various changes, substitutions, variations, and improvements disclosed herein may be made without departing from the spirit and scope of the disclosure in its broadest form.
