One or more embodiments of the present invention relate to lighting systems, methods for tracking fixtures used in lighting systems, and methods for creating functional groups of fixtures in a lighting system.
Lighting systems for areal illumination typically comprise (1) a set of “luminaires” (light fixtures comprising mounting hardware and one or more light-emitting elements such as incandescent or fluorescent bulbs or arrays of light-emitting diodes [LEDs]), together with (2) one or more sensor elements (motion sensors, light sensors, and the like), (3) control devices (such as dimmers and switches), and (4) power drivers to set the output light level of each luminaire as a function of sensor outputs and control device settings. Such systems can range in complexity from a single wall switch and bulb to commercial building lighting systems comprising hundreds of luminaires, sensors, and control devices.
A common way to specify, configure, and install such systems requires the use of discrete components, where each of the above elements are purchased separately, and the control logic is implemented by the way the components are connected together using wired or wireless connections. Where convenient, certain elements can be physically grouped. For example, an outdoor security light fixture can have a motion sensor built into the fixture, or a table lamp can have an on/off switch built in. Often, however, such combinations are not used, and each element is separately purchased, installed, and wired together in order to create functional groups.
As the total number of components increases, there can be a need for more sophisticated control systems. These are typically implemented using electronic control systems, which can be implemented using either custom electronics or software running on a more general-purpose control device such as a digital computer. Such systems require a trained engineer to manually connect all devices, describe the system to the control hardware and software, and to define the control functions to be implemented.
The cost of discrete components as well as the cost of installation and programming labor have thus far inhibited wide-spread adoption of sophisticated control systems. There are, nevertheless, obvious cost savings and performance benefits that can be realized by intelligently managing the on-time and on-intensity of each light source within lighting systems. Potential saving in electricity usage can be large, and safety and security can be enhanced. Nevertheless, to be widely adopted, the components need to be inexpensive, the installation should be quick and easy, and all configuration work should be possible within the skill range of an average commercial electrician or that of building maintenance personnel.
In order to reduce installation and commissioning costs as well as the skill level required to implement these tasks, it is possible to automate some of the commissioning steps. For example, co-owned and co-pending U.S. patent application Ser. No. 12/538,806 which is incorporated herein by reference, discloses methods for auto-commissioning a lighting system by using signal sources and sensors built into each fixture to automatically determine proximity of fixtures to each other and to automatically create logical groups. However, whether or not such auto-commissioning is used, in many cases, further refinements must be manually implemented. An example of such manual commissioning is disclosed in co-owned and co-pending U.S. patent application Ser. No. 12/708,460 which is also incorporated herein by reference.
Radio Frequency Identification (RFID) is used in a variety of applications as a means of providing unique identification codes associated with a set of related items. These items may range from products in a store to pallets in a warehouse, persons in a race, pets, racehorses, farm animals, cars passing a tollbooth or entering a parking lot, etc. Typically, individual RFID “tags” are attached to each item where each tag comprises a “chip” encoding digital identification data and an antenna that can communicate wirelessly to an RFID “reader.” Most embodiments use “passive” tags, where the power necessary to receive a query and transmit identification data back to the reader is also provided via the wireless connection. Some embodiments use “active” tags which incorporate batteries to provide a higher power signal that can be read from greater distances. RFID systems have been implemented over a wide range of radio frequencies. Common embodiments exist using frequencies near 100 kHz, 10 MHz, and various UHF frequencies (100s of MHz to a few GHz). The choice of frequencies is dictated in part by available radio bands not designated for other applications and in part by the performance needs of particular applications. Each frequency band provides different performance and price characteristics.
A lighting system is disclosed wherein each fixture in the lighting system includes a permanently attached radio frequency identification (RFID) tag. Each fixture also includes either a matching hardwired identification chip or an RFID reader capable of reading the RFID tag. The tags can be used for commissioning the lighting system by reading the tags with a portable reader and assigning or removing fixtures from groups. The tags can also be used for other tasks requiring identification and tracking of specific fixtures.
Before the present invention is described in detail, it is to be understood that unless otherwise indicated this invention is not limited to specific construction materials, electronic components, or the like, as such may vary. It is also to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the scope of the present invention.
It must be noted that as used herein and in the claims, the singular forms “a,” “and” and “the” include plural referents unless the context clearly dictates otherwise. Thus, for example, reference to “a fixture” includes two or more fixtures; reference to “a sensor” includes two or more sensors, and so forth.
Where a range of values is provided, it is understood that each intervening value, to the tenth of the unit of the lower limit unless the context clearly dictates otherwise, between the upper and lower limit of that range, and any other stated or intervening value in that stated range, is encompassed within the invention. The upper and lower limits of these smaller ranges may independently be included in the smaller ranges, and are also encompassed within the invention, subject to any specifically excluded limit in the stated range. Where the stated range includes one or both of the limits, ranges excluding either or both of those included limits are also included in the invention.
Embodiments of the present invention can be used with various supersets and subsets of the exemplary components described herein. For concreteness, embodiments of the invention will be described in the context of a commercial building illumination system comprising a set of LED luminaires, but the invention is not limited to the use of LEDs as light sources nor to use in illuminating buildings.
Certain embodiments, such as those using fluorescent light sources, generally use local “ballasts” that each individually provide power control for one light source, and the central control unit provides a signal to instruct each local ballast to set a particular light level. In other embodiments such as those using LED luminaires 10, the central control unit can also function as a remote driver to provide the power for each luminaire. As used herein, a “remote driver” is “remote” in the sense that it is located at some distance from the luminaires and may provide power for a plurality of luminaires. As used herein, a “fixture” can be a luminaire, or a standalone control or sensor; a “luminaire” is a light fixture including a light source plus suitable mounting hardware and decorative trim. In particular embodiments of the present invention, luminaires can further include light sensors designed to sense light from the light sources of adjacent luminaires (either via direct transmission or via reflection from the area under illumination) and additional signal sources and matching sensors using other wavelengths of light or other signal source/sensor technologies. These sensors and additional signal sources are typically co-located with a “light adaptor” 13 which also includes a microcontroller to enable communications between a fixture and the central control unit.
In accordance with one or more embodiments of the present invention, each luminaire is co-located with at least one sensor and one signal source. The luminaire's light source (for example, a set of LEDs capable of emitting visible white light or a facsimile thereof) can serve as the signal source. As used herein, the term “light source” is to be construed narrowly to encompass sources emitting predominantly visible light unless specifically identified otherwise (as, for example, “infrared light source”). The term “radio frequency” is to be construed herein to describe electromagnetic waves from about 100 kHz to 10 GHz. Such waves do not include infrared, visible, or ultraviolet light.
In certain embodiments, additional signal sources using various technologies such as radio frequency antennas; infrared, ultraviolet, or visible light sources; or ultrasonic emitters can also be provided. Such additional signal sources can provide means for measuring a variety of quantities useful for providing input to a remote driver for a lighting system. Such quantities include motion, daylight, equipment-on status, presence of people, sound and noise, and the like. Sensors capable of receiving signals from the signal source(s) are also provided. For example, if the luminaire light source is the sole signal source provided, then an optical sensor such as a photodiode, phototransistor, or photoresistor built into the luminaire can be used as a suitable sensor. As another example, if an ultrasonic emitter is built into each luminaire or other fixture, then an ultrasonic detector can be built into each fixture to receive and detect the ultrasonic signals emitted by the emitter co-located in the same fixture as the detector as well as those co-located with other fixtures. Further, each luminaire is associated with a microcontroller which serves as a luminaire controller. The microcontroller is capable of transmitting the output of sensors to the remote driver. In certain embodiments, the microcontroller is also capable of controlling one or more of the installed signal sources, although typically it is not capable of directly controlling the power to the luminaire's main light source which is controlled instead by the remote driver. Microcontrollers can be dedicated to single luminaires or shared among two or more fixtures.
In accordance with one or more embodiments of the present invention, each fixture or luminaire is further provided with a radio frequency identification (RFID) tag 12 (see
Many luminaires' frames are constructed predominantly from sheet metal. Such structures can interfere with the reading of RFID tags in close proximity depending on the proximity spacing and operating frequency. Lower frequency tags (for example, those operating near 100 KHz), which must be detected using very short distances (less than a few centimeters) between tag and reader antenna, are less sensitive to the proximity of conducting surfaces such as sheet metal and may be preferred for that reason. Luminaires that are made predominantly from non-conductive materials such as plastics can be used with higher frequency RFID tags. This can allow the use of larger distances between tag (luminaire) and reader. At certain operating frequencies such as the 10.6 MHz tags commonly used for building access control, it can still be possible to use tags near conducting surfaces as long as the tag can be positioned a short distance away from the conducting surface via a non-conductive standoff. See Examples below for typical spacings and read distances.
One use of RFID technology with lighting systems is to implement the manual commissioning methods disclosed in co-owned and co-pending U.S. patent application Ser. No. 12/708,460. Those methods use a “pointing device” 20 that enables a user to “point” at individual fixtures for the purpose of assigning and removing fixtures from “groups” (see
It is also possible to invert the geometry, putting RFID readers into each fixture and using RFID tags as a pointing devices (item 12 in
In this geometry, the RFID tag ID code (now carried by the person performing the manual commissioning task) can be used to identify the person performing the manual commissioning, or alternatively, the person could carry several RFID tags and use a different tag for each group to which fixture assignments are to be made.
While many systems use expensive readers incorporating a lot of functionality, a basic reader need only comprise a suitable antenna and some interface circuitry to allow communication with a computing device. These can be sufficiently inexpensive to build that it is affordable to incorporate a reader into each fixture. Nevertheless, since tags are generally cheaper than readers, if there are no operational advantages to using the inverted geometry, it may be attractive from a cost point of view to put the tags in the fixtures and use a portable reader.
In accordance with one or more embodiments of the present invention, each fixture or luminaire includes an identification chip 11 (see
In accordance with one or more embodiments of the present invention, the RFID tag 12 in each fixture also provides the functionality of the identification chip, and no separate identification chip is used. In order for the system controller to be able to read the RFID tag 12 at all times once the fixture is installed and connected to the controller, each fixture in these embodiments includes a simple RFID reader with an antenna located permanently adjacent to the RFID tag 12. (This is not illustrated in
The location of RFID tags and/or receiving antennas within fixtures can vary according to the mechanical design of the fixture. The antennas are typically loops or coils that are typically large compared to the circuit board real estate required for microcontroller and sensor components. It can therefore be a preferred design choice to provide a separate antenna component or components. For assembly convenience, the antenna can be mounted into another fixture component such as a trim ring or diffuser element. LED fixtures, for example typically comprise a plurality of “point” light sources and require a diffuser to spread the light over the area to be illuminated. A flex-circuit loop antenna can be conveniently located around the edge of such a diffuser. Alternatively, the antenna(s) can be similar to the WiFi antenna in a laptop computer and integrated into the fixture.
The RFID tags in the fixtures can be used for any tasks requiring identification of particular fixtures. They can be used in the sales and distribution channels in the same ways that such tags are routinely used for such purposes: inventory control in warehousing and shipping, point-of-sale product identification, etc. Because the tags are attached to the fixtures themselves and not to external packaging (boxes, pallets, bags, and the like), the fixture identification is not lost when the fixture is removed from the packaging. Handheld or stationary readers can be used at any stage from manufacturing to post-installation and even ultimate disposal or recycling to verify the identity of the fixture and check its associated property data. For example, the lighting plot plan for a new installation typically specifies specific fixtures or at least fixture types to be installed at particular locations on a floor plan. The installer can scan each fixture with a reader to verify that it is the correct fixture or fixture type to be installed at the next location. An inspector can similarly verify that the installation conforms to the approved plan. If the RFID tag is capable of storing data in addition to a fixed identification number, then such data can be used to record relevant history such as installation date, commissioning details (group assignments, dates), usage hours, operating levels, sensor data, etc. At the end of fixture life, the RFID tag can be further used to assist in proper de-installation followed by subsequent recycling and/or disposal. For example, the tag can be scanned at any point during transfer, sorting, and ultimate disposition to ensure that each fixture is processed correctly and at the correct location for recycling and/or disposal.
Once fixtures are installed and connected to a system controller, they can be assigned to groups by a “commissioning” process. Any suitable method described in co-owned and co-pending U.S. patent application Ser. No. 12/708,460 can be used. For example, a pointing device comprising a handheld computing device such as a personal digital assistant (PDA) with an attached RFID reader antenna at the top of a pole (optionally telescoping) can be used. Any similar computing device such as a laptop computer, tablet computer, or cell phone with computing capabilities can also be used. The handheld computing device can store all commissioning information for later upload to the system controller, or it can communicate wirelessly with a wireless access point connected to the system controller. The handheld computing device can have a menu driven touch screen which allows the user to read the RFID tag in the luminaire and then associate that luminaire with a group of peripherals (luminaires, switches, sensors). It is also possible to remove the luminaire from a group to which it was previously assigned.
Prototype systems were built using RFID evaluation kits sold by Texas Instruments: the TRF7960evm kit operating at 13.56 MHz and the TMS27157 kit operating at 134.2 kHz. Systems using these evaluation kits can be configured as illustrated in
For the 134.2 kHz system, the RFID tags comprised passive transceiver chips attached to 12 mm diameter coils of magnet wire. The reader antenna was a 38 mm diameter coil of magnet wire. If the reader antenna was mounted well away from any metal surface, the tag detection range ranged from about 38-50 mm depending on the relative angular orientation of the planes of the tag coil and receiver coil (shortest range when the two coils were perpendicular, longest range when parallel). With the reader antenna coil mounted 2 mm above a metal surface, the detection range was reduced to 25-38 mm.
For the 13.56 MHz system, the RFID tags comprised passive transceiver chips attached to foil loop antennas (single loop). Various RFID tags were tested with antenna loop sizes from 25×38 mm to 50×75 mm. The reader antenna was a single loop on the microcontroller circuit board approximately 50×75 mm in size. If the reader antenna was mounted well away from any metal surface, the tag detection range ranged from about 50-90 mm depending on the size of the tag loop antenna. With the reader antenna loop mounted 2 mm above a metal surface, the detection range was reduced to about 20 mm for all tags.
It will be understood that the descriptions of one or more embodiments of the present invention do not limit the various alternative, modified and equivalent embodiments which may be included within the spirit and scope of the present invention as defined by the appended claims. Furthermore, in the detailed description above, numerous specific details are set forth to provide an understanding of various embodiments of the present invention. However, one or more embodiments of the present invention may be practiced without these specific details. In other instances, well known methods, procedures, and components have not been described in detail so as not to unnecessarily obscure aspects of the present embodiments.