Patent Abstract:
A lighting system includes a remotely controllable step dimmer for controlling one or more fluorescent light fixtures with a fixed or transportable light controller with a wireless signal transmitter and at least a first control input or switch configured for manual actuation by a lighting system user. The light controller transmitter is configured to wirelessly transmit one of a plurality of uniquely encoded or modulated lighting control signals to at least a first light fixture&#39;s wireless receiver.

Full Description:
[0001]    This application claims the benefit of U.S. Provisional Application No. 61/333,699, Filed May 11, 2011, of Jeffrey M. Paul, the entire disclosure of which is incorporated herein by reference. 
     
    
     BACKGROUND OF THE INVENTION 
       [0002]    1. Field of the Invention 
         [0003]    The present invention relates to control circuits for use with illumination sources such as fluorescent light fixtures, and more particularly to a programmable radio frequency transmitter to control a three-level, step-dimming ballast circuit configured for use with a fluorescent lighting fixture including fluorescent lamps, linear bulbs or tubes. 
         [0004]    2. Discussion of the Prior Art 
         [0005]    Fluorescent lighting has, in the past, been controlled by hard wired switches, where an on-off switch controls a ballast circuit in each light fixture which, in turn, energizes and controls one or more fluorescent light tubes. This method for controlling fluorescent lighting fixtures provided only on-off options for control, however, so a need arose for a method for regulating the light output, or brightness, of a fluorescent lamp, and in particular for regulating linear fluorescent lamps. This need was initially met by the development of a three-step dimming control wherein a fluorescent lamp was provided with a ballast that emulated the well-known multi-filament incandescent lamp and its three-step switching arrangement. 
         [0006]    Switching provided two live inputs, and the ballast produced a high frequency and high voltage when both live inputs were connected, to produce a high lamp current, and a low frequency and low voltage lamp current when one of the two live inputs were connected, to produce a lower lamp current during dim level settings. Such systems have been unsatisfactory, however, for it has been difficult to achieve satisfactory preheat and ignition under low-voltage conditions. 
         [0007]    The difficulties encountered in such designs were partially overcome in the prior art by the provision of a dimming florescent ballast utilizing an integrated circuit which provided closed loop regulation of the voltages supplied to the lamp to thereby achieve optimum preheat and ignition. However, such three-step dimmer ballasts still required a hard-wired three-way switch, which limits the usability of the dimmer control. 
         [0008]    Accordingly, there is a need for an economical and easy to use remote controller for use with one or more dimmable fluorescent light fixtures. Such a controller would be particularly useful in large-scale commercial applications, but would be desirable for other applications, such as residential use, as well. 
       OBJECTS AND SUMMARY OF THE INVENTION 
       [0009]    It is, therefore, an object of the present invention to overcome the above mentioned difficulties by providing an economical, flexible and easy to install fluorescent lighting fixture control system. 
         [0010]    It is another object of the present invention to provide an economical, flexible and easy to install remote control dimmer control for fluorescent lamps. 
         [0011]    In accordance with the present invention, a simple to use lighting control system is provided for use with fluorescent lighting fixtures that are connected to a multi-level (e.g., three level) step dimming ballast circuit. Multi-level step dimming ballast circuits are well known to persons of skill in the art and are commercially available from many vendors such as General Electric, who sell, for example, the GE® LFL UltraMax™ Step Dimming Electronic Ballast #73231-GE332Max90-S60. Another example is the Sunpark Electronics Corp model U-2/32-3W-HBF step dimming ballast. 
         [0012]    As will be explained in further detail below, in accordance with the method and apparatus of the present invention, a number of different configurations are provided to serve different operational purposes to permit easy control of florescent lamps to allow users to save on the amount of energy used in lighting and to lower energy costs for the user. These control circuits and methods are well suited to help meet new statutory requirements (e.g., California&#39;s Title 24, part 6) for energy efficiency. 
         [0013]    The system of the present invention controls the light levels from a fluorescent light fixture remotely, without resort to wired control, utilizing a system with a programmable light control signal transmitter that generates radio signals that are received by a control signal receiver affixed near or included within the fluorescent light fixture and connected to operate a multi-level ballast in the fixture. 
         [0014]    In one embodiment, suitable, for example, for installations configured to control one or more lamps in individual rooms, a light control transmitter is installed in a typical wall switch box. This light control transmitter is used to sense, detect or receive a user&#39;s control input and, in response, the light control transmitter is programmed or configured to generate and transmit a radio frequency (RF) light control signal to a remote receiver configured to receive the transmitted light control signal. In response, the receiver generates a lamp control signal which might include, for example, a pair of output control signals (e.g., output signal A and output signal B) which are supplied to a three-level step dimming ballast circuit included in the light fixture, to thereby control the on/off function and the level of the light emitted from one or more fluorescent lamps in the light fixture. 
         [0015]    In summary, then, the present invention is directed to a lighting system incorporating a remotely controllable step dimmer for controlling one or more fluorescent light fixtures. The system includes at least one light fixture having a wireless receiver configured to receive and demodulate lighting control signals transmitted from a remotely located light controller and a light controller having a wireless signal transmitter and at least a first control input or switch configured for manual actuation by a lighting system user. The light controller transmitter is configured to wirelessly transmit a selectable one of a plurality of uniquely encoded or modulated lighting control signals to said at least one light fixture wireless receiver, and circuitry is provided in the wireless receiver for generating a light fixture ballast control signal in response to the demodulated lighting control signals. 
         [0016]    The first light fixture also includes a first multi-level fluorescent lamp ballast configured to sense and respond to the light fixture ballast control signal and having first and second ballast outputs. The first light fixture also has a lamp socket adapted to receive at least one fluorescent lamp having first and second contacts, whereby the first contact is connected to the first ballast output and the second contact is connected to the second ballast output. When the light controller senses a user&#39;s actuation of the control input, it transmits a light control signal selected from the plurality of uniquely encoded or modulated lighting control signals, and the first fixture receiver controls the florescent lamp in response thereto. 
         [0017]    The invention further includes a method for remotely controlling the luminous intensity generated by one or more fluorescent light fixtures, wherein at least one light fixture incorporates a wireless receiver configured to receive and demodulate lighting control signals transmitted from a remotely located light controller. The method includes providing, in the light controller, a wireless signal transmitter and at least a first control input configured for manual actuation by a lighting system user and incorporating in the transmitter circuitry for generating a plurality of uniquely encoded lighting control signals. 
         [0018]    The method further includes configuring the light controller transmitter to wirelessly transmit a selected one of the plurality of uniquely encoded lighting control signals to the wireless receiver in the light fixture, receiving and demodulating in the wireless receiver the selected wirelessly transmitted lighting control signal, generating in the receiver a light fixture ballast control signal in response to the demodulated lighting control signals, providing in the first light fixture a first multi-level fluorescent lamp ballast configured to sense and respond to the light fixture ballast control signal and having first and second ballast outputs, and providing in the first light fixture a lamp socket adapted to receive at least one fluorescent lamp having first and second contacts. 
         [0019]    When a lamp is connected in the fixture, the first lamp contact is connected to the first ballast output and the second lamp contact is connected to the second ballast output, so that when the light controller senses a user&#39;s actuation of the control input it transmits a light control signal selected from the plurality of uniquely encoded lighting control signals. The first fixture receiver then controls a florescent lamp connected in said lamp socket in response to the actuation of the lighting system controller by a user. 
         [0020]    The method and apparatus of the present invention, including a programmable wireless radio frequency transmitter to control the three level step dimming ballast circuit in the lighting fixture, provides an effective and cost efficient method to conform with energy consumption regulations or laws such as California&#39;s Title 24, part 6. 
     
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
         [0021]    The foregoing, and still further objects, features and advantages of the present invention will become apparent upon consideration of the following detailed description of a specific embodiment thereof, particularly when taken in conjunction with the accompanying drawings, wherein like reference numerals in the various figures are utilized to designate like components, wherein: 
           [0022]      FIG. 1  is a block diagram of an RF system for controlling the dimming of a florescent lamp, in accordance with the present invention; 
           [0023]      FIG. 2  is a rear elevation view of a remote control unit for the system of  FIG. 1 , suitable for installation in a conventional wall switch receptacle; 
           [0024]      FIG. 3  is a side elevation view of the unit of  FIG. 2 ; 
           [0025]      FIG. 4  is a front elevation view of the unit of  FIG. 2 ; 
           [0026]      FIG. 5  is an exploded view of the unit of  FIGS. 2-4 ; 
           [0027]      FIG. 6  is a block diagram of the control circuit for the unit of  FIGS. 2-4 ; 
           [0028]      FIG. 7  is a perspective view of a dimmer receiver module for use in the system of  FIG. 1 ; 
           [0029]      FIG. 8  is an exploded view of the receiver module of  FIG. 7 ; 
           [0030]      FIGS. 9A ,  9 B,  9 C,  10  and  11  illustrate alternative circuit diagrams for a portion of the module of  FIGS. 7 and 8 ; and 
           [0031]      FIG. 12  is a front elevation view of a control module incorporating an occupancy sensor, in accordance with the present invention. 
       
    
    
     DESCRIPTION OF PREFERRED EMBODIMENTS 
       [0032]    Turning now to a more detailed description of the present invention as illustrated in  FIGS. 1-12 , a controllable and dimmable florescent lighting fixture  10  is diagrammatically illustrated in  FIG. 1  as including a commercially available multilevel florescent lamp ballast  12 , in this embodiment a three-level ballast such as the GE® LFL UltraMax™ Step Dimming Electronic Ballast #73231-GE332Max90-S60 ballast available from General Electric, two outputs  14  and  16  of which are connected, in this case, to corresponding contacts  18  and  20 , respectively, of a three-way florescent lamp  22  by way of a conventional three-way lamp socket diagrammatically illustrated at  21 . Output voltages on either output  14  or  16 , or both, control the illumination level of the fluorescent lamp, in known manner. 
         [0033]    Although a single fluorescent lamp  22  is illustrated in  FIG. 1 , it is to be understood that the ballast may be connected to, and control, multiple lamps in a fixture  10 , and that the fixture may be a ceiling light in a commercial or residential space. In accordance with the invention, the fixture  10 , or if desired multiple such fixtures, are to be controlled through a remotely located, fixed or portable light controller  30  connected to the light fixture through a wireless link  32  that may be, for example, a 433 MHZ encoded RF signal. The controller  30  consists of a wall mounted or a portable control switch  34  connected to activate an RF transmitter  36 , which communicates with a corresponding RF receiver  38  installed in the light fixture  10 . Again, although a single lighting fixture is illustrated, it will be understood that multiple fixtures can be controlled by a single controller  30 . A transmitter/receiver pair  36 ,  38 , operates to provide several modes of operation for the fluorescent lights, not only controlling the on/off function but also energy saving modes for any fixture that receives the control signals, with the energy saving mode serving to dim the lamps in the fixtures by controlling the corresponding adjustable ballast. 
         [0034]    The RF remote control switch and transmitter  30  is, in the embodiment of the invention illustrated in  FIGS. 1-5 , a wall mountable module  40  having a front housing segment, or faceplate  42 , a back housing segment  44 , and a printed circuit board  46  enclosed between the front and back housing segments and secured by suitable fasteners. A battery (not shown) is mounted on the back segment  44  and secured in place by a cover  50  that snaps in place on the back segment  44 . The circuit board  46  carries multiple control switches, such as “high”, “medium”, “low” and “off” pushbutton switches  60 - 63 , respectively, which are activated by a user through corresponding membranes on a panel overlay  66  that is secured to the face of housing segment  42 . The switches are interconnected so that only one can be “on” at a time; pressing one pushbutton releasing all the others so that only one lighting level can be selected at a time. A red LED light  68  is designed into the faceplate to indicate when a transmission is in progress. 
         [0035]    The switches  60 - 63  carried by the module  40  are illustrated in the diagram of  FIG. 6  as being connected to corresponding inputs of a programmable RF transmitter  70  (indicated by dotted line  72  in  FIG. 5 ) which corresponds to the Transmitter  36  of  FIG. 1 . The transmitter is mounted on the circuit board  46  and is connected to a battery  74  mounted in the module through the control switches  60 - 63 , as illustrated. Each switch is connected to the RF transmitter to cause the transmitter to emit a corresponding encoded, or programmed, RF signal  32 ; for example, the RF signal may be pulse width or frequency modulated or otherwise encoded in known manner to send unique “high”, medium”, “low”, or “off” signals from the control module for reception by the corresponding receiver  38 . The transmitter&#39;s DC power is provided by a battery instead of by an AC power line to enable the module  40  to either be mounted in a wall receptacle or to be portable. The transmitter hardware operates in a low power standby mode in order to conserve battery power. Only when a button is depressed on the faceplate does the transmitter hardware wake up and transmit the function code to the receiver. After a transmission it goes back into a sleep or standby mode. 
         [0036]    The encoded RF control signals  32  are detected by the RF receiver  38  which in the illustrated embodiment is incorporated in a receiver module  80  which is mounted in the lighting fixture  10 ; this module is illustrated diagrammatically in  FIGS. 7 and 8  as including a bottom housing  82  and a top housing  84  enclosing a printed circuit board  86 . A face cover  88  may be provided on the top housing and an indicator lamp  90 , which may be a red LED, for example, may be provided to indicate reception of RF signals. An exemplary block diagram of the circuitry on module  80  is illustrated in  FIG. 1 , wherein an AC to DC power supply  100  is connected to an AC supply  102 . The power supply  100  is mounted on the circuit board  86  in module  80 , and furnishes AC power by way of line  104  to a series of AC relays  106 , also on the circuit board  86 , which in turn are activated to supply power to the three-level ballast  12  in the fixture  10  to energize the florescent lamp connected to a bulb socket  21  in the fixture  10 . 
         [0037]    The power supply  100  also supplies DC power by way of line  108  to the RF receiver  38 , which responds to the encoded RF signals  32  to decode the received signals at decoder  109 , as illustrated in the example of  FIG. 9A , and to produce control signals on output lines  110 , and or  112  to activate relays  106 . As illustrated diagrammatically in  FIG. 9A , switches  106  are selectively activated by the decoded signals on lines  110  and  112  to produce AC supply voltages on lines  116  or  118  to activate the ballast  12  with a voltage on one or the other, or both of lines  110  and  112 , as described above, to thereby illuminate the bulb to the desired level of brightness. 
         [0038]    Alternative embodiments are illustrated in the schematic diagrams of  FIGS. 9B and 9C . Comparing the alternative embodiments of  FIGS. 9B and 9C  with the embodiment of  FIG. 9A , Relays  1  and  2  are connected differently. The relays are preferably solid state devices that are activated by the output from the RF receiver/decoder.  FIGS. 9B and 9C  show both switches being activated, where two distinct signals operate two distinct relays. For the 2 and 3 fluorescent lamp or tube ballasts, the ballast connections differ. There are eight (8) ballast connections for a 3 tube fixture  122  and six (6) ballast connections for a 2 tube fixture  124 . Referring specifically to  FIG. 9B , the diagram illustrates two separate relays with a common input to both, where two separate outputs are controlled by separate signals.  FIG. 9C  illustrates two tube fixture  124  having six (6) ballast to lamp connections. 
         [0039]    It will be understood that each fluorescent light fixture will have a receiver module  80  connected between an AC power line and a single ballast or multiple ballasts. The receiver module has two AC input lines (120 or 277 VAC) which supply the AC-DC power supply and also supply AC to the ballast via the AC relays  106  which are activated in response to the two switch control signals indicated at  110  and  112  in  FIGS. 1 and 9 , produced by the receiver in response to received RF control signals. The two AC output lines  116  and  118  from the relays  106  in the module  80  control the ballast. In an example of a controller in accordance with the invention, the receiver was set to switch the ballast to a default setting of 40% (medium) whenever the AC power was initially applied to the module. Then, in order to switch the ballast to a 100% (high) or 10% (low) mode, the proper control button on the transmitter faceplate must be depressed. The LOW mode provided the lowest AC power consumption while dimming the lamp to 10% of its maximum setting. The medium mode provided a 40% AC power saving with a 40% light output, while the high mode provided 100% light output. 
         [0040]      FIGS. 10 and 11  illustrate diagrammatically at  130  and  132  the control of 2-tube and 3-tube ballasts,  134  and  136 , respectively. In the block diagram of  FIG. 10 , an RF receiver module receives AC power via line  142  and supplies that power via line  146  to a pair of controllable switches  150  and  152 . Input RF control signals are received by the RF receiver  140  by way of antenna  154 , are decoded as explained above, and are used to selectively activate switches  150  and  152 , as indicated by dotted lines  156  and  158 . Either one or both of the switches may be activated to supply AC power from line  146  through lines  160  or  162 , or both, to the ballast  134 . In the diagram of  FIG. 11 , in which similar components are similarly numbered, similar switches  150  and  152  are activatable by RF control signals to supply AC power through lines  160  and  162  to the ballast  136 . 
         [0041]    Each space to be lighted preferably will have its own wall mounted or portable transmitter, and the transmitter and receiver modules will be programmed with their own exclusive address codes. This prohibits a transmitter from activating not only its designated receiver, but receiver modules in nearby spaces. To assist in this, the transmitter should have a maximum range of about 100 feet. 
         [0042]    If desired, the system of the present invention may employ an “occupancy sensor” wall mounted control module, or unit, such as that illustrated at  170  in  FIG. 12 . In the illustrated configuration, control module or unit  170  and its RF transmitter comprises a hardwired wall mounted module that may replace a regular AC—powered on/off mechanical switch for a lighting area. Such a unit may incorporate a transmitter faceplate having three buttons, illustrated at  172 - 174  to send selected encoded RF signals to the corresponding receiver to control the ballasts. The transmitter and its corresponding receiver cannot operate until AC power is switched ‘on’ by a motion detector  176  sensing movement in the designated space. The receiver, in response to the detection of motion, switches the ballast to a default setting of 40% light intensity whenever the AC power is initially applied to the receiver module. In order to switch the ballasts to a 100% or 10% mode, the proper button on the transmitter faceplate must be depressed. The low mode provides the lowest AC power consumption while dimming the controlled lamp or lamps to 10% of the maximum setting. The high mode provides 100% light output, in an exemplary mode of operation. 
         [0043]    In operation of an example of the system of the present invention, when a selected one of the control inputs or buttons is pressed on the transmitter module  30  in  FIG. 1 , a corresponding unique RF data packet is transmitted. 
         [0044]    The RF data packet may be comprised of the following: 
         [0045]    8 Bit Sync+24 Bit Address+8 Bit Status(4)/cmd(4)+8 Bit CheckSum 
         [0046]    MSBit of each byte is sent first. Byte send order is below 
         [0047]    Sync (Bit 7  . . . Bit 0 )→SYNC 1110.0111 
         [0048]    RF Addr 0  (Bit 7  . . . Bit 0 )→ADR 0 (LSB) 
         [0049]    RE Addr 1  (Bit 7  . . . Bit 0 )→ADR 1 (MID) 
         [0050]    RF Addr 2  (Bit 7  . . . Bit 0 )→ADR 2 (MSB) 
         [0051]    Command (Bit 7  . . . Bit 0 )→CMD_BYTE (1010.0xxx) xxx are buttons 
         [0052]    Chksum (Bit 7  . . . Bit 0 )&gt;CKSUM (sum of xor 0×55 of all bytes) 
         [0000]    The RF receiver will receive the RF packet, demodulate, decode or decipher it and, as per the command bit, will turn ON two relays RLY 1  and RLY 2 , which may be the two relays in block  106 , to produce the indicated light level, as below: 
         [0000]                                                                      RLY1   RLY2   LIGHT LEVEL                                        OFF   OFF   0%    (OFF)           ON   OFF    10%    (LOW)           OFF   ON   40%    (MED)           ON   ON   100%    (HIGH)                        
For the transmitter, a 4 MHz internal oscillator may be used, for example, and for the receiver an 8 MHz internal oscillator may be used for the timing. The data packet duration in the illustration was 50 msec.
 
         [0053]    In another embodiment, the lighting system of the invention may also incorporate a daylight or ambient light sensor to sense ambient light and automatically reduce light levels in a building, when appropriate. This light sensor would be employed in a lighting control method typically used in large buildings with a significant source of outside light which can be “harvested” and put to productive use, supplementing the light generated by the light fixtures during the day. 
         [0054]    Having described preferred embodiments of a new and improved circuit, apparatus and method, it is believed that other modifications, variations and changes will be suggested to those skilled in the art in view of the teachings set forth herein. It is therefore to be understood that all such variations, modifications and changes are believed to fall within the scope of the present invention.

Technology Classification (CPC): 7