Patent Document

CROSS REFERENCES TO RELATED APPLICATIONS 
     This application is a continuation of application Ser. No. 10/810,481 filed Mar. 26, 2004, which is a continuation of application Ser. No. 09/971,367, filed on Oct. 4, 2001, now U.S. Pat. No. 6,788,011, which is a continuation of application Ser. No. 09/669,121, filed on Sep. 25, 2000, now U.S. Pat. No. 6,806,659, which is a continuation of application Ser. No. 09/425,770, filed Oct. 22, 1999, now U.S. Pat. No. 6,150,774, which is a continuation of application Ser. No. 08/920,156, filed Aug. 26, 1997, now U.S. Pat. No. 6,016,038. Each of the foregoing applications is hereby incorporated herein by reference. 
    
    
     BACKGROUND OF THE INVENTION 
     The present invention relates to providing light of a selectable color using LEDs. More particularly, the present invention is a method and apparatus for providing multicolored illumination. More particularly still, the present invention is an apparatus for providing a computer controlled multicolored illumination network capable of high performance and rapid color selection and change. 
     It is well known that combining the projected light of one color with the projected light of another color will result in the creation of a third color. It is also well known that the three most commonly used primary colors—red, blue and green—can be combined in different proportions to generate almost any color in the visible spectrum. The present invention takes advantage of these effects by combining the projected light from at least two light emitting diodes (LEDs) of different primary colors. 
     Computer lighting networks are not new. U.S. Pat. No. 5,420,482, issued to Phares, describes one such network that uses different colored LEDs to generate a selectable color. Phares is primarily for use as a display apparatus. However, the apparatus has several disadvantages and limitations. First, each of the three color LEDs in Phares is powered through a transistor biasing scheme in which the transistor base is coupled to a respective latch register through biasing resistors. The three latches are all simultaneously connected to the same data lines on the data bus. This means it is impossible in Phares to change all three LED transistor biases independently and simultaneously. Also, biasing of the transistors is inefficient because power delivered to the LEDs is smaller than that dissipated in the biasing network. This makes the device poorly suited for efficient illumination applications. The transistor biasing used by Phares also makes it difficult, if not impossible, to interchange groups of LEDs having different power ratings, and hence different intensity levels. 
     U.S. Pat. No. 4,845,481, issued to Havel, is directed to a multicolored display device. Havel addresses some, but not all of the switching problems associated with Phares. Havel uses a pulse width modulated signal to provide current to respective LEDs at a particular duty cycle. However, no provision is made for precise and rapid control over the colors emitted. As a stand alone unit, the apparatus in Havel suggests away from network lighting, and therefore lacks any teaching as to how to implement a pulse width modulated computer lighting network. Further, Havel does not appreciate the use of LEDs beyond mere displays, such as for illumination. 
     U.S. Pat. No. 5,184,114, issued to Brown, shows an LED display system. But Brown lacks any suggestion to use LEDs for illumination, or to use LEDs in a configurable computer network environment. U.S. Pat. No. 5,134,387, issued to Smith et al., directed to an LED matrix display, contains similar problems. Its rudimentary cur-rent control scheme severely limits the possible range of colors that can be displayed. 
     It is an object of the present invention to overcome the limitations of the prior art by providing a high performance computer controlled multicolored LED lighting network. 
     It is a further object of the present invention to provide a unique LED lighting network structure capable of both a linear chain of nodes and a binary tree configuration. 
     It is still another object of the present invention to provide a unique heat-dissipating housing to contain the lighting units of the lighting network. 
     It is yet another object of the present invention to provide a current regulated LED lighting apparatus, wherein the apparatus contains lighting modules each having its own maximum current rating and each conveniently interchangeable with one another. 
     It is a still further object of the present invention to provide a unique computer current-controlled LED lighting assembly for use as a general illumination device capable of emitting multiple colors in a continuously programmable 24-bit spectrum. 
     It is yet a still further object of the present invention to provide a unique flashlight, inclinometer, thermometer, general environmental indicator and light bulb, all utilizing the general computer current-control principles of the present invention. 
     Other objects of the present invention will be apparent from the detailed description below. 
     SUMMARY OF THE INVENTION 
     In brief, the invention herein comprises a pulse width modulated current control for an LED lighting assembly, where each current-controlled unit is uniquely addressable and capable of receiving illumination color information on a computer lighting network. In a further embodiment, the invention includes a binary tree network configuration of lighting units (nodes). In another embodiment, the present invention comprises a heat dissipating housing, made out of a heat-conductive material, for housing the lighting assembly. The heat dissipating housing contains two stacked circuit boards holding respectively the power module and the light module. The light module is adapted to be conveniently interchanged with other light modules having programmable current, and hence maximum light intensity ratings. Other embodiments of the present invention involve novel applications for the general principles described herein. 
    
    
     
       DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a stylized electrical circuit schematic of the light module of the present invention. 
         FIG. 2  is a stylized electrical circuit schematic of the power module of the present invention. 
         FIG. 2A  illustrates a network of addressable LED-based lighting units according to one embodiment of the invention. 
         FIGS. 2B-1  and  2 B- 2  respectively illustrate a linear chain of nodes (daisy chain configuration) and a binary tree configuration of a network according to various embodiments of the present invention. 
         FIG. 3  is an exploded view of the housing of one of the embodiments of the present invention. 
         FIG. 4  is a plan view of the LED-containing side of the light module of the present invention. 
         FIG. 5  is a plan view of the electrical connector side of the light module of the present invention. 
         FIG. 6  is a plan view of the power terminal side of the power module of the present invention. 
         FIG. 7  is a plan view of the electrical connector side of the power module of the present invention. 
         FIG. 8  is an exploded view of a flashlight assembly containing the LED lighting module of the present invention. 
         FIG. 9  is a control block diagram of the environmental indicator of the present invention. 
         FIG. 10  illustrates an LED-based light bulb according to one embodiment of the present invention. 
     
    
    
     DETAILED DESCRIPTION 
     The structure and operation of a preferred embodiment will now be described. It should be understood that many other ways of practicing the inventions herein are available, and the embodiments described herein are exemplary and not limiting. Turning to  FIG. 1 , shown is an electrical schematic representation of a light module  100  of the present invention.  FIGS. 4 and 5  show the LED-containing side and the electrical connector side of light module  100 . Light module  100  is self-contained, and is configured to be a standard item interchangeable with any similarly constructed light module. Light module  100  contains a ten-pin electrical connector  110  of the general type. In this embodiment, the connector  110  contains male pins adapted to fit into a complementary ten-pin connector female assembly, to be described below. Pin  180  is the power supply. A source of DC electrical potential enters module  100  on pin  180 . Pin  180  is electrically connected to the anode end of light emitting diode (LED) sets  120 ,  140  and  160  to establish a uniform high potential on each anode end. 
     LED set  120  contains red LEDs, set  140  contains blue and set  160  contains green, each obtainable from the Nichia America Corporation. These LEDs are primary colors, in the sense that such colors when combined in preselected proportions can generate any color in the spectrum. While three primary colors is preferred, it will be understood that the present invention will function nearly as well with only two primary colors to generate any color in the spectrum. Likewise, while the different primary colors are arranged herein on sets of uniformly colored LEDs, it will be appreciated that the same effect may be achieved with single LEDs containing multiple color-emitting semiconductor dies. LED sets  120 ,  140  and  160  each preferably contains a serial/parallel array of LEDs in the manner described by Okuno in U.S. Pat. No. 4,298,869, incorporated herein by reference. In the present embodiment, LED set  120  contains three parallel connected rows of nine red LEDs (not shown), and LED sets  140  and  160  each contain five parallel connected rows of five blue and green LEDs, respectively (not shown). It is understood by those in the art that, in general, each red LED drops the potential in the line by a lower amount than each blue or green LED, about 2.1 V, compared to 4.0 V, respectively, which accounts for the different row lengths. This is because the number of LEDs in each row is determined by the amount of voltage drop desired between the anode end at the power supply voltage and the cathode end of the last LED in the row. Also, the parallel arrangement of rows is a fail-safe measure that ensures that the light module  100  will still function even if a single LED in a row fails, thus opening the electrical circuit in that row. The cathode ends of the three parallel rows of nine red LEDs in LED set  120  are then connected in common, and go to pin  128  on connector  110 . Likewise, the cathode ends of the five parallel rows of five blue LEDs in LED set  140  are connected in common, and go to pin  148  on connector  110 . The cathode ends of the five parallel rows of five green LEDs in LED set  160  are connected in common, and go to pin  168  on connector  110 . Finally, on light module  100 , each LED set is associated with a programming resistor that combines with other components, described below, to program the maximum current through each set of LEDs. Between pin  124  and  126  is resistor  122 , 6.2 Ohms. Between pin  144  and  146  is resistor  142 , 4.7 Ohms. Between pin  164  and  166  is resistor  162 , 4.7 Ohms. Resistor  122  programs maximum current through red LED set  120 , resistor  142  programs maximum current through blue LED set  140 , and resistor  162  programs maximum current through green LED set  160 . The values these resistors should take are determined empirically, based on the desired maximum light intensity of each LED set. In the present embodiment, the resistances above program red, blue and green currents of 70, 50 and 50 A, respectively. 
     With the electrical structure of light module  100  described, attention will now be given to the electrical structure of power module  200 , shown in  FIG. 2 .  FIGS. 6 and 7  show the power terminal side and electrical connector side of an embodiment of power module  200 . Like light module  100 , power module  200  is self contained. Interconnection with male pin set  110  is achieved through complementary female pin set  210 . Pin  280  connects with pin  180  for supplying power, delivered to pin  280  from supply  300 . Supply  300  is shown as a functional block for simplicity. In actuality, supply  300  can take numerous forms for generating a DC voltage. In the present embodiment, supply  300  provides 24 Volts through a connection terminal (not shown), coupled to pin  280  through transient protection capacitors (not shown) of the general type. It will be appreciated that supply  300  may also supply a DC voltage after rectification and/or voltage transformation of an AC supply, as described more fully in U.S. Pat. No. 4,298,869. 
     Also connected to pin connector  210  are three current programming integrated circuits, ICR  220 , ICB  240  and ICG  260 . Each of these is a three terminal adjustable regulator, preferably part number LM317B, available from the National Semiconductor Corporation, Santa Clara, Calif. The teachings of the LM317 datasheet are incorporated herein by reference. Each regulator contains an input terminal, an output terminal and an adjustment terminal, labeled I, O and A, respectively. The regulators function to maintain a constant maximum current into the input terminal and out of the output terminal. This maximum current is pre-programmed by setting a resistance between the output and the adjustment terminals. This is because the regulator will cause the voltage at the input terminal to settle to whatever value is needed to cause 1.25 V to appear across the fixed current set resistor, thus causing constant current to flow. Since each functions identically, only ICR  220  will now be described. First, current enters the input terminal of ICR  220  from pin  228 . Of course, pin  228  in the power module is coupled to pin  128  in the light module, and receives current directly from the cathode end of the red LED set  120 . Since resistor  122  is ordinarily disposed between the output and adjustment terminals of ICR  220  through pins  224 / 124  and  226 / 126 , resistor  122  programs the amount of current regulated by ICR  220 . Eventually, the current output from the adjustment terminal of ICR  220  enters a Darlington driver. In this way, ICR  220  and associated resistor  122  program the maximum current through red LED set  120 . Similar results are achieved with ICB  240  and resistor  142  for blue LED set  140 , and with ICG  260  and resistor  162  for green LED set  160 . 
     The red, blue and green LED currents enter another integrated circuit, IC 1   380 , at respective nodes  324 ,  344  and  364 . IC 1   380  is preferably a high current/voltage Darlington driver, part no. DS2003 available from the National Semiconductor Corporation, Santa Clara, Calif. IC 1   380  is used as a current sink, and functions to switch current between respective LED sets and ground  390 . As described in the DS2003 datasheet, incorporated herein by reference, IC 1  contains six sets of Darlington transistors with appropriate on-board biasing resistors. As shown, nodes  324 ,  344  and  364  couple the current from the respective LED sets to three pairs of these Darlington transistors, in the well known manner to take advantage of the fact that the current rating of IC 1   380  may be doubled by using pairs of Darlington transistors to sink respective currents. Each of the three on-board Darlington pairs is used in the following manner as a switch. The base of each Darlington pair is coupled to signal inputs  424 ,  444  and  464 , respectively. Hence, input  424  is the signal input for switching current through node  324 , and thus the red LED set  120 . Input  444  is the signal input for switching current through node  344 , and thus the blue LED set  140 . Input  464  is the signal input for switching current through node  364 , and thus the green LED set  160 . Signal inputs  424 ,  444  and  464  are coupled to respective signal outputs  434 ,  454  and  474  on microcontroller IC 2   400 , as described below. In essence, when a high frequency square wave is incident on a respective signal input, IC 1   380  switches current through a respective node with the identical frequency and duty cycle. Thus, in operation, the states of signal inputs  424 ,  444  and  464  directly correlate with the opening and closing of the power circuit through respective LED sets  120 ,  140  and  160 . 
     The structure and operation of microcontroller IC 2   400  will now be described. Microcontroller IC 2   400  is preferably a MICROCHIP brand PIC16C63, although almost any properly programmed microcontroller or microprocessor can perform the software functions described herein. The main function of microcontroller IC 2   400  is to convert numerical data received on serial Rx pin  520  into three independent high frequency square waves of uniform frequency but independent duty cycles on signal output pins  434 ,  454  and  474 . The  FIG. 2  representation of microcontroller IC 2   400  is partially stylized, in that persons of skill in the art will appreciate that certain of the twenty-eight standard pins have been omitted or combined for greatest clarity. 
     Microcontroller IC 2   400  is powered through pin  450 , which is coupled to a 5 Volt source of DC power  700 . Source  700  is preferably driven from supply  300  through a coupling (not shown) that includes a voltage regulator (not shown). An exemplary voltage regulator is the LM340 3-terminal positive regulator, available from the National Semiconductor Corporation, Santa Clara, Calif. The teachings of the LM340 datasheet are hereby incorporated by reference. Those of skill in the art will appreciate that most microcontrollers, and many other independently powered digital integrated circuits, are rated for no more than a 5 Volt power source. The clock frequency of microcontroller IC 2   400  is set by crystal  480 , coupled through appropriate pins. Pin  490  is the microcontroller IC 2   400  ground reference. 
     Switch  600  is a twelve position dip switch that may be alterably and mechanically set to uniquely identify the microcontroller IC 2   400 . When individual ones of the twelve mechanical switches within dip switch  600  are closed, a path is generated from corresponding pins  650  on microcontroller IC 2   400  to ground  690 . Twelve switches create  212  possible settings, allowing any microcontroller IC 2   400  to take on one of 4096 different IDs, or addresses. In the preferred embodiment, only nine switches are actually used because the DMX-512 protocol, discussed below, is employed. 
     Once switch  600  is set, microcontroller IC 2   400  “knows” its unique address (“who am I”), and “listens” on serial line  520  for a data stream specifically addressed to it. A high speed network protocol, preferably a DMX protocol, is used to address network data to each individually addressed microcontroller IC 2   400  from a central network controller  1000 , as shown for example in  FIG. 2A . The DMX protocol is described in a United States Theatre Technology, Inc. publication entitled “DMX512/1990 Digital Data Transmission Standard for Dimmers and Controllers,” incorporated herein by reference. Basically, in the network protocol used herein, a central controller creates a stream of network data consisting of sequential data packets. Each packet first contains a header, which is checked for conformance to the standard and discarded, followed by a stream of sequential bytes representing data for sequentially addressed devices. For instance, if the data packet is intended for light number fifteen, then fourteen bytes from the data stream will be discarded, and the device will save byte number fifteen. If as in the preferred embodiment, more than one byte is needed, then the address is considered to be a starting address, and more than one byte is saved and utilized. Each byte corresponds to a decimal number 0 to 255, linearly representing the desired intensity from Off to Full. (For simplicity, details of the data packets such as headers and stop bits are omitted from this description, and will be well appreciated by those of skill in the art.) This way, each of the three LED colors is assigned a discrete intensity value between 0 and 255. These respective intensity values are stored in respective registers within the memory of microcontroller IC 2   400  (not shown). Once the central controller exhausts all data packets, it starts over in a continuous refresh cycle. The refresh cycle is defined by the standard to be a minimum of 1196 microseconds, and a maximum of 1 second. 
     Microcontroller IC 2   400  is programmed continually to “listen” for its data stream. When microcontroller IC 2   400  is “listening,” but before it detects a data packet intended for it, it is running a routine designed to create the square wave signal outputs on pins  434 ,  454  and  474 . The values in the color registers determine the duty cycle of the square wave. Since each register can take on a value from 0 to 255, these values create 256 possible different duty cycles in a linear range from 0% to 100%. Since the square wave frequency is uniform and determined by the program running in the microcontroller IC 2   400 , these different discrete duty cycles represent variations in the width of the square wave pulses. This is known as pulse width modulation (PWM). 
     The PWM interrupt routine is implemented using a simple counter, incrementing from 0 to 255 in a cycle during each period of the square wave output on pins  434 ,  454  and  474 . When the counter rolls over to zero, all three signals are set high. Once the counter equals the register value, signal output is changed to low. When microcontroller IC 2   400  receives new data, it freezes the counter, copies the new data to the working registers, compares the new register values with the current count and updates the output pins accordingly, and then restarts the counter exactly where it left off. Thus, intensity values may be updated in the middle of the PWM cycle. Freezing the counter and simultaneously updating the signal outputs has at least two advantages. First, it allows each lighting unit to quickly pulse/strobe as a strobe light does. Such strobing happens when the central controller sends network data having high intensity values alternately with network data having zero intensity values at a rapid rate. If one restarted the counter without first updating the signal outputs, then the human eye would be able to perceive the staggered deactivation of each individual color LED that is set at a different pulse width. This feature is not of concern in incandescent lights because of the integrating effect associated with the heating and cooling cycle of the illumination element. LEDs, unlike incandescent elements, activate and deactivate essentially instantaneously in the present application. The second advantage is that one can “dim” the LEDs without the flickering that would otherwise occur if the counter were reset to zero. The central controller can send a continuous dimming signal when it creates a sequence of intensity values representing a uniform and proportional decrease in light intensity for each color LED. If one did not update the output signals before restarting the counter, there is a possibility that a single color LED will go through nearly two cycles without experiencing the zero current state of its duty cycle. For instance, assume the red register is set at 4 and the counter is set at 3 when it is frozen. Here, the counter is frozen just before the “off” part of the PWM cycle is to occur for the red LEDs. Now assume that the network data changes the value in the red register from 4 to 2 and the counter is restarted without deactivating the output signal. Even though the counter is greater than the intensity value in the red register, the output state is still “on”, meaning that maximum current is still flowing through the red LEDs. Meanwhile, the blue and green LEDs will probably turn off at their appropriate times in the PWM cycle. This would be perceived by the human eye as a red flicker in the course of dimming the color intensities. Freezing the counter and updating the output for the rest of the PWM cycle overcomes these disadvantages, ensuring the flicker does not occur. 
     The network interface for microcontroller IC 2   400  will now be described. Jacks  800  and  900  are standard RJ-8 network jacks. Jack  800  is used as an input jack, and is shown for simplicity as having only three inputs: signal inputs  860 ,  870  and ground  850 . Network data enters jack  800  and passes through signal inputs  860  and  870 . These signal inputs are then coupled to IC 3   500 , which is an RS-485/RS-422 differential bus repeater of the standard type, preferably a DS96177 from the National Semiconductor Corporation, Santa Clara, Calif. The teachings of the DS96177 datasheet are hereby incorporated by reference. The signal inputs  860 ,  870  enter IC 3   500  at pins  560 ,  570 . The data signal is passed through from pin  510  to pin  520  on microcontroller IC 2   400 . The same data signal is then returned from pin  540  on IC 2   400  to pin  530  on IC 3   500 . Jack  900  is used as an output jack and is shown for simplicity as having only five outputs: signal outputs  960 ,  970 ,  980 ,  990  and ground  950 . Outputs  960  and  970  are split directly from input lines  860  and  870 , respectively. Outputs  980  and  990  come directly from IC 3   500  pins  580  and  590 , respectively. It will be appreciated that the foregoing assembly enables two network nodes to be connected for receiving the network data. Thus, a network may be constructed as a daisy chain  3000  (or linear chain of nodes), if only single nodes  2000  are strung together, as shown in  FIG. 2B-1 , or as a binary tree  4000 , if two nodes are attached to the output of each single node as shown in  FIG. 2B-2 . 
     From the foregoing description, one can see that an addressable network of LED illumination or display units  2000  as shown in  FIG. 2A  and  FIGS. 2B-1  and  2 B- 2  can be constructed from a collection of power modules each connected to a respective light module. As long as at least two primary color LEDs are used, any illumination or display color may be generated simply by preselecting the light intensity that each color emits. Further, each color LED can emit light at any of 255 different intensities, depending on the duty cycle of PWM square wave, with a full intensity pulse generated by passing maximum current through the LED. Further still, the maximum intensity can be conveniently programmed simply by adjusting the ceiling for the maximum allowable current using programming resistances for the current regulators residing on the light module. Light modules of different maximum current ratings may thereby be conveniently interchanged. 
     The foregoing embodiment may reside in any number of different housings. A preferred housing for an illumination unit is described. Turning now to  FIG. 3 , there is shown an exploded view of an illumination unit  2000  of the present invention comprising a substantially cylindrical body section  10 , a light module  20 , a conductive sleeve  30 , a power module  40 , a second conductive sleeve  50  and an enclosure plate  60 . It is to be assumed here that the light module  20  and the power module  40  contain the electrical structure and software of light module  100  and power module  200 , described above. Screws  62 ,  64 ,  66 ,  68  allow the entire apparatus to be mechanically connected. Body section  10 , conductive sleeves  30  and  50  and enclosure plate  60  are preferably made from a material that conducts heat, most preferably aluminum. Body section  10  has an open end  10 , a reflective interior portion  12  and an illumination end  13 , to which module  20  is mechanically affixed. Light module  20  is disk shaped and has two sides. The illumination side (not shown) comprises a plurality of LEDs of different primary colors. The connection side holds an electrical connector male pin assembly  22 . Both the illumination side and the connection side are coated with aluminum surfaces to better allow the conduction of heat outward from the plurality of LEDs to the body section  10 . Likewise, power module  40  is disk shaped and has every available surface covered with aluminum for the same reason. Power module  40  has a connection side holding an electrical connector female pin assembly  44  adapted to fit the pins from assembly  22 . Power module  40  has a power terminal side holding a terminal  42  for connection to a source of DC power. Any standard AC or DC jack may be used, as appropriate. 
     Interposed between light module  20  and power module  40  is a conductive aluminum sleeve  30 , which substantially encloses the space between modules  20  and  40 . As shown, a disk-shaped enclosure plate  60  and screws  62 ,  64 ,  66  and  68  sad all of the components together, and conductive sleeve  50  is thus interposed between enclosure plate  60  and power module  40 . Once sealed together as a unit, the illumination apparatus may be connected to a data network as described above and mounted in any convenient manner to illuminate an area. In operation, preferably a light diffusing means  17  will be inserted in body section  10  to ensure that the LEDs on light module  20  appear to emit a single uniform frequency of light. 
     From the foregoing, it will be appreciated that PWM current control of LEDs to produce multiple colors may be incorporated into countless environments, with or without networks. For instance,  FIG. 8  shows a hand-held flashlight can be made to shine any conceivable color using an LED assembly of the present invention. The flashlight contains an external adjustment means  5 , that may be for instance a set of three potentiometers coupled to an appropriately programmed microcontroller  92  through respective A/D conversion means  15 . Each potentiometer would control the current duty cycle, and thus the illumination intensity, of an individual color LED on LED board  25 . With three settings each capable of generating a different byte from 0 to 255, a computer-controlled flashlight may generate twenty-four bit color. Of course, three individual potentiometers can be incorporated into a single device, such as a track ball or joystick, so as to be operable as a single adjuster. Further, it is not necessary that the adjustment means must be a potentiometer. For instance, a capacitive or resistive thumb plate may also be used to program the two or three registers necessary to set the color. A lens assembly  93  may be provided for reflecting the emitted light. A non-hand held embodiment of the present invention may be used as an underwater swimming pool light. Since the present invention can operate at relatively low voltages and low current, it is uniquely suited for safe underwater operation. 
     Similarly, the present invention may be used as a general indicator of any given environmental condition.  FIG. 9  shows the general functional block diagram for such an apparatus. Shown within  FIG. 9  is also an exemplary chart showing the duty cycles of the three color LEDs during an exemplary period. As one example of an environmental indicator  96 , the power module can be coupled to an inclinometer. The inclinometer measures general angular orientation with respect to the earth&#39;s center of gravity. The inclinometer&#39;s angle signal can be converted through an A/D converter  94  and coupled to the data inputs of the microcontroller  92  in the power module. The microcontroller  92  can then be programmed to assign each discrete angular orientation a different color through the use of a lookup table associating angles with LED color register values. A current switch  90 , coupled to the microcontroller  92 , may be used to control the current supply to LEDs  120 ,  140 , and  160  of different colors. The microcontroller  92  may be coupled to a transceiver  95  for transmitting and receiving signals. The “color inclinometer” may be used for safety, such as in airplane cockpits, or for novelty, such as to illuminate the sails on a sailboat that sways in the water. Another indicator use is to provide an easily readable visual temperature indication. For example, a digital thermometer can be connected to provide the microcontroller a temperature reading. Each temperature will be associated with a particular set of register values, and hence a particular color output. A plurality of such “color thermometers” can be located over a large space, such as a storage freezer, to allow simple visual inspection of temperature over three dimensions. 
     Another use of the present invention is as a light bulb  5000 , as shown for example in  FIG. 10 . Using appropriate rectifier and voltage transformation means  97 , the entire power and light modules may be placed in an Edison-mount (screw-type  5010 ) light bulb housing. Each bulb can be programmed with particular register values to deliver a particular color bulb, including white. The current regulator can be pre-programmed to give a desired current rating and thus preset light intensity. Naturally, the light bulb will have a transparent or translucent section  5050  that allows the passage of light into the ambient. 
     While the foregoing has been a detailed description of the preferred embodiment of the invention, the claims which follow define more freely the scope of invention to which applicant is entitled. Modifications or improvements which may not come within the explicit language of the claims described in the preferred embodiments should be treated as within the scope of invention insofar as they are equivalent or otherwise consistent with the contribution over the prior art and such contribution is not to be limited to specific embodiments disclosed.

Technology Category: f