JP2000503125A - A retrofit lighting system that interacts non-invasively with the host machine - Google Patents

Abstract

A retrofit lighting system (100) for use with a host machine (104) is provided from the host system (104) or otherwise powers the lamps (108) of the host machine (104). To generate a lighting effect in response to the lamp output signal used to generate the lighting effect. The EL lamp system (108) has a plurality of EL lamp cells. An ordering circuit (106) independently controls each EL lamp cell of the EL lamp system (108) such that the EL lamp cells collectively illuminate in an order according to the EL lamp drive signal. Provide a drive signal. The microcontroller (406) controls the frequency, amplitude and duty ratio for the electroluminescent lamp (108). The microcontroller (406) changes the brightness and the color of the illumination by changing the frequency. The microcontroller (406) changes the illuminance by changing the amplitude. Further, the data signal lines are provided by the microcontroller (406) to select which electroluminescent lamps illuminate, thereby producing an animated display. The signal conditioning circuit (102) non-invasively samples the lamp output signal provided by the host system (104) and provides a drive signal to the EL lamp (108) accordingly.

Description

DETAILED DESCRIPTION OF THE INVENTION A retrofit lighting system that interacts non-invasively with the host machine Copyright notice   Part of the disclosure of the Patent Document is Includes materials subject to copyright protection. Copyright The owner is As evident in the Patent and Trademark Office's patent file or patent record, Object to facsimile reproduction by any person in the patent literature or patent disclosure Although not something, In other cases, Reserve all copyright rights Shall be. Technical field   The present invention For lighting systems that interact with host machines such as game consoles Things. More specifically, The present invention Preferably non-invasively, Host machine and phase Interact, Illuminate in order according to the status display sampled from the host machine It relates to a retrofit lighting system. background   Many machines, such as vending machines and game machines, According to the internal condition of the machine Illuminate one or more bulbs outside the machine. For example, Slot machine Is The "payment line" according to the number of coins inserted into the machine To illuminate, Illuminates various incandescent bulbs.   However, Incandescent light bulb Consumes a lot of power. Therefore, Incandescent light bulb It would be desirable to replace it with a Cutro Luminescent (EL) light. what By the way, EL light, Because it consumes less power. Electro ・ Luminescence (EL) lamp A special phosphor or phosphor that emits light when exposed to an electric field Is a light source containing a combination of phosphors. perhaps, More importantly, Light It would be desirable to modify it to be illuminated according to the internal conditions of the machine That's what it means. For example, The style in which the light is illuminated Pull people to the machine Attached Or it can be changed to provide useful information .   Typically, Most circuits for controlling the lighting system of the machine are: Lower It is incompatible with power supply to a light source having a high output. Furthermore, Light illuminated The circuit for controlling the manner in which Normal, Inside the machine. as a result, Modifying that lighting system It costs money. this is, The machine Is a game console, Especially expensive. Because, State Game Regulations Is After any changes have been made to those internal circuits, For game consoles Because they are required to undergo a wide range of tests and certifications.   in the past, EL lamp, Need high voltage current to operate them did. For this reason, To supply the proper power to make the lamp fire , Large power supply, Inverters and / or other electronic circuits and batteries (cords Less driving) is required. Its power supply is Normal, Than a lamp, Yoro bulk It is a stretch.   A typical EL lamp is High voltage (usually, Power supply (greater than 10V) Power supply. These power supplies often, With AC (AC) type power supply is there. The predetermined EL is Directly from standard home current (typically 120 VAC) They receive power. If it ’s a battery instead of standard home current, Normal, Step up the DC current of the battery to a higher voltage AC current and / or To convert, An inverter or other circuit will be required.   EL lamp display circuit Memory and An audio sequencer, Teru A counter for defining a segment of the EL display to be disclosed. It is possible to However, Output discs in such systems Play control Limited by limited data manipulation capabilities of memory and counters It is. Because a constant AC voltage wave generator drives the display, Its output Is Dynamic control of color and brightness is not feasible for the output display In terms of It is further restricted. Overview   The present invention Provided by the host system, Otherwise the lamp of the host machine Lighting effects depending on the lamp output signal that will be used to power the Made to be used with a host machine to spawn, Retrofit lighting System. EL lamp system It has a plurality of EL lamp cells. The sequencing circuit is EL lamp cells collectively in order according to EL lamp drive signal To illuminate Independently each EL lamp cell of EL lamp system An EL lamp driving signal to be controlled is provided. For details, The ordering circuit is: Drive Microcontroller connected to power supply circuit to supply signals That encompasses The drive signal is Electro luminescence display Signals of appropriate magnitude and frequency to drive the ray elements. The selection circuit is Receiving a plurality of signals from the microcontroller, From the power supply circuit Is also received. The selection circuit is Received from the microcontroller Based on the signal Each drive signal is sent to a separate electroluminescent display Selectively transfer to ray elements. According to this configuration, Micro-control La Blinking each display element in order, By that hand, You will generate an animated expression. The signal conditioning circuit host· Provided by the system, Provide EL lamp drive signal accordingly Like The lamp output signal will be sampled non-invasively.   The circuit is The content presented by the elements of the electroluminescence panel In addition to the quantitative load, To present a capacitive load to the drive signal generator, This A load capacitor selectively switchable by the controller. No. The load capacitor is Switch drive signal from one element to another Not only can it address the "spike" phenomenon that comes with The sequence Arising from different sized elements driven at different points in It is also possible to provide corrections for different capacitive loads. BRIEF DESCRIPTION OF THE FIGURES   FIG. A retrofit lighting system 100 according to one embodiment of the present invention FIG.   FIG. A retrofit lighting system 100 shown in FIG. 1 may be used. Shows a gaming machine.   FIG. Retrofit lighting system, According to one embodiment of the present invention, Get It shows how to interface with the game machine.   FIG. The EL lamp system 108 of the retrofit lighting system of FIG. FIG. 4 is a top level schematic diagram illustrating one embodiment of a circuit for controlling one of the above. .   FIG. FIG. 5 is a schematic diagram illustrating the drive signal generator of the schematic diagram of FIG. 4 in more detail; .   FIG. 5 is a schematic diagram showing the switching circuit of the schematic diagram of FIG. 4 in more detail.   FIG. The microcontroller (and accompanying glue logic) in the schematic of FIG. FIG. 3 is a schematic diagram showing in more detail.   FIG. Occurs when the switching circuit is switched in the first sequence. It is a graph which shows the spike phenomenon obtained.   FIG. A second switching sequence; Load control to deal with spikes It is a graph which shows adopting a densa.   FIG. High level for an EL controller according to a further embodiment of the invention FIG. 3 is a conceptual block diagram of a file.   FIG. Detailed blocks for the EL controller according to the embodiment of FIG. FIG.   12A to 12D show: Microcontroller pulse signal and EL panel And a drive signal.   FIG. Block diagram of an EL controller according to yet another embodiment of the present invention. FIG.   FIG. Detailed block diagram of the high voltage driver of the EL controller of FIG. There is a plan.   FIG. Exemplary timing sequence in the EL controller of FIG. FIG.   FIG. It is a block diagram of an EL panel multiplexing circuit.   FIG. Regarding another further embodiment of an EL panel controller device It is a block diagram. Detailed description   FIG. Retrofit electro luminescence according to one embodiment of the present invention The sense (EL) lighting system 100 is shown in block form. EL lighting system The system is Less than the incandescent bulb of the host machine that would otherwise be used Only consumes power. Alternatively, Even if incandescent bulbs are used, EL lighting system The system 100 Providing supplementary lighting effects with a minimum amount of additional power Is possible. Refitting the machine with the retrofit EL lighting system 100 According to Modifying the way the lights are illuminated according to the internal conditions of the machine is not , It is quite easy.   In one embodiment, shown in block form in FIG. The system 100 Three EL lamp panels 108a, 108b and 108c (comprehensive in the text 108 (referred to as No. 108). Each EL lamp panel 108 Independent And a plurality of EL lamp cells that can be driven. Those panels are Electronic control It is driven by the module 101. Each panel is Electronic control module 101 Of And included in the ordering circuit 106, Each separately Seq1, Driven by seq2 and seq3. example If As shown in FIG. When the game machine 104 is a slot machine, run Panel 108a, 108b and 108c are The top of the slot machine 104 Glass "152, Arranged above "Rotating part glass" 154 and "Body part glass" 156 Is appropriate to be done. The slot designated by reference numeral 158 in FIG. An additional area of the machine 104 is "Bill collector" function of slot machine 104 To attract attention to It may be provided in an EL panel.   Each lamp of the EL panel AC driving current or DC pulse current is applied to the lamp. Lights when supplied to The brightness of the lamp is The magnitude of the lamp drive current It changes according to the frequency, The color of the lamp is For example, According to the frequency of the drive current Change.   FIG. Retrofit lighting system 100, According to one embodiment of the present invention, hand, Shows how to interface to game console 104 . The electronic control module 101 Standard 120V, Connect to 60Hz AC power supply (Via a standard plug 303). Figure In 3, A single state control signal Located in the area 158 of the slot machine 104 In order to control the EL panel 108a to be Obtained from the game machine 104. More specifically, The signal generated by the game machine 104 is Game console 104 Indicates the status of the These status indication signals Preferably, Electronic control module It is sampled non-invasively by circuitry in module 101. That is, Status display The signal is Preferably, Without affecting the internal state of the game machine 104, Sun It is pulled.   For example, Provided by game console 104 to power an external incandescent bulb The output signal is It can be used as a status indication signal. The output signal is , Sampling by tapping the output signal provided for incandescent bulbs Will be performed. One specific example of this is "Coins" The output signal provided to the "insertion ramp" 302 is Sampled, Connect To be provided to the electronic control module 101 via the data 305 , This is shown in FIG. As another specific example, Original light bulb of the machine Is Can be placed in place, To determine when a light bulb is illuminated To The photo sensor is Could be adopted. The difficulty with this is that Origin Naru Is that some light bulbs may burn out. Yet another specific example hand, A coil may be provided around the wire that provides the output signal to the bulb Noh, Magnetic field induced by current in the wire measured by the coil The world It can be used as a status indication signal. In either case, Its purpose Is Non-invasive sampling of the output signal for the bulb. (Alternative In If not optimal, The status display signal is Micro console of game machine 104 It can be provided directly from a controller or other circuit. )   According to the status display signal provided from the game machine 104, Electronic control module 1 01 is One of the EL lamp panels (in this case, The EL panel shown in FIG. A panel driving signal for driving the panel 108a) is generated. In FIG. As indicated, These lamp / panel drive signals are Electronic control module 10 1 to the EL lamp panel 108a via the interconnecting cable 309 Provided. Those lamp panels Bridgeton, NJ (Br idgeton, New Jersey) from MKS.   Electro luminescence (EL) lamps EL lamp thin line, filament Like In addition to the EL panel, It will take several forms. The lighting the system, It is possible to include any of these forms of EL lamp is there. EL panel, The EL lamp strip on the surface of the backing sheet You. These EL panels are Preferably, Selective deposition of a phosphor compound; Conductive Back electrode (for example, Polymer material that contains many silver particle fillers) Formed by selective deposition. Many parts of this phosphor-electrode configuration Pa To form a turn, It can also be applied to the panel. Each part is Since they are individually connected to the power supply, They are, Which can be flashed independently, Obedience Would make the animation easier. In this example, See EL panel Is explained in reference to One or many EL lamp filaments easily It can be replaced with an EL panel.   here, A detailed example of the electronic control module 101 is as follows. Referring to FIG. 4 to FIG. Explained. FIG. Electronic control module 1 more detailed than that shown in FIG. FIG. 2 is a top level schematic diagram illustrating the example of Example 01. As shown in FIG. The electronic control module 101 In the area 158 of the slot machine 104, A According to the sequence of the animation scheme, Selective illumination of EL lamp panel cells It is to cause light. Still referring to FIG. Host machine The interface circuit 102 A status display signal from the game machine 104 (for example, White A sample of the output signal used to power the heat bulb) Sump The ringed signal appropriate for input to microcontroller 406 As (for example, By shifting the level of the sampled signal )adjust. The details of the conversion are Depends on the particular game console 104, More specifically, It will depend on the level of the sampled signal.   The adjusted status display signal is Via opto-isolator 404 or 405 Provided to the microcontroller 406. Opto isolator 404 or Is 405 Since the electronic control module 101 is insulated from the game machine 104, The internal circuit of the game machine 104 In the electronic control module 101 (for example, , The result of the shock caused by the release of static electricity from the player of the game machine 104 and And protected from being affected by possible glitches. Electronic control module If the console 101 is directly connected to the internal electronic device of the game machine 104, If Any electrostatic discharge to the electronic control module 101 is: Perhaps game Will be connected directly into the machine 104, Interrupt that process, "Hot Causing a "dump" dump.   The drive signal generator 408, powered by the power supply 410, EL de Via the driver circuit 412, Eventually, also via the pins of the connector 416, E Provide a sine drive signal for driving the L cell. Incorporated by reference above 08/591, As described in the '014 application, Micro control Roller 406 is According to the adjusted status display signal, Inside EL driver circuit 412 To selectively enable the switching circuit of The switching circuit is EL center To selectively provide a drive signal to the device. (The switching circuit is FIG. Will be described later in connection with )as a result, These EL cells are: Animation show It is illuminated in a one-off sequence. The microcontroller 406 I It is connected to the inverter 408 via the enable H signal. Enable H signal By asserting The microcontroller 406 Drive signal generator It is possible to disable the provision of the drive signal by the lator 408.   Details of the drive signal generator 408 according to one embodiment of the present invention include: In FIG. In more detail. The inverter 502 Provides sine drive signal . Capacitors C6 and C6A are: Limit the maximum output voltage from inverter 502 Provide the load capacitance.   The low voltage monitor 504 is Amplitude of sine drive signal provided from inverter 502 Monitor More specifically, When EL lamp / cell is damaged, They are, Scripture Typeically, A direct and / or partial short circuit will occur. this is, I Inverter 502 attempts to supply enough current to drive the shorted EL cell. and when, It is possible to overload it severely. Low voltage monitor 504 Is It is a voltage comparator circuit. that is, The sine output of the inverter 502 is I The DC voltage is converted into a DC voltage proportional to the output voltage of the inverter 502. EL cell shorted , The output of the inverter 502 is a resistor R11, Set by R12 and R13 Drop below The output of the low voltage comparator 504, L bolt H Will be asserted. The output of L volt H is Light to microcontroller 406 Logically linked. The microcontroller 406 Monitor L volt H signal do it, Upon detecting that the L volt H signal has been asserted, Inverter 502 It is programmed to prohibit use. this is, Via inverter 502 Excessive current that will be drawn can cause permanent damage to inverter 502 To prevent giving.   Zero crossing detector 506 The drive signal provided from the inverter 502 is It can be provided to detect when it crosses the pressure amplitude. Ze When a crossing is detected, Zero crossing detector 506 Micro controller 40 Provides a zero XE control signal for the six RB1 inputs (FIG. 4). The micro ・ The controller is By switching the switching circuit in the EL driver circuit 412, Inn Only when the drive signal provided from barter 408 has a voltage amplitude of almost zero , Start providing drive signals via connector 416. Like this If EL cells are Protected from rapidly increasing drive signal inputs (ie spikes) It is possible to Causing potentially annoying visual "flashes" In addition to, Such drive signal spikes Breakage of capacitance in EL cell Cause breakage, This may render the EL cell inoperable.   here, Some of the detailed embodiments of the EL driver circuit 412 include: Theory related to FIG. Will be revealed. For details, EL drive generated by drive signal generator 408 The signal is Provided for AC hot input of EL driver circuit 412. plural Each of the switching circuits 602a to 602i Switching control input (RC0 to R C7 and RB7, respectively); Drive signal output (DRC0 to DRC7 and DRC7) B7). Furthermore, Each of the switching circuits 602a to 602i Is To receive the EL drive signal generated by drive signal generator 408 , It is also connected so as to receive an AC hot input. From 602a The switching circuit of 602i is Four rectifier diodes, One double pole junction transistor And   Depending on the program executed by the microcontroller, The microphone B Controller Each switching control input R of each switching circuit 602a to 602i Connected from C0 to RC7 and RB7, The switching control input RC0 to R Assert various of C7 and RB7. Accordingly, Specific switching When the circuit switching control input is asserted, The switching circuit is AC drive signal Pass from hot to the output of the switching circuit. Referring back to FIG. Switching times Each of the roads 602a through 602i Via connector 4016, game machine "Bill collector" EL panel (FIG. 2) EL cell located in region 158 of 104 Will be understood to be connected to independent ones.   Still referring to FIG. here, Auxiliary switching circuits 604a and 604 b will be explained. These auxiliary switching circuits 604a and 604b Microphone B. From the switching control outputs RB5 and RB6 of the controller 406, Each supplement The respective switching control inputs RB5 and RB5 of the auxiliary switching circuits 604a and 604b Responds to a switch signal provided to RB6. For details, Auxiliary switching times Roads 604a and 604b Drive signal from AC hot Switching control input RB 5 and RB6 are each asserted to a respective auxiliary switching circuit 6 The outputs DRB5 and DRB6 of the outputs 04a and 604b are passed. The drive signal is Via their outputs DRB6 and DRB7, Load condensate C7 and C7A, Or reach the load capacitors C8 and C8A respectively. Will be.   here, Load capacitors C7 and C7A, Or load capacitors C8 and C8 The reason for providing a drive signal to A is explained. Drive signal generator 408 inverter 502 (FIG. 5) Load dependent, And self-correcting There is also. (In a preferred embodiment, The inverter 502 Provided by NEC "NS" series inverters. ) The inverter 502 Inn The frequency of the sine drive signal provided by the barter 502 can be any value in the lighting sequence. Configuration as determined by the capacitance of the load being driven at a particular point did, It encompasses the circuit (nominally, The load of the EL cell is Provide drive signal Through a particular one of the switching circuits of the EL driver circuit 412 selected to provide Driven by the Furthermore, The capacitance of the EL cell is EL cells age It changes as you do. The inverter 502 Detect the change in the capacitance, So Even if the capacitance of the EL cell changes, the EL cell is illuminated with a relatively constant brightness, The frequency of the generated drive signal is adjusted.   The capacitance load of the EL cell is It is mainly determined by its dimensions, Alone A plurality of EL cells driven in a certain sequence by the inverter 502 If the dimensions are Frequency of the sine drive signal provided by inverter 408 The number is The dimensions of the driven EL cell (or a combination thereof) (and thus also the capacitance) Will fluctuate accordingly. as a result, Proposed by different combinations of EL cells If no adjustment is made for the different loads shown, Each EL The brightness at which the cell is illuminated It will fluctuate greatly compared to each other. This phenomenon is Not visually appealing.   However, For the capacitive load experienced by inverter 502, negative Load capacitors C7 and C7A, Alternatively, add load capacitors C8 and C8A By The inverter 502 Substantially throughout the lighting sequence You experience a constant capacitive load. Maintaining a substantially constant capacitive load And by The frequency of the sine drive signal provided by inverter 502 is Real It can be kept qualitatively constant. as a result, The EL cell is The brightness illuminated during the Maintained at each point in the lighting sequence Will be. this is, Inverter 502 Each specific E due to aging By "detecting" the change in capacitance for the L cell, Allow to correct it It is.   Number of auxiliary switching circuits and load capacitors, The capacitance value of the load capacitor, as well as, Required to equalize the capacitive load on inverter 502 The configuration of the load capacitor is For variations in the dimensions of the driven EL cell and variations in brightness And the desired percent tolerance. Experienced by inverter 408 Switch auxiliary switching circuit to include load capacitor in load The sequence Can be predetermined, Micro controller 4 06 can also be included in the ordering program executed by . That is, A switching circuit in the EL driver circuit 412 is controlled to illuminate the EL cell. In addition to controlling, The microcontroller 406 Which EL cell is Various (or combinations) of load capacitors as a function of In order to selectively load the inverter 502, Control the auxiliary switching circuit Yo It is also possible to be pre-programmed in this way.   In the embodiment shown in FIG. Capacitors C8 and C8A are: In addition, 0. 01μ F, and the capacitors C7 and C7A together have 0 effective capacitance. . It has an effective capacitance of 022 μF. Therefore, as shown below Achieved by selectively enabling DRVR # A and DRVR # B There are four variations of load capacitance that can be done :DRVR♯A DRVR♯B Total "additional" load Use prohibited Use prohibited 0.0μF Usable Use prohibited 0.01μF Use prohibited Use possible 0.022μF Usable Usable 0.032μF   The actual values for the load capacitors and their shapes are qualitatively (ie, various To experiment numerically and qualitatively examine the resulting lighting sequence Therefore) can be determined. However, preferably, the lighting sequence The surface area of the EL cell driven during the sensing is quantitatively correlated to the equivalent capacitance. It is possible to be. A memory (eg, a read-only memory) is provided It is also possible. Tables in memory have a lighting sequence where each table entry is Any load during the corresponding step of the sequence Multiple table entries showing whether to switch on the capacitor Is included.   FIG. 7 illustrates an embodiment of the microcontroller 406 and its associated glue logic. Is schematically shown.   FIG. 8 shows that the microcontroller 406 uses the second EL cell (in FIG. A short time (number) before switching on the switching circuit corresponding to In the first EL cell (even in a case as short as microsecond) (in FIG. 8, A switching circuit (ie, 602a to 602i) corresponding to "cell # 1" Is turned off, and the inverter 502 generates If the resulting sine drive signal is at the peak, the drive signal will be applied to the capacitive load. Spikes (up to 400V or more) due to sudden decrease in And potential damage to either or both inverter 502 and EL cell # 2 This shows the phenomenon of causing scratches.   FIG. 9 shows that even when the zero-crossing detector 506 is not used, How spikes can be avoided. First, cell # The switching circuit corresponding to cell 2 is turned off by the switching circuit corresponding to cell # 1. Before being turned on. Turn on the switching circuit corresponding to cell # 2 One switch corresponding to one load capacitor (or each capacitor) before switching The switching circuit (or each circuit) is turned on. It corresponds to cell # 2 The switching circuit is subsequently switched on (for example, a switch corresponding to the load capacitor). Spike occurs when 0 to 5 μs after the switching circuit is switched on) Large capacitive loads are placed on inverter 502 in such a way that It is. Finally, sufficient time for the load on inverter 502 to stabilize (eg, After about 100 μs), cell # 1 is switched off. Become.   Appendix A is executed by the microcontroller 406 to execute the sequence. Here is a source listing of assembly language code that can be executed.   In a well-integrated drive circuit, the microcontroller must turn off each lamp. It is possible to control not only the switching of the lamp but also the lamp brightness and lamp color. is there. The microcontroller 406 can be any kind of one-dimensional, two-dimensional and three-dimensional Used to generate animated displays on 3D luminous objects It is also possible that Examples of such objects are cloth, works of art, molded parts, And an information display. For example, on fabric, electro-luminescence Thin lines for animated logos, designs, or other accents Could be used for   A conceptual block diagram of a further embodiment of the EL panel controller device is shown in FIG. 0 is shown. In this embodiment, the microcontroller 1100 includes multiple Of the EL lamp 1102, and the switching sequence. EL Dora The EVA 1106 receives the control of the microcontroller 1100 and AC current is supplied to The plurality of solid state switches 1104 The EL driver 1106 is connected to the EL panel 1102. Labeled from 1 to n Input / output pin 1110 of the switched microcontroller 1100 is a switching circuit. A control signal for the control line 1104 is output. The switching circuit 1104 is an EL driver. The circuit of electric energy flowing through the driver 1106 and the EL panel 1102 Control.   Control line 1108 is optional. Control, if mounted Line 1108 connects microcontroller 1100 to EL driver 1106 I do. Through the control line 1108, the microcontroller 1100 operates as an EL driver. The frequency and magnitude of the current output by the inverter 1106 are controlled. Do The frequency, duty ratio, and intensity of the output of driver 1106 are The color and brightness of the loop 1102 will be determined.   A more detailed block diagram of the EL panel controller of FIG. 10 is shown in FIG. Have been.   Microcontroller 1100 preferably has low cost and few peripherals. And the total number of container components. Microchip (MICROCHIP) A commercially available myc such as PTC16C55 or PIC16C57 from The black controller is used as the microcontroller 1100 Is possible. However, any suitable microcontroller or microphone A microprocessor may be used instead.   Voltage regulator 1202 connects battery to microcontroller 1100 To power the microcontroller 1100 with the voltage from the battery. Adjust to the level needed for In this specific example, the adjuster 1202 A 5.0 volt DC voltage is supplied to the black controller 1100.   Ceramic resonator or crystal (XTAL), resistor and / or capacitor Such a timing circuit 1204 provides a tie to the microcontroller 1100. Connected to provide a video signal. Inside the microcontroller 1100 A variation of this embodiment that includes a built-in timer requires a timing circuit. It is also possible not to do it.   Push buttons 1206 are for on / off, pattern selection, color, and output timing Allows user to control microcontroller functions such as adjusting Connected to the microcontroller.   The EL driver circuit 1106 includes an oscillator (or function generator) 1208, It comprises a power amplifier 1210 and a transformer 1212. The transformer 1212 The oscillator 1208 and the power amplifier 1210 are connected to the EL driver circuit 1106 (FIG. 10). Connect to output. Power amplifier 1210 receives the output of oscillator 1208. This Signal is then amplified by power amplifier 1210 and Drive the next winding. The oscillator 1208 may have a sinusoidal, square, or sawtooth waveform, for example. It is possible to supply Typical drive signal transmitted from transformer 1212 Is, for example, a sine signal with a frequency of 1000 Hz and an amplitude of 35 volts. It is possible to   The format and frequency of the waveform output from oscillator 1208 are mapped via control line 1214. It can be controlled by the microcontroller 1100. Likewise Therefore, the amplification of the power gain 1210 is also performed by the microcontroller via the control line 1216. It can be controlled by the roller 1100.   Changing the frequency of the drive signal for the EL lamp will affect its color and brightness. Affect. Color change from yellow-green or dark green to blue or purple color is driven It can also be implemented by simply changing the frequency and duty ratio of the signal . This corresponds to a shift of approximately 150 nm in the visible light spectrum.   Changing the amplitude of the drive signal affects its brightness. Perceived brightness The degree is adjusted by adjusting the duty ratio of the switching signal (described later). It is also possible that it is changed.   Switching circuit connected to and controlled by input / output pin 1110 The road 1104 connects their respective EL panels 1102 to an EL driver 1106 Connect to The switching circuit 1104 includes a high-voltage transistor 12 18 is included. The base of each transistor 1218 is a microcontroller. Connected to a resistor 1220 connected to the mirror 1100. Each transition The emitter of the star 1218 is connected to ground and the The collector of 18 is connected to a diode bridge 1222. Each The EL panel 1102 includes one of the diode bridges 1222 and the transformer 1212. Are connected between one ends of the secondary windings.   The switching circuit 1104 is operated by an input / output pin of the microcontroller 1100. Duplicated for each EL panel controlled. The number of circuits 1104 is However, not all output pins must be used, Depending on the number of output pins available on the black controller 1100 Be restricted.   In operation, the embodiment of FIGS. 10 and 11 functions as follows.   The microcontroller 1100 includes a switching circuit via an input / output pin 1110. 1104 is controlled. The high output ("1") at any of the inputs and outputs 1110 is The EL drive current flows through the corresponding EL panel 1102 of the switch. To allow the lamp to illuminate and close the switching circuit. I / O pin Low output ("0") at any of the switches 1110 To prevent the EL drive current from flowing through the EL panel 1102 Is turned off, and the switching circuit is opened. See Figure 11 for details Then, the high output ("1") causes the current to flow through the resistor 1220. Which will turn on transistor 1218. this is, G Transistor 1218, diode bridge rectifier 1222, and EL panel 1 Allow current to flow through 102, thereby illuminating the EL panel Because Similarly, low output ("0") turns off the EL panel become.   If the control line 108 is implemented, the microcontroller 1100 The frequency and amplitude of the driving voltage output are controlled by the L driver circuit 1106. this In this way, the microcontroller 1100 can control the EL panel output display. The color and the brightness of the image are controlled.   The push button 1206 that can be used is a microcontroller On / off, pattern selection, and timing. For example, if the button is 1 Pressing twice will switch the controller on for a predetermined time period. And then the controller executes the sleep instruction, essentially It is possible to switch itself off. The sequence ends Pressing the push button 1206 twice before will display a continuous display. Command A. Pressing push button 1206 three times stops the display Reset the controller to standby mode. Indicator light It can be used to flush the current state of the Troller.   The microcontroller 1100 determines the status of each EL panel (ie, on or off). Off) using its input / output pin 1110 to control Supports pre-programmed animation sequences to be displayed Output a sequence. Microcontroller is an animation sequence When the next word in is output to its input / output pin, the EL panel The state changes to the state corresponding to the pattern. In this way, the pre-programmed The display sequence is displayed on the EL panel.   Each of the EL panels is connected to an input / output pin on the microcontroller 1100 The complete state of the EL panel is determined by the microcontroller 1100 Determined when placing outputs on each input / output pin 1110 connected to the L panel. Is defined. The animation of the EL panel shows the output state of the input / output pin 1110. It is achieved by continuous updates.   To time sequence the pattern of the I / O pins 1110, two software A software approach has been used. The first approach is my Coded as part of the cross controller programming To specify the state of all panels for each step in the Is to build a table of words. For example, a three-step sequence: All panels on, every other panel on, all panels off It is possible that If 15 EL panels are used, Is represented by the state table as follows:         11111111 1111111         10101010 1010101         00000000 00000000 The microcontroller 1100 stores the first row in the table Simply output to 0 and switch on all EL panels. Wait for a predetermined period After that, the microcontroller 1100 reads the next line in the table To another panel 1110 to switch off every other panel. Another predetermined After the delay, the last row is transferred, turning off all panels. You.   The second sequence approach is to initialize the state of I / O pin 1110. And then calculate subsequent states based on the previous state and the selective bit manipulation function To do. For example, the “tracking” pattern indicates the state of the input / output pin 1110. Initialize the state as follows:         10111111 Then executed by executing a right turn command at this port Is possible. As a result, the next output sequence is as follows:         11011111 The bit manipulation functions used are performed by the microcontroller 1100. It can be any combination or sequence function that can be performed. The approach Reduces the size of the table required to hold the required state. Thus, it has the potential advantage of saving memory space.   A common problem in the prior art relating to EL lamps is that the lamp may not operate at high frequencies. When driven over a long period of time, they release heat and eventually burn. That is, it may be broken. The heating problem is a microcontroller Switch off the hot EL panel periodically, or if the EL panel is ON signal can be pulsed when it should be on for a period of time It can be alleviated by the present invention.   FIG. 12A and FIG. 12D show micro-controllers for controlling the switching circuit 1104. 3 shows a pulse signal from the controller 1100. These signals are By the microcontroller 1100 as a sub-signal during the conduction period of the Or, correspondingly, the external circuit is a microphone. Used to pulse the ON signal from the controller 1100. Both are possible.   The human eye does not perceive light that flashes faster than about 60 Hz as flashing It has an afterimage. Therefore, the frequency of the ON signal from the input / output pin 1110 is As long as the number is pulsed at least 60 Hz, the illuminated EL panel will be It will appear to be on continuously.   FIG. 12A shows a pulse signal with a 50% duty ratio that flashes at 60 Hz. No. is shown. High frequency signal from transformer 1212 during the high (“on”) period (Shown in FIG. 12B) is passed through the switching circuit 1104, They are controlled by the pulse signal 12A. The synthesized signal (shown in FIG. ) Drives the EL panel 1102 and thus illuminates it. The EL panel can be driven at a much higher frequency from the driver 1106. If so, they are driven when the pulse signal in FIG. 12A is low. Therefore, it is actually driven only for half the time. This is E The disadvantageous heating of the L panel is greatly reduced.   The pulse signal in FIG. 12A is generated by the microcontroller 1100. Therefore, the duty ratio can be easily changed. 6 An explanatory diagram of a pulse signal with a duty ratio of 75% blinking at 0 Hz is shown in FIG. 12D. Changing the duty ratio of the pulse signal To change the perceived brightness for the light being emitted. In FIG. 12D In the case of each completion period of the pulse signal, the signal is ON for three quarters of the time. Yes, since it is off for a quarter of the time, three quarters of the drive signal in FIG. Has arrived at the EL panel 1102. The human eye has a duty ratio 12A and 12D, since it is not perfectly linear with respect to A 25% increase in the teat ratio will give the observer a 25% brightness It will be perceived as slightly less than the rise.   The new EL panel controller device described above is small, lightweight, and fully integrated It can be packaged as a customized unit. In addition, color, brightness, perception Dynamic with respect to brightness and heat dissipation for multiple EL panels or filaments Control is feasible, thus allowing a wide range of animation capabilities. You.   A block diagram of a further embodiment of the EL panel controller device of the present invention is shown in FIG. It is shown in FIG. In this embodiment, the EL panel 1412 is a high-voltage driver 1 Connected to 410. Here, three EL panels are shown for illustrative purposes. But more or less can also be used easily. Noh. In addition, instead of using three separate panels, A single panel that is split can also be used equally.   Microcontroller 1400 includes a voltage regulator connected to battery 1406. Power is received from the integrator 1404. Switch 1402 is a microcontroller On / off, pattern control, timing control It can be used for various control functions such as control. Voltage adjustment The regulator 1408 is a high voltage regulator for supplying power to the high voltage driver 1400. is there. Typically, 200 volts is provided for driver 1410, Very high or low voltages may be used depending on the special lighting requirements of the three ELs. It is also possible that   In operation, the microcontroller 1400 provides an output enable (OE)line , Polarity lines, data lines, and clock lines, The lighting of the L panel 1412 is controlled. The data line is preferably a driver 141 Load data continuously into shift register encapsulated in 0 It is a single line. For applications that require faster load times, More data lines could be used.   FIG. 14 is a detailed block diagram of the high voltage driver 1410. Driver 14 10 contains the shift register 1500. The shift register 1500 Information from the data line is received in synchronization with the clock. Register clear line or Other register input lines, such as shift register direction control lines, are not shown. However, the input from the microcontroller 1400 into the shift register 1500 It is possible to be forced.   The data output from the shift register 1500 is input to the logic circuit 1502. You. Output enable signal, input from shift register 1500, and polarity signal , The logic circuit 1502 opens and closes the MOS FETs 1504 and 1506 based on You. Depending on the state of those MOS FETs, the EL panel 1412 may be charged or Or discharge, illuminating them.   In operation, the microcontroller 1400 provides clock, polarity, and output Each enable signal is sent to each logic circuit 1502 in the high voltage driver 1410. I believe. Clock and data signals are coupled to shift register 1500. Entered continuously. The shift register 1500 synchronizes with the clock signal to Data from the first segment to the second segment and finally to the third segment Shift to At any given time, the microcontroller 1 400 controls the shift register 1500, data and clock signals. Thus, only a single “1” or ON bit exists in the shift register 1500. Exist. A “1” in one of three locations in shift register 1500 indicates that This corresponds to a potential ON state of the corresponding logic circuit 1502. Each clock In the pulse, the “1” shifts down the shift register 1500 Is done. In this way, the microcontroller 400 determines the E to be actuated. The L panel 1412 can be controlled. “0”, ie, OFF bit, Corresponding to a potential OFF state in the logic circuit 1502. OFF state At one time, the logic circuit 1502 turns off the MOSFETs 1504 and 1506. Switching, and therefore a high impedance to the EL panel 1412 Will be presented.   OEThe signal is a low active line. When this line is low, the shift register The logic circuit 1502 corresponding to “1” in the star 1500 responds to the polarity signal according to the polarity signal. The corresponding EL panel 1412 is charged or discharged.OEIs high When all the logic circuits 1502 are 4 and 1506, the EL panel 1412 is connected to the high-voltage driver 141. Foresee a high impedance state at zero. In this state, the panel 141 Neither of them will appreciably discharge or charge.   The polarity lines correspond to the optional panel 1412 (ie, Used to select the polarity of charging experienced by the Used. EL panels 1412 may be used when they experience a change in potential. Only emits light. The panel is selected by a "1" in the shift register and the output When enable is enabled, the panel turns off the MOS FET 1504. By turning on and turning off the MOSFET 1506. Is charged or the MOS-type FET 1504 is turned off. , And by turning on the MOSFET 1506, If the polarity is low, it will be discharged. EL panel 1412 is DC Stores the charge input by the power supply (they act like capacitors ), The microcontroller 1400 is preferably a continuous EL panel The polarity lines are alternated between the selections.   FIG. 15 illustrates the interaction of clock, data, polarity, and output enable signals. FIG. The timing interval from t1 to t3 is shown in FIG. Is labeled horizontally across the top of the. At interval t1, data Signal "1" is preferably applied to the shift register at the rising edge of the clock. 1500 is loaded into the first segment. Output enable disabled All the MOSFETs 1504, 1506 are off (high in (Pedance state). At this point, the EL panel 1412 displays the driver 1 Examining 410 will effectively "see" the open circuit. This is the EL panel 1414 means that it is not charging or discharging .   At time interval t2, since the data signal is low, shift register 1500 Shifts the previously loaded "1" to the second segment. Output enable Is again forbidden to use, and therefore all the MOS FETs 1504, 1506 is off.   At the beginning of t3, the output enable is enabled. Shift cash register A "1" in the second segment of the The logic circuit is then switched to one of the MOS FETs 1504, 1506. Will be switched on. The MOS FET to be switched on is Determined by the polarity signal. In this example, the polarity signal is now High, which corresponds to switching the MOSFET 1504 on. You. This allows current to flow from the power supply to the central EL panel, It is charged and emits light. Microcontroller creates central EL panel The next time it is activated, it does so by a low polarity signal. And This turns off the MOS FET 1504 and turns off the MOS F150. ET1506 will be switched on and current will flow from the EL panel And allow it to emit light.   The clock signal controls the frequency at which drive circuit 1410 is activated. clock Since the signal is controlled by the microcontroller 1400, its frequency And duty ratio are controlled by software that controls the microcontroller. It can be easily changed. Typical operating frequencies range from 100 Hz to 2 It can vary up to 000 Hz. Changing the frequency of a clock signal Is the luminance and illumination color of the EL panel in the same manner as in the embodiment of FIG. Affect.   Microcontroller 1400 operates in a pre-programmed sequence. Control the clock, data, polarity, and output enable lines. Controls the color, brightness, and state of the EL panel. It creates an animated visual display.   Block of yet another embodiment of the EL panel controller device of the present invention A diagram is shown in FIG. In this specific example, the EL panel 1806 Connected to driver 1800. High voltage driver 1800 is shown in FIG. It is located in a circuit similar to that of the high voltage driver 1410. However, In this embodiment, each data line from 1802a to 1802n is Instead of the example OE, polarity and clock, the microcontroller 140 Input from 0. Solid state switching from 1804a to 1804n The circuit is controlled by respective data lines from 1802a to 1802n The EL panel 1806 is connected to either DC input high voltage or ground. Continue.   In operation, a high ("1") value on data line 1802a indicates a solid state. Port switching logic 1804 connects the corresponding EL panel to DC high voltage In this way, the EL panel is charged and emits light. Microphone The controller 1400 sets the value on the input data line 1802a to low (“0”). ) When changing to a value, the solid state switching logic 1804a will Connect the corresponding EL panel to ground, discharge it, and make it emit light. is there.   Alternatively, both charging and discharging of the EL panel 1806 can be performed by a microcontroller. Instead of having the circuits control independently, supplementary circuits 1804a through 1804n Up to the value of the data control line. It is also possible to detect a change from a low value to a high value. So Is detected, the solid state switching circuit, as a result, EL The high voltage for the panel 1806 is automatically pulse-switched. this is Microcontroller to charge and discharge EL panel alternatively Useful for operators because they do not have to be involved in programming It is. This is because each solid stay from 1804a to 1804n This is because it is automatically executed by the switching circuit.   FIG. 16 shows one panel by alternatively switching between two panels. 2 shows a multiplexing circuit for simulating an EL panel. Replacement switch 1700 Connects the EL panel 1702 drive power supply to one of the two EL panels. Switch The switch 1700 periodically switches between panels, so that any panel It will not be driven over a time period. The switching operation is specified External clock signal, internal clock signal, or power supply input signal It can also be based on The two EL panels are driven by the drive signal as described above. By multiplexing the signals onto two EL panels, each individual panel Used to simulate one panel driven at twice the frequency of . At high drive frequencies, this significantly reduces the heat generation of the EL panel. Yes, and thus prove to increase the life of the EL panel. Was. This multiplexing configuration can be implemented in any of the above embodiments. Noh.   The above apparatus and method constitute a preferred embodiment of the present invention. However, Various modifications and variations will occur to those skilled in the art from the scope or spirit of this invention. Without departure, in the method or apparatus of the present invention, and even in the structure of the embodiment It will be clear that also can be performed. As a first specific example, a microcontroller Roller 1400 is used to dynamically control voltage regulator 1408 Is also possible. This is because the microcontroller is responsible for the illuminance of the EL panel. And will be able to exert further control. As a second specific example, FIG. The oscillator, power amplifier and transformer sections used in the ten embodiments are Conventional output, provided that the output stage can be fluid with respect to the input power. An inverter design can also be used.

[Procedure of Amendment] Article 184-8, Paragraph 1 of the Patent Act [Submission date] January 23, 1998 (1998.1.23) [Correction contents]                               The scope of the claims   1. Provided by the host system or otherwise power the lamps on the host machine Before to generate the lighting effect according to the lamp output signal used to supply Retrofit electroluminescence (E) used with the host machine L) A lighting system, wherein the retrofit lighting system comprises:   An EL lamp system having a plurality of EL lamp cells;   The EL lamp cells collectively illuminate in an order responsive to an EL lamp drive signal. Independently control each of the EL lamp cells of the EL lamp system. An ordering circuit for providing the EL lamp drive signal for:   Non-invasive sampling of the lamp output signal provided by the host system Providing the EL lamp drive signal to the sequencing circuit in response thereto. And a signal adjustment circuit that performs the operation.   2. Provided by the host system or otherwise power the lamps on the host machine Before to produce a lighting effect according to the lamp output signal used to supply Retrofit electroluminescence (E) used with the host machine L) A lighting system, wherein the retrofit lighting system comprises:   An EL lamp system having a plurality of EL lamp cells;   The EL lamp cells collectively illuminate in an order responsive to an EL lamp drive signal. Independently control each of the EL lamp cells of the EL lamp system. An ordering circuit for providing the EL lamp drive signal for:   Sampling a lamp output signal provided by the host system; A signal regulator that provides the EL lamp drive signal to the sequencing circuit in response to And a regulating circuit. 3. Electroluminescent (EL) lighting system for producing lighting effects Wherein the lighting system is:   An EL lamp system having a plurality of EL lamp cells;   The EL lamp is illuminated such that the EL lamp cells illuminate collectively in sequence. Periodic E for controlling each of the EL lamp cells of the pump system independently. An ordering circuit for providing an L lamp drive signal;   Signal level detection for detecting a periodic EL lamp drive signal having a specific level Circuit, wherein the ordering circuit detects a result of the detection by the signal level detection circuit. Control the EL lamp cell in response to   4. The ordering circuit comprises:   A switching signal generation circuit for generating a plurality of switching signals,   A plurality of switch circuits, each switch circuit receiving a generated switching signal. A periodic E corresponding to one of the EL lamp cells, corresponding to one of the A switching signal generation circuit formed to selectively provide an L lamp driving signal; Generates a switching signal according to the result of detection by the signal level detection circuit, The EL lighting system according to claim 3.   5. Each switch circuit, when the corresponding switching signal has the first level, Not providing said periodic EL lamp drive signal to the corresponding EL lamp cell Said periodic EL lamp when the corresponding switching signal has a second level. Formed to provide a drive signal to a corresponding EL lamp cell;   For each of the generated switching signals, the switching signal generation circuit includes: The switching signal is changed from the first level to the first level according to the result of the detection by the level detection circuit. The EL lighting system according to claim 4, wherein the EL lighting system is changed to two levels.   6. The specific level detected by the signal level detection circuit is substantially zero. The EL lighting system according to claim 5, wherein the EL lighting system is at a low level.   7. For each of the generated switching signals, the switching signal generation circuit includes the signal The switching signal is changed from the second level to the second level in accordance with the result of detection by the level detection circuit. The EL lighting system according to claim 5, wherein the EL lighting system is changed to one level.   8. A first switching signal of the plurality of switching signals is a first switching signal of the plurality of EL lamp cells. Corresponding to EL lamp cells;   A second switching signal of the plurality of switching signals is a second E signal of the plurality of EL lamp cells. Corresponding to L ramp cell;   The switching signal generation circuit changes the first switching signal from the first level to the second level. A first EL lamp cell that is switched and then the drive signal is switched After recovering from the instability caused by the second switching signal from the second level Is switched to the first level, whereby the second switching signal is switched from the second level Avoid spikes in the drive signal when switching to the first level The EL illumination system according to claim 5, wherein the level of the switching signal is changed. Stem.   9. The specific level detected by the signal level detection circuit is substantially zero. 5. The EL lighting system according to claim 4, wherein the EL lighting system is at a low level.   10. A first switching signal of the plurality of switching signals is a first switching signal of the plurality of EL lamp cells. Corresponding to one EL lamp cell;   A second switching signal of the plurality of switching signals is a second E signal of the plurality of EL lamp cells. Corresponding to L ramp cell;   The switching signal generation circuit is configured to switch the first EL lamp cell while the second EL lamp cell is on. The EL lamp cell is switched on and then the drive signal is switched on After recovering from the instability caused by the resulting first EL lamp cell, The second EL lamp cell is switched off, thereby causing the second EL lamp Avoiding spikes in the drive signal when cells are switched off In this manner, the level of the first and second switching signals is changed. An EL lighting system as described.   11. The sequencing circuit is configured to provide the first EL lamp cell while the first EL lamp cell is on. The EL lamp cell is switched on and then the drive signal is switched on. After recovering from the instability caused by the first EL lamp cell, the second The EL lamp cell is switched off, thereby causing the second EL lamp cell to be turned off. To avoid spikes in the drive signal when the switch is switched off The EL lighting system according to claim 3, wherein the EL lighting system is formed.   12. Electroluminescence (EL) lighting system for producing lighting effects Wherein the lighting system comprises:   An EL lamp system having a plurality of EL lamp cells;   The EL lamp so that the EL lamp cells illuminate collectively in sequence A periodic EL lamp for independently controlling each of the EL lamp cells of the system; An ordering circuit for providing a pump drive signal;   A capacitive load circuit having a plurality of load capacitance means, said ordering circuit In addition, one or more combinations of load capacitance means may be included in the operating sequence. And actuated collectively to independently control each load capacitance means, The actuation sequence includes the capacitive load circuit corresponding to a lighting sequence.   13. The operation sequence includes a drive signal generator for generating the EL drive signal. The capacitance presented to the data during each step of the lighting sequence 13. The EL lighting system of claim 12, wherein the EL lighting system is substantially constant.   14． The ordering circuit is:   A primary switching signal generation circuit for generating a plurality of primary switching signals;   The plurality of primary switch circuits and each primary switch circuit are adapted to generate the primary switching signal. To selectively provide the EL lamp drive signal to a corresponding one of Each primary switch circuit is formed;   A secondary switching signal generation circuit for generating a plurality of secondary switching signals;   A plurality of secondary switch circuits, wherein each secondary switch circuit includes a load capacitance means. Formed to selectively provide the EL lamp drive signal to the corresponding one of The EL lighting system according to claim 12, wherein   15. In the operation sequence, each step of the lighting sequence is performed by the load capacitance means. Is activated between steps, thereby causing the lighting sequence to go from step to step. 14. Avoiding spikes in the drive signal when going to a step. 3. The EL lighting system according to claim 1.

────────────────────────────────────────────────── ─── Continuation of front page    (31) Priority claim number 08 / 783,732 (32) Priority date January 16, 1997 (Jan. 16, 1997) (33) Priority country United States (US) (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FI, FR, GB, GR, IE, IT, L U, MC, NL, PT, SE), OA (BF, BJ, CF) , CG, CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AP (KE, LS, MW, SD, S Z, UG), UA (AM, AZ, BY, KG, KZ, MD , RU, TJ, TM), AL, AM, AT, AU, AZ , BA, BB, BG, BR, BY, CA, CH, CN, CU, CZ, DE, DK, EE, ES, FI, GB, G E, HU, IL, IS, JP, KE, KG, KP, KR , KZ, LC, LK, LR, LS, LT, LU, LV, MD, MG, MK, MN, MW, MX, NO, NZ, P L, PT, RO, RU, SD, SE, SG, SI, SK , TJ, TM, TR, TT, UA, UG, US, UZ, VN (72) Inventor Lipsky, Mark             United States 92130-1257 California             San Diego Kelam Court, Lunia               Number 32 13 127 (72) Inventor Haines, Brian Dee.             United States 94044 California             State Pacifica Alcala Court 19 (72) Inventor Cassora, Earl             United States 14617 New York               Rochester Biltmore Drive               199 (72) Inventor Looper, Norman             United States 92104-1313 California             San Diego Surtees, Lunia             Avenue 4357 [Continuation of summary] , Thereby producing an animated expression I do. The signal conditioning circuit (102) is a host system. Non-invasively the lamp output signal provided by (104) Sampling, and the EL lamp accordingly A drive signal is provided to (108).

Claims (1)

[Claims]   1. Multiple electro-luminescence to generate animated displays A device for controlling a display element, said device comprising:   A microcontroller;   Suitable large size for driving the electroluminescent display element A power supply circuit for supplying a drive signal of magnitude and frequency;   Receiving a plurality of signals from the microcontroller; and Connected to also receive the drive signal from the Drive signals based on the signals received from each of the individual electroluminescent A selection circuit for selectively transferring to the display element.   The microcontroller turns on or off the display elements in order. Generates an animated display by switching off.   2. Light emitted by the electroluminescent display element In order to change the color and brightness of the drive signal, The control device according to claim 1, wherein the magnitude and the frequency can be changed.   3. The magnitude and frequency of the drive signal are determined by the microcontroller. The control device according to claim 2, wherein the control device is dynamically controlled.   4. For each of the electroluminescent display elements, the panel The circuit selection circuit selects whether to transfer the drive signal based on the following circuit. And the circuit comprises:   A resistor connected at one end to the microcontroller;   A transistor having a base, an emitter, and a collector, wherein the transistor A resistor is connected to the other end of the resistor at the transistor base. The transistor is connected to the power supply circuit at the collector end. The microcontroller allows current to flow through the resistor. When said transistor is turned on, said transistor;   The collector of the transistor and each of the electroluminescent panels; And a diode bridge connected to the control circuit. Control device.   5. The microcontroller is connected to a pushbutton switch Allows the user to enter a function to be performed by the microcontroller. The control device according to claim 1, wherein the control device allows the operation.   6. The power supply circuit:   A function generator for generating a periodic signal;   Connected to the function generator to amplify the periodic signal A power amplifier;   And a transformer connected to the power amplifier. Control device.   7. The electroluminescent display element comprises an electroluminescent display element. The control device according to claim 1, which is a essence filament.   8. The electroluminescent display element is an electroluminescent display element. The control device according to claim 1, which is a sense panel.   9. An electroluminescent partition to generate an animated display An apparatus for controlling a tunnel, said apparatus comprising:   A power supply for supplying high voltage power;   Microcontroller for providing timing, data, and polarity signals With Troller;   Operate synchronously with the timing signal and from the microcontroller A driver circuit for receiving the data signal and the polarity signal; The data circuit is, when the data signal is high and the polarity signal is also high, By charging the electroluminescent panel from the power supply Illuminating the electroluminescent panel, wherein the data When the signal is high and the polarity signal is low, the electro-luminescence Discharging the electroluminescent panel by discharging the electroluminescent panel. The driver circuit adapted to illuminate the device;   The microcontroller can change the frequency of the timing signal. Controls the color of the electroluminescent panel.   10. A second EL panel and a multiple storage controller circuit, wherein the multiple storage The control device controls the electroluminescence based on the timing signal. Panel or one of the second electroluminescent panels. And thereby the electroluminescent panel and The expected illumination life of the second electroluminescent panel is increased The control device according to claim 9.   11. The microcontroller has a duty ratio of the timing signal. 10. The method according to claim 9, wherein the color is controlled by changing the color. Control device.   12. Electroluminescence for generating animated displays An apparatus for controlling a panel, the apparatus comprising:   A power supply for supplying high voltage DC power;   Voltage ground;   A microcontroller that supplies a signal line for controlling the on / off state of the panel With the controller   Connected to the power supply and the panel, from the microcontroller Receiving the signal line and, based on the signal line, alternatively, from the power source, So as to charge the panel and discharge the panel to the voltage ground. The solid state switching logic that the panel emits light during charging and discharging operations. Prepare.   13. Provided by the host system or otherwise power the lamps on the host machine To generate lighting effects according to the lamp output signal used to supply power , Retrofit electroluminescence used with the host machine (EL) a lighting system, wherein the retrofit lighting system comprises:   An EL lamp system having a plurality of EL lamp cells;   The EL lamp cells collectively illuminate in an order responsive to an EL lamp drive signal. In this way, each of the EL lamp cells of the EL lamp system is independently controlled. An ordering circuit for providing the EL lamp drive signal for controlling   Provided by the host system, and the EL Signal conditioning for non-invasively sampling said lamp output signal to provide a lamp drive signal And a regulating circuit.   14． Provided by the host system or otherwise power the lamps on the host machine To generate lighting effects according to the lamp output signal used to supply power Retrofit electroluminescence used with the host machine ( EL) a lighting system, wherein the retrofit lighting system comprises:   An EL lamp system having a plurality of EL lamp cells;   The EL lamp cells collectively illuminate in an order responsive to an EL lamp drive signal. Independently control each of the EL lamp cells of the EL lamp system. An ordering circuit for providing the EL lamp drive signal for:   The EL lamp driving signal provided from the host system and correspondingly provided. A signal adjusting circuit for sampling the lamp output signal to be provided.