TREA

Digital power controller for gas discharge devices and the like

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Information

  • Patent Grant
  • 7449844
  • Patent Number
    7,449,844
  • Date Filed
    Monday, September 13, 2004
    19 years ago
  • Date Issued
    Tuesday, November 11, 2008
    15 years ago
Information
Abstract
A programmable digital power controller for gas discharge devices such as fluorescent lamps or other devices using all digital internal and external programmable controls. A specific ASIC is described. A gate array and microcomputer share parallel functions with fast sub-functions carried out by the gate array and slower sub-functions carried out by a micro-processor. Circuits are provided for automatic shut down when a high frequency ground fault is detected; for connecting the filaments of multiple gas discharge devices in a series/parallel circuit in a manner that power for a particular device is disabled when that device is removed from the circuit; for driving the load as close to resonance as possible but in an inductive mode; and for developing a dead time between high side and low side switches which is related to transformer current, switch current, bridge voltage or bridge voltage dv/dt.
Description
FIELD OF THE INVENTION

This invention relates to power controllers and more specifically relates to a power controller, using digital implementation with such stand-alone features as automatic shut down; dead time control, close to inductive side driving; and filament connections.


BACKGROUND OF THE INVENTION

Power controllers are well known and normally employ analog techniques. Digital techniques are normally avoided where smooth control is desired, for example, in controlling the dimming gas discharge lamps such as fluorescent lamps in an electronic ballast.


The present invention provides a novel digital implementation for power control circuits, particularly for the control of fluorescent lamp dimming.


Some limitations on analog power control systems are:


I. Inflexible Driving Algorithm


Optimal driving of power switches (MOSFETs, bipolar, transistors, thyristers, IGBTs and the like) requires complex algorithms based on non-linear multiple stage and variable functions, with a variety of predetermined parameters being chosen as the circuitry's physical parameters change.


For example, in the case of a fluorescent ballast power controller, flexible algorithms are desired to supply special loads when:


a) a complex working regime for fluorescent lamps including the preheat startup operation is needed.


b) Non-linear or special operation requirements for the fluorescent lamp complying to its V/I working curve, and as a function of the dimming decision table to provide the best operation at all light levels.


c) Flexibility to enable use of different lamp configurations (types and numbers of lamps) and different main voltages.


II. The number of electronic circuits increases as number of control function increases. If silicon implementation is feasible, it requires a large silicon overhead.


III. No Decision Tables


An analog solution does not provide “IF-THEN” decisions. It only provides “YES-NO” decisions using analog comparators and only linear predetermined algorithms. For example: voltage controlled oscillator (VCO) for frequency modulation (FM) or pulse width modulation (PWM) zero to max., pulse control, etc.


IV. No Parameters Set Tables


This has to do with different lamp configurations, in the case of a fluorescent lamp ballast, but also with many other decisions made by the controller in every state of its operation. One specific example is the time response of the lamp current loop being different at high level or low level as well as during transient or at steady state operation.


BRIEF DESCRIPTION OF THE PRESENT INVENTION

The present invention provides a number of novel improvements which can be integrated into a simple system, or, in some cases can be used singly in a stand-alone circuit. These improvements are:


I. Programmable predetermined fixed internal parameters can be programmed by the designer, by means of simple MMI, adapting control loops to the desired operation regimen and power circuit, while protecting the power circuit from damage if running it under “non-legal” settings. This technique allows on-the-spot matching of control to power circuit, instead the tedious and costly procedure common in digital signal processing (DSP) devices that requires programming of dedicated software and back and forth adapting of control to power.


The predetermined fixed internal parameters above refer to a set of numbers and tables intended for:

    • limits, constants, parameters and signed coefficients included in the control loop algorithm; and
    • addressing/identification; etc.


Examples of the above are:

    • 1. to normalize to “real” signals;
    • 2. to create the limits for the “IF-THEN” algorithm.
    • 3. to adapt to the designed configuration and the work regimen of the ballast.


II. Programmable predetermined parameter internal power configuration tables are provided.


III. An externally programmable new parameters table is provided that can be set for a specific application that cannot use the already existing tables (for example: an EEPROM function).


IV. Software substitutes may be used for analog circuits.


V. An application specific integrated circuit (ASIC) handles, in principle, an indefinite quantity of functions with an insignificant amount of silicon. Thus, all possible components/circuits/algorithms are integrated on the same silicon. This provides a simple low cost and enhanced solution with all the flexibility provided by software. The integration provides high noise immunization, eliminates intercircuit interfacing components, shares circuitry elements and allows dramatic space reduction.


VI. A gate array is provided which includes the fast algorithms or the fast portion of them, like:

    • 1. Center Tap;
    • 2. Zero, minimum and maximum current of the power factor corrector (PFC);
    • 3. Generation of driver pulses.


VII. A microcomputer and the gate array share functions that are being carried out in parallel.


VIII. A very low-end microprocessor processes all the jobs by time-sharing instead of using the super-scalar processor used in DSPs.


IX. A gate array carries out all of its assignments in parallel. Functionally, the assignments operate in parallel and require separate gate array sections or blocks for each one.


X. The microprocessor manages the gate array operation, among others.


XI. The gate array receives input from monitoring nets and operates the immediate algorithm protections. In the case of fluorescent lamp dimming, the job is done by using all the main ASIC elements A/D, microprocessor, and gate array. In the embodiment described, the gate array also carries out watchdog functions.


XII. The microprocessor monitors protections being operated and takes care of long term actions.


XIII. In general, the functions constructed by fast and slow sub-functions are handled as follows:


The algorithm implemented in the gate array carries out the fast sub-functions which include fast pulses or actions. The sub-functions which require processing or actions that can be carried out during a slower mode, are carried out by the microprocessor. The novel structure and process of the invention provide a programmable integrated digital control module which can be used for a dimming fluorescent ballast. The control module features are:


a) Combines the Integrated Digital Control Dimmable Electronic Ballast (DEB) ASIC on a programmable printed circuit board product for new lighting ballast designs and evaluation suitable for low to medium volume production.


b) A large number of “on board” programmable, for example, 14, parameters define preheat, absolute light-level and dimming range.


c) An EEPROM enables the control parameters described above to use a single hardware platform for multiple lamps, diverse operation regimens and applications.


d) Integrated software defaults predefined parameters to a 2-lamp 32 w/36 w lamp drive for 120/230V a-c line/mains.


e) Incorporates all dimming ballast controls, including power conversion, into a single digital ASIC with multi-mode closed-loop control and pulse-by-pulse bridge protection.


f) A modified critical-mode boost PFC control achieves lowest total harmonic distortion (THD) at all light levels.


g) A series resonant lamp inverter control achieves less than 1% current-level control as required for architectural dimming fluorescent ballasts.


h) Module flexibility speeds product redesign and field testing in advance of custom ASIC software specification suitable for high-volume ballast products.


A large number of other features can be incorporated into the novel system of the invention, as integral parts of the system, or as stand alone features which could be incorporated into any ballast control circuit. These include:


1. A novel shut down circuit for turning off power to ballast in response to the sensing of a common mode high frequency current which exceeds a given value. In particular, an added winding is wound on the common mode choke to sense a high frequency around fault current and turn of power to the ballast in response thereto.


2. A novel circuit for connecting two or more filaments of two or more gas discharge lamps, particularly fluorescent lamps, in parallel so that removal of any lamp breaks that circuit while permitting the voltage applied to the lamp to be reduced for dimming. In particular, a series/parallel circuit is provided which enables energization of the lamp filaments with a half wave rectified DC.


3. A control arrangement for DC to AC inverters for driving non-linear loads such as electronic ballasts for high pressure and low pressure gas discharge lamps, resonant power supplies and laser power supplies and the like, wherein the control scheme employs both variable pulse width and frequency modulation, driving the load as close to resonance as possible but on the inductive side of resonance. Both the high side and low side switches of the bridge (half or full wave) are independently controlled in this arrangement.


4. A novel protection circuit for a bridge connected (half or full wave) inverter which supplies a resonant load such as a resonant electronic ballast for gas discharge lamps, which forces a dead-time during which no switch is driven in conduction without limiting the performance of the circuit. The point at which a dynamic dead-time begins is sensed by sensing the point where current collapses to zero in a capacitive timed circuit case. The sensing circuits may sense inductor current using a current transformer or shunt resistor, by sensing the current through the switching devices, by sensing the bridge voltage or by sensing the bridge voltage dv/dt.


According to the present invention, an electronic ballast for a gas discharge lamp is provided in which the electronic ballast has an input a-c circuit, a common mode inductor for connecting said input a-c circuit to a bridge connected rectifier, an inverter circuit including a high side switch and a low side switch which is coupled to the bridge connected rectifier, and a resonant circuit coupling the inverter circuit to and driving the gas discharge lamp. A monitor circuit is coupled to the common mode inductor for sensing a high frequency fault ground current, which has a frequency greater than the frequency of the input a-c circuit, to a ground connection. A controller circuit is coupled to the monitor circuit for turning off the inverter circuit or the power to the inverter circuit when the high frequency ground current exceeds a given value.


As another aspect of the present invention, an electronic ballast for at least two parallel connected gas discharge lamps removably mounted in a fixture is provided in which there is an inverter circuit, a resonant coupling circuit and at least two gas discharge lamps. The gas discharge lamps have first and second filaments. The resonant coupling circuit includes an inductor and a capacitor connected in series with the first and second filaments. First and second windings are coupled to the inductor and first and second diodes are connected in series with the first and second windings respectively and the first and second diodes respectively, whereby the disconnection of the lamps and the filaments from their fixtures opens the output circuit from the inverter circuit.


As another aspect of the present invention, an electronic ballast or a gas discharge lamp is provided in which there is an input a-c circuit. An a-c filter is connected to the input a-c circuit. A rectifier bridge is connected to the a-c circuit for producing an output d-c voltage from the a-c circuit input. An inverter circuit including a high side switch and a low side switch is connected in series at a node and connected across the output of the inverter circuit and a load circuit is connected to the node and includes the gas discharge lamp. The high side and low side switches each comprise MOSgated devices, and the like, having input control terminals energizable to turn them on and off and each has a parallel diode. A master control circuit applies suitably timed control signals for alternately turning the high side and low side switches on and off. A dynamic dead time control circuit in provided in the master control circuit for insuring only a short interval between the end of current conduction by either the high side and low side MOSgated devices, and the like, and the beginning of conduction by the other by the control of the application of controls signals to their control terminals. The dynamic dead time control circuit is coupled to and monitoring at least one of the current in the resonant load, the current in the first and second switches, the output voltage of the rectifier bridge or the rate of chance dv/dt of the bridge voltages, and adjusts the application of turn on signals to the high side and low side switches for both capacitive and inductive operations.


As still another aspect of the present invention, an electronic control module for controlling the operation of an electronic ballast for at least one lamp is provided in which the control module has an integrated circuit operable in accordance with control information to drive a first switch and a second switch to power the at least one lamp using a combination of pulse width modulation and frequency modulator. A first memory is coupled to the integrated circuit, the first memory storing a plurality of parameters tables, each parameters table having the control information for the integrated circuit.


As yet another aspect of the present invention, an integrated circuit for controlling the operation of an electronic lamp ballast is provided in which a central logic supervisor controls the overall operation of the electronic lamp ballast. A dc/ac generator module is coupled to the central logic supervisor and provides drive signals for an inverter circuit, the inverter circuit having a first switch and a second switch. A power line communication module is coupled to the central logic supervisor and receives dimming control data across a power line. A power factor correction module is coupled to the central logic supervisor and controls power factor detection and correction for the electronic lamp ballast.


As another aspect of the present invention, a method for controlling the dimming operation of an electronic ballast is provided in which a current through a load coupled to the electronic ballast is monitored and the current to maintain a dimming level is controlled.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 is a prior art electronic ballast circuit which presents a hazard in the presence of a high frequency, high voltage ground fault.



FIG. 2 shows a novel circuit to provide high frequency hazard protection and is an improvement of the circuit of FIG. 1.



FIG. 3 is a circuit diagram of a lamp ballast with a known serial connection of lamp filaments.



FIG. 4 shows a circuit diagram of a lamp ballast with a known parallel connection of lamp filaments.



FIG. 5 shows an improvement of the circuit of FIGS. 1 and 4 and is a novel circuit arrangement for a lamp ballast employing a novel series/parallel connection of filaments.



FIG. 6 shows a known generic half-bridge ballast circuit operated in a near resonance operation.



FIG. 7 shows the voltages and currents in the circuit of FIG. 6 on a common time base for a reactive phase condition.



FIG. 8 shows the voltages and currents in the circuit of FIG. 6 for a capacitive phase condition.



FIG. 9 shows the circuit of FIG. 6 adapted with a novel current sense protection circuit.



FIG. 10 shows the circuit of FIG. 5 with a novel voltage sense protection circuit.



FIG. 11 shows the circuit of FIG. 6 with a novel dv/dt sense protection circuit.



FIG. 12 shows the curves of FIG. 8, using a novel continuous reactive load mode of operation.



FIG. 13 shows the curves of FIG. 12, modified by a novel use of predicted minimum dead time.



FIG. 14 shows a novel voltage sense protection circuit (FIG. 10) for an electronic ballast.



FIG. 15 is a block diagram of a preferred ASIC which can be used to control the circuit of FIG. 14.



FIG. 16 is a block diagram of a full control module using the circuits of FIGS. 14 and 15.



FIGS. 17 and 17A show the curves for the novel independent control of the high side and low side switches of a DC/AC bridge inverter.



FIG. 18 is a block diagram of the silicon topology of the ASIC of FIGS. 14 and 15.



FIG. 19 shows relevant voltage and current curves produced by the ASIC of FIG. 18.



FIG. 20 is a diagram of light level versus current in which the curve is divided into matched segments of the conventional non-linear curve.



FIG. 21 is an interconnect diagram of a PLC Remote Controlled Dimmable Ballast.



FIG. 21A is a schematic diagram of the ASIC used in FIG. 20.



FIG. 22 shows the ASIC pin assignment for FIGS. 20 and 21.



FIG. 23 is a Wall Control Unit schematic diagram for the diagram of FIG. 21.



FIG. 24 is a further electrical diagram of the ballast control module of the invention.



FIG. 25 is an electrical diagram of the ballast platform with control module.





DETAILED DESCRIPTION OF THE DRAWINGS

There is next described the various novel features which can be combined with one another and/or can stand alone. These are described in Sections I through V hereinafter.


I. The High Frequency Hazard Protection Circuit


Referring to the drawings in which like reference numerals refer to like elements, FIG. 1 schematically shows a prior art electronic ballast circuit in which an AC input line is connected to a full wave bridge connected rectifier circuit 30 through a common mode choke 31. The windings of the common mode choke or inductor 31 both have stray capacitances associated therewith as shown. The output of bridge 30 may be connected to a DC-to-DC power factor converter circuit 33 which has one output connected to the VSS bus and another output to the VCC bus.


A high side switching MOSFET (or other MOS controlled device such as an IGBT) Q1 is connected to the VCC bus and a low side switching MOSFET Q2 is connected to the VSS bus. MOSFETs Q1 and Q2 are suitably controlled to alternately turn MOSFETs Q1 and Q2 on and off with controlled frequency, duty cycle and/or phase delay.


Output node 35 is then connected to a resonant load, which, in FIG. 1, consists of blocking capacitor 40, inductor 41, parallel capacitor 42 and fluorescent lamp 45 having filaments 43 and 44.


The line conductors in FIG. 1 are connected to ground 46 through capacitors 47 and 48. A hazard exists if, because of a ground fault or the like an individual 50 is connected between the circuit and ground.


The hazard caused by the low frequency (50/60 Hz) is generally treated with a residual current sensor (not shown). However, the high frequency (20-100 Khz) voltage used in electronic ballasts might be dangerous because the voltages are high (especially during the ignition period) and the gas in the tube behaves like a large capacitor.



FIG. 2 shows the novel circuit for avoiding the above hazard problem. In FIG. 2, those parts which are similar to those of FIG. 1 have identical identifying numerals. A novel additional winding 60 is added to the common mode choke 31. Winding 60 is connected through diode 61 to a controller 62 which is adapted to sense a fault condition. If winding 60 senses a common mode high frequency current higher than a safe value, controller 62 applies a “shut-down” signal to converter 33, thereby shutting down the DC/AC power bridge. Details of a typical converter and DC/AC power bridge which could be used with this invention are later described herein.


II. DC Filament Supply Circuit for Safe Parallel Lamp Operation.


A fluorescent lamp has two filaments at its two sides. Thus, in FIG. 3, lamp 45 has filaments 43 and 44. These filaments must be heated before the lamp 45 can be ignited, and must remain heated if one wishes to operate lamp 45 at a “Low Light” or dimmed condition. There are two principal connections for lamp filaments used in electronic ballasts, a serial connection and a parallel connection. FIG. 3 shows the serial connection.


In this configuration the heating current flows through the resonance circuit formed by inductor 41 and capacitor 42. Prior to ignition and during a phase the voltage on the lamp should be low (under the ignition voltage). Therefore the operating frequency should be significantly above resonance. At that frequency the current is determined by inductor 41 and might be too low to produce adequate filament heating. At and after ignition the current through the filament is adequate.



FIG. 4 shows a prior art parallel connection of filaments 43 and 44. In this configuration the inductor 41 has additional windings 70 and 71 which are used a supply a heating voltage to filaments 43 and 44 (rather than a series) current. This circuit provides an adequate current through the full lamp operating mode, but it has a serious drawback. That is, when a lamp is taken out of its housing, current still flows through the resonance circuit 41 and 42 and might damage the ballast especially when it is used to drive two parallel lamps.


In accordance with the invention, and as shown in FIG. 5, a novel series/parallel connection is provided. Thus, windings 70 and 71 of FIG. 4 are reconnected as shown and are connected to filaments 44 and 43 respectively through diodes 75 and 76 respectively.


This approach applies parallel heating to the filaments and connects the lamp in such a manner that pulling it out of the housing will open the lamp circuit.


The result is a serial-parallel combination, the parallel segment feeding the lamp 45 with a half wave rectified DC wave form. The diodes 75 and 76 are connected in such a manner that whenever the lamp 45 is pulled out, current flow is blocked.


The connection of a second lamp 45 is shown in phantom lines in FIG. 5. Under this arrangement, the removal of one of the lamps still allows the remaining lamp (or lamps where more than two lamps are driven) to operate. The removal of all lamps blocks the current flow.


III. Protective Circuits for the Bridge Inverter.



FIG. 6 shows a “generic” half-bridge circuit for driving any desired resonant load, such as an electronic ballast. The half-bridge consists of the high side and low side MOSgated devices, and the like, such as MOSFETs Q1 and Q2 respectively. MOSFETs Q1 and Q2 are shown with conventional parallel body diodes 80 and 81 respectively and load 82 can be any desired resonant load such as gas discharge lamp. Basically the circuit of FIG. 6 is a resonant topology and the work regime is near resonance; that is, close to the resonant frequency of inductor 41 and capacitor 42. The invention to be described is suitable for any application in which a reactive current might flow through the bridge Q1, Q2. Note that everything described below applies to a full bridge topology as well as the half-bridge shown in FIG. 6.



FIG. 7 shows relevant voltages and currents in the circuit of FIG. 6 on a common time axis when the excitation frequency of MOSFETs Q1 and Q2 is above the resonant frequency of inductor 41 capacitor 42 and load 82. In this condition the load is reactive. In FIG. 7, line 100 is the HO signal to Q1 and line 101 is the LO signal to Q2. The bridge voltage at node 35 is shown by line 102 and the bridge current is shown by line 103.


At the end of each excitation cycle in FIG. 7, the current 103 through the inductor 41 lags behind the excitation voltage 102. When the upper switch Q1 is closed, a current flows into the inductor 41. When the upper switch Q1 opens or turns off, the current must continue flowing through the inductor 41 and does so by flowing through the lower switch integral diode 81 as shown by line 104 in FIG. 7. When the lower switch Q2 closes Q2, the integral diode 81 recovers from conduction at a zero voltage by a recombination of carriers effect only.


The same behavior described above applies to the half cycle controlled by lower switch conduction line 105.


The following can be observed:


1. When upper switch Q1 is turned off, the inductive current is steered to the lower switch integral diode 81 and the voltage 102 at the bridge swings immediately from Vdd to Vss.


2. The current steered into the lower switch integral diode 81 collapses to zero while the lower switch Q2 is closed.


3. Simultaneous conduction of both upper and lower branches Q1 and Q2 and of the bridge is not possible.


The diagram of FIG. 8 shows the behavior of the inverter bridge of FIG. 6 when the excitation frequency is below resonance (and the load is therefore called capacitive). The various traces of FIG. 8 have the same numerals as those of FIG. 7.


At each excitation cycle the current through the inductor 41 leads the excitation voltage and reverses its direction before the excitation cycle ends. Thus at the end of the excitation cycle the current flows through the integral diode of the power switch Q1 or Q2 which is turned on and which is about to close. When the upper switch Q1 is closed, current still flows through its integral diode 80. When the lower switch Q2 closes the current still flows through upper integral diode 80; therefore it recovers at a full DC bus voltage through a forced recovery process, which is harsh. This forced recovery process causes a momentary short circuit condition with a high current spike (labeled in line 105 of FIG. 8) and may lead to a device failure.


The same behavior applies to the lower switch of FIG. 6.


The following can be observed for a capacitance condition:


1. When upper switch Q1 is driven “Off” the current through the inductor 41 flows into the upper switch integral diode 80 due to current direction reversal that occurs before the excitation ends.


2. The bridge will stay at Vdd level until the collapse of the current flowing from the inductor 41 to the integral diode 81 or until the lower switch Q2 is driven into conduction.


3. If the lower switch Q2 is driven into conduction while the upper switch internal diode 80 is still carrying current, it will be driven into a harsh recovery which may damage the device.


4. The same phenomenon can be observed at the lower switch Q2 conduction period.


The problem of simultaneous conduction caused by a harsh recovery is commonly corrected by inserting an intentional dead time which is a period in the cycle in which none of the switches are driven into conduction. The dead time should be long enough to provide protection for the switching devices, but, on the other hand, inserting a large dead time will deteriorate the performance of the bridge by limiting the duty cycle. It also limits the ability of the bridge to operate near resonance. Thus, the common solution is a compromise offering insufficient protection at the cost of limited performance.


In accordance with the invention, a variable dead time is provided that adapts itself to circuit needs. This dead time is termed a “dynamic dead time.” The dynamic dead time is achieved by sensing the point where the current collapses to zero in a capacitive case. There are four variants:


1. Sensing the current through the inductor 41 by a current transformer or a shunt resistor in series therewith.


2. Sensing the current through the switching devices Q1 and Q2.


3. Sensing the bridge voltage.


4. Sensing the rate of rise (dv/dt) of the bridge voltage.



FIG. 9 shows the use of a current sense protection circuit in which a current transformer 110 is provided to monitor the bridge current. FIG. 9 also shows the control module 111 which provides the LO and HO outputs to MOSFETs Q2 and Q1 respectively. This current measuring function can also be carried out by current transformers (not shown) in series with Q1 and Q2 or by the shunt resistor 112 in the Vss Bus. These current measurement devices are then connected to comparator 113 in control module 111. Any “ringing” sensed by comparator 113 close to the end of the current conduction period can be controlled by a regenerative circuit such as a Schmidt trigger, a flip-flop or a bus-holder.



FIG. 10 shows the circuits of FIGS. 6 and 9 modified for a voltage sense protection mode. Thus, in FIG. 10, a connection is made from node 35, through resistor 115 to comparator 111.


The operation of the circuit of FIG. 10 is described in the following:


1. An inversion of the bridge voltage at node 35 occurs at the point that the current collapses to zero in a case of “capacitive” operation of the bridge (line 103 in FIG. 8).


2. That inversion is sensed by means of a voltage comparator (line 102, FIG. 8). A dead time is inserted from the period of the switch being closed till the inversion of bridge voltage (line 102, FIG. 8).


3. Any “ringing” sensed by the comparator 113 near the end of the current conduction period can be controlled by a regenerative device such as a Schmidt Trigger or flip-flop or a bus holder (not shown).


4. When the bridge operates in an inductive zone (FIG. 7) the inversion of the voltage occurs immediately after closing a switch; and therefore a dead time is not inserted.



FIG. 11 shows a dv/dt sense protection scheme which provides a capacitor 117 coupled from node 35 to a logic gate 118 within control module 111. A control module connection is provided from resistor 119 to a node between diodes 120 and 121.


The circuit of FIG. 11 is a modification of the voltage sensing control of FIG. 10 and is suitable for digitally controlled DC/AC Bridges. This embodiment uses a logic gate 118 instead of the comparator 113, which is basically an analog device.


As long as the voltage is rising a current flows through the sensing capacitor 117 and is clamped to VCC. At a falling voltage capacitor 117 is clamped to the control circuit. When the voltage of the bridge does not rise or fall, the input of the logic gate 118 might float and, therefore, it is held to an appropriate value by the control logic.


It is possible to use a continuous reactive load protection arrangement in which the DC/AC bridge of FIG. 6 is operated in a continuous capacitive regime, rather than providing protection only.


When the dead time is being determined automatically by the current or voltage commutation, the operation of the bridge tends to be irregular, which means that the bridge might be driven into asymmetrical operation and the current waveform will be irregular.


A simple case of such an irregularity is shown in the wave forms of FIG. 12 which shows the curves of FIG. 8 but containing the irregularity.


This irregular operation could be corrected by using the previous (measured) dead time to predict a minimum dead time for the cycles to come, and sense the current or voltage afterwards, as shown in, FIG. 13.



FIG. 14 shows a specific circuit diagram of a voltage sense protection system for a fluorescent lamp ballast (FIGS. 3 and 10) in conjunction with a specific ASIC 130 for providing all control signals.


In FIG. 14, the inversion of the bridge voltage at node 35 is sensed by an internal voltage comparator (within ASIC 130) at Pin CT and is used by internal logic to expand the dead time.


Note that the voltage sensing method shown in FIG. 14 overcomes delays caused by bus capacitance in the capacitive lead detection circuits.



FIG. 15 is a block diagram of the ASIC 130, which will later be more specifically described. FIG. 16 shows the full control module, including the circuits of FIGS. 14 and 15.


IV. The DC to AC Inverter Bridge for Non-Linear Loads.


The following describes a novel process for operating the DC to AC inverter bridge of FIG. 6, which drives a non-linear, resonant, and time varying load, for example, electronic ballasts for low-pressure and high pressure lamps, resonant power supplies, laser power supplies, and the like.


There are two common control methods in use; pulse width modulator (PWM) and frequency modulation (FM) control. Both methods provide only partial solutions for the problem that those power supplies present. The problem arises when the control circuit tries to achieve a goal of low light level (for example, very low dimming) at a small current. Trying to reach a low current using a PWM circuit could drive the DC/AC bridge into the capacitive area and can lead to the destruction of the power switches Q1 and Q2. On the other hand trying to do so by varying the frequency usually leads to an irregular light output (rings or snakes in fluorescent lamps) and instability.


Although not shown in FIG. 16, the various modules in ASIC 130 are interconnected within the ASIC (see FIG. 15) to a central logic supervisor. The central logic supervisor controls the overall operation of ASIC 130 by facilitating communications and passing data between modules.


According to the control method of the invention, both pulse width and frequency modulation are employed and are constantly varied in order to dim the lamp and/or to maintain a high quality control regime. The goal is to work as close as possible to resonance but to be at the inductive behavior shown in FIG. 7, under transients, lamp aging, malfunctions, use of a non-compatible lamps, etc. The novel method is combined with a center tap protection solution that prevents, “pulse by pulse”, being accidentally reflected into the inverter's bridge as the capacitive load, shown in FIGS. 12 and 13.


The novel algorithm for controlling the bridge when used for dimmable electronic ballasts, controls the preheat, ignition and dimming control functions. In a particular case, at high light levels a constant width pulse is used for the lower switch Q2 of the bridge, and a pulse of variable width is used for the upper switch Q1. This control scheme is shown in FIG. 17 which shows light level as a function of pulse width Ton for the high side and low side switches Q1 and Q2 in FIGS. 6 and 14 to 16. At the present time, low side curve 141 is employed for constant pulse width, but any of the alternates curves 142 can be used. FIG. 17a further explains the high side switch behavior shown in FIG. 17. In FIG. 17a, the terms shown are defined as follows:

    • T—Full period of the half bridge
    • T1—High side switch reverse current time
    • T2—High side switch “legal direction” conduction time
    • T3—Low side switch conduction time


As explained above, the aim of the half-bridge drive algorithm is to keep the half-bridge load inductive but close to resonance at all operation regimes.


The novel method is to drive the switches under reverse (parallel diode) conduction, when switch voltage is close to zero. For example, the high side drive rising edge must come during the T1 time frame.


The algorithm must keep time T1 short in order to be close to resonance but never zero or negative which is the expression for capacitive load to the half bridge.


Through all operation regimes, the algorithm provides high and low side drives that preserves a short fixed T1, during steady state conditions. If however, during transients the T1 shortens and gets close to zero, then, the center tap mechanism will bring it back to a safe length or duration.


In addition, the dead time between upper and lower switch operation is controlled simultaneously. For low light levels, this method is too coarse and a method of variable width is simultaneously applied also to the lower switch Q2 operation.


As a general rule, the novel method allows independent control of each one of the bridge switches Q1 and Q2 (or pairs of switches in case of full bridge) in a zero voltage switching full protected mode.


The stability of the control is achieved by changing the time constant of the DC/AC bridge control through the different operation regimens. A small time constant is used (fast control) when the light level is changed on request and a larger time constant (slow control) is used at steady state (fixed) light control. This method avoids overshoots or undershoots and light fluctuations respectively.


The ASIC 130 of FIGS. 14, 15 and 16 carries out the control scheme described above. A further block diagram of the silicon topology that controls switches Q1 and Q2 of the bridge, including center tap protection is shown in FIG. 18. FIG. 19 shows the control pulses produced by the circuit of FIG. 18 on a common time base.


The following is a description of the operation of the block diagram of FIG. 18 and the curves of FIG. 19.


1. A lamp current sample is provided to microprocessor 160 through A/D converter 161 (also included in ASIC 130).


2. Microprocessor 160 processes all information and provides one DATA BUS 162 that includes all processed information (PLC, PFC, DC/AC).


3. Selector 163 latches appropriate data into the appropriate LATCH 164 and 165. The rate of relatching is a decision or default of the software.


4. Counters “High Side PWM LOGIC” and “Low Side PWM LOGIC” together create the HIGH SIDE waveform (FIG. 19) that can be described as a pulse train. The pulse width is determined by “HS DATA” and “LS DATA” which determine the time between pulses.


5. The HS waveform is fed into AND1 gate 168. Fixed dead time and also variable dead time (determined by the center tap input) is added to the waveform which then exits through the HSDV (High Side Driver) output 169.


6. The waveform is also inverted by NOT3 gate 170 and fed to AND2 gate 171. Fixed and variable dead time is added to the waveform which then exits through the LSD (Low Side driver) output.


7. NOT1 and NOT2 gates 173 and 174 respectively avoid the possibility of the 2 outputs HSD and LSD respectively being both “High” at the same time.


8. Description of center tap protection circuit:


The outputs of AND1 an AND2168 and 171 respectively, are monitored. If there is no overlapping with the original waveform (as getting out from HS PWM Logic) for 16 consecutive pulses, then the 16 tries counter 176 increases by 1, enabling 4 consecutive cycles with no interrupting. If the same phenomenon repeats itself the 16 tries counter 176 continues to increase. If the phenomenon disappears the 16 tries counter 176 is reset.


If the 16 tries counter 176 reaches 16 it sends an “Abnormal” message to the microprocessor 160 and enters an abnormal protection regime.


It should be noted that the above technique is applicable to a full-bridge as well as a half bridge.


In order to achieve a smooth change of light output, a variable depth “dithering” technique is applied in the variable width pulse mechanism through the entire lamp dimming work line.


Thus, using a digital control for the upper or the lower switch pulse width by a simple PWM procedure will cause the light to flicker. To smooth the steps of the light control, a dithering method can be used. Thus, a PWM of an average level which lies between PWM steps (defined by an integer number) is composed of a mixed sequence of pulses made from these two time steps.


Precise light level control is achieved by measuring the lamp current only. This method is implemented by matching the current versus light-level non-linear curve into linear segments. Each segment enables a ratio between percentage of light-level and the lamp current, allowing a very precise light level control as shown in FIG. 20. This technique avoids the need for a complex lamp power or current measurement algorithm for each type of lamp to characterize the above non-linear behavior. Light control accuracy can be further increased by adding additional linear segments to the matched current versus light-level non-linear curve.


This method is implemented by using a dedicated parameter table that can be set or defined by the user. The above ratio is between the light level and the current at certain points (the extremes of each segment).


It is instructive to now summarize the principles adopted in algorithms used in the control method of the DC/AC inverter bridge for extreme non-linear AC load. Consider an extreme non-linear load, particularly for a gas discharge lamp that behaves like a negative impedance throughout most of its dimming range. These lamps have a transfer function whose gain varies between wide limits and it is therefore difficult to attain fast and smooth control. There are two common methods for controlling such a load through an AC bridge: pulse width modulation (PWM) and frequency (FM). Both are effective only within some sub-range of the load being controlled.


The control method described uses a PWM whose frequency and dead times are variable. It is applied in a half/full bridge topology: high side pulse width, low side pulse width with dead times between them are programmed and applied in a manner designed to achieve stable, smooth control loop throughout the whole range of no load to full load.


The method used suggests working near resonance at all loads but always keeping the load just a little above resonance. This is done first by providing best open loop control behavior (minimum gain variation) at every joint of the load regime. Pulse width and frequency are manipulated in a manner that achieves a constant open loop gain (sometimes the PWM is used to increase load current and the frequency used to decrease it and vice versa). These manipulations are performed according to the load V/I characteristics.


The following is an example of an embodiment in a ballast application. The control of dimmable discharge lamps over the full dimming range is based on a control range that is divided into three portions by two breaking points:


1. PWM control is used from minimum load to the first breaking point: the high side pulse increases and the low side pulse decreases. The total periodic time is kept at a fixed number.


2. Fix the low side and PWM the high side pulse from the first breaking point to second breaking point. The duty cycle is increased and at the same time frequency is decreased.


3. Frequency control is used from the second breaking point to maximum load both high side and low side pulses increase.


This method creates an open loop work-line with minimum gain variation and minimum predetermined dead time between pulses. This will best control a predictable load (e.g., a lamp with normal operating behavior). In order to prevent failures caused by unpredictable behavior of the load, the center-tap voltage of the bridge is sampled to ensure that switching is at zero voltage. Pulses are dynamically chanced to protect against destructive currents. Dead time is increased dynamically to the zero voltage point. This feature of the method enables working at high frequencies with very short predetermined dead time for a lamp with normal operating behavior. In addition, its permits increasing the dead time in the event of transients and changes in load behavior, for example, as the discharge lamps age.


V. A Digital Implementation of a Power Control Circuit.


The following describes various techniques employed in the novel digital approach to power management controllers, in particular to a dimmable electronic ballast. FIG. 21 shows the power line carrier (PLC) controlled dimmable ballast of layout similar to that shown in FIG. 16. The ballast control ASIC 200 is shown within the solid line block 200 in FIG. 20. PLC operation allows the ballast to receive dimming control information across the same power line being used to power the ballast. ASIC 200 is in turn schematically shown in FIG. 21A. The ASIC Pin assignments are shown in FIG. 22. The wall control unit (W.C.U.) schematics are also shown in FIG. 23. The techniques used in FIGS. 20, 21 and 22 are generally described as follows:


I. Feed Forward Dynamic Response Adaptation Based on Energy Consumption Prediction


The dynamic response of the control loop is “flexible”. It will use a different “dumping factor” & loop response time for a number of pre-decided conditions. For example the following decisions table is applied in the case of the electronic ballast:

    • If DC bus voltage is within the limits of Vref+−1% then “no response”;
    • If DC bus is within the limits of +−3%>Vref>+−1% then “slow” response;
    • If DC bus is within the limits of +−10%>Vref>+−3% then “fast” response;
    • If step light level+if under 90% of desired then fast response;


If input voltage step changed more than +−2% then fast response, etc.


If a large change of the light is desired, the desired light level is first given to the controller, as for example, going from full light to light off (transient mode), then the PFC operation mode will be switched to fast response in order to avoid DC bus dips. At constant light (steady state) the PFC control switches to slow response mode preventing light flickering/glimmering.


Limits, dumping factors and response times are parameters listed in predefined designer programmable tables.


The control can be adjusted to handle all kinds of applications, including motor control, temperature control and many others.


II. Programmable Parameter Tables


Tables of parameters are programmed for all possible regimes of the needed application. For example, in the electronic ballast case there are about 12 different regimes for the Dimmable Electronic Ballast, including:

    • DC bus soft start;
    • Auxiliary build up;
    • Lamp preheat;
    • Lamp ignition;
    • Up going light level;
    • Down going light level;
    • Step up light level;
    • Step down light level;
    • Steady state “high” load;
    • Steady state “low” load;
    • Abnormals—output power shut-down; and
    • Input voltage switched off—or “black outs.”


Every single regime has its own specific parameters table that is chosen when entering a new regime.


Each parameter table contains all the special parameters for PFC control and DC/AC bridge control for each specific regime. The designer can program these parameters.


In order to maintain a stable DC bus and the best PFC at all regimes, a digital control using programmable look-up tables gives the best “treatment” to each different regime (i.e. in the DC/AC bridge inverter control case the response time changes according to the lamp regimen operation).


With this approach, the more complicated the application, the more efficient the digital solution.


III. Adaptive Loop Parameters


Static and dynamic loop response adapt themselves to the inputs by getting feedback information from a number of digital and/or analog inputs chosen according to the right parameter tables, decision tables and addressed equations.


IV. Idle Periods Insertion to Change to Discontinuous Mode for Low Power Loads, Keeping Frequency Within Desired Limits


As loads get smaller, frequency gets very high and “ON” pulses have to be very short in order to preserve critical mode conduction. Under a certain load, critical mode becomes impractical. At this point the control changes to “Discontinuous” mode and it stops controlling the “ON” time and begins controlling the “OFF” time of the pulse. The “ON time” is fixed to a desired “minimum usable pulse” (programmable parameter). “Off time” can change between none and “Discontinuous mode maximum dead time” (programmable parameter).


V. A Method for Controlling the Converter at No Load Conditions by Means of Implementing a Special “Stand By” PWM Regimen Mode Using Dedicated Programmable Parameters Table


Special modes of operation can be “tailored” by using digital programmed control. All parameters, including: “pulse width”, time between pulses, burst parameters and other parameters can be assigned for a specific task.


One example of this ability is the “stand by” mode which we use for the electronic ballast.


This mode is operational any time the ballast output stage is inhibited and the PFC stage must carry on its operation in standby mode. At this mode the PFC stage has two tasks: first—to provide the auxiliary voltages 5V and 12V to the control and second—to keep the DC bus voltage within limits.


When the PFC stage has very small load, the DC bus capacitor will charge rapidly to a nominal limit and will inhibit PFC control pulses. Special parameters are used in order to allow the PFC stage to provide auxiliary voltages: minimum pulse width and fixed dead time between pulses. Another mode of operation is to change from controlling the DC bus (except for maximum) to controlling the auxiliary voltage to 12V.


VI. Protection Method by Combining Multiple Parameter Levels Using Programmable Tables.


The parameter tables also contain some limits to provide part of the protections. For example: control pulses will be inhibited (pulse-by-pulse) in case of DC bus over-voltage (the pulses are inhibited if the DC bus is higher than 110%). Also, if input voltage is above a certain predetermined limit, pulses will be inhibited. Input under-voltage is also monitored; the PFC control will go to power shutdown mode under a predetermined limit (over-voltage protection (OVP) in the present ASIC implementation).


The PFC theory and parameters, are described as follows:

















MinPFCParam



Max. PFC Ton pulse for Max load at Min Input RMS voltage



Ton = (255 − n)/12 MHz



100 1.29E−05 Sec



MaxPFCParam



Minimum usable Pulse for PFC control



125 4.17E−07 Sec



LowDelPrs



Discontinuous mode Maximum Dead time.



0 2.13E−05 Sec



HighDelPrs



At Critical mode only.



When getting ZC signal, waits 83 more nsec to activate PFC



switch.



254 8.33E−08 Sec



ShutHighDelPrs



Fixed Dead time in Shut Down mode.



150 8.75E−06 Sec



DampingFactor



1/Control Speed. control step = {[(Vref − VDC)/n] + 1} * 83 nsec



14



MaxVDC



Software ShutDown PFC Ton pulse will go off when VDC



crosses this reference.



245 439.5 Volt



VDCRef



2.19 Volt (A/D level) This is the normal VDC reference.



223 400 Volt



VdcHys1



Range of steady state. At VDCRef +/− n PFC Ton pulse will



not change.



2 3.6 Volt



VdcHys1



Demand for fast response, fast PWM at VDC +− VdcHys1 or



higher. When error is between VdcHys and VdcHys1, there



will be a slow response. PWM = Fast



14 25.1 Volt



PfcPWMPrs



Slow PWM response factor.



20



PfcPWM1Prs



Fast PWM response factor (0 when no PWM).



0



MinPFCStartUp



Soft Start. Width of PFC Ton pulse when dc bus voltage



climbs from zero to VDC.



253 1.67E−07 Sec



PFCTimerPRs



“Slow” Loop response = 100 mSec. Every 10 msec, counter



increased by 1.



10



PFCLoopCounterPRs



“Fast” Loop response = 1 mSec. Every 250 usec, counter



increased by 1.



4



Sampling rate of VDC



Fixed at 500 usec.










Linkage between PFC and DC/AC: for step new light, PFC is “FAST” up to 90% of new light, and then becomes “SLOW” between 90% and 100% of new light. “90%” is not included as a parameter.


When changing the light by “UP” or “DOWN” PFC control is always “SLOW”.














DcAc Parameters:









DcAcHys



Range for Fast/Slow response when Curr. Ref. is higher



then 75. When Curr. Ref. is lower then 75, there is only



slow response. Under 2 there is no change in Ton pulse.



2 is not included as a parameter.



5 1.96%



SlowDcAcPrs



Slow response PWM of 20 possible combinations of last and



next Ton (HSD). Pulse may change every 250 usec.



20



FastDcAcPrs



Fast response PWM of 5 combinations. Pulse may change



every 250 usec.



5



StartDcAcPrs



Response for DcAc StartUp (PWM) climbing to start up light



after ignition.



15



HSD



Ton pulse changes always through all workline points.



StartTon



HSD Ton Pulse for lamp ignition.



175 6.67E−06 Sec



StartTonTime



Duration of HSD Ton Pulses for lamp.



ignition = 2 * 250 usec = 500 usec



2 500 uSec



Very fast Climbing to StartTon with NOPWM.



AbDelayPrs



Wait after shut down Shut Down period.



200 2 Sec



ShutTimerPrs



Wait after shut down Shut Down period.



200 2 Sec



EBCurrentRef



Lower Current reference for lower power dissipation on



shunt resistor (EB).



51 1 Volt



LightLevel(6)



Table for IR Light decoding = n/2



“0, 2, 30, 80, 150, 200”  “0, 1, 15, 40, 75, 100”%



LightBasePrs(4)



Fix points on lamp curve - 15, 40, 65, 100% Lamp current must



be provided for each percentage point.”



“30, 80, 130, 200”  “15, 40, 75, 100”%



CurrentBase4



Volt 100% Light REFERENCE for ALL LIGHT LEVELS



227 2.23



MaximumLightLevel



Ballast Factor.



200 100%







Accessories Parameters:









MaxLightSensor



If n = 251 to 255 then occupancy switch closed.



250 2.45 Volt



MinStartDC



For DC control. If value is under 10(5%) then power



shutdown



10 5%







PLC Parameters:









NoiseHys1



Digital filter for PLC after summation stage.



10



GlobalZone



0



TrxFreq(4)



PLC frequencies. F = 3ee06/(64 − n)



“33, 34, 35, 36”  “96.77, 100, 103.44, 107.13” kHz










The following is a lead assignment and function description for the ASICS of FIGS. 15 and 21 and the control module of FIG. 16:













Pin
Electrical Data (VCC = 5 V)












No
Name
Function
Parameter
Value
Units










RESET, LINE SYNC, PROTECTION & P.L.C. PINS












1
RST
Reset Schmidt Trigger Input







Reset Input of the Control Module, Control Module is
pull-up
200
KOhm




in Reset state until Input reaches VIH level (2.2 X-3.5 V).




Reset action is automatic. Reset Initialization




Process is completed about 200 msec after Power on.





Capacitance
0.47
uF





Threshold
2.2-3.5
Volt


2
LINE
Line Phase Schmidt Trigger Input




Line Phase Input (see Ballast Platform Diagram for
Positive
2.2-3.5
Volt




connection manner of LINE pin).
Threshold





Negative Threshold
1-2.2
Volt





Frequency
47-63
Hz


3
SD
Shut-down Schmidt Trigger Input




Shut-down (Protection) Input for Abnormal Operation
Positive
2.2-3.5
Volt




Protection. When voltage goes high, LSD&HSD
Threshold




immediately disables for 2 seconds. The controller




tries to start the operation again at normal start-up




routine. If Abnormal situation still exists it will shut-




down again. After 10 attempts with 2 sec. intervals




between attempts, Half Bridge Drive signals (HSD &




LSD Outputs) are permanently inhibited (low level).




If No Failure Operation lasts above 2 seconds, the




Counter of 10 attempts resets (zero value).





Negative

Volt





Threshold





Min Pulse Width

uSec





Max Delay Time

uSec


4
PLC
Power Line Carrier Comparator Input




Power Line Carrier (PLC) Remote Control data input.
Frequency Range
95-105
KHz




The following operations can be done via PLC




Communication: Dimming, Ballast Turn on, Ballast




Turn off & Zone Select.





Threshold
1.67
Volt





pull-up
100
KOhm







PFC SECTION












5
ZC
Zero Current Schmidt Trigger Input







Zero Current (ZC) pulse (High to low edge) Switch-
Positive Threshold
2.2-3.5
Volt




On Time period.





Negative Threshold
1-2.2
Volt


6
PFCD
PFC Drive Digital Output




PFC Drive signal Drives the PFC switch driver.
Min High
4.5
Volt





Max Low
0.3
Volt





Max Sink
5
mAmp





Max Source
5
mAmp


7
CL
Current Limiter Comparator Input




Current Limiter Comparator limits (pulse-by-pulse)
Threshold
2.5
Volt




PFC Switch current by comparing PFC Switch Current




Sample to 2.5 V. When pin voltage exceeds 2.5 V




PFCD turns to low until the next PFC Cycle.





Pull-up
100
KOhm


8
REF
Current Reference Comparator Input




User Adjustable Current Reference Voltage compared
Max Ref.
0.4
Volt




to CL pin Voltage. Used to calibrate the PFC to




minimum Input Line Current THD.





Min Ref.
0.2
Volt





Pull-up
100
KOhm







POWER SUPPLY & REFERENCE SECTION












9
GND
GND Power Supply Input







The GND of the 5 VDC supply is also reference for all
Max Current
50
mAmp




Control Module signals


10
VCc
VCC Power Supply Input 5 VDC supply to the control
VCCmax
5.1
Volt




module





VCCmin
4.9
Volt





Ivcc max
44
mAmp







A/D ANALOG INPUT SECTION








General
All Analog Inputs are connected to 8 bit A/D Converter via 4 inputs Analog Selector. The A/D Reference



Voltage is 2.5 V. Input Voltage between 2.5 V to VCC converts to 255 Digital Value. The Digital Converted



Value is: #D = 255*VANALOG/2.5 (Integer 8 bits)












11
CNFG
Ballast Configuration Analog Input







Analog input is used to define 5 Ballast Configurations
DC Range
0-0.24
Volt




by different Voltage Level Limits. See Configuration




Table 1 for details. CNFG Voltage is sampled during




Reset Initialization Process to determine Ballast




Configuration. CNFG Pin is ignored during Ballast




operation after the initialization.





Occupancy
0.25-0.73
Volt





PLC Range
0.74-1.22
Volt





Local Range
1.23-1.71
Volt





E.B. Range
1.72.2.5-1.71
Volt





Pull-up
100
KOhm


12
ZONE
Zone Select/Analog Input




Analog input used:




1) to define 8 Ballast Zone at PLC Configuration, by
Zone Range Width
0.25
Volt




different voltage Level Limits. See Zone




identification Table 2 and PLC D.E.B section for




detail





All Zone
0-0.25
Volt





Zone 1 Range
0.25-0.5
Volt





Zone 7 Range
1.75-5
Volt




2) to determine Light Level at DC configuration, by
Max Light
2.22
Volt




voltage Level See DC D.E.B. section for details





Zero Light
Parameter
digital




3) as Light Sensor Analog Feedback Input at Local
Max Level
2.2
Volt




Configuration. See LOCAL D>E>B> section for




details





Min Level
0.2
Volt




4) to determine Low Light Level at Occupancy




Configuration, by voltage Level. The % Light Level




is determined according to formula:




% Light = (VZONE 2.23) × 100




At Occupancy, ZONE pin is sampled at transit from




normal light to (non) occupancy. See Occupancy




D.E.B. section for details


13
VDC
PFC stage, output DC bus voltage Analog Feedback Input




Analog Feedback input for PFC output DC bus
0% Light
Customer




voltage. This voltage is Software Compared to

determines




2.23 VDC (the Converted Value Compared to #227)

the expected




predefined reference, to provide the DC/AC stage with

ILAMP




the required DC voltage. (The Feedback Loop

Voltage for




stabilizes the VDC Pin to 2.23 VDC.)

each of these






4 fixed points






(By PDK






Software)





15% Light





40% Light





65% Light





100% Light
2.23
Volt







DC/AC SECTION












15
HSD
High Side Switch Driver Signal Digital Output







5 V Pulse Modulated Drive Signal to High Side switch
Max Current
5
mAmp




of the DC/AC Driver





Min High
4.5
Volt





Max Low
0.3
Volt


16
LSD
Low Side Switch Driver signal Digital Output
Max Current
5
mAmp




5 V Pulse Modulated Drive Signal to Low Side switch
Min High
4.5
Volt




of the DC/AC Driver





Max Low
0.3
Volt


17
CT
Center Tap Voltage sample Schmidt Trigger Input




The Center Tap voltage sample from Half Bridge
Positive Threshold
2.2-3.5
Volt




center tap is used to keep Half Bridge at Zero Voltage




Switching mode and to match the HSD & LSD timing




to keep the Half Bridge Load's inductive character.





Negative Threshold
1-2.2
Volt







DIGITAL INPUTS









All Digital Inputs, except IR, are sampled during Reset Initialization Process and ignored during Ballast



operation after the Initialization














The following data is related to all Digital Inputs.
Min High
2.4
Volt




Pull-up is semiconductor type





Max Low
0.8
Volt


18
IR
Infrared Control Digital Input




Infrared Control Digital input signal used to control
Pull-up
7.5 to 8
KOhm




Light Level y Digital Code in LOCAL configuration




only.







SO-S3: Parameters Tables Select Digital Inputs












19
SO
Desired Parameters Table is selected by 4 bit
Pull-up
30 to 40
KOhm




hexadecimal.




Code 0-12 selects one of 13 Internal Predefined




Parameter Tables.




Code 13 selects EEPROM Parameter Table.




Code 15 selects Programming Mode of EEPROM




Parameters Table.




Code 14 is not applicable


20
S1


21
S2


22
S3


23
STP
Step-by-Step operation Digital Input.




Input enables Step by Step operation of the Ballast.
Pull-up
30 to 40
KOhm




Digital “low” activates Step by Step operation mode.




Momentary Digital “high” forwards to the next step.




Step 0 (Reset): Before any Digital “high” pulse to




STP Pin. No Drive pulses from PFCD, HSD & LSD




pins.




Step 1: Operates PFC stage operation only




Step 2: Operates Lamp Preheat




Step 3: Lamp Ignition & Steady State Operation


24
DLCTR
Inhibits Center Tap Protection. Digital Active Low




Input




Digital “Low” to DLCTR Pin Inhibits Center Tap
Pull-up
30 to 40
KOhm




Protection




Facility for Ballast development only. (Refer to PDK




Manual)








25
NOT APPLICABLE












26
LOD
Local Oscillator Driver Digital Output







Local Oscillator Driver 46.9 KHz fixed frequency
Max Current
5
mAmp




digital square wave is available immediately after




Reset.





Min High
4.5
Volt





Max Low
0.3
Volt





Duty Cycle
0.5





Frequency
46.9
KHz


27
TX
Parameters Programming Transmitter Digital Output




TX Pin is used as a transmitting output for RS232
Min High
4.5
Volt




Communication using Parameters Development Kit




(PDK, SI/PDK-02) during Programming Mode.





Max Low
0.3
Volt





Max Sink
1
mAmp





Max Source
1
mAmp


28
RCV
Parameters Programming Receiver Digital Input




RCV Pin is used as Receiving input for RS232
Min High
2.4
Volt




Communication using Parameters Development Kit




(PDK, SI/PDK-02) during Programming Mode.




RCV Pin is also used as Occupancy signal input at




Occupancy and Local configurations. (see Local




D.E.B. and Occupancy D.E.B. sections for details)





Max Low
0.8
Volt





Pull-up
30 to 40
KOhm









The following is a description of operating voltages and the like for the ASIC 200 and Control Module:












MAXIMUM RATINGS











Units
Max
Min
Parameter Definition
Symbol














V
5.5
−0.5
DC Supply Voltage (Referenced to
VCC





GND)


mAmp
50

DC Supply Current. VCC & GND
ICC





pins


V
vCC + 0.5
−0.5
Pick Inputs Voltage, Referenced to
Vout





GND (RST, LINE, SD, PLC, ZC,





CL, CREF, CNFG, ZONE, VDC





ILAMP, CT, IR, S0, S1, S2, S3,





STP, DLCTR, RCV.)


V
VCC + 1
−1
Pick outputs Voltage Referenced to
Iout





GND





(PFCD, HSD, LSD, DCLK,





PLCD, XMT.)


mAmp
+5
−5
Pick outputs Current
Iout1





(PFCD, HSD, LSD, PLCD)


mAmp
+1
−1
Pick outputs Current
Iout2





(DCLK. XMT)


mW
275

Power Dissipation
PD


° C.
+150
−55
Storage Temperature
Tstg


° C.
260

Lead Temperature
TL



















RECOMMENDED OPERATION CONDITIONS











Symbol
Parameter
Min
Max
Unit














VCC
DC Supply Voltage
4.9
5.1
V



(Referenced to GND)


ICC
DC Supply current, VCC & GND
36
44
mAmp



pins


Vin (A)
Analog Inputs Voltage
0
2.5
V



(CNFG. ZONE. VDC. VLAMP)


Vin (D)
Digital Inputs Voltage
0
VCC
V



(All other inputs)


Vout
Output Voltages
0
VCC
V



(PFCD, HSD, LSD, DCLK, PLCD,



XMT.)


TAMB
Ambient Temperature
0
70
° C.



















ELECTRICAL CHARACTERISTICS









VCC = 5 V unless Test Conditions are different



Parameter











Pin

Test

















Sec.
Type
Name
No.
Symbol
Definition
Min
Typ
Max
Units
Conditions










Power Supply


















Power Supply
VCC
10
UVLO
Under-voltage Lock
4.3
4.5
4.7
V
Vcc Applied,







Out voltage




Vcc Disabled






ICC
Supply current
39
43
47
mA







Reset

















Digital Input
RST
1
VRST
Pin voltage at steady
4.5
4.9
5
V







state






TRST1
Hard Reset Time (4)
65
100
150
mSec






TRST2
Total Reset Time (5)
165
200
250
mSec







Interrupt

















Schmidt
LINE
2
VIH
Positive going Input
2.5

3.5
V



Trigger Input



Threshold






VIL
Negative going Input
1

2.2
V







Threshold






FLINE
Operational Frequency
47
50/60
63
Hz







Protection

















Schmidt
SD
3
VIH
Positive going Input
2.5
2.7
3.5
V



Trigger Input



Threshold






VIL
Negative going Input
1

2.2
V







Threshold






SDPW
Minimum Pulse Width



uSec







to activate SD







protection







PLC Communication


















Comparator
PLC
4
VPLC
Voltage at PLC input
4

5
V
Open input



Input with



100k Pull-Up






PLC REF
Comparator Internal

1.67

V
Vcc = 5.0 V







Reference Voltage







PFC


















Schmidt
ZC
5
VIH
Positive going Input
2.5

3.5
V




Trigger Input



Threshold






VIL
Negative going Input
1

2.2
V







Threshold



Digital Output
PFCD
6
VOH
High level voltage of
4.5
4.9
5
V
10 pF load







PFC pulse






VOL
Low level voltage of
−0.3
0
0.3
V
10 pF load







PFC pulse






IO
Output Current Sink &

5

mA







Source



















TonMax
Maximum applicable
12.9(1)
66(2)
uSec







PFC Ton Pulse-Width




















TonMin
Minimum applicable

0.42

uSec







PFC Ton Pulse-Width



















ToffMax
Maximum applicable
21.3(1)
66(2)
uSec







PCF Dead time







(Discontinuous mode)


















Comparator
CL
7
CLREF
Current Limit

2.5

V




Input with



Comparator Internal



100k Pull-Up



Reference Voltage



Comparator
CREF
8
VCREF
Voltage at comparator
0.2

0.4
V
Adjusted by



Input with



input (Fine Tuning of




user



100k Pull-Up



Minimum THD)







A/D Analog Inputs Section


















Analog Input
CNFG
11
Vopen
Open Analog Input
4.5
4.9
5
V
open input







Voltage (Analog Input







with Internal 100k Pull-







Up)



Analog Input
ZONE
12
Voper
Operation Analog Input
0

2.5
V
set by voltage












divider



Analog Input
VDC
13



Analog Input
ILAMP
14







DC to AC Section


















Digital Output
HSD
15
VHSD
High level value of
4.5

5
V
10 pF load







HSD output






TonMax
High limit of HSD Ton
0.37

20.4
uSec
(3)







Pulse Width






TonMin
High limit of HSD Ton
0.37

20.4
uSec
(3)







Pulse Width






TonWU
Ton Pulse Width
0.37

20.4
uSec
(3)






TonIGN
Ton Pulse Width
0.37

20.4
uSec
(3)



Digital Output
LSD
16
VLSD
High level value of
4.5

5
V
10 pF load







LSD output






LSDTon
Ton Pulse Width
0.37

20.4
uSec
(3)



Schmidt
CT
17
VIH
Positive going Input
2.5

3.5
V



Trigger Input



Threshold






VIL
Negative going Input
1

2.2
V







Threshold







Digital Inputs


















Digital Input
IR
18
VIRO
Voltage at IR Open
4.8
4.98
5
V
open input



With Internal



Input



7.5K Pull-Up



Digital Input
SO
19
VDIO
Voltage at Digital Open
4.5
4.98
5
V
open input







Input



With Internal
S1
20



30K to 40K
S2
21



Pull-Up
S3
22




STP
23




DLCTR
24







Local Oscillator/Output Driver


















Digital Output
LOD
26
FLOD
Frequency of LOD

46.9

KHz








output






VLOD
Amplitude of LOD
4.5
5
5
V
10 pF load







output







Serial Communication Section


















Digital Output
XMT
27
VXMT
Amplitude Voltage of
4.5
4.98
5
V
10 pF load



7.5K Pull-Up



XMT output



Digital Input
RCV
28
VRCV
Voltage at RCV open
4.5
4.98
5
V
open input



5K Pull-Up



input





Notes:



(1)Numbers are subject to Customization



(2)Reaching its maximum value at Line Zero Cross, under Max Load and minimum input Line RMS voltage


(3) EEPROM Programmable Parameters. E1 Char.do


(4) C20 (See CONT_B.Sch) Charge Time to Schmidt Trigger Input Positive going Input Threshold (VIH).


(5) C20 Charge Time + Software Delay Time






The following is an operation description which describes control module 111 and ASIC 200 settings:


Customer Selectable Parameters for D.E.B. Applications


The customer can influence ballast behavior by determining several ballast parameters. Software is used to determine the ballast parameters. The customer parameters below describe these parameters.












Customer Parameters Table















Possible




No.
Parameter Name
Parameter Description
Range
Rational Range
Units










Frequency Parameters












1
Low Switch Ton
Required LSD Pulse







Width


2
Minimum High
Required Minimum



Switch Ton
HSD Pulse Width


3
Maximum High
Required Maximum



Switch Ton
HSD Pulse Width







Lamp Curve Parameters












4
Minimum Light
Expected Minimum







Lamp Current Sense




Voltage VILAMP(mim


5
15% Light
Expected 15% Lamp




Current Sense Voltage




VILAMP (15%)


6
40% Light
Expected 15% Lamp




Current Sense Voltage




VILAMP (40%)


7
65% Light
Expected 15% Lamp




Current Sense Voltage




VILAMP (65%)







Warm-up Parameters












8
Warm-up High
Required Warm-up






Switch Ton
HSD Pulse Width


9
Time
Required Warm-up




Time







Light Parameters












10
Minimum Light
Required Minimum %







Light Level


11
Start Up Light
Re







Ignition Parameters












12
Ignition High
Required Ignition HSD
 0.37-20.37
2-13




Switch Ton
Pulse Width


13
Ignition Time
Required Ignition Time
 0-25
0-25
mSec


14
Post Ignition
Required Post Ignition
 0.37-20.37
1-13



High Switch Ton
HSD Pulse Width










Parameters Tables Selection


The control module 111 contains 13 parameters tables in its PROM and one customer parameters table in its EEPROM. Only the manufacture can change the parameters of tables 0-12. The customer can program its own parameters in EEPROM Table 13 using a Parameter Development Kit (PDK).


Tables 0-3: Versions for two T8-32W (parallel configuration) lamps (120V line application). Tables 4-12: Versions for two T8-36W (parallel configuration) lamps (230V line application).


Of course, customization of internal parameter tables is possible. A desired parameter table is selected by combination of micro-jumpers S0, S1, S2, S3 (connected to S0-S3 pins) to create a hexadecimal number. Insert jumper for a logic “0”, and leave open for logic “1”. The Parameter Tables Selection Table below defines the selection of the desired parameters table.












Parameters Tables Selection Table












Table
S0
S1
S2
S3
Function















0
0
0
0
0
Select parameters from one of 13 Pre-Defined







Tables in the PROM


1
1
0
0
0


2
0
1
0
0


3
1
1
0
0


4
0
0
1
0


5
1
0
1
0


6
0
1
1
0


7
1
1
1
0


8
0
0
0
1


9
1
0
0
1


10
0
1
0
1


11
1
1
0
1


12
0
0
1
1


13
1
0
1
1
Select parameters from EEPROM Parameters







Table


14
0
1
1
1
Reserved for Internal Use


15
1
1
1
1
PDK Programming mode. Disable Ballast







Operation and enable EEPROM







Parameters Table Programming by PDK.










Selected Ballast Configuration Options: Selected via A/D Input CNFG


Control module 111 and ASIC 200 enable ballast operation in 5 different configurations as follows:


















PLC D.E.B.
Ballast is remote controlled from Wall




Control Unit with Power Line Carrier (PLC)




interface. In PLC configuration, the




ballast can be designated as belonging to




one of 7 different zones or as belonging to




all zones. Ballast zone designation is




selected via A/D input ZONE. (See PLC




D.E.B. Section below).



DC D.E.B.
Ballast is controlled from DC Wall Control




Unit via DC lines. (See LOCAL D.E.B.




Section below).



LOCAL D.E.B.
Ballast is controlled from local infrared




IR light & occupancy sensors. (See LOCAL




D.E.B. Section below).



Occupancy
Ballast is controlled from local occupancy



D.E.B.
sensor. (See occupancy D.E.B. Section




below).



E.B.
Non Dimmable Electronic Ballast. (See E.B.




Section).










The Ballast Configuration Table shows ballast configuration selection via the CNFG pin. To get the required configuration, connect a resistor between CNFG pin and GND.












Ballast Configuration Table















Oc-




Configuration
PLC
DC
cupancy
Local
E.B.





CNFG Voltage
0.73-1.22
0-0.24
0.25-0.73
1.23-1.71
1.71-2.5 


Range


Converted
 75-125
0-25  
25-75
125-175
175-255


Digital Value


Recommended
30 KΩ
0 Ω
13 KΩ
51 KΩ
130 KΩ


Resistor (5%)










PLC D.E.S.


Start Up


The ballast starts lamps at “last light level” (saved on the EEPROM). The light level stays in Last Light Level until a dimming command is sent from the wall Control Unit via PLC communication.


PLC Function


The ballast receives a 17-bit string from the Wall Control Unit (W.C.U.) via PLC Remote Controlled Communication. Bit allocation is as follows:


















1 bit
Start



2 bits
Control operation modes



3 bits
 7 Selected zones



6 bits
64 light level



4 bits
Check Sum



1 bit
Spare











The rate of communication is 1 bit per line cycle. PLC communication is synchronized to the line phase.


Ballast Zone Identification


Designation of the ballast zone identity (0-7) is implemented by providing a voltage in equal equidistant increments between 0 to 2.5V to the zone pin. The Zone Selection Table is shown below.












Zone Selection Table















Zone
All Zone
1
2
3
4
5
6
7





Center
0.125
0.375
0.625
0.875
1.125
1.375
1.625
1.875


Voltage


Voltage
0-0.25
0.25-0.5
0.5-0.75
0.75-1
1-1.25
1.25-1.5
1.5-1.75
1.75-2


Range










EEPROM Function


When “Line Disappeared” is detected, (via the line pin) the present light is saved as “last light level” in the EEPROM. When the ballast is switched on it will revert to this “last light level”. When “Table 15” (S0, S1, S2, S3=“1”) is selected, the EEPROM can be programmed to a desired parameters table. When Table 13 is selected, the parameters table is obtained from the EEPROM.


DC D.E.B.


Start Up


The ballast starts the lamps according to the last light level from the EEPROM parameters table and then increases or decreases to the DC controlled light level present in the ZONE pin. This DC level is applied from the DC control unit. The light level is related to ZONE pin voltage according to the following formula:

Light Level=(ZONE pin Voltage/2.23V)×Maximum Light Level


The maximum light level is obtained when the ZONE pin voltage is 2.23V (converted to 227).


The lamp light goes to 0 when the ZONE pin voltage drops under 110 mV. The Ballast starts-up when ZONE pin voltage exceeds 140 mV.


LOCAL D.E.B.


Start Up


The ballast will start the lamps according to the last light level saved in the EEPROM parameters table.


Local IR Function


The IR receiver output signal is connected to the IR pin.


The IR transmitter sends 8 codes: 5 Preset light levels, Up, Down and Off commands.


Light Sensor Function


The ballast light level is controlled by a light sensor connected via the ZONE pin. The ZONE pin is feedback input converted to a digital number and compared to the sensor reference value.


The Sensor Reference value is set to the light sensor (ZONE pin) value during reset initialization. In the case of constant voltage at the ZONE pin (open loop), the light level stays at the last light level (no error detected—Sensor Reference=ZONE pin voltage, and no dimming UP or DOWN command is generated).


The dimming command from the IR transmitter changes the sensor reference and changes the light level by a controlled close loop mechanism to get:


Light Sensor=New Sensor Reference.


Light Sensor voltage range is 0.2V to 2.45V.


Occupancy Function (at Local Configuration)


Two inputs serve the occupancy function:


The “Occupancy OFF” command uses the RCV pin. Logic “1” (open circuit) at the RCV pin detected as a “No Presence” and turns the ballast off. Logic “0” at the RCV pin is detected as “presence” and starts-up the ballast to last light value.


The ZONE analog input pin is also used as a “No Presence Inhibit”. If ZONE pin Voltage>2.5V then “No Presence” disabled. The ballast dims the light to the minimum light level.


After the occupancy sensor detects a presence in the room, the ballast returns to the last light level. There is no delay time between “No Presence” detection (by the control module) and the dimming operation.


Occupancy D.E.B.


Start Up


Ballast will start lamps according to last light level saved in the EEPROM parameters table.


Occupancy Function


The RCV pin series as a “Presence Detection” input. When “No Presence” detected (logic “High”-open circuit) at the RCV pins he ballast dims the light to the defined “Dim Light Level” on the ZONE pin. The dim light level is saved a the “No Presence Detected” moment according to following formula:

Dim Light Level=[Maximum Light Level]×[ZONE Voltage at Initialization Time]2.23V.


The ballast returns to the maximum light level after occupancy sensor detects a presence in the room (logic “0” at ZONE pin).


Note: There is no delay time between “No Presence” detection (by Control Module) and the dimming operation.


EB


Start Up


Ballast will start lamps to “Maximum Light Level”.


E.B. Function


The ballast operates only at the maximum light level. Dimming is not possible. As in all other configurations, the lamp current is stabilized by closed loop control via the ILAMP feedback input pin. The ILAMP pin voltage is 0.5V at the maximum light level situation.


Housekeeping/Protection Circuits


Four input pins of the control module 111 and ASIC 200 are used for the protection functions of the ballast.


The CL input is used for current limit protection of PFC switch. The PFCD output in (PFC Drive Pulse Signal) is pulse-by-pulse inhibited when the CL input exceeds 2.5V.


The VDC A/D input pin is used for closing the DC bus (PFC Output) loop and also as a hardware over-voltage protection sense input. (Input to analog comparator). The PFCD output is pulse-by-pulse inhibited when the VDC pin voltage exceeds 2.5V. Also, the VDC input is used for software over-voltage protection. Alternatively, the PFCD output is pulse-by-pulse inhibited (by software) when the VDC pin voltage exceeds 2.4V.


The CT input is used to keep the half bridge at a zero voltage switching (ZVS) operation. If the load becomes capacitive, the CT input will partially block the HSD or LSD outputs (increase dead times in order to keep ZVS operation). If the limitation causes total disappearance of HSD pulses 16 times, then 4 cycles are enabled without interfering with the CT input. This total cycle of 20 (16+4) will repeat itself 16 times and if the malfunction does not disappear, it will activate the abnormal function.


The SD input is used to sense catastrophic failures of the ballast. When the SD input exceeds the Schmidt Trigger positive going threshold (2.2V-3.5V) according to catastrophic ballast failure occurrence, then hardware immediately inhibits (shuts down) the HSD & LSD outputs and software activates the abnormal function. The controller will try to start-up the ballast again 2 seconds after shutdown. If no abnormal indication is detected 2 seconds after ignition of the lamps, the abnormal protection procedure automatically resets an internal failure counter. If the failure is still detected, the controller will try to start-up the ballast 10 times with 3 second intervals between attempts. After 10 tries, the HSD & LSD outputs will be permanently inhibited. CT protection is also monitored as a catastrophic failure.


An abnormal condition of CT protection initiates the same abnormal protection procedure.

Claims
  • 1. An electronic power controller for a gas discharge device, said power controller comprising: an input circuit adapted to provide input a-c power;an a-c filter connected to said input circuit;a rectifier bridge connected to said input circuit for producing an output d-c voltage from said a-c input power;an inverter circuit including a high side switch and a low side switch connected in series at a node and connected across the output of said inverter circuit;a load circuit connected to said node and including said gas discharge device;said high side and low side switches each having input control terminals energizable to turn them on and off and each having a parallel diode;a master control circuit for applying suitably timed control signals for alternately turning said high side and low side switches on and off; anda dynamic dead time control circuit in said master control circuit for insuring only a short interval between the end of current conduction by either said high side and low side devices and the beginning of conduction by the other by the control of the application of controls signals to their control terminals;said dynamic dead time control circuit being coupled to and monitoring at least one of the current in said resonant load, the current in said first and second switches, the output voltage of said rectifier bridge or the rate of change dv/dt of said bridge voltages and adjusting the application of turn on signals to said high side and low side switches for both capacitive and inductive operations.
  • 2. An electronic power controller according to claim 1, which further includes a PFC stage coupled between said rectifier bridge and said inverter.
  • 3. An electronic power controller according to claim 1, wherein: said gas discharge device has first and second filaments; and said resonant coupling circuit includes:an inductor and a capacitor connected in series with said first and second filaments;first and second windings coupled to said inductor; and first and second diodes connected in series with said first and second windings respectively and said first and second diodes respectively, whereby the disconnection of said device and said filaments from its fixture opens the output circuit from said inverter circuit.
  • 4. An electronic power controller according to claim 1, wherein said a-c filter includes a common mode inductor.
  • 5. An electronic power controller according to claim 4, which further includes: a monitor circuit coupled to said common mode inductor for sensing a high frequency ground fault current at a frequency greater than the frequency of said input a-c power to a ground connection; and acontroller circuit coupled to said monitor circuit to turn off the power to said inverter circuit when said high frequency ground current exceeds a preset value.
  • 6. An electronic power controller according to claim 5, wherein: said gas discharge device has first and second filaments;said resonant coupling circuit includes:an inductor and a capacitor connected in series with said first and second filaments;first and second windings coupled to said inductor;first and second diodes connected in series with said first and second windings respectively and said first and second diodes respectively, whereby the disconnection of said device and said filaments from its fixture opens the output circuit from said inverter circuit.
  • 7. An electronic power controller according to claim 5, wherein: said power controller operates at least two gas discharge units connected in parallel in a fixture, said gas discharge units each have first and second filaments;said resonant coupling circuit includes:an inductor and a capacitor connected in series with said first and second filaments;first and second windings coupled to said inductor;first and second diodes connected in series with said first and second windings respectively and said first and second diodes respectively, whereby the disconnection of all of said devices and said filaments from the fixture opens the output circuit from said inverter circuit.
  • 8. The device of claim 1, wherein said dynamic dead time control circuit comprises: a current transformer in series with said resonant load circuit to measure the current therethrough;and a comparator circuit operative to compare the output of said current transformer to a reference value to generate a dead time interval having a small value.
  • 9. The device of claim 1, wherein said dynamic dead time control circuit comprises: current transformer connected to said node which is operative to monitor the voltage at said node;and a comparator circuit operative to compare the output of said current transformer to a reference value to generate a dead time interval having a small value.
  • 10. The device of claim 1, wherein said dynamic dead time control circuit comprises: a dv/dt circuit coupled to said node operative to monitor the dv/dt at said node; and a comparator circuit operative to compare the output of said current transformer to a reference value to generate a dead time interval having a small value.
  • 11. An electronic power controller according to claim 1, wherein: said power controller operates at least two gas discharge units connected in parallel in a fixture, said gas discharge units each have first and second filaments;said resonant coupling circuit includes:an inductor and a capacitor connected in series with said first and second filaments;first and second windings coupled to said inductor;first and second diodes connected in series with said first and second windings respectively and said first and second diodes respectively, whereby the disconnection of all of said gas discharge units and said filaments from their fixture opens the output circuit from said inverter circuit.
Parent Case Info

This application is a division of 09/857,616 Jan. 2, 2002, U.S. Pat. No. 6,963,178 which is a 371 of PCT/IB 99/02087 Dec. 7, 1999 which claims benefit of 60/111,296 Dec. 7, 1998, and claims benefit of 60/111,235 Dec. 7, 1999 60/111,302 Dec. 7, 1998 60/111,332 Dec. 7, 1998 60/111,216 Dec. 7, 1998.

US Referenced Citations (13)
Number Name Date Kind
5063490 Maehara et al. Nov 1991 A
5287008 Pahr Feb 1994 A
5406471 Yamanaka Apr 1995 A
5469028 Nilssen Nov 1995 A
5500792 Song et al. Mar 1996 A
5569984 Holtslag Oct 1996 A
5598326 Liu et al. Jan 1997 A
5691605 Xia et al. Nov 1997 A
5757141 Wood May 1998 A
5877926 Moisin Mar 1999 A
6002213 Wood Dec 1999 A
6104147 Nakamura et al. Aug 2000 A
6707261 Ito et al. Mar 2004 B2
Foreign Referenced Citations (4)
Number Date Country
19639873 Jun 1997 DE
0469255 Feb 1992 EP
2298749 Sep 1996 GB
9009087 Aug 1990 WO
Related Publications (1)
Number Date Country
20050035729 A1 Feb 2005 US
Provisional Applications (5)
Number Date Country
60111322 Dec 1998 US
60111302 Dec 1998 US
60111296 Dec 1998 US
60111235 Dec 1998 US
60111216 Dec 1998 US
Divisions (1)
Number Date Country
Parent 09857616 US
Child 10939722 US