EP2538753A1 - Driver device for LEDs, and a method for providing electric current to LEDs - Google Patents

Driver device for LEDs, and a method for providing electric current to LEDs Download PDF

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Publication number
EP2538753A1
EP2538753A1 EP11170654A EP11170654A EP2538753A1 EP 2538753 A1 EP2538753 A1 EP 2538753A1 EP 11170654 A EP11170654 A EP 11170654A EP 11170654 A EP11170654 A EP 11170654A EP 2538753 A1 EP2538753 A1 EP 2538753A1
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EP
European Patent Office
Prior art keywords
buck converter
voltage
output
driver device
control
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Application number
EP11170654A
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German (de)
English (en)
French (fr)
Inventor
Harri Naaka
Hannu Vihinen
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Helvar Oy AB
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Helvar Oy AB
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Priority to EP11170654A priority Critical patent/EP2538753A1/en
Priority to CN201210211349.0A priority patent/CN102843821B/zh
Publication of EP2538753A1 publication Critical patent/EP2538753A1/en
Withdrawn legal-status Critical Current

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    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B45/00Circuit arrangements for operating light-emitting diodes [LED]
    • H05B45/40Details of LED load circuits
    • H05B45/44Details of LED load circuits with an active control inside an LED matrix
    • H05B45/48Details of LED load circuits with an active control inside an LED matrix having LEDs organised in strings and incorporating parallel shunting devices
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B45/00Circuit arrangements for operating light-emitting diodes [LED]
    • H05B45/30Driver circuits
    • H05B45/37Converter circuits
    • H05B45/3725Switched mode power supply [SMPS]
    • H05B45/375Switched mode power supply [SMPS] using buck topology

Definitions

  • the invention concerns generally the field of controllably feeding electric current to a number of LEDs (light-emitting diodes) for lighting purposes.
  • a number of LEDs light-emitting diodes
  • Especially the invention concerns a way of ensuring that high efficiency can be maintained, and the need for large and expensive inductive components can be avoided, even if a driver device leaves its user with considerable freedom concerning the number and mutual connections of LEDs to which the driver device will feed current.
  • LEDs and LED chains must be fed with electric current of controlled magnitude in order to maintain the emission intensity and color at desired values. It has become customary to equip a LED lighting arrangement with a so-called driver device, the task of which is to ensure that the voltage across the load that includes the LEDs remains at an appropriate value.
  • a buck converter is a popular choice as the basic building block of the driver device, because it combines relatively simple configuration with good efficiency and well-known operational principles.
  • Fig. 1 illustrates a known driver device 101, in which a buck converter is configured to feed electric current to a LED chain 102.
  • a DC voltage V in appears at the input terminals of the buck converter.
  • the point between the switch 105 and the inductor 106 is coupled to the cathode of a diode 108, the anode of which is coupled between the current-sensing resistor 107 and the second input terminal 104.
  • a capacitor 109 is coupled in parallel with the load, i.e.with the LED chain 102.
  • a control circuit 110 is configured to control the switch 105 on the basis of a current measurement, for the implementing of which the control circuit 110 is shown to have couplings to both ends of the current-sensing resistor 107.
  • the current-sensing resistor could also be somewhere else along a current path that carries the load current or a current directly proportional to it.
  • the control circuit 110 applies so-called current hysteresis control. This means that when, during the conduction period of the switch 105, the current through the load (which is sensed as the voltage across the current-sensing resistor 107) reaches a predetermined maximum value, the control circuit 110 opens the switch 105. The current through the load starts to decrease, and would ultimately decrease to zero, if the whole energy stored in the inductor 106 and the capacitor109 would be allowed to discharge. When the current has reached a predetermined minimum value, the control circuit 110 closes the switch 105 again and the cycle starts anew. The difference between the predetermined current maximum and minimum values is called the current hysteresis or ripple.
  • a large difference between the input and output voltages of the buck converter makes the conduction interval through the switch 105 short, so most of the time current flows through the diode 108 causing relatively high conduction losses.
  • a large input/output voltage difference also increases the switching frequency of the buck converter, which leads to increasing switching losses in the switch 105 (which is typically a field-effect transistor).
  • a driver device for light-emitting diodes, which driver device accepts a wide range of LED arrangements as a load, and is still capable of efficient operation and low losses.
  • a driver device is provided that can be built from affordable components and still matches a wide range of output specifications.
  • a versatile method for providing electricity to light-emitting diodes with high efficiency and wide applicability is provided.
  • the control principle according to embodiments of the invention can be easily coupled with a dimming arrangement, with which the desired lighting intensity of the LEDs can be varied.
  • a control unit can repeatedly issue on and off commands to the buck converter with a pulse frequency that is preferably higher than 100 Hz but significantly lower than the switching frequency of the buck converter.
  • the buck converter may apply current hysteresis control or some other control principle to provide electricity to the LEDs.
  • the relative lengths of the on- and off-periods determine the lighting intensity that a human observer will perceive.
  • Fig. 2 illustrates schematically a driver device 201 for light-emitting diodes or LEDs. It comprises a controllable first power source 202, which is configured to produce a first voltage at its output. The magnitude of said first voltage depends on a control signal that in fig. 2 comes to the first power source 202 from below.
  • the driver device 201 comprises a buck converter 203, which has an input coupled to the output of the first power source 202.
  • the buck converter 203 has an output for coupling light-emitting diodes thereto.
  • the LEDs are shown schematically as a block 204 in fig. 5 .
  • block 204 comprises for example a LED chain of N essentially equally dimensioned LEDs, so that in order to make the LEDs emit light, the voltage delivered to block 204 needs to equal N times the voltage drop across an individual LED.
  • the driver device 201 comprises a load voltage indicator 205, which is configured to produce an indication signal depending on a load voltage that is required by a load coupled to the output of the buck converter 203, and a feedback coupling 206 configured to couple said indication signal as a control signal to the controllable first power source 202.
  • Fig. 3 is a simplified general representation of a buck converter, known parts of which carry the same reference designators as the corresponding parts in fig. 1 .
  • Fig. 4 illustrates schematically the current i fed to the LED chain 102.
  • V D1 is the voltage drop across the diode 108.
  • V out t on t on + t off ⁇ V in - t off t on + t off ⁇ V D ⁇ 1
  • V in of which is 100 V
  • V out required of the buck converter
  • ⁇ i 70 mA
  • L 1 mH
  • V D1 0.7 V.
  • Curve 501 in fig. 5 illustrates how the switching frequency of the buck converter varies, having a maximum value over 350 kHz at the output voltage 50 V and dropping below 150 kHz when the output voltage approaches 90 V.
  • the purpose of the load voltage indicator 205 is to produce an indication signal depending on a load voltage required by block 204. If this indication signal or some unambiguous derivative thereof is used to control the controllable first power source 202, it is possible to vary the voltage V in in synchronism with variations in the voltage V out , so that there is always a predetermined voltage difference between them.
  • the driver device 601 comprises a comparator 605 that is configured to compare a voltage difference between the input and the output of the buck converter 203 to a target value, and to produce the indication signal as an indication of how much said voltage difference differs from the target value. Additionally the driver device comprises a feedback coupling 606 configured to couple said indication signal as a control signal to the controllable first power source 202.
  • the controllable first power source 202 is configured to produce the voltage V in so that its magnitude is dependent on the control signal
  • the effect of using the comparator 205 and the feedback coupling 206 is that the input voltage V in to the buck converter 203 is made to follow the voltage V out (which is essentially determined by the number of serially coupled LEDs in block 204) at a predetermined offset.
  • the configured effect of the feedback coupling 206 is to control the output voltage of the controllable first power source 202 so that the voltage difference between the input and output of the buck converter 203 remains within predetermined limits of a constant, and preferably equal to said constant. As we have shown above with reference to equation (9) and curve 602 in fig. 6 , this has the effect that the switching frequency of the buck converter 203 changes only relatively little even if the voltage V out required by block 204 varies within a relatively wide range.
  • V ctrl f sw ⁇ ⁇ ⁇ i ⁇ L ⁇ V out + V D ⁇ 1 V out + V D ⁇ 1 - f sw ⁇ ⁇ ⁇ i ⁇ L which constitutes an unambiguous definition of the voltage difference V ctrl as a function of the output voltage V out , if all other factors (including the switching frequency f sw ) on the right side of the equation are constants.
  • Fig. 8 illustrates in a slightly more detailed manner a driver device for LEDs according to an embodiment of the invention.
  • the first power source mentioned above the task of which is to produce the input voltage for the buck converter, is a switched-mode power supply. It comprises an inductive element, which here is the primary coil of a transformer 801, and a primary current switch 802 coupled in series with said inductive element. Repeatedly switching on and off the current through the inductive element according to a duty cycle causes energy to be repeatedly stored into and discharged from its magnetic field.
  • discharging energy takes place through a secondary winding of the transformer 801, and the discharged energy is converted into a voltage with the help of a diode 803 and a capacitor 804.
  • the duty cycle of the switched-mode power supply is configured to be proportional to the value of an indication signal indicative of how much the voltage difference of a subsequent buck converter differs from the target value, in a manner described in more detail below.
  • the input voltage of the buck converter appears across the capacitor 804, which constitutes the output of the switched-mode power supply.
  • the buck converter comprises a controllable switch 105 that has a conducting state, in which it is configured to conduct electric current from the output of the switched-mode power supply (here: from the positive electrode of the capacitor 804), and a non-conducting state.
  • the buck converter comprises also an LC circuit that comprises an inductor 106, a capacitor 109, and a flywheel switch (here: diode) 108.
  • the LC circuit is configured to receive electric current through the controllable switch into the inductor 106 during the conducting state of the controllable switch.
  • the LC circuit is also configured to deliver current from the inductor 106 into a loop comprising the inductor 106, the flywheel switch 108, and a load (here: LED chain 102) coupled to the output of the buck converter, during a non-conducting state of the controllable switch 105.
  • a load here: LED chain 102
  • the buck converter comprises further a control circuit 805, which is configured to repeatedly change the state of the controllable switch 105 based on a measured momentary current through the buck converter. Measuring the momentary current through the buck converter takes place in a current sensing resistor 107, which is here located so that the current goes through it both during the conducting state and during the non-conducting state of the controllable switch 105. More exactly, there is a current path from the positive output node of the first voltage source to the negative one, along which are the controllable switch 105, the inductor 106, the LED chain 102, and the current sensing resistor 107.
  • the diode that acts as a flywheel switch 108 has its anode coupled to the negative output node of the first power source and its cathode coupled between the controllable switch 105 and the inductor 106.
  • a capacitor 109 is coupled in parallel with the LED chain 102.
  • the comparator and feedback coupling are illustrated in the lower part of fig. 8 .
  • a diode 806 the anode of which is coupled to the positive node of the buck converter output, i.e. the point between the inductor 106 and the LED chain 102.
  • the cathode of the diode 806 is coupled to a capacitor 807, the other electrode of which is coupled to the ground potential of the buck converter. From the point between the diode 806 and the capacitor 807 there is a connection through a voltage divider 808 to the non-inverting input of a differential amplifier 809.
  • a sample of the voltage at the input of the buck converter is taken through a zener diode 810 and another voltage divider consisting of resistors 811 and 812.
  • the cathode of the zener diode 810 is coupled to the positive output node of the switched-mode power supply, i.e. to the anode of the diode 803.
  • the output of the differential amplifier 809 is configured to drive the LED of an optoisolator 813, the phototransistor side of which is coupled to a voltage controller 814 of the switched-mode power supply.
  • the voltage controller 814 is responsible for forming and delivering the switching pulses to the primary current switch 802 of the switched-mode power supply.
  • the switched-mode power supply that acts as the controllable first power source in fig. 8 comprises a transformer 801 that divides the switched-mode power supply to a primary side (leftmost part in fig. 8 ) and a secondary side (from the secondary coil of transformer 801 up to capacitor 804), with galvanic isolation between the primary and secondary sides.
  • the driver device of fig. 8 comprises a galvanically isolating signal transmitter (the optoisolator 813) for conveying the indication signal to the primary side of the switched-mode power supply.
  • Galvanic isolation may be advantageous or even mandatory in electric devices that leave it free for the user to select and connect the load, because it increases security against accidental or intentional failures in selecting and connecting the load.
  • the zener diode 810 sets the voltage difference, for which the symbol V ctrl has been used in the equations earlier, between the input and output of the buck converter.
  • the voltage dividers at the inputs of the differential amplifier 809 are selected so that as long as the voltage difference between the input and output of the buck converter is larger than or equal to V ctrl , the output of the differential amplifier 809 remains negative or zero.
  • the output of the differential amplifier 809 becomes positive, and lits up the diode in the optoisolator 813.
  • the differential amplifier 809 acts as the comparator that compares a voltage difference between the input and output of the buck converter to a target value; here the target value is the reverse breakdown voltage of the zener diode 810.
  • the differential amplifier 809 is configured to produce an indication signal indicative of how much said voltage difference differs from said target value, even if in this case this is literally true concerning only differences in the direction where the difference is smaller than said target value.
  • FIG. 9 illustrates a driver device according to an alternative embodiment of the invention, where the diode 806, the capacitor 807, and the voltage divider 808 are basically the same as in fig. 8 . However, the anode of the diode 806 is now coupled to an auxiliary inductor 901 that is inductively coupled with the inductor 106 of the buck converter. As a difference to fig. 8 , the coupling from the voltage divider 808 is now to the inverting input of the differential amplifier 809.
  • the non-inverting input of the differential amplifier 809 is coupled to the cathode of a zener diode 902, the anode of which is coupled to the ground potential of the buck converter. From the non-inverting input of the differential amplifier 809 there is also a coupling through a resistor 903 to a feed voltage V cc .
  • the output of the differential amplifier 809 is coupled to the cathode of the LED in the optoisolator 813.
  • the anode of said LED is coupled to the feed voltage V cc through a resistor 904.
  • the voltage across the inductor 106 is equal to the difference between the input and output voltages of the buck converter. Due to the close inductive coupling and the chosen polarities, the voltage across the auxiliary inductor 901 follows the voltage across the inductor 106, scaled with the relation of the numbers of turns in the inductors. This voltage charges the capacitor 807, the capacitance of which is large enough so that it retains the voltage also during the non-conducting periods of the controllable switch 105 (when the dotted end of the auxiliary inductor 901 goes negative).
  • the positive potential of the node between the diode 806 and the capacitor 807 in fig. 9 is directly proportional to the voltage difference between the input and output voltages of the buck converter.
  • the differential amplifier 809 compares a sample of this positive potential to a fixed reference voltage generated with the zener diode 902, fed from the feed voltage V cc through resistor 903. The larger the voltage difference across the buck converter, the more negative will go the output of the differential amplifier 809, and the brighter the LED will shine in the optoisolator 813.
  • the voltage controller 814 of the switched-mode power supply must be built so that the stronger signal it receives through the optoisolator 813, the more it decreases the output voltage of the switched-mode power supply.
  • figs. 8 and 9 illustrate the well-known fact that in electronics, a number of possible ways, circuit architectures, and component configurations can be presented to implement a desired functionality, even if no programmable components are used. It should be noted that various parts of the circuit solution, e.g. the sampling of the input and output voltages, the comparison, and the conveying of a feedback signal, can be independently implemented in various ways, without being limited to the combinations shown here. For example the inductive way of sampling the output voltage illustrated in fig. 9 could easily be combined with the other features as shown in fig. 8 , or inductive sampling could be used to replace the direct sampling of the input voltage of the buck converter illustrated in fig. 8 .
  • the galvanically isolating signal transmitter on the feedback path may become unnecessary.
  • the whole sampler and comparator circuitry would be galvanically connected to the primary side of the switched-mode power supply instead of its secondary side.
  • Fig. 10 illustrates an embodiment that offers even more versatility in the form of a functional block 1001 that may include or consist of programmable parts (although this is not a necessary requirement of the invention).
  • the components and circuit architecture of the switched-mode power supply and the buck converter are here shown as equal to those in figs. 8 and 9 , for reasons of simplicity.
  • Sampling the input and output voltages of the buck converter is shown to be done with first and second voltage dividers 1002 and 1003 respectively.
  • the comparator that is configured to compare the voltage difference between the input and output of the buck converter to a target value and to produce an indication signal indicative of how much said voltage difference differs from said target value, is included within the functional block 1001.
  • the functional block 1001 may comprise a microcontroller configured to execute a stored program.
  • a microcontroller configured to execute a stored program.
  • the stored program may be made to include all kinds of filtering functions and signal processing, for which additional analog circuit elements would otherwise be needed.
  • a program-executing microcontroller it is easy to implement e.g. the constant switching frequency embodiment of the invention, in which the target value of the voltage difference varies as a function of the magnitude of the output voltage of the buck converter (see fig. 7 ).
  • Fig. 11 illustrates another example of how applications of the invention are independent of particular circuit topology.
  • the parts of the switched-mode power supply as well as the (possibly microcontroller-based) comparator and feedback functions are similar to those in fig. 10 , but the buck converter has a slightly different topology.
  • the buck converter In accordance with the known operating principle of a buck converter, it still comprises a controllable switch 105 as well as an LC circuit comprising an inductor 106, a capacitor 109, and a flywheel switch 108.
  • the LC circuit is configured to receive electric current through the controllable switch 105 into the inductor 106 during a conducting state of the controllable switch 105, and to deliver current from the inductor 106 into a loop comprising the inductor 106, the flywheel switch 108, and a load (the LED chain 102) coupled to an output of the buck converter, during a non-conducting state of said controllable switch.
  • the buck converter comprises a control circuit 1102 that is configured to repeatedly change the state of the controllable switch 105 based on a measured momentary current through the buck converter.
  • the current path between the positive and negative output nodes of the switched-mode power supply now comprises the current-sensing resistor 107, the LED chain 102, the inductor 106, and the controllable switch 105 in this order.
  • the cathode of the diode that acts as a flywheel switch 108 is coupled to the positive output node of the switched-mode power supply, and the anode of said diode is coupled between the inductor 106 and the controllable switch 105.
  • the voltage at the output of the buck converter is sampled from between the inductor 106 and the LED chain 102 through the voltage divider 1101.
  • the control circuit 1102 which is configured to repeatedly change the state of the controllable switch 105 between conducting and non-conducting states based on a measured momentary current through the buck converter, is illustrated with a different reference designator than before, because the different circuit topology may require some (very straightforward) changes in e.g. its internal component values.
  • Different circuit topologies of buck converters, and the corresponding requirements for control circuitry, are as such known to the person skilled in the art.
  • the switched-mode power supply (or other circuit arrangement used as the controllable first power source) significantly longer than one switching period of the controllable switch in the buck converter.
  • changes in the input voltage of the buck converter should be relatively slow compared to changes in its output voltage.
  • Several approaches can be taken to affect the time constant.
  • the transfer function of the differential amplifier circuitry can be tuned by selecting the auxiliary components properly.
  • the voltage controller 814 of the controllable first power source may include filtering and integrating functions, and especially if a programmable entity is used as the functional block 1001 seen in figs. 10 and 11 , the timing of the control loop can be quite freely selected.
  • Fig. 12 illustrates some timing considerations.
  • a driver device operates under steady state conditions, until at the time T illustrated with a vertical line across the graphs, the number of serially coupled LEDs in its load is suddenly decreased for example by closing a lossless switch that short circuits a number of LEDs in the LED chain.
  • the load current had varied between its minimum and maximum values according to the principle of current hysteresis control, drawing a regular sawtooth pattern.
  • the input voltage to the buck converter which is illustrated in fig. 12 as the SMPS (switched-mode power supply) voltage, was steady and larger in magnitude than the output voltage of the buck converter.
  • controlling the switched-mode power supply aims at keeping the voltage difference between V in and V out constant, instead of e.g. keeping the switching frequency f sw constant.
  • the time scale of fig. 12 has been made artificial for reasons of graphical clarity; typically it could take thousands or even millions of switching pulses in the buck converter for the change to take effect and for the transition period to reach its end at time T'.
  • driver device to adapt to different numbers of serially coupled LEDs in the load is typically more useful in the sense that the same or a similarly built driver device can be used in a variety of applications, that differ from each other in the number of serially coupled LEDs that need to be driven.
  • a driver device is particularly well suited for applications where a controllable lighting intensity of the LEDs, commonly referred to as dimming, is desired. It is known that a dimming effect can be achieved by chopping the current delivered to the LEDs and varying the duty cycle of the chopping according to the PWM (pulse width modulation) principle.
  • the PWM frequency should be high enough so that the human eye does not perceive any flickering of the LEDs. PWM frequencies over 100 Hz are usually considered sufficiently high.
  • Fig. 13 illustrates a principle of dimming applied in a driver device according to an embodiment of the invention.
  • the buck converter comprises a control input for receiving on and off commands.
  • this control input was schematically shown as an input labeled PWM to the control circuit 805; in the embodiments of figs. 9 and 10 a corresponding input of the control circuit is shown as being coupled to the functional block 1001.
  • the driver device comprises a control unit with an output coupled to said control input of the buck converter.
  • the control unit can be easily implemented as a part of the functional block 1001.
  • control unit is configured to repeatedly issue on and off commands to the buck converter through its control input, in response to external commands indicative of a desired lighting intensity.
  • the external commands may come, for example, from a lighting control knob or button operated by a human user, or from an automaton that aims at adjusting the lighting intensity to match the brightness of light in the environment.
  • each PWM pulse means an on command and the trailing edge an off command.
  • the second line of fig. 13 is a reminder that the on and off commands related to PWM control mean activating and deactivating the whole switching process in the buck converter.
  • the controllable switch of the buck converter repeatedly changes between conducting and non-conducting states at the switching frequency of the buck converter, whereas between PWM pulses the controllable switch of the buck converter remains nonconductive.
  • the relative time scales that are illustrated have been selected for graphical clarity; in practice the buck converter may execute hundreds or thousands of switching pulses during each PWM pulse.
  • a pulse frequency of the on and off commands should be higher than 100 Hz in order to avoid perceivable flickering, and significantly lower than the switching frequency of the buck converter in order to ensure stabile operation.
  • PWM of current is an advantageous method for controlling the lighting intensity of LEDs, because the color of light emitted by the LEDs typically depends on the current.
  • the PWM method means feeding pulses of essentially constant current through the LEDs and not feeding any current to them between the pulses. This is illustrated schematically on the third line of fig. 13 , where the load current is seen to be zero between PWM pulses and oscillate (due to current hysteresis control) around an effective constant current value during each PWM pulse.
  • the relatively coarse zig-zag pattern seen in the drawing is a consequence of heavily exaggerating the relative width of the switching pulses of the buck converter in relation to the width of the PWM pulses (and heavily exaggerating the current hysterersis, i.e. the margin ⁇ i in which the load current is allowed to vary).
  • the load current graph will resemble a neat square wave.
  • the lowest line in fig. 13 emphasizes the fact that PWM control or other form of dimming should not interfere with controlling the input voltage that the switched-mode power supply or other kind of controllable first voltage source produces for the buck converter.
  • This voltage is called here the SMPS voltage for short.
  • the voltage delivered to the load i.e. the output voltage of the buck converter
  • the principle of controlling the SMPS voltage is zero. If one would stricly apply the principle of controlling the SMPS voltage on the basis of the difference between the input and output voltages of the buck converter, this would cause the SMPS voltage to drop between each SMPS pulse, and to raise back to its intended level during each SMPS pulse.
  • the control unit that executes PWM control (i.e. repeatedly gives the on and off commands to the buck converter) within a common integrated circuit with the comparator that implements the comparing of voltages between the input and output of the buck converter.
  • the common integrated circuit additionally includes the control circuit of the buck converter, which control circuit is configured to repeatedly change the state of the controllable switch in the buck converter between conducting and non-conducting states based on a measured momentary current through the buck converter.
  • Fig. 14 illustrates schematically a method for providing electricity to light-emitting diodes according to an embodiment of the invention. It comprises producing a first voltage as illustrated in step 1401, and using a buck converter to convert said first voltage into an output voltage that is coupled across a chain of said light-emitting diodes, as illustrates in step 1402.
  • an indication signal should be produced depending on a load voltage required by a load coupled to an output of said buck converter.
  • step 1403 illustrates comparing a voltage difference between the input of the buck converter and the output of the buck converter to a target value that may be constant or may vary e.g. as a function of the output voltage, as was explained earlier in association with equation (10).
  • Step 1404 illustrates producing an indication signal indicative of how much said voltage difference differs from the target value
  • step 1405 illustrates using said indication signal to control the magnitude of the first voltage.
  • step 1405 involves controlling the magnitude of said first voltage so that the voltage difference between the input and output voltages of the buck converter remains within predetermined limits of a constant, and preferably equal to said constant.
  • predetermined limits emphasizes the fact that no practically applied control is completely accurate, but aims at achieving a magnitude of the controlled quantity that is reasonably close to the target value. How close is reasonably close depends on the application environment, for example on the accuracy standards that the circuit arrangement should achieve.
  • the circuit arrangement used to produce the first voltage in step 1401 is a switched-mode power supply
  • an advantageous and easily implemented way of using the indication signal to control the magnitude of the first voltage is to make a duty cycle of the switched-mode power supply proportional to a value of said indication signal.
  • the method may comprise repeatedly switching the buck converter on and off at a frequency that is higher than what is needed to avoid perceivable flickering (e.g. higher than 100 Hz) but lower than a switching frequency of the buck converter. Forming the on and off commands to the buck converter at the PWM frequency for this purpose is illustrated in fig. 14 as step 1406.
  • the conducting and non-conducting periods of the flywheel switch are an exact complement of the non-conducting and conducting periods of the actual controllable switch in the buck converter, the additional switching pulses for the controllable flywheel switch are easily produced by inversion from the switching pulses to the actual controllable switch.
  • the load can comprise various networks of LEDs and LED chains.
  • the output voltage required of the buck converter is in each case the sum of voltage drops over the largest number of individual LEDs that together form a current path across the output of the buck converter.
  • Principles according to embodiments of the invention can be applied also in cases where there are multiple buck converters that all receive their input voltages from a common controllable first power source.
  • Another class of variations involves the way in which the current measurements are made, or more generally, how the generation of switching pulses in the buck converter is implemented.
  • Current hysteresis control based on measuring the current during both the conducting and non-conducting periods is only one alternative.
  • the current sensing resistor would be out of the inner loop of the buck converter, and consequently only measure the current during the conducting periods of the controllable switch 105.
  • the length of the non-conducting period is a function of only the output voltage of the buck converter, it is easy to time the beginning of the next switching pulse by applying a non-conducting period of calculated length (taken that the circuit element that forms the switching pulses is made conscious of the present output voltage, for example with a connection from the voltage divider 1101).
  • the driver device may comprise a reader unit configured to read the required load voltage from the connector and use it to form the indication signal.

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EP11170654A 2011-06-21 2011-06-21 Driver device for LEDs, and a method for providing electric current to LEDs Withdrawn EP2538753A1 (en)

Priority Applications (2)

Application Number Priority Date Filing Date Title
EP11170654A EP2538753A1 (en) 2011-06-21 2011-06-21 Driver device for LEDs, and a method for providing electric current to LEDs
CN201210211349.0A CN102843821B (zh) 2011-06-21 2012-06-21 用于led的驱动器设备以及用于向led提供电力的方法

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Application Number Priority Date Filing Date Title
EP11170654A EP2538753A1 (en) 2011-06-21 2011-06-21 Driver device for LEDs, and a method for providing electric current to LEDs

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EP2538753A1 true EP2538753A1 (en) 2012-12-26

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EP11170654A Withdrawn EP2538753A1 (en) 2011-06-21 2011-06-21 Driver device for LEDs, and a method for providing electric current to LEDs

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EP2654385B1 (en) 2012-04-17 2017-11-08 Helvar Oy Ab An apparatus, a method, an arrangement and a computer program for controlling operation of a power supply circuit
EP3370479A1 (en) * 2017-03-01 2018-09-05 Helvar Oy Ab Method and circuit for protecting leds from transient currents
EP2974547B1 (en) * 2013-03-13 2018-10-17 Cree, Inc. Lighting apparatus and methods using switched energy storage
CN111096077A (zh) * 2017-09-13 2020-05-01 赤多尼科两合股份有限公司 用于电气负载的操作设备和方法

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Publication number Priority date Publication date Assignee Title
EP2654385B1 (en) 2012-04-17 2017-11-08 Helvar Oy Ab An apparatus, a method, an arrangement and a computer program for controlling operation of a power supply circuit
EP2974547B1 (en) * 2013-03-13 2018-10-17 Cree, Inc. Lighting apparatus and methods using switched energy storage
GB2514642A (en) * 2013-04-28 2014-12-03 Tridonic Gmbh & Co Kg Regulator, converter and controlling method
WO2016110396A1 (en) * 2015-01-05 2016-07-14 Philips Lighting Holding B.V. Power supply for deep dimming light
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EP3370479A1 (en) * 2017-03-01 2018-09-05 Helvar Oy Ab Method and circuit for protecting leds from transient currents
CN111096077A (zh) * 2017-09-13 2020-05-01 赤多尼科两合股份有限公司 用于电气负载的操作设备和方法
CN111096077B (zh) * 2017-09-13 2022-08-30 赤多尼科两合股份有限公司 用于电气负载的操作设备和方法

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