EP3289828A1 - Circuit arrangement and method for decreasing the light modulation of at least one light source operated at a voltage - Google Patents

Abstract

The invention relates to a circuit arrangement and a method for decreasing the light modulation of at least one light source operated at a voltage, which voltage has an AC component that causes the light modulation, wherein the circuit arrangement is connectable in series with the at least one light source and is set up to measure an instantaneous value of the current through the at least one light source, wherein it has a current regulating device that regulates the current through the at least one light source, wherein the instantaneous value of the measured current through the at least one light source is usable as an actual value for the current regulating device and wherein a mean value of the instantaneous value of the measured current through the at least one light source is usable as a target value for the current regulating device.

Description

 description

Circuit arrangement and method for reducing the light modulation of at least one voltage source operated at a voltage

Technical area

 The invention relates to a circuit arrangement and a method for reducing the light modulation of at least one operated at a voltage light source.

background

 The invention relates to a circuit arrangement according to the preamble of the main claim.

For cost and space reasons converter or operating devices for light sources such as LEDs are increasingly designed so that they no longer completely smooth the changing pulsating ^DC voltage, which arises from the mains voltage after rectification, since this large storage such as electrolytic capacitors necessary which are expensive, bulky and unreliable in use. Rather, it is transferred to provide smaller energy ^¬ memory, which are cost effective or reliable executable. In addition, more and more is being adopted to provide several smaller instead of a single concentrated converter, which are then also assigned to only one part of the light sources. However, this results in the problem that the current is modulated by the ^{Lichtquel ¬} len with twice or multiple mains frequency, resulting in light emitting diodes as light sources to an unwanted light modulation. To defuse this light modulation, a simple ohmic resistor in series with the light sources is often sufficient. In order to eliminate the light modulation, it is known in series to the light sources a current agreed on a reserved by the light sources controlling linear regulator provided, which regulates the current through the light sources on a gleichmäßen current value vorzu as setpoint ^¬ give. As a result, however, much energy is lost in the respective peaks of the voltage supplying the light sources, which in turn is undesirable. Likewise uner ^¬ wishes is often that a desired value for the current through the light sources inside its transducer is fixed, or even inherently parameterized because such a setpoint then from the outside, z. B. when dimming, no longer accessible let alone changeable.

task

 It is an object of the invention to provide a circuit arrangement for reducing the light modulation of at least one operated at a voltage light source, the lent possible efficient and no longer has the disadvantage of regulating to a predetermined current linear regulator.

Presentation of the invention

The object is achieved with respect to the device according to the invention with a circuit arrangement for Verringe ^¬ tion of the light modulation of at least one operated at a voltage light source having a Lichtmodu ^¬ lation causing alternating component, wherein the circuit arrangement is serially switchable to the at least one light source and is set up, a current ^¬ value of the current through the at least one light source wherein it has a current control device which regulates the current through the at least one light source, wherein the instantaneous value of the measured current through the at least one light source is used as the actual value for the Stromreg geleinrichtung and wherein an average value of the instantaneous value of the measured current through the at least a light source is used as the setpoint for the flow control device.

As a result of this measure, the circuit arrangement according to the invention is particularly advantageously active only in the case of correspondingly large and rapid current changes, while at constant current it has a very low impedance and thus hardly consumes energy. Another advantage is the adaptability of the circuit arrangement according to the invention: Since it reacts only to changes in current, it can be used for any applications with a wide range of average and average currents in an unchanged circuit structure, in a particularly advantageous embodiment even with identical component values. The design is relevant only for the measure of the current change, not for the absolute magnitude of the current. This is applied in the dimensioning of the circuit, which is to be regarded as a "large" or "fast ^¬ le" current change. This depends on the respective application. When using a mains voltage, this current change will therefore be in the ms range, whereas it is more in the ys range in an application, for example on an electronic transformer and thus will be much faster. In a particularly preferred embodiment, the

Circuit arrangement an averaging device (17). So she can easily and elegantly average advantageous even from the instantaneous value of the current determ ^¬ men, and the average value does not have to be entered in the circuit ^¬ arrangement from the outside.

In another embodiment, the dung means Mittelwertbil- is a low-pass, and the average value of the ge ^¬ measured current through the at least one light source is formed by the low pass. This measure ensures a very simple, inexpensive and precise analogue ^averaging value. In a further embodiment, the flow control device further preferably comprises:

- a transistor having a reference electrode, a working ^¬ selektrode and a control electrode,

 - An operational amplifier with a positive input, a negative input and an output, wherein

- the output of the operational amplifier is coupled to the control electrode of the transistor ^¬,

- the instantaneous value of the current measured by the Minim ^¬ least one light source to the positive input of the Operati- is input onsverstärkers,

 the mean value of the instantaneous value of the measured current through the at least one light source is input to the negative input of the operational amplifier,

wherein the path between the working electrode and the reference electrode of the transistor is connected in series with the at least one light source. This measure is advantageous ^¬ a very simple, inexpensive and effective analo ^¬ ge embodiment of the circuit arrangement according to the invention. In a further preferred embodiment, the flow control device further comprises:

a transistor with a reference electrode, a working selektrode and a control electrode, wherein

- the instantaneous value of the current measured by the Minim ^¬ least one light source is input as a counter-voltage in the Bezugselekt ^¬ rode of the transistor,

- the mean of the instantaneous value of the measured current through the at least one light source to the control electrode of the transistor is inputted ^¬ de,

wherein the distance between the working electrode and Be ^¬ zugselektrode of the transistor is connected in series with the at least one light source. This measure beneficial ^¬ way represents a very simple, very cheap and effective analogue design of the circuit arrangement.

In another embodiment, the Schaltungsanord- voltage is arranged to measure the instantaneous value of the current through the at least one light source by means of a Strommesseinrich ^¬ tung, which is connected in series with the at least one light ^¬ source and to the distance between working electrode and reference electrode of the transistor. The provision of a current measuring device advantageously eliminates the need for an additional input through which the current value must be supplied from the outside.

When the current measuring device is an ohmic resistance, then the current can be measured by the light sources advantageously a particularly simple and cost-effective manner from the lining ^¬ processing arrangement itself.

In another embodiment, the circuit arrangement is a two-terminal, which can be connected in series at any point in the circuit of the at least one light source. This measure provides a particularly advantageous mush ^¬ tes application for the invention Schaltungsan ^¬ properly secure. In a further embodiment, the circuit arrangement has an integrated auxiliary voltage supply. With this measure, the circuit arrangement is even more universal, since it generates the internally required voltages themselves.

 It is particularly advantageous if the auxiliary voltage supply generates the auxiliary voltage from the voltage drop across the two-pole. Thus, the circuit arrangement consists solely of the advantageous two-terminal, which is particularly versatile.

In a particularly advantageous embodiment, the auxiliary voltage supply comprises a half-wave rectifier. This solution is particularly simple and inexpensive, since only one diode and one capacitor are necessary for this. In one embodiment, the at least one ^{Lichtquel ¬} le is an LED. LEDs are particularly efficient and an indispensable part of the lighting industry.

In another embodiment, the at least one light source is an OLED. Organic light-emitting diodes will play an increasingly important role in lighting in the future, and the circuit ^arrangement according to the invention is advantageously also suitable for this light source type.

The solution of the object with respect to the method is carried out according to the invention with a method for reducing the light modulation of at least one operated at a voltage light source, which voltage has an alternating component, wherein serially to the at least one light ^¬ source a current control circuit is provided, the actual value of the instantaneous value of the current is derived by the at least one light source, and their setpoint from an average of the instantaneous value of the current through the at least one light source is derived. Which the erfindungsge ^¬ Permitted method performing circuitry is already stated above, this measure particularly advantageous only with correspondingly large and rapid Stro- mänderungen active, while having a very low impedance at a constant current and thus hardly consumes energy.

 Further advantageous developments and refinements of the circuit arrangement according to the invention and of the inventive method for reducing the light modulation of at least one operated at a voltage

Light source will be apparent from further dependent claims and from the following description.

Brief description of the drawings

 Further advantages, features and details of the invention will become apparent from the following description of exemplary embodiments and with reference to the drawings, in which identical or functionally identical elements are provided with identical reference numerals. Showing:

Fig.l is a schematic block diagram of the inventive ^¬ circuit arrangement for reducing the

Light modulation of at least one light source in a typical application on a chain of serially connected LEDs, which are operated at a mains voltage.

2 shows a first embodiment of the circuit ^arrangement for reducing the light modulation of at least one light source with a PNP

Transistor as variable impedance, 3 shows a second embodiment of the circuit ^arrangement for reducing the light modulation of at least one light source with an NPN transistor as variable impedance, FIG. 4 shows the current through the at least one light source without the circuit for reducing the light modulation of at least one voltage operated light source,

Fig. 5 shows the current through the at least one light source with the circuit arrangement for reducing the

Light modulation of at least one operated at a voltage light source.

Fig. 6 shows a third embodiment which is similar to

 Arrangement of FIG. 3 is, however, with interchangeable component arrangement in series with the light source,

7 shows the basic circuit with only one Transis ^¬ gate as a fourth embodiment,

8 shows the circuit from FIG. 7 with saturation ^prevention , even with transistors connected in parallel, FIG. 9 shows the circuit from FIG. 8 with half-wave rectifier,

10 shows the reciprocal circuit of FIG. 9 with pnp instead of npn transistor as a fifth embodiment.

Preferred embodiment of the invention

Fig.l shows a schematic block diagram of the circuit arrangement OF INVENTION ^¬ to the invention 1 in a typical application to a chain of series-connected LEDs 5 that are operated at an alternating supply voltage UN. The network AC voltage UN is input to a full-wave rectifier 3 and converted into a pulsating DC voltage. This is applied to a chain 55 of serially connected LEDs 5. Between this LED chain 55 and the supplying them pulsating DC voltage, a converter 7 is connected, which operates the LEDs with the appropriate current. For converters with low storage capacity, for example, a part of the serially connected LEDs is bridged depending on the current voltage in order to be able to emit light in the network zero crossing. The storage capacity of the converter is selected so that a predetermined light modulation in Netznull ^¬ passage is not exceeded, since the voltage at the storage capacitor drops so far that the current decreases in the LED chain 55. In the following, the temporal change in brightness of the at least one light source 5, in this case the at least one LED 5, is referred to as light modulation. The change in the light brightness emitted by the at least one LED 5 is due to the change in the current through the at least one LED 5. Straight LEDs have, in contrast to classic incandescent lamps a very low inertia in the implementation of the input electric power in light and are therefore very critical regarding light modulation (see also

http: // en. wikipedia. org / wiki / Gl% C3% BClamp # light modulation).

With many operating devices, this results in a current profile which follows that of the voltage at the (very small) storage capacitor in the operating device 7. Since this current profile results in undesired light modulation, the circuit arrangement 1 according to the invention is connected in series with the LED chain 55 from the LEDs 5 and to the operating device 7. The circuit arrangement 1 has two connections and is thus a two-pole. The circuit arrangement 1 has a current control device 11 and a current measuring device 13, which are connected in series. The series circuit of the current control device 11 and the current measuring device 13 is coupled to the two terminals of the circuit arrangement 1. The first terminal of the circuit arrangement 1 is coupled to one end of the series circuit, the second terminal of the circuit arrangement 1 is coupled to the other end of the series circuit. Through the LED chain 55, a current ILED flows. Accordingly, this current also flows through the current regulating device 11 and the current measuring device 13. The current measuring device 13 measures the instantaneous value of the current ILED and transmits it as the actual value I i to the current regulating circuit 11 and to an averaging device 17. As instantaneous value of the time just ^¬ Lich currently measured value of the current ILED is referred to (see also http://de.wikipedia.org/wiki/Istwert). The averaging device 17 forms a moving average from the actual values of I i and forwards them to the current control device 11 as the setpoint value I s. In the following, the mean value over a certain period of time, which runs along with the current time, is regarded as the moving average (see also

http: // en. wikipedia. org / wiki / Gleitender_Mittelwert) The current control device 11 thus receives as the actual value, the instantaneous value of the current ILED and as the setpoint the moving average of the instantaneous value of the current ILED. It is thereby achieved that the circuit arrangement according to the invention intervenes in the case of strong current fluctuations and smoothes the current, while they are weak or slow

Power fluctuations do not or hardly intervene and thus causes little loss. The circuit arrangement 1 comprises wei ^¬ terhin nor an auxiliary power supply 15 which their Energy over the first and the second connection of the

Circuit 1 relates and provides an auxiliary voltage U _B for the current control circuit 11 is available.

Fig. 2 shows a first embodiment of the circuit arrangement for reducing the light modulation of at least one light source with a PNP transistor Ql as a variable impedance. The PNP transistor is part of the current regulating device 11 and controls the current through the LEDs 5 with its collector-emitter path. It is driven by the output of an operational amplifier U1 via a base resistor R17. The current ILED through the LEDs is converted by a shunt R2 into a measuring voltage which is input as the actual value I i into the positive input of the operational amplifier U1. The shunt R2 is thus the current ^¬ measuring device 13. This voltage is passed through a low-pass from the resistor R3 and the capacitor C2, and the voltage across C2 is input as a setpoint Is in the negative input of the operational amplifier Ul. The low-pass ^¬ from the resistor R3 and the capacitor C2 is thus the averaging means 17, which generates as a low pass filter moving average of the instantaneous value of the current ILED through the LED chain 55th The shunt R2 is connected to the collector of the PNP transistor Ql. The other terminal of the shunt R2 is connected to the second terminal of the circuit arrangement 1. The emitter of transistor Ql is connected to the first terminal of the scarf ^¬ processing arrangement. 1 The averaging device 17 consists of the low-pass filter with the components R3 and C2, wherein a connection of the resistor R3 to the first terminal of the shunt R2 and is connected to the collector of the transistor Ql, and the other terminal of the resistor R3 is connected to the capacitor C2 and the negative input of the operational amplifier Ul. The other terminal of the capacitor C2 is connected to the second terminal of the shunt R2 and to the second terminal of the circuit arrangement 1.

The circuit arrangement 1 also has an auxiliary voltage supply 15. The auxiliary voltage supply 15 has a decoupling diode D20 and a serially connected charging resistor R20. The first connection of this

Series circuit identical to the anode of the diode D20 is connected to the first terminal of the circuit arrangement 1. The second terminal of this series circuit is connected to one terminal of a capacitor C20 and to the positive supply terminal of the operational amplifier whose negative supply terminal as well as the other terminal of the capacitor C20 is connected to the second terminal of the circuit arrangement 1. Parallel to the capacitor C20, a Zener diode D21 is connected. By the voltage applied to the first terminal of the circuit 1, a current flows through the Auskoppeldio ^¬ de D20 and the resistor R20 in the capacitor C20 and charges him. The auxiliary voltage supply 15 thus comprises a half-wave rectifier, represented by the capacitor C20 and the decoupling diode D20. The voltage at Kon ^¬ capacitor C20 is limited by the parallel Zener diode D21. The voltage applied to the capacitor C20 voltage is used as a power supply for the operational amplifier Ul. How it works:

The current control device 11 controls, like all control devices, to the desired value Is, which is the average value of the LED. Electricity is ILED. So long as this LED current does not change greatly, the output of the operational amplifier Ul is at a potential near the reference potential of the Operationsver ^¬ amplifier Ul on. This potential is input to the PNP transistor through resistor R17 and leads to it

Turning on, which has the consequence that the impedance of the collector-emitter path of the transistor Ql is very low, and thus the circuit arrangement causes very little loss.

Now increases the LED current very strong, the instantaneous value I i of the LED current ILED is greater than the average value I s of the LED current ILED. The actual value is greater than the target value ^¬. Due to the unusual assignment of setpoint and actual value to plus and minus input of the operational amplifier Ul, the potential at the output of the operational amplifier Ul increases, instead of reducing as usual, and the transistor is successively high-impedance. Thus, the impedance of the collector-emitter path of the transistor Ql increases, and the current ILED through the LEDs becomes smaller. When the LED current ILED falls below its mean value, the circuit arrangement correspondingly reverses and controls its transistor successively at a lower impedance. Thus, the circuit arrangement 1 counteracts the current fluctuations of the LED current ILED and equalizes them.

Fig. 3 shows a second embodiment of the circuit arrangement for reducing the light modulation of at least one light source with an NPN transistor as a variable impedance. The second embodiment is similar to the first embodiment, in principle "horizontal". gelt ", therefore, only the differences from the first embodiment will be described.

The second embodiment uses, instead of the PNP transistor, an NPN type in the current regulating circuit 11. As a result, the current measuring device 13, which is in

Series connected to the collector-emitter path of the NPN transistor Ql and the collector of this transistor verbun ^¬ is, now connected at its other end to the first terminal of the circuit arrangement 1, so seen in the classic voltage direction "above" the The reason for this is the fact that the now used as variable impedance NPN transistor is to drive with positive base current, which is why in connection with the base resistor R17 the output potential of a correspondingly interconnected Operations ^¬ amplifier above all potentials of the transistor Ql Since both input potentials of said operational amplifier are directly or indirectly coupled to the current measuring device and the output of the same operational amplifier drives the variable impedance, that is to say the transistor Q1, it is close due to the rather short auxiliary voltage UB, the same Minimize clock suppression in the operational amplifier and to put the entire circuit mimic on that side of the transistor Ql, from which side of his drive must come: Namely from above. The emitter of the NPN transistor Q1 is connected to the second terminal of the circuit arrangement 1.

At the connection point of the shunt R2, which again represents the current measuring device 13, and the collector of the transistor Ql, the instantaneous value of the current I LED is again measured by the LEDs 5. This point is in turn connected to a low-pass filter from the components C2 and R4. This low-pass filter in turn represents the averaging device 17. A first terminal of the capacitor C2 is connected to the first terminal of the circuit arrangement 1. The second terminal of the capacitor C2 is connected to the first terminal of the Widerstan ^¬ of R4 and the negative input of the operational amplifier Ul. The second terminal of the resistor R4 is connected to the collector of the transistor Ql and to the positive input of the operational amplifier Ul.

Also, the auxiliary voltage supply 15 is dual in comparison with the first embodiment. The capacitor C5 and the cathode of the parallel-connected Zener diode D3 are connected to the first terminal of the circuit arrangement 1 and to the positive terminal of the power supply of the operational amplifier Ul. The other terminal of the parallel circuit is connected to the first terminal of the resistor R5 and the negative terminal of the voltage ^¬ supply of the operational amplifier Ul. The second terminal of the resistor R5 is connected to the anode of the diode D2, the cathode of the diode D2 is connected to the second terminal of the circuit arrangement 1 and the emitter of the transistor Ql. The auxiliary power supply 15 thus comprises again a peak value rectifier, represented by C5 and D2, but which here works "suction": The diode D2 sucks the potential at the connection ^¬ point to capacitor C5 whose second point is fixedly connected to the first terminal of the circuit arrangement 1 The circuit arrangement 1 of the second embodiment operates analogously to the circuit arrangement 1 of the first embodiment, in a dual manner The operational amplifier acts in a reverse manner and controls the NPN transistor of this embodiment again accordingly, so that this at low current changes of the current ILED remains low-ohmic through the LEDs 5, while it successively becomes more highly ohmic in the event of faster and stronger changes of the current ILED by the LEDs 5. The constant input assignment of the operational amplifier in both embodiments is due to the fact that not only its input signals but ge ^¬ nauso also the output signals in the second embodiment to those in the first negative exactly. Further embodiments not illustrated arise through the use of so-called open-collector amplifiers, or by exchanging the order of current Regels circuit and current measuring device.

For example, the second embodiment illustrated in FIG. 3 and described above in detail is preferably suitable for using an open-collector amplifier instead of the operational amplifier and the NPN transistor, which thus represents the entire current-regulating circuit. Its special feature is that an output current can only flow into its output, and that at the same time the output current flows out at its negative supply connection. Said output current can be, for example, the current to be regulated ILED.

This second embodiment "reflected back" gives its equivalent, which consequently resembles the first embodiment shown in Fig. 2. This should be mentioned for the sake of completeness, since open-collector amplifiers with one at their Output integrated PNP transistor as good as not in use.

Both variants with open-collector amplifiers necessarily require the order shown in Fig. 2 or 3 between current measuring device and current control circuit.

This compulsion is eliminated as soon as power amplifier circuits are fully operational amplifiers with discrete transistors driven by their outputs via a base resistor as effective variable impedance in use.

Then, in contrast to the figures 2 or 3, the respective current measuring means may also be connected to the emitter of the transistor acting as a variable impedance. Regardless of the polarity of the transistor itself then applies, however, that the instantaneous value of the LED current I LED is to be led to the inverting input, ie the negative input of the operational amplifier, and that the mean ^¬ value of the same current to the non-inverting input , So is to lead to the positive input of the operational amplifier.

4 and 5 show the effects of the circuit arrangement on the current through the LEDs 5 and the LED chain. Fig. 4 shows the current through the LEDs 5 without the circuit arrangement according to the invention. It is interpreting ^¬ Lich to see a high current modulation of over 50%, which shows up in the same way in a corresponding light modulation due to the characteristic of the LED. The current varies from a minimum value of approx. 33mA to a maximum value of approx. 77mA within a period of approx. 5ms. Fig. 5 shows the current through the LEDs 5 with the circuit arrangement according to the invention. The circuit arrangement according to the invention acts as described above, the current flow through the LEDs 5 in FIG. 5 is very uniform at about 45 mA and no longer shows any significant modulation. With this measure, therefore, the Lichtmo ^¬ modulation in converters with a small energy storage according to the invention can be virtually completely suppressed. The result is a uniformly emitted light, which is very well absorbed by the human organism and does not lead to any impairment of human physiology.

Fig. 6 shows a third embodiment which differs from the second embodiment of the circuit arrangement characterized in that to reduce the light modulation of at least one light source, the order of the construction ^¬ elements and functional blocks is switched in series with the light source.

In contrast to the second embodiment shown in FIG. 3 and described in detail above, the third embodiment from FIG. 6 is not suitable for use with an open-collector amplifier instead of the operational amplifier and the NPN transistor. For both variants with open-collector amplifiers necessarily require the order shown in Fig. 2 or 3 between current measuring device and current control circuit. This compulsion is eliminated as soon as current control circuits as here fully developed operational amplifier with a basic resistor of their outputs controlled discrete transistors as effective variable impedance in use. Then, in contrast to the figures 2 or 3, the respective current measuring devices may also be connected to the emitter of the transistor acting as a variable impedance Ql. Regardless of the polarity of the transistor Ql itself then applies, however, that the instantaneous value of the LED current I LED is to be led to the inverting input, ie the negative input of the operational amplifier, and that the mean ^¬ value of the same current to the non-inverting Input, so it is to lead to the positive input of the operational amplifier.

 Should the transistor be integrated into the amplifier output, this would result in a so-called open-emitter amplifier, which is not available on the market.

The current measuring device 13, which is connected in series with the collector-emitter path of the NPN transistor Ql and connected to the emitter of this transistor, is now connected at its other end to the second terminal of the circuit arrangement 1, so it is seen in the classical voltage direction. below the variable impedance associated therewith. The collector of the NPN transistor Q1 is connected to the first terminal of the circuit arrangement 1.

At the connection point of shunt R2, which again represents the current measuring device 13, and the emitter of the transistor Ql, the instantaneous value of the current I LED is again measured by the LEDs 5. This point is in turn connected to a low pass filter of components C2 and R4. Again, this low-pass filter represents the averaging means 17th A first terminal of gate capacitors C2 is connected to the second terminal of the circuit arrangement ^¬. 1 The second terminal of Kondensa ^¬ tors C2 is connected to the first terminal of resistor R4 and the positive input of the operational amplifier Ul connected. The second terminal of the resistor R4 is connected to the emitter of the transistor Ql and to the negative input of the operational amplifier Ul. The auxiliary voltage supply 15 is here not dual, but as in the first embodiment of Fig. 2 constructed.

The circuit arrangement 1 of this third embodiment operates analogously to the circuit arrangement 1 of the first embodiment. Because of the also "lying down"

Shunts R2 are the voltage changes across the resistor R2 and thus the actual values Ii poled same as in the first ^embodiment of FIG. 2. Because the operational amplifier is to work in the same way, but must drive an NPN transistor accordingly, its inputs here are between ^¬ exchange setpoint and actual value. Then Ql also acts here so that it remains low impedance at low current changes of the current I LED through the LEDs 5, while it is successively higher impedance at times faster and stronger changes of the current I LED by the LEDs 5 and thus counteracts the current change.

The advantage of minimizing the common-mode rejection in the operational amplifier by location of the entire circuit mimic from both input potentials and the output driving the NPN transistor Q1 into the same half of the rather short auxiliary voltage U _B is lost in FIG. 6 in comparison to FIG. For this purpose, a structure is obtained here which, of itself, comes much closer to a necessary current negative feedback. In FIG. 7, the proximity to current feedback already established in the precursor figure is used to propose a significantly simplified fourth embodiment. The principle of negative feedback of a measured current value by a voltage at the emitter of the considered NPN transistor applies here.

 The arrangement of variable impedance Ql and current measuring device R2 is taken over unchanged from the predecessor figure. Ql is an NPN transistor, which is considered to be the easiest way to build an amplifier. Its Gegenkoppeleingang is its emitter, the signal for a voltage whose Mitkoppeleingang its base. This closes the circle of polarities with the known properties of each NPN transistor. A positive feed-in signal is a current that flows into the base.

As in all other embodiments, the capacitor C2 is also charged to a voltage whose value corresponds to the mean value of the measured current flowing through the light source. For this purpose, it is connected substantially parallel to the current measuring ^resistor R2, and the mesh is supplemented by the low-pass-forming resistor R4. In contrast to the first three embodiments here is this low-pass-forming mass at the node between R4 and R2 not directly, but over the base-emitter path of

Transistor Ql closed. Therefore, C2 is charged higher by the base-emitter forward voltage and by the voltage at R4 produced by the positive base current than in the previous embodiments. Because it is both are offset initially set ^¬ imputed context applies here. The low-pass filter 17, which still consists of C2 and R4, however, merges here with the auxiliary voltage supply 15. The capacitor C2 is used twice and therefore also has the value of the former buffer capacitor C5. Thanks to the safe limit its voltage by R4, R2 and the base-emitter path of the parallel Ql geschal ^¬ preparing zener diode D3 may be omitted. The charging resistor ver ^¬ melts with the former base series to the pull-up resistor R17 at similar values. To improve the low-pass effect, R4 can also be replaced here by an inductance with a value of a few millihenries.

Fig. 8a shows a development of the third embodiment ^¬ example with linearization of the gain of the NPN transistor Ql through a resistor R18, which is switched directly pa ^¬ rallel to the base-emitter path of this transistor ge ^¬ . This linearization shows clear advantages at low input voltages, in particular, it avoids the saturation of the transistor and then the following dips in the current through the light source, which undesirably increase the current ripple.

FIG. 8b shows how several small NPN transistors can be connected in parallel. All collector and base connections are interconnected, but not the emitter connections: Each individual transistor gets its own current sense resistor R2 ^λ and its own linearization resistance R18 ^x .

Finally, in FIG. 9 the original idea of the peak value rectifier as auxiliary voltage supply 15 is shown. the picked up. Since the base voltage of Ql can never correspond to the peak value of the voltage dropping between the first and second terminals of the circuit arrangement, the peak value rectifier becomes a half-wave rectifier. The drop across the pull-up resistor R17 voltage compensates for this, because in C2, a significantly small ^¬ rer value for the average light source current is now saved and no longer a peak value of the total voltage.

However, at the input voltage minimum, the overall voltage drop across the circuitry may become less than the voltage currently stored in C2. Then, the so-called collector gene coupling begins, portions of the actual ^¬ provided for the base current from C2 flow instead via the collector of the same transistor and displace not only the actually provided there

Light source current, but at the same time weaken the control. The result is burdens in the light source current, which are similar to gaps and thus let the current ripple go to 100%. The solution to this problem is to (re) introduction of the former peak value detection diode D2, which now operates all ^¬ recently as an ordinary half-wave rectifier and prevents charge from C2 flow away only by the base of Ql or by its linearization resistor R18 SEN can.

Finally, FIG. 10 shows a fifth embodiment of the circuit arrangement, which essentially corresponds to FIG. 9 with a PNP transistor Q1, which is used as a variable impedance. The auxiliary voltage supply 15 is now again "suction" constructed as in Fig. 3, as is the

Current measuring device 13 consisting of the low-resistance Resistor R2 again "overhead", that is connected to the first terminal of the circuit arrangement 1. The remaining functional blocks are analogous to FIG. 9.

LIST OF REFERENCE NUMBERS

I circuit arrangement for reducing the light modulation of at least one light source

3 full wave rectifier

 5 LEDs

 55 LED chain

 7 operating device

 II flow control device

13 current measuring device

 15 auxiliary power supply

 17 averaging device

 UN mains voltage

 ILED electricity through the LED chain

Ii actual value for the flow control device

 Is setpoint for the flow control device

 Ql transistor

 Ul operational amplifier

Claims

claims

 Circuit arrangement (1) for reducing the light modulation of at least one light source (5) operated at a voltage, which voltage has an alternating component causing the light modulation, wherein the circuit arrangement (1) can be switched serially to the at least one light source (5) and

 - is set up to measure an instantaneous value of the current (ILED) through the at least one light source (5),

 wherein it has a current control device (11) which regulates the current (ILED) through the at least one light source,

 - Where the instantaneous value of the measured current (ILED) by the at least one light source (5) as the actual value (Ii) for the flow control device (11) is usable, and

- wherein an average value of the instantaneous value of the ge ^¬ measured current through the at least one light source ^¬ as a desired value (Is) for Stromregeleinrich ^¬ device (11) is usable.

Circuit arrangement according to claim 1, characterized in that it ^comprises an averaging means (17).

Circuit arrangement according to claim 2, characterized in that the averaging device (17) is a low pass, and the average value of the measured current through the at least one light source ^¬ (5) is formed by the low-pass.

Circuit arrangement according to Claim 3, characterized in that the current-regulating device (11) further comprises:

 a transistor (Q1) having a reference electrode, a working electrode and a control electrode,

- An operational amplifier (Ul) with a positi ven input, a negative input and an output, wherein

 the output of the operational amplifier is coupled to the control electrode of the transistor,

- the instantaneous value of the measured current is input through the at least one light source in the positive ^¬ A transition of the operational amplifier,

the mean value of the instantaneous value of the measured current through the at least one light source is input to the negative input of the operational amplifier,

wherein the distance between the working electrode and loading reference electrode of the transistor (Ql) is connected serially to at least one light source.

 Circuit arrangement according to claim 3, characterized in that the current control device (11) further comprises:

 a transistor (Q1) having a reference electrode, a working electrode and a control electrode,

- the instantaneous value of the measured current is input through the at least one light source in the loading ^¬ zugselektrode of the transistor,

the mean value of the instantaneous value of the measured current through the at least one light source is input to the control electrode of the transistor,

- where the distance between the working electrode and Reference electrode of the transistor (Ql) is connected in series with the at least one light source.

 6. Circuit arrangement according to one of the preceding claims, characterized in that it comprises an integrated auxiliary voltage supply (15).

7. Circuit arrangement according to claim 6, characterized in that the auxiliary voltage supply (15) comprises a peak value rectifier and generates the auxiliary voltage (UB) from the total voltage dropping across the circuit arrangement.

8. Circuit arrangement according to one of the preceding claims, characterized in that it is ^¬ directed to measure the instantaneous value of the current through the at least one light source by means of a current measuring device (13), the serial to the at least one light source and to the track is connected between the working electrode and the reference electrode of the transistor.

 9. Circuit arrangement according to claim 8, character- ized in that the current measuring device (13) is an ohmic resistor.

 10. Circuit arrangement according to one of the preceding claims, characterized in that the at least one light source (5) is an LED.

11. Circuit arrangement according to one of the preceding claims, characterized in that the at least one light source (5) is an OLED.

12. Circuit arrangement according to claim 8, based on claim 5 or 6, characterized in that it is a two-terminal, the serially at each point in the circuit of the at least one light source (5) can be switched.

13. A method for reducing the light modulation of at least one at a voltage (UN) operated light source (5) having an alternating component, characterized in that serially to the at least one light source (5) Stromre ^¬ gel circuit (11) whose actual value is derived from the instantaneous value of the current (I LED) by the at least one light source, and whose

Desired value is derived from an average of the instantaneous value of the current through the at least one light source.