NL1033446C2 - Controlling LEDs. - Google Patents

Description

LED control

The present invention relates to a method for controlling a light-emitting component, such as an LED, with on the one hand a minimum operating voltage and on the other a maximum operating voltage and current.

Usually a control signal for switching means is generated or deduced on the basis of a measured current signal. No one takes into account the supply or control voltage across a diode or a series of diodes. It must at all times preferably be within a tightly defined range of minimum voltages in order to be able to operate the component, and a maximum voltage, also known as the forward voltage, and the corresponding current, which is not be exceeded in order not to cause damage to the component. The components furthermore also show a combination of a maximum current and a maximum voltage, whereby the development of heat can still be tolerated. In particular in applications in which a number of light-emitting components are connected in series with each other, the minimum and maximum voltages to be applied thereto must be increased by the same number of times as the number of components in the series circuit. In addition, light-emitting components often exhibit a fluctuation, depending on temperature, etc., in the minimum and maximum forward voltage in order to be able to become or remain in operation without damage due to heat developments. For example, the voltage over a component may have to become higher in order to make it operable as the temperature of that diode becomes higher, in particular in its operation.

1033446 2

In particular, when a number of light-emitting components are connected in series, the total voltage across such a series connection of components can exhibit large fluctuations, partly depending on the temperature. To compensate for this, it is customary in the art that amplifiers are used to adjust the supply or control voltage across the (series of) light-emitting components to their operating conditions, and linear amplifiers are usually used for this purpose, boost amplifiers, buck amplifiers, or combinations thereof. In particular, a series circuit of 35 LEDs, for example, may require a voltage of 150 V. The fluctuations can vary up to 20 V in the voltage to be applied across the series circuit 15. This must be adapted to the conditions, in particular the temperature of the light-emitting components, and other properties thereof.

The present invention has for its object to remedy or at least reduce the above-mentioned problems of the known art. To this end, a method and a control are provided which are distinguished from the known controls by the combinations of properties and measures defined in the independent claims.

The switching means are thus controlled on the basis of a current and condition-dependent power, without having to apply complex gains in connection with the power supply. This prevents the voltage having to be controlled separately, in particular the forward voltage, when switching on current. This provides a high degree of design freedom, and a voltage can be applied across the (series of) light-emitting component, which can be considerably higher than the usual forward voltage, without having to take into account voltage variations induced by temperature differences to hold. The supply voltage over the (series of) components can thus be selected high and constant, without requiring difficult and complex amplifiers for adjusting the voltages to be applied over the individual light-emitting components. The invention is thus based on the insight that the switching behavior of the switching means entails that the supply voltage can be made so high that no coordination is required with any fluctuations in the minimum or maximum operating states that depend on temperature or other influences. of the component.

Moreover, by switching on the power, and not only on the current through the light-emitting components, predetermined light settings can be generated in a simple manner and be kept stable.

A typical example of switching the switch may be based, for example, on pulse-width modulation as a control signal for the switch. There are also many other preferred embodiments within the scope of the present invention, as defined in the main claim, and which preferred embodiments are discussed in the dependent claims.

A control according to the invention can for instance have the feature that the control comprises a power supply to be connected to the light-emitting component with a higher voltage value than a nominal voltage required for operating the light-emitting component. Within this framework, nominal voltage means the forward voltage required to operate a light-emitting component. By choosing the supply voltage much higher than that nominal or forward voltage or sum thereof in the case of a series of components, and switching the switch based on the power consumed, an accurate control of the voltage over the individual light-emitting components, or in the combined case the series thereof, are omitted. A much simpler power supply can thus be provided, without appreciably increasing the complexity of the control. Incidentally, the power supply can be part of the control.

In another preferred embodiment, the power supply in use is connected to at least two light-emitting components, and with a higher voltage value than as many times the nominal voltage of each of the light-emitting components as the number thereof. This is specific to the situation where a series of light-emitting components is used, each with its own temperature dependence, which, due to the chosen control according to the present invention, does not lead to a need for accurate adjustment and adjustment during the use of the forward or nominal voltage, but where a considerably higher supply voltage is sufficient.

In yet another preferred embodiment of the invention, at least one of the control circuit, the measuring circuits, the multiplier and the conversion circuit is connected or connected to a power supply for providing an operating power to the light-emitting components, as well as to the control itself . The power supply for the light-emitting components thus also forms a power source for the control itself, with which the configuration of the control according to the present invention can remain simple, and whereby a separate power supply can be dispensed with for control only.

In yet another preferred embodiment use can be made of a conversion circuit with a separate input for input of a synchronization signal. Thus, changes of the light, over time, that come from the single or series of at least one light-emitting component, can be realized based on the synchronization signal. To the extent that the control signal can be taken into account with the synchronization signal on the basis of the requirement as measured by the measuring circuit and calculated in the conversion circuit, very varied lighting patterns are possible over time with a separately supplied synchronizing signal, for which a separate entrance is thus provided in this embodiment.

In yet another preferred embodiment, it is possible that the control is manufactured in a chip without external components, such as a coil. In the controls according to the known art, a coil is often used, which appears to be superfluous and has been found to be according to the present invention.

In yet another preferred embodiment, it is possible that the control according to the invention comprises a pulse-width modulation (PWM) circuit in the conversion circuit. The use of a PWM circuit is known per se, but not in combination with driving a pulse width modulation circuit based on measured powers and power indications, as is proposed according to the present invention.

In yet another preferred embodiment of the present invention, control signals to be generated by the 6 conversion circuit are pulsed with a random pulse shape. To this end, use can be made of various variants of conventional PWM circuits, which are considered to be within the range of the normal technical knowledge of the person skilled in the art, for which purpose no further description is therefore deemed here and below for a complete disclosure .

Various ramp-up characteristics can be applied, and also the down-flank of the pulse shapes can be adjusted as desired or required with per se known and conventional PWM circuits, each of which can display their advantages or properties in connection with the present invention.

In yet a last preferred embodiment according to the present invention, the control has the feature that determining means are provided for determining the ratio between the active voltage across the at least one light-emitting diode and the voltage across a shunt resistor, and wherein ratio to be entered is in the conversion circuit. In this way an optimization of the operation of the control can be effected in order to achieve optimum control of the light-emitting component or a series with various light-emitting components.

It is noted that, in particular through the use of a higher supply voltage across the light-emitting component or components than the forward or nominal voltage required for operating the light-emitting component or components, light-30 emitting components at greater distances can be driven with lower losses, in particular when the control is located at the location of the light-emitting component or components, and the power supply for applying an operating voltage across the component or components is remote . With a higher supply voltage, relatively lower losses occur in any case along the length of the conductors to the light-emitting component or components.

The invention will be explained in more detail below with reference to a single example of a possible embodiment, such as that shown in the accompanying figures, in which the same or the same components and elements are indicated by the same reference numbers, and in which: FIG. 1 shows a schematic view of a part of a possible embodiment of a control according to the present invention; and

FIG. 2 shows a schematic view of an additional part of a control in a possible embodiment according to the present invention.

Fig. 1 shows a part 1 of a control in a possible embodiment of the present invention. The part 1 of the control in Fig. 1 comprises two inputs 2, 3 for the LED voltage and the LED current, respectively. The inputs 2, 3 are connected to respective amplifiers 5, 6, the outputs of which lead to a multiplier 4. The output of the multiplier 4 leads to a summation circuit 8, where the output signal 25 from the multiplier 4 can be combined with a feedback signal with with respect to shifting the frequency setting for the switch, which acts on the light-emitting components, as will be further described below in connection with FIG. 2.

The output of the summing circuit is connected to one of the inputs of a differential circuit 10, the other input of the differential circuit 10 being connected to the output of the differential circuit 10 to form a feedback loop 8. The output of the differential circuit 10 forms part of a conversion circuit, together with the components shown in Fig. 2, as part of the control according to the present invention. Namely, a signal is generated at the output of the difference circuit 10, which signal can be fed to a PWM control 11 via a processing circuit 12, the output of which leads to an oscillator 13 to make the signal obtained from the difference circuit 10 suitable for thereby control the oscillator 13 on the basis of an operation performed thereon by the processing circuit 12. It is otherwise possible, but not required, that the oscillator 13 comprises a further input 14 for a synchronization signal. Such a synchronizing signal can be used to switch LEDs or other light-emitting components on and off in a desired manner at a desired rhythm or otherwise. Fig. 2 shows a series connection of such light-emitting components, only two of which are explicitly shown in Fig. 2.

In line with the series of LEDs 15, a switch 16 is provided which comprises a transistor 17, the output signal of the PWM control acting on the switch 16 to open or keep a current path closed as required.

Furthermore, a shunt resistor 18 is provided over the source and the drain of the transistor 17. This shunt resistor 18 can be used to provide the various measurements that can be applied to the input 2, or else as a supplement or as alternatively also at input 3 it can be input to the part 1 of the control in fig. 1. The shunt resistor can serve for measuring the current and in a possibly adapted configuration this can also be used for measuring the tension. The 9 connection 19 can be connected to a power source with a higher voltage value than the sum of the maximum voltage value for each of the LEDs 15.

It will be clear that many alternative and additional embodiments will occur to those skilled in the art after taking note of the foregoing. A random embodiment can thus be realized with a different possible transistor than the transistor shown in Fig. 2. Furthermore, a shunt resistor is provided, but other constructions can also be used for measuring various quantities. In any case, it is important to note that no further coil is required in the control. The voltage on the connection 19 can be made arbitrarily high, but not arbitrarily low. For example, it is undesirable to make the supply voltage on the terminal 19 lower than the sum of the forward or nominal voltages across each of the LEDs. The amplifiers 5 and 6 can provide a weighted product at the output of the multiplier circuit 4. For example, it is possible to make the current or voltage weigh more heavily than the others. Thus, if desired, a current signal can be multiplied by a different value than the voltage signal which is applied to the input 3. For this purpose use can be made of the amplifiers 5 and 6. With a sufficiently stable operation of the control according to the present invention, a feedback signal over the line 7 can be dispensed with. Depending on the need, an input 14 can be dispensed with for input. of any synchronization signal. It is, however, possible to realize desired patterns of switching LEDs on and off with such a synchronizing signal. It is also possible to switch only on the basis of measured currents and / or all measured voltages.

1033446

Claims (14)

Method for controlling at least one light-emitting component, such as a light-emitting diode (LED), with a maximum operating voltage (Vf (max)) and current (If (max)), the component being safe being operable, which method comprises: applying a supply voltage across the component, which is at least equal to a minimum voltage for activating the component; - selectively switching the component on and off, - - at least one of * measuring the current through the component and generating a current signal, and * measuring the voltage across the component and generating a voltage signal and - generating a control signal on the basis of at least one of the current signal and the voltage signal for switching the component on and off accordingly, CHARACTERIZED BY - applying a higher voltage than the maximum operating voltage Vf (max). 2. Method as claimed in claim 1, wherein the switching on and off of the component comprises: generating the control signal such that the sum of intermittently supplied power to the component in the switched-on state is at most equal to the product of Vf (max) * If (max). 3. Method as claimed in claim 1 or 2, wherein the switching on and off of the component comprises: generating the control signal such that a temperature of the component 1033446 resulting from a heat development is at most equal to the threshold value, above which there is a risk of damage to the component exists. 4. Control for at least one light-emitting component, such as a light-emitting diode (LED), with a maximum operating voltage (Vf (max)) and current (If (max)), with the component operating safely comprising: - a power source for the component / switching means for operating the light-emitting component at a frequency; - at least one of * a measuring circuit for measuring at least the current through the component and providing a current signal to the control circuit and * a measuring circuit for measuring at least the voltage across the component for providing a voltage signal to the control circuit, - a conversion circuit connected to the switching means for providing the switching means 20 with a switching frequency control signal associated with at least one of the current signal and the voltage signal, characterized in that the supply source supplies a higher voltage than the maximum operating voltage Vf ( max). 5. Control as claimed in claim 4, wherein the control circuit comprises a multiplier for multiplying the current signal and the voltage signal to provide a power indication to the conversion circuit. Control as claimed in claim 4 or 5, wherein a power supplied to the component is at most equal to the product Vf (max) * If (max). 7. Control as claimed in claim 4, 5 or 6, further comprising a power supply source to be connected to the light-emitting component with a higher voltage value than a nominal voltage required for activating the light-emitting component 5. 8. Control as claimed in claim 7, wherein the power supply in use is connected to at least two light-emitting components and with a higher voltage value than as many times the nominal voltage of each of the light-emitting components as the number thereof. 9. Control as claimed in at least one of the foregoing claims 4-8, wherein at least one of the control circuit, the measuring circuits, the multiplier and the conversion circuit is connected or can be connected to a power supply for providing an operating power to the light emitting components, as well as the control. 10. Control as claimed in at least one of the foregoing claims 4-9, wherein the conversion circuit comprises an input for input of a synchronizing signal. The control according to at least one of the preceding claims 4-10, which is manufactured in a chip without external components such as, a coil. 12. Controller according to at least one of the preceding claims 4-11, wherein the conversion circuit comprises a pulse-width modulation (PWM) circuit. 13. Control as claimed in at least one of the foregoing claims 4-12, wherein control signals to be generated by the conversion circuit are pulsing with an arbitrary pulse shape. Control according to at least one of the preceding claims 4-13, wherein determining means are provided for determining the ratio between the active voltage across the at least one light-emitting diode and the voltage across a shunt resistor, and this ratio to be entered in the conversion circuit. 1033446