EP1641323A1 - LED lighting system and method with at least two lighting sources - Google Patents

Abstract

A driver device (22) operates a LED (11) with a direct current (DC) signal. An storage device (14) stores an actual value of features of light output determined by sensor (12). A set point selection device (18) stores set point of feature. A control device (16) transmits actual value and set point to provide driver device with control signal that changes characteristic of DC signal such that actual value approaches set point. An independent claim is also included for illuminating system operating method.

Description

Technical area

The present invention relates to a lighting system with at least two light sources, of which at least one light source comprises an LED. It also relates to a method for operating such a lighting system.

State of the art

Lighting systems of the type mentioned are well known in the art, the simplest method to operate LEDs is to connect the LED together with a series resistor to a DC power source. The series resistor serves to limit the current of the light-emitting diode current I _F (forward current). By varying the series resistance, the forward current I _{F can be} varied, whereby the brightness of the light emitted by the light-emitting diodes is also varied. In this simple way, the dimming capability of a system, which may include light emitting diodes and other bulbs as a light source, can be achieved. One problem, however, is that with some LEDs, in particular with InGaN LEDs, there is a greater or lesser correlation between the current intensity of the forward current I _F and the associated wavelength of the emitted light. Depending on the forward current I _F , a wavelength or color locus shift occurs here, ie when dimming the wavelength and thus the color of the emitted light changes simultaneously.

Color coordinates: In the standard valence system, a color is described as the sum of three mixing values, the so-called standard color values X, Y, Z (DIN 5033). Frequently, the two-dimensional representation also specifies the standard color value components Cx and Cy, where Cx = X / (X + X + Z) and Cy = Y / (X + Y + Z). In the graphic representation of the chromaticity in In a two-dimensional color chart, Cx and Cy serve as rectangular coordinates of the so-called color loci.

Most strikingly, the phenomenon of color locus shift in green LEDs can be observed. In the type LT E673 (Power TOPLED), the dominant wavelength at a forward current of 3 mA is greater than 540 nm and decreases as the forward current increases to 90 mA below 512 nm. For a type LW W5SG (Dragon) LED, the color location changes. defined by Cx and Cy, from Cx = 0.322 and Cy = 0.316 at a forward current of 100 mA to Cx = 0.316 and Cy = 0.301 at a forward current I _F = 1000 mA.

In the prior art, the principle of pulse width modulation is used to solve this problem, ie to keep constant the color location of the light emitted by the LED. In this case, a LED is always switched on and off with the same forward current I _Fmax over a period T. The duty cycle, which is calculated from the quotient of the turn-on time t _p divided by the period T, determines the brightness of the light emitted by the LED. A large duty cycle results in a bright LED, a small duty cycle inversely to a weaker LED. In this case, the integration of the light emitted by the LED is performed by the human eye. For periods T less than 10 ms, the light is registered by the eye as continuous. At longer periods, a flickering of the light can be perceived by the eye.

At low power, this known from the prior art control is not a problem. However, if you go to greater benefits, as is required for lamps for general lighting or use in a motor vehicle, it may cause undesirable interference. Essentially, two types of interference come into consideration, namely radio interference (EMC) and conducted interference.

To prevent such electromagnetic interference, for example, the corresponding standard of BMW provides that the rising edge in clocked operation is a maximum of 20 mA / μs. If this limit is met, then very long turn-on and turn-off and associated very high switching losses. With the measures known from the prior art, one must therefore decide for one of the evil, either disturbances or Farbortverschiebungen or high switching losses.

Presentation of the invention

The present invention is therefore based on the object, a lighting system of the type mentioned above or the aforementioned method such that the brightness can be varied, but without disturbances or high switching losses occur, the color point remains largely constant.

This object is achieved by a lighting system having the features of claim 1 and by a method having the features of claim 14.

The present invention is based on the recognition that initially switched to DC operation to avoid interference from the clocked operation. However, the color locus change occurring in DC operation in the dimming mode is detected according to the invention and the DC signal used to drive the at least one LED is changed in such a way that the desired brightness is established, the color locus remaining largely unchanged.

Due to the fact that at least two light sources can be used in the illumination system whose light has different spectrums, color shifts of the light emitted by the illumination system can be effected by different control of the individual light sources, depending on which requirements exist or which effort is operated the illumination system is formed, desired Farbortverschiebungen of the light emitted by the illumination system light, which is composed of the light of the individual light sources achieve. For example, in a simple embodiment, if the illumination system comprises a plurality of LEDs that emit light of different color locations, such as red, green, and blue light, a color locus shift caused by dimming may be corrected if the individual LEDs are driven with different parameters after dimming.

A preferred embodiment is characterized in that the sensor device comprises at least one voltage-frequency converter. Particularly in connection with corresponding filter devices, for example for the blue, the red and the green spectral range of the light emitted by the illumination system, the light components located in a certain spectral range can be determined by counting the pulses emitted by the respective voltage-frequency converter. The control device includes a microprocessor connected to the output of the at least one voltage-to-frequency converter is connected, it can count the pulses in the output signal of the at least one voltage-frequency converter, without the interposition of an A / D converter would be necessary. The standard color values X, Y, Z are thus easily reflected as the number of pulses per unit time. From this, the standard color value components Cx and Cy can be determined, see above. Alternatively, voltage signals can be provided by the filter devices, which are evaluated by the microprocessor with the interposition of at least one A / D converter.

In an illumination system according to the invention, in addition to the at least one light source comprising at least one LED, at least one further light source may be present, which may preferably be selected from the following types: LED, fluorescent lamp, halogen incandescent lamp, high-pressure discharge lamp. The at least one feature of the light emitted by the illumination system may be the color temperature and / or the brightness and / or the color location.

Further preferably, it can also be provided that the setpoint specification device has an interface into which at least one desired value can be input by an operator or at least one desired value can be selected from a number of setpoint values already stored in the setpoint specification device. This allows the same lighting of a room to be used to create different moods. When operating in a motor vehicle, country-specific color temperatures or fashion colors, eg. B. Cool Blue, be realized.

Furthermore, it is preferred if the components of the illumination system are designed for operation in a motor vehicle, in particular the supply voltage required for the operation of the components, as well as the quality of the light emitted by the illumination system. Since the brightness can be adjusted independently of the color temperature with an illumination system according to the invention, this makes it possible to realize dimmable headlights. This feature is very important for daytime running lights, which is already mandatory in many countries. So far, halogen lamps with a color temperature of, for example, 3200 K for H4 lamps or high-intensity discharge lamps (D2 / D1 lamps) with a color temperature of 4200 K are used for headlights, with which also a function as a daytime running light is possible. The disadvantage is that the life is very limited. This amounts to several 100 hours for halogen lamps, about 3,000 hours for D2 / D1 lamps. So far, LEDs have been a lifetime of typically have more than 10,000 hours, as a headlight with daylight option, among other things, due to the said unwanted Farbortverschiebungen not applicable.

The driver device may be configured to operate all the light sources of the lighting system. Alternatively, the light sources of the illumination system, in particular grouped by types, can also be controlled independently of one another.

In the driver device, parameters for operating the light sources may be stored in the event that the sensor device and / or the actual value memory device and / or the setpoint presetting device fails. It can be provided that the control of the light sources takes place so that they give white light with preset values. Alternatively, it can be provided that a color temperature is predefined by the user for the error case and stored, for example, in a memory unit.

The determination of the at least one feature of the light emitted by the illumination system according to the invention can be carried out completely independently of the activation of the at least one LED. In the case of a pulse-width-modulated operation of the LED, the determination of the respective feature would have to be performed with an increase in complexity exactly when the corresponding LED is switched on. In contrast, an inventive lighting system is characterized by easier realizability and increased reliability.

Not only in connection with the realization of a daytime running light or a parking light when using a lighting system according to the invention in a motor vehicle, but also in a general lighting system, for example, to illuminate a living space, a desired value of a dimming position of the lighting system can correspond.

Further advantageous embodiments of the invention can be found in the subclaims.

Short description of the drawing

Hereinafter, an embodiment of the invention with reference to the accompanying drawings, which contains a figure, described in more detail. The figure shows a schematic representation of a block diagram of a lighting system according to the invention.

Preferred embodiment of the invention

FIG. 1 shows a schematic circuit diagram of a lighting system according to the invention. It comprises a plurality of light sources, which are combined in a block 10, wherein at least one light source - as shown schematically - is an LED 11, which is operated with a direct current signal. The light emitted by the block 10 is detected by a sensor device 12, with which at least one feature of the light emitted by the illumination system can be determined. As characteristics come into consideration the color temperature, the brightness or the color location. The at least one feature determined by the sensor device 12 is stored in an actual value memory device 14. The actual value memory device 14 may be designed to store the values of several features. The actual value of the at least one feature is provided to a control device 16. This further receives a setpoint of the at least one feature provided by a setpoint presetting device 18. Again, this may be designed to store a variety of feature values. This has an interface 20 via which at least one desired value can be input by an operator or at least one desired value can be selected from a number of setpoint values already stored in the desired value presetting device 18. The control device 16 compares the setpoint value of the at least one feature with the actual value of the at least one feature and provides at its output a control signal to a driver device 22 such that the driver device changes a characteristic of the DC signal used to drive the at least one LED the actual value of the at least one feature approaches the target value of the at least one feature. As already mentioned, only LEDs may be present as light sources in block 10, but LEDs may also be combined with other types of light sources, for example high pressure discharge lamps, halogen incandescent lamps, fluorescent lamps. Driver device 22 may be configured to change only the signals used to drive the at least one LED, but may also be configured to modify the drive signals of the other light sources as well. In the sensor device 12, a filter device 24 and a voltage-frequency converter 26 is shown schematically. Preferably, there are three such combinations of filter device 24 and voltage-to-frequency converter 26 for determining the standard color values X, Y, Z. The output signals of the three voltage-frequency converter 26 are supplied to a microprocessor, which determines the standard color values X, Y, Z by counting the pulses in a simple manner. Optionally can be provided be calculated that the microprocessor from the standard color values X, Y, Z calculates the standard color value components Cx and Cy.

Claims (14)

Lighting system comprising _at least two light sources, of which at least one light source comprises an LED (11);
characterized,
that it further comprises: - A driver device (22) which is designed to operate at least one LED (11) with a DC signal; a sensor device (12) with which at least one feature of the light emitted by the illumination system can be determined; - An actual value storage device (14) which is connected to the sensor device (12) and in which an actual value of the at least one feature is storable; - A setpoint specification device (18) in which a desired value of the at least one feature can be stored; - A control device (16), which is the input side connected to the actual value memory device for transmitting the actual value of the at least one feature and with the setpoint specification device (18) for transmitting the desired value of the at least one feature, and which is designed at its output to provide a control signal to the driver device (22) such that the driver device changes a characteristic of the DC signal used to drive the at least one LED (11) such that the actual value approaches the setpoint value. Illumination system according to claim 1,
characterized,
that the characteristic of the DC signal is its amplitude. Illumination system according to claim 1 or 2,
characterized,
in that the sensor device (12) comprises at least one voltage-frequency converter (26). Illumination system according to claim 3,
characterized,
in that the at least one voltage-frequency converter (26) for determining the actual value of the at least one feature of the light emitted by the lighting system is connected to at least one filter device (24). Illumination system according to one of claims 3 or 4,
characterized,
in that the sensor device (12) comprises a microprocessor which is connected to the output of the at least one voltage-frequency converter (26), in particular for counting the pulses in the output signal of the at least one voltage-frequency converter (26). Illumination system according to one of the preceding claims,
characterized,
in addition to the at least one light source comprising at least one LED (11), there is at least one further light source which is of the following type: - LED; - fluorescent lamp; - halogen bulbs; - High pressure discharge lamp. Illumination system according to one of the preceding claims,
characterized,
in that the characteristics of the light emitted by the illumination system are the color temperature and / or the brightness and / or the color location. Illumination system according to one of the preceding claims,
characterized,
that the illumination system comprises at least two LEDs that emit light of different colors. Illumination system according to one of the preceding claims,
characterized,
in that the setpoint presetting device (18) has an interface (20) into which at least one desired value can be input by an operator or at least one desired value can be selected from a number of setpoints already stored in the setpoint presetting device (18). Illumination system according to one of the preceding claims,
characterized,
in that the driver device (22) is designed to operate all light sources of the illumination system. Lighting system according to claim 10,
characterized,
that parameters for operating the light sources are stored in the driver device (22) in the event that the sensor device (12) and / or the actual value memory device (14) and / or the setpoint specification device (18) fails. Illumination system according to one of the preceding claims,
characterized,
in that the components of the illumination system are designed for operation in a motor vehicle, in particular the supply voltage required for the operation of the components, the quality of the light emitted by the illumination system. Illumination system according to claim 12,
characterized,
that a target value of a dimming of the illumination system corresponds. Method for operating an illumination system with at least two light sources, of which at least one light source comprises an LED (11), comprising the following steps: a) determining the actual value of at least one feature of the light emitted by the illumination system; b) comparing the actual value of the at least one feature with a predefinable desired value of the at least one feature; c) driving the at least one LED with a DC signal such that the actual value approaches the desired value.

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