DE2616274A1 - Luminescent diode operation as constant light source - uses conversion of dissipated diode light into electric control magnitude - Google Patents

Abstract

The luminous output of the luminescent diode, operated at a constant light source, is held constant by electric control. The dissipated light, impinging at a constant spatial angle from the diode, is received and converted into an electric control magnitude, changing inversely with the luminous output. The control magnitude regulates the operating current of the luminescent diode. Preferably a current analogous to the control magnitude is super-imposed with an independent base current, and the luminous output of the diode is adjusted by changes in the base current. Alternately a base voltage may be used in the same manner. An opto-electronic receiver is used for this purpose, i.e. a phototransistor, or a photodiode.

Description

Method and device for operating a light-emitting diode

as a constant light source The invention relates to a method of operation a light emitting diode as a constant light source and a device for implementation of the procedure.

With a variety of optical measurement methods, the attenuation becomes one Light beam measured in a measuring section. To do this, you can first adjust the intensity of the unattenuated light beam in a blank sample and then the intensity of the light beam in the measuring section and determine the difference between the Use both intensities for measurement. It is easier, however, to use a light source whose light has a constant intensity, and the absolute values the intensity of the weakened light beam to measure luminescent diodes wiser. extremely small dimensions and deliver a light of high intensity. You are therefore for probes and other measuring devices whose dimensions should be kept small, suitable. However, their use as a source of constant light is due to their strong dependency the radiation intensity from the ambient temperature and the age of the light emitting diode opposite.

From the magazine ~ Siemens-Components-Information11, 11th year, 1973, page 14 f., It is known that the temperature dependence of a light emitting diode can be compensated within a certain temperature range that a first resistor is connected in parallel to the light emitting diode and the through the light emitting diode and this first resistor current flowing through a second one Resistance is conducted, the two resistors in one fixed relationship to the internal resistance, its temperature behavior, the operating current and the radiation intensity of the light emitting diode. However, these change Data of the light emitting diode as a result of aging, the temperature constancy deteriorates the arrangement. Furthermore, such a circuit is only sensitive to a very specific radiation intensity matched to the light emitting diode, so the intensity of the emitted light can be cannot be changed. For the serial production of constant light sources with light emitting diodes, it is also disadvantageous that the resistors each to the exemplary data of each individual light emitting diode must be adjusted.

The invention is based on the object of a method and a Specify device for operating luminescence diodes as constant light sources, whereby the temperature and age-related fluctuations in light intensity are switched off and the specimen variance of the data of the light emitting diodes can be compensated.

This object is achieved in that the light intensity of the light emitting diode is kept constant in that scattered light falling into a constant solid angle received the light emitting diode and the luminous intensity of the scattered light in itself If the light intensity changes, the amount of electrical energy changes in opposite directions Control variable is implemented and the operating current of the light emitting diode is analogous to this Control variable is controlled.

According to the invention, therefore, most of the can from the light emitting diode emitted light can exit unhindered (e.g. in a downstream measuring section), while only a fixed fraction of the light, namely that in a fixed solid angle falling scattered light, wholly or partly to control the operating current of the luminescent diode is used. For this purpose, e.g. a Serve recipients. The output of this receiver changes as it changes Light intensity in general in the same direction (analog), i.e. with additional taking or decreasing light intensity, the output signal increases or decreases. This output signal is now converted into an oppositely changing electrical control variable, for example by subtracting it from a fixed, predeterminable electrical control variable. the The control variable can then be given e.g. in a ## amplifier in order to use it to control the operating current of the luminescent diode. So there is a countermeasure of the operating current, at which, with increasing luminous intensity of the scattered light, So with increasing radiation intensity of the light emitting diode, the operating current is reduced or with decreasing radiation intensity the operating current is increased. The strength of the flow of the light emitting diode, which increases with increasing operating current, can thus on be kept constant at a certain value.

The control of the operating current can advantageously take place in such a way that a current analogous to the disturbance variable with a basic current independent of the control variable is superimposed on the operating current.

By changing the basic current, the radiation intensity the light emitting diode can be adjusted.

But it can also be advantageous for counter-controlling the operating current one of the .SWeuelgröSe analog voltage of a basic voltage independent of the control variable are superimposed and the superimposed voltage obtained to regulate the operating current be used. Here, the radiation intensity of the luminescent diode can be changed by changing the basic voltage can be set.

But it can also be advantageous to form the control variable by that a voltage analogous to the light intensity of the scattering is formed and from a Basic voltage is subtracted, which is independent of the light intensity of the scattered light is. Here, too, the radiation intensity of the luminescent diode can be changed by changing the basic voltage can be set.

In order to avoid overloading the light emitting diode, the amount the basic voltage or the basic current are limited so that even with vanishing Light emission the operating current, which in this case only from the The basic voltage or the basic current does not depend on the maximum permissible value increases.

There is a device for carrying out the method according to the invention with a luminescent diode particularly suitable, in which din optoelectronic The receiver is arranged laterally to the radiating surface of the luminescent diode in such a way that that stray light emitted by the light emitting diode hits the receiver, that the outputs for the output signal of the optoelectronic receiver with a Mixer are connected, that the mixer is designed so that in it the Output signal of the E-receiver with a predeterminable from the output signal of the receiver independent electrical basic quantity to one of the output signal of the receiver conversely, analog electrical control variable is superimposed and that the mixer stage so connected to the light emitting diode and its power supply that the The operating current to be fed into the luminescent diode is analogous to the stevedore size. A phototransistor or a photodiode can be used as the optoelectronic receiver be used.

The photodiode can practically be operated in a short-circuit or also in no-load mode i.e. between the outputs of the photodiode there can be a low resistance or a high resistance are, thus a short circuit current or an open circuit voltage that can be amplified in a subsequent amplifier.

The output signal is then one of the light intensity of the scattered light analog photo current or an analog photo voltage. When using a phototransistor It may be possible to dispense with an amplification of the signal, an analog one is created Photocurrent. Photo voltage or photo current are fed into the mixing stage.

Will. Enter a photo voltage in the mixer stage, so it can be used there can be subtracted from a predeterminable basic voltage.

This creates a voltage that is used as an electrical control variable for the operating current can serve. The course of this voltage is reversed insofar as an increasing radiation intensity of the light emitting diode (increasing light intensity of the scattered light) a corresponds to the amount of anticipated tension. This electrical voltage can now be applied to the power supply of the device connected amplifier, one of which is proportional to this voltage Generates electricity. The light emitting diode can be operated with this current. at The operating current and consequently also increase in the basic voltage also increases the radiation intensity of the light emitting diode, thereby increasing its setpoint can be adjusted.

If, on the other hand, a photocurrent is fed to the mixer, the mixer can for example an inverting amplifier e.g. contain a transistor which ehen photocurrent conversely analogous, i.e. with increasing or decreasing (in each case according to the absolute amount) Photocurrent supplies a decreasing or increasing current. As a specifiable electrical In this case, the basic variable for the mixer stage can be a stream that is the same Has polarity as the current coming from the inverting amplifier and, from one pole coming from the power supply, can be changed via a rheostat. The two Currents are combined as the operating current on the polarity of this operating current given input of the light emitting diode; the other input of the light emitting diode is connected to the other pole of the power supply. On an increasing The inverting amplifier reacts with a radiation intensity of the light emitting diode decreasing output current, which together with the base current becomes a decreasing one Operating current added. This increases the radiation intensity of the light emitting diode counteracted.

A reduction in the rheostat is effective in this arrangement an increase in the base current, consequently also an increase in the setpoint for the Light intensity.

It is particularly advantageous if the photodiode is used as a light emitting diode enclosing ring is formed. This ensures that even with a The shift in the focal spot on the light-emitting diode is always about the same fraction of the light emitted by the light emitting diode falls on the photodiode.

In a particularly preferred embodiment of the device the luminescent diode and the optoelectronic receiver formed as one component. This results in a very space-saving arrangement that serves as a light source for measuring probes can be used in small appliances. Such a miniaturized component has only a few connections (two connections for the light emitting diode and two up to three connections for the photodiode or the phototransiator), which are connected to the mixing stage and the power supply must be connected. The mixer that just made some building blocks, e.g. transistors and resistors, can be manufactured in an integrated design.

The light source and the optoelectronic can also be advantageous Receiver be designed so that the spectral sensitivity of the receiver is adjusted to the emission spectrum of the light emitting diode. For example the light emitting diode can be used as an approximately monochromatic light source, a corresponding filter can be placed in front of the light emitting diode and in front of the receiver can be placed in front of a specific spectral range as a filter For example, a synthetic resin mixed with appropriate dyes can be used, in which the light emitting diode and the receiver are poured together.

The invention is illustrated by means of several figures and exemplary embodiments explained in more detail.

1 shows a block diagram for carrying out the method.

FIGS. 2 to 4 show advantageous designs of the device for carrying out the method according to the invention.

In Fig. 1, 1 is the light emitting diode, with the arrows 2 that of denotes their emitted light. Laterally to the emitting surface of the light emitting diode a receiver 3, e.g. a phototransistor or a photodiode, is shown, wherein the photodiode can encircle the light emitting diode, as indicated by the dashed line Contour 4 is indicated. So only a small part of the emitted light, namely the side escaping stray light the light emitting diode, while the direct emitting perpendicular to the luminous surface Light can be passed into an optical measuring section. The outputs 5 for the measurement signal of the receiver are led to a mixer 6, which via lines 7 and 8 with the power supply is connected. The light emitting diode 1 is connected via lines 9 and 10 connected to the mixer 6 and the power supply. Parallel to A resistor 11 can also be connected to the luminescent diode.

The double arrow 12 indicates that in the mixer 6 for Setting of a basic electrical quantity (an electrical current or a electrical voltage) can be intervened to achieve a desired radiation intensity to regulate the light emitting diode.

In a particularly simple embodiment, the receiver 3 consist of a photodiode betl3e) enen with open circuit voltage, which consequently as Output signal supplies a photo voltage.

The mixer stage can then consist of a constant voltage source that is connected to the polarity is reversed in the signal line of the photodiode (voltage subtraction), and an amplifier.

The amplifier receives the difference between the specifiable voltage of the constant voltage source and the photo voltage and supplies a current proportional or at least analogous to this voltage difference, the can be given as operating current directly to the inputs of the light emitting diode.

However, since the open circuit voltage of the current photodiodes itself is still have a certain temperature dependence, it is advisable to use the photodiode to operate in a short circuit, since the short circuit currents of photodiodes largely independent of temperature are.

Such a modified embodiment is shown in FIG.

The signal lines 22 of the photodiode 23 are connected to the inputs a current voltage amplifier 24 is connected. The from the luminescent diode 21 incoming scattered light calls you through the entrance gears of the amplifier 24 flowing short-circuit current out and at the output 25 of the amplifier 24 is a negative, the size of the short-circuit current corresponding to the voltage the negative pole of an adjustable constant voltage source 26 is given. Of the The positive pole of this constant voltage source is at the positive input of the light emitting diode, while the negative input of the light emitting diode is grounded.

GaAs luminescence diodes, for example, can be used as luminescence diodes of type CQY 17 (Siemens) or SG-1002/40736 R (RCA) can be used. As a photodiode For example, a BPX 90 or BPY 11 type diode can be used. the maximum light intensity of the light emitting diode is limited by the letter that a maximum voltage of 2 volts is applied to the positive input of the light-emitting diode target. At this maximum voltage, so much stray light falls on the photodiode that a short-circuit current of 5 / uA arises. This short-circuit current is converted into a temperature-compensated Voltage amplifier, e.g. type M890 Dz 310 "(Siemens), fed in, its output supplies a voltage of -0.5 V at an input current of 5 / uA. The voltage booster is connected to a supply line (220 V) and can be up to one power operated by 3 VA. A so-called "constant" serves as the constant voltage value. at the voltages up to the maximum value of 1.5 V (corresponding to the load limit the light emitting diode) can be set. Is now e.g.

a voltage of 1.2 V is set and the photodiode is unexposed (e.g. when switching on the device), this is due to the luminescent diode Voltage of +1.2 V, which thus begins to glow strongly. At maximum lighting the photodiode, on the other hand, has a voltage of 0.7 V on the luminescent diode, namely the difference between the constant voltage (1.5 V) and the amplifier voltage (0.5 V). The light emitting diode is now only with a low voltage and operated with a correspondingly low current and the light intensity decreases sharply. In both cases, an average operating state is quickly established.

This exemplary embodiment is for the pulsed operation of light emitting diodes suitable. In the case of pulsed light-emitting diodes, it is advisable to use suitable pulse amplifiers and pulse generators are necessary.

Fig. 3 shows an # embodiment in which the light emitting diode 31 incoming light is received by a phototransistor 33.

The collector of the phototransistor 33 is connected to the base of the transistor 34 and connected to a bleeder resistor 35. The one operated in emitter circuit Transistor 34 and resistor 35 serve as a reversing amplifier. With increasing Irradiation of the phototransistor 33 causes that which flows off through the resistor 35 Photocurrent that the potential of the base in transistor 34 rises and this transistor increasingly locks. The collector current of the transistor 34 thus increases with increasing Luminous intensity and can be used as an electrical control variable to regulate the operating current the light emitting diode 31 are used. A is superimposed on the collector current via the Variable resistor 36 given to the input 37 of the luminescent diode 31, which is independent of the collector current. By changing the resistance 36 is the basic current and consequently also the operating current can be set, thus also the setpoint for the radiation intensity of the luminescent diode 31 can be changed.

Instead of the phototransistor 33, a transistor 42 with a Photodiode 43 are used between the base and collector of this transistor is connected, as shown in FIG. To adapt the individual components In this case, low-ohmic resistors 48 are provided. There is also a between Base and emitter of transistor 44, which corresponds to transistor 34 from FIG. 3, a regulating resistor 47 is provided, the transistor 44 and the resistor 45 are used again as an inverting amplifier, the gain factor being controlled by a variable resistor 47 can be changed. The regulation of the setpoint for the light intensity of the light emitting diode 41 can advantageously be done by adjusting the control resistor 47. Instead of of the variable resistor 36 from FIG. 3, a fixed resistor 46 can then be used will. The photodiode 43 is advantageously designed as a ring diode.

The light generated with the device according to the invention is therefore adjustable in sinter thickness and in a larger range independent of the temperature and signs of aging. The device can easily be mass-produced and are miniaturized to such an extent that their size is practically only dependent on the Size of the element required to adjust the radiation intensity (e.g. potentiometer or constant voltage source). It can therefore be used in many ways.

13 claims 4 figures L e r s e i t e

Claims (13)

Claims method for operating a light emitting diode as a constant light source, characterized in that the light intensity of the light emitting diode is thereby constant is held that falling in a constant solid angle scattered light of the light emitting diode received and the light intensity of the scattered light in a changing light intensity opposing changing electrical control variable is implemented and the operating current the light emitting diode is controlled analogously to this control variable. 2. The method according to claim 1, characterized in that for control din the control variable analog current with a basic current independent of the control variable is superimposed on the operating current. 3. The method according to claim 2, characterized in that the radiation intensity the light emitting diode is adjusted by changing the basic current. 4. The method according to claim 1, characterized in that for control a voltage analogous to the control variable and a basic voltage dependent on the control variable is superimposed and the voltage obtained is used to regulate the operating current will. 5. The method according to claim 4, characterized in that the radiation intensity the light emitting diode is set by changing the basic voltage. 6. The method according to claim 1, characterized in that the control variable is formed in that a voltage analogous to the light intensity of the scattered light and is subtracted from a basic voltage that is derived from the luminous intensity of the Scattered light is independent. 7. The method according to claim 6, characterized in that the radiation intensity the light emitting diode is set by changing the basic voltage. 8. Device with a light emitting diode for carrying out the method according to one of claims 1 to 7, characterized in that laterally to the radiating Surface of the light emitting diode an optoelectronic receiver is arranged in such a way that stray light from the light emitting diode strikes him, that the outputs for the Output signal of the optoelectronic receiver are connected to a mixer stage, that the mixer is designed so that in it the output signal of the receiver with a predeterminable electrical signal that is independent of the output signal of the receiver Basic variable for an electrical analogue inversely to the output signal of the receiver Control variable is superimposed and di the mixer 80 to the light emitting diode and whose energy supply is connected that the one to be fed into the light emitting diode Operating current is analogous to the control variable. 9. Apparatus according to claim 8, characterized in that the optoelectronic The receiver is a phototransistor. 10. Apparatus according to claim 8, characterized in that the optoelectronic The receiver is a photodiode. 11. The device according to claim 10, characterized in that the Photodiode is designed as a ring surrounding the luminescent diode 12. Device according to one of claims 8 to II, characterized in that luminescent diode and optoelectronic receiver housed in a single electronic component are. 13. Device according to one of claims 8 to 12, characterized in that that the light emitting diode and optoelectronic receiver are designed so that the Spectral sensitivity of the receiver to the emission spectrum of the light emitting diode is aligned.