WO2019201805A1 - Light source for generating light pulses with a short pulse duration, and method for generating a short light pulse by means of a light source - Google Patents

Abstract

The invention relates to a method for generating a short light pulse and to a light source (1) for generating light pulses with a short pulse duration, in particular for use in a vehicle, said light source comprising a light-emitting diode (3) for generating light pulses and a push-pull circuit (2) for controlling and supplying energy to the light-emitting diode (3), wherein: the light-emitting diode (3) has a first connection (10), which is connected to an output port (20) of the push-pull circuit (2), and a second connection (12); the push-pull circuit (2) can be switched into a first state in which positive electrical energy from a first supply line (42) is present at an output port (20) of the push-pull circuit (2) and the light-emitting diode (3) emits electromagnetic radiation, and can be switched into a second state in which negative electrical energy from the second supply line (44) is present at the output port (20); and the value of the difference between the potential of a mid-potential line (14) at the second connection (12) of the light-emitting diode (3) and the potential of the first supply line (42) is smaller than the value of the difference between the potential of the mid-potential line (14) and the potential of the second supply line (44).

Description

 Elmos Semiconductor Corporation

Light source for generating light pulses with a short pulse duration and method for generating a short light pulse by means of a light source

The present invention relates to a light source for generating light pulses with a short pulse duration in the nanosecond range, in particular for use in a vehicle. It comprises a light-emitting diode for generating the light pulses and a push-pull circuit for controlling and powering the light-emitting diode. The present invention further relates to a method for generating a short light pulse by means of a light-emitting diode and a push-pull circuit.

In the field of vehicle technology, the support of the driver is becoming increasingly important. The support ranges from driver assistance systems to the autonomous driving of vehicles. For this purpose, systems are used for optical distance and speed measurement. The LIDAR system (Light Detection and Ranging) plays an important role, which works in a similar way to radar measurement but uses laser beams or other light sources. The LI DAR systems will play an even more important role in the future in advanced driver assistance systems (ADAS) and in autonomous driving. the prevailing strict requirements for functional safety require reliable and sensitive systems so that the right decisions are made even in extreme situations. The systems therefore require very short light pulses in many fields of application. For this purpose, expensive laser diodes are often used to enable pulses whose pulse duration is less than about 10 ns. A main application of such pulsed light sources is the measurement of the light transit time for distance determination, as used, for example, in what is known as the Flash LIDAR.

Since the information of the measurement is located in the flanks of the pulses, a reduction in the pulse length is equivalent to an improvement in the efficiency. This can be directly translated into an improvement in performance. However, especially with LIDAR systems with a long range, the system performance is limited by the permissible emission power of the light source. An efficient light source is therefore just as crucial for system performance as a sensitive sensor.

Conventional LIDAR systems generally use deflectable laser beams which are guided by mirrors. The lasers used, however, have the problem of high energy density to build systems with a long range. Lasers with high energy density can damage the eyes, so that the light output is governed by legal requirements.

Flash LIDAR systems today use dedicated infrared pulse sources. They are limited in their range and sensitivity by the legally limited transmission power to maintain eye safety. Due to the given boundary conditions, the importance of pulsed light sources with short light pulses for the time of flight measurement increases, which is necessary for distance determination or distance determination. The effi ciency of the light transit time measurements is also determined by the pulse length. A Shortening the pulse length increases the efficiency, because with a constant average light output, a higher range can be achieved.

The LIDAR systems known in the automotive art in the prior art are generally constructed with dedicated lighting sources. For reasons of acceptance, one is restricted to the invisible wavelength range and at the same time has to make do with the small dimensions which are predetermined by the space available in the vehicle. Both limitations have a decreasing effect on the maximum transmission power and thus also on the performance of the systems, taking into account the limits for the radiation power due to the avoidable damage to the eyes.

There is thus a great need for an increase in range. This can be achieved in particular with pulsed light sources. In the context of the invention, it has been recognized that a key question is the generation of light pulses for light-emitting diodes, LEDs, or for laser diodes which have steep edges, ie have a steep rising edge and a steep falling edge. The rising edge reflects the switching on, the falling edge the switching off of the diode.

LED pulses are generated in the prior art by switchable current sources or voltage sources. The achievable rise and fall times of the light pulses are typically of the order of 10 ns. In conventional light-emitting diodes and laser diodes, this limit results from the diode-dependent transfer of the junction capacitance in conjunction with parasitic components of the diodes and their terminals. EP 0 470 780 A1 describes a device for improving the pulse shape of an LED, in particular the leading edge. In this case, four bipolar transistors are connected in an H-bridge circuit to operate a light emitting diode, LED. The disclosed circuit must have two resistors in the reverse direction in order to avoid cross-talk as a result of use. to limit currents in the two H-bridges. This limits the turn-off behavior of the circuit. In addition, the proposed circuit must include a current source that requires the integration of at least one other current source transistor into the circuit. The circuit shown is thus not supplied with power, but supplied with power from the existing power source. However, additional power sources cause additional on-chip footprint when the circuit is integrated into an integrated microelectronic circuit. The LED is operated in the switched-off state when the first high-side transistor of the first half-bridge is switched off and the second high-side transistor of the second half-bridge is switched off and at the same time the first low-side transistor of the first half-bridge is switched on is while the second low-side transistor of the second half-bridge is turned off. The light-emitting diode is thus connected only with its anode via the first low-side transistor of the first half-bridge to the power source. This is shown in FIG. 1 of EP 0 470 780 A1. Since the cathode of the LED is not charged in this state, the LED is not connected to a power source even when switched off. In order to generate the shortest possible light pulse, shortly after the first high-side transistor and the two low-side transistors are switched on, the second high-side transistor is switched with a delay t and thus takes over part of the current power source. The LED is switched off exclusively via the first low-side transistor. However, the "Ausräumstrom" is limited by the power source. The LED can only be switched off with the time set by the current source t = Q _L ED / lstromqueiie = CLED XU LED / I current source. The discharge process is also hindered by the resistors. The discharge time is thus increased. Although the circuit is suitable hervorzu call a particularly steep increase in light output. However, a short light pulse of the LED or a steep switch-off edge can not be realized with this circuit due to the parasitic effects mentioned above.

The driving of a LED with two half-bridges is also from the document Wesen, Björn [et al.j: "Fastest way of doing on / off modulation of a LED". 22 ^nd June 201 1, edited 23rd June 2014. 4. pp URL: https: //electronics.stackex- change.com/questions/15818/fastest-way-of-doing-on-off-modulation-of-a-led [accessed 23.01.2018] known. Further half-bridge drives and half-bridge drivers without the use of an LED are known, for example, from "TPS28226 High-Frequency 4-Sink Synchronous MOSFET Drivers", an application note from the company Texas Instruments, and from "2A Synchronous Buck Power MOSFET Driver", an application note from the company. Microchip to microchip product MCP14628, known.

EP 2 761 978 B1 shows an H-bridge circuit for driving LED lamps with different color and polarity. However, the reversal here serves to select different colors. However, the device is not suitable for emitting short light pulses.

EP 0 762 651 A2 describes the switching on of an LED with an initially higher current which is above the then lower operating current. This achieves steep switch-on edges of the light pulse. DE 10 2016 116 718 A1 describes a dimming circuit for LED lights.

The combination of a light pulse source with a TOF camera (time of flight camera) is known for example from DE 10 2014 105 482 A1.

JP S 587941 also describes a light source for short light pulses with a driver circuit, in which initially a positive switch-on pulse is generated, followed by a negative voltage pulse for switching off the LED.

WO 2016/187566 describes a bipolar drive circuit for laser diodes or LEDs which provides two temporally successive pulses of different polarity and different values to deliver ultrashort light pulses with pulse durations in the range of 100 picoseconds to 2 nanoseconds in a laser diode or LED produce.

The US 9,681, 514 B1 and US 9,603,210 B1 each describe control circuits for connecting an LED or light emitting diode, wherein the No. 9,681, 514 B1 discloses a push-pull drive circuit for dimming a light source, in which the output of the push-pull circuit is operated with electrical energy from a positive and a negative supply voltage line.

The documents known in the prior art are primarily concerned with the problem of creating a light pulse which has the shortest possible rise time. How an overall very short light pulse can be generated in light-emitting diodes with a large self-capacitance and how the problem when switching off in terms of area and capacity usually very large LED bulbs is addressed in these documents is not addressed.

There is also a great need in the art for an improved and more reliable measurement system, particularly LIDAR system. In order to increase the range or to allow the visibility of dark objects, the sensitivity of the system must be increased. In principle, this can be done either by a photosensitive sensor or by an improved transmitter (transmitting diode) or by an increased transmission power. However, sensors are already being operated close to the physical limits and technical possibilities. The transmit power, however, is subject to legal restrictions, also to protect people in the vicinity of the system. There is therefore a great need for an improved transmitter diode for measuring systems, in particular LIDAR systems.

The solution to the problem is based on the recognition that an essential task consists in optimizing the outgoing LED used as a transmitting diode or light source. One aspect of the invention relates to generating as fast as possible flanking light pulses with short rise and fall times. Another aspect of the invention relates not only to producing steep light pulses, but also particularly short light pulses without slow rise or fall times of the pulse width. As a rule, in conventional light-emitting diodes, the parasitic effects of the light-emitting diode lead to longer rise and fall Fall times. This applies in particular to light-emitting diodes in vehicle technology, in particular when the light-emitting diodes are also used for illumination purposes.

The present object is achieved with a light source having the features of claim 1 and with a method having the features of claim 16.

The proposed technical solution massively shortens the rise and fall times of an LED light pulse and thus makes it possible to generate light pulses which are extremely short and have a pulse duration of a few nanoseconds, preferably less than 2 nanoseconds. In particular, the switch-off of the light pulses can be greatly shortened. This makes it possible to use light emitting diodes (LEDs) effectively and powerfully in applications such as Flash LIDAR systems. Expensive laser diodes can in many cases be replaced by LEDs (light emitting diodes). According to the invention, the light source for generating light pulses with a short pulse duration in the nanosecond range comprises a light-emitting diode for generating light pulses and a push-pull circuit for driving and powering the light-emitting diode. The light source may preferably be used in a vehicle, such as to be used as part of a LIDAR system for object recognition and distance measurement.

According to the invention, the light-emitting diode of the light source has a first terminal which is connected to an output port of the push-pull circuit. The second terminal of the light-emitting diode is connected to a center potential line, which may preferably be the system ground. The push-pull circuit has a first input port which is connected to a first supply voltage line and its potential. Its second input port is connected to a second supply line and its potential, wherein the second supply line preferably provides a negative potential. The potential between the center potential line (GND) is between the potential of the first supply line and the potential of the second supply line.

The push-pull circuit can be switched to a first state in which positive electrical energy of the first supply line is present at the output port. In a second state of the push-pull circuit, negative electrical energy of the second supply line is present at the output port. The push-pull circuit can be switched between the first and the second state.

When the push-pull circuit is switched to the first state and then positive electrical energy is present at the output port, the light emitting diode emits electromagnetic radiation, for example in the form of visible or non-visible light or in the infrared range. In this case, the first terminal of the light emitting diode is at a positive potential which is greater than the potential of the middle potential line, which is connected to the second terminal of the light emitting diode.

According to the invention, the light source is designed such that the amount of the difference between the potential of the middle potential line and the potential of the first supply line is smaller than the amount of the difference between the potential of the middle potential line and the potential of the second supply line. The amount of the positive voltage applied in the first state to the first terminal of the light-emitting diode (LED) is therefore greater than the amount of the negative voltage which is present in the second state at the first terminal of the light-emitting diode.

While in the first state of the push-pull circuit, the LED is turned on, so that the charge carriers are built in the light emitting diode, in the second state of the push-pull circuit at the first terminal of the light emitting diode to a negative voltage. By applying a back-to-back reverse voltage to the LED, the charge stored in the LED does not have to be dissipated by "radiative recombination" when switched off but mainly by "sucking off" by means of the applied counter field. This eliminates the charge carriers from the space charge zone of the LED. This concern of the negative voltage at the first connection of the light-emitting diode leads to a very fast switching off of the light-emitting diode. Ultimately, a switch-off pulse is generated in the LED, which has a particularly steep edge. The large switch-off edge of the light pulse of the light-emitting diode leads in measuring systems to a large bandwidth and a correspondingly high resolution. As a result, the luminous pulse or light pulse of the LED can also be shortened overall since both the rise time and the fall time of the luminous pulse are very short and are preferably less than 1 ns each. The light source according to the invention is therefore particularly suitable for use in the vehicle.

Since the push-pull circuit according to the invention has no internal current source, as described, for example, in EP 0 470 780 A1, the parasitic effects and boundary conditions due to the current source also do not occur. The circuit is only voltage controlled, but not current controlled and therefore allows shorter turn-off and thus a steeper edge when turning off.

In contrast to the general technical view, according to which the application of a reverse voltage to a light-emitting diode would drastically shorten the service life, the present invention makes use of the application of this reverse voltage. In this case, it was recognized that the magnitude of the negative voltage (potential difference between the second supply line and the middle potential line) can and should be greater than the magnitude of the "flux voltage" (operating voltage). This is also in contrast to the generally prevailing opinion.

In the context of the invention, it was recognized that the countervoltage can assume values which, for example, correspond to twice or three times the value of the forward voltage of the light-emitting diode. Preferably, higher values of the reverse voltage are possible, for example, five times, ten times or twenty times the flux voltage. With very careful quality management, even reverse voltages of fifty times the forward voltage can be applied to the LED without damaging it. Such reverse voltages or clearing voltages at the light-emitting diode were tested in the context of the invention, with the clearances in ranges of 20 V to 40 V and even up to 60 V, while the forward voltages at 1.2 V for a series connection with few LEDs were realized.

The light source according to the invention is therefore particularly well suited as a light transmitter of a LIDAR system. The effect of rapid turn-off and the associated steep cut-off edge creates a particularly wide bandwidth of the system. This leads to a high triggering and to a long range of the measuring system.

The light source according to the invention and its advantages are particularly evident in light-emitting diodes which are used for illumination purposes (so-called illumination light-emitting diodes or illumination LEDs). While the monofrequency laser diodes radiate coherent radiation and, after the high stimulated emissions have been switched off, a rapid drop of the charge carrier density in the barrier layer occurs, the illumination barrier initially essentially remains in the case of illumination LEDs since the stimulated emission is only very low. As a result, the illumination LEDs light up for a very long time, at least for much longer than laser diodes. Finally, lighting LEDs are developed for long afterglow, also to minimize the perception of flicker due to pulse width modulation (PWM) control. In that regard, the requirements for laser diodes and signal transmission diodes (signal transmission LEDs) are contrary to illumination LEDs. Illumination LEDs are thus more sluggish than the faster signal transmission diodes, which have a significantly smaller junction capacitance. The junction capacitance of a laser diode is in the range of about 50 pF. In contrast, a lighting LED is a multiple, often in the range of several nanofarads, in particular from 10 nF to 100 nF.

The illumination LEDs known in the prior art are generally fluorescence LEDs. Here, a fluorescent layer is illuminated by a UV LED. However, these LEDs can not be modulated because the fluorescence layer is luminescent. For headlamps, RDG LEDs are therefore often used, in which the white fluorescent fluorescent layer is replaced by three color LEDs whose primary colors are actively mixed to form white light.

Since illumination LEDs are preferably distinguished by a diffuse light emission, an individual control and synchronization of the individual LEDs preferably takes place, in particular during the switch-off process, when a negative voltage is applied to the first terminal of the light-emitting diode. In a preferred embodiment, the light source comprises three light-emitting diodes, which preferably each have a different color, and three driver circuits (push-pull circuit), so that each LED is driven by a push-pull circuit. The control and synchronization is preferably carried out by a control unit, which controls the control inputs of the LEDs.

The application of a magnitude greater reverse voltage than the operating voltage leads to the rapid clearing of the space charge zone of the light-emitting diode, in particular in the case of illumination LEDs. The junction capacitance of the diode is eliminated quickly. This effect is particularly noticeable in light-emitting diodes, which have a high intrinsic capacity and thus inertia. In a preferred embodiment of the invention, the light emitting diode is not only used as a radiation source or transmitter in a measuring system, but at the same time for lighting purposes, such as headlights or vehicle headlights. These LEDs have a large inertia and self-capacitance, so that the circuit according to the invention is even more effective. Overcoming the inertia of the light source is achieved by driving the LED by means of the push-pull circuit.

So that the light-emitting diode can also be used simultaneously as a transmitting diode of a measuring system and as a lighting means or headlight in a vehicle, the first terminal of the light-emitting diode is preferably connected to a third supply voltage via a third switch. The light-emitting diode can then be supplied with electrical energy from the third supply line, wherein the third supply line likewise has a positive potential, that is to say a positive voltage is applied to the first connection. In this way, the LED can be used for lighting purposes. The voltage potential of the third supply line can be selected accordingly. The potential of the third supply line can thus be independent of the potential of the other supply lines, wherein the potential of the first supply line and the potential of the second supply line may differ from each other. Preferably, the push-pull circuit can be switched to a third state in which the output port of the push-pull circuit is disconnected from the first supply line and from the second supply line. This is preferably done when the light source is operated for lighting purposes.

Thus, it is preferable to switch between pulsed operation of the light-emitting diode in which it is used in a measuring system and continuous operation with a turn-on time of at least 1 s for illumination purposes. When used in a motor vehicle, the light source is used as a headlight. The switched-on headlight is switched off whenever a measurement with a measuring system, for example a LIDAR system, takes place. Switching off is generally carried out for a period of less than or equal to 1 ms, preferably in the microsecond range, very preferably in a range of less than 1 mb. During this switch-off time, when the third supply line is disconnected from the LED, the LED is switched to a pulse mode in which the push-pull circuit is not operated in the third state. The push-pull circuit is first in the first state switched, whereby the LED is turned on again. Subsequently, it is switched to the second state, whereby the switching off of the LED takes place. In this case, the blocking capacity of the light-emitting diode is removed, thus freeing the space charge zone from charge carriers. As described above, this produces a steep cut-off edge for switching off the light-emitting diode. Subsequently, the light-emitting diode is switched back to the lighting mode. Since the switching off of the lighting operation of the light-emitting diode for a period of less than 1 ms, it is not visible to the human eye. The user can not detect a changeover from lighting operation to measuring operation. There is thus no restriction on the use of the light source as a vehicle headlight.

In the context of the invention has also been recognized that the vote of the time duration, for which the counter-voltage or Ausräumspannung applied to the light emitting diode, is important. If the reverse voltage is still present even when the space charge zone is emptied (barrier layer capacitance is removed), the LED will be damaged or destroyed. It has been recognized that the period of time for which the push-pull circuit is switched to the second state must be limited.

In a preferred embodiment of the light source, the light source has a current monitoring circuit with which the discharge current occurring in the light-emitting diode is monitored when the push-pull circuit is switched to the second state. When a given current limit value is undershot, the countervoltage which is applied to the first terminal of the light-emitting diode is preferably reduced. Preferably, the back voltage is then reduced to a predetermined continuous-lock voltage value. This is the voltage value at which the LED will not be damaged when operated in reverse operation. Particularly preferably, the reverse voltage at the light-emitting diode is reduced below the predetermined continuous-locking voltage value. The continuous-lock voltage value depends on the LED used and is either known or can be determined by simple measurements. In a likewise preferred embodiment, the light source comprises a voltage monitoring unit which monitors the reverse voltage or reverse voltage applied to the light-emitting diode when the push-pull circuit is switched to the second state. The discharge of the junction capacitance is preferably carried out with an increased voltage via a series resistor, which can be formed by the internal resistance of the discharge voltage source. If the junction capacitance is not yet discharged, then the junction capacitance shorts the voltage across the diode. As the discharge current sinks, the voltage increases. When a predetermined voltage limit value of the voltage across the light-emitting diode is exceeded, the countervoltage is reduced, for example below a predetermined continuous-locking voltage value, preferably to zero. Alternatively and also preferably, the second supply voltage of the light source can be separated from the output port of the push-pull circuit, so that no voltage in the reverse direction is applied to the light-emitting diode more.

In a further preferred embodiment, the time duration in which the push-pull circuit is switched to the second state is limited. The second state is terminated at a predefinable time, so that it is applied only for a predetermined period of time. The time can be determined or calculated if the exact configuration of the light source with all the parasitic parameters of all circuit elements is previously known. The switch-off time then essentially corresponds to the two above-mentioned times, ie when the discharge current falls below a current limit value or the clearance voltage exceeds a voltage limit value.

Preferably, the predetermined period of time after which the second state of the push-pull circuit is turned off is at most 2 ns long. Particularly preferably, the time duration is at most 1 ns, more preferably at most 0.5 ns. For some configurations of the light source, the predetermined time is at most 0.2 ns, more preferably at most 0.1 ns. However, it may also be lower, for example at most 0.05 ns. Especially with the short switching times of the second state, which is a very fast clearing As a result of the blocking layer capacitance of the light-emitting diode, very short light pulses can be realized overall during measuring operation since the switch-off duration is also low and thus the switch-off edge of the light-emitting diode is very steep.

In the context of the invention, it was recognized that after the application of the blocking voltage (countervoltage) or evacuation voltage, ie after the switching of the push-pull circuit to the second state, the voltages are again to be "normalized" to avalanche effects in the space charge zone to avoid the light emitting diode. Therefore, the push-pull circuit can preferably be switched to a third state in which the output port is disconnected from both supply lines. The third state of the push-pull circuit, in which the output port is disconnected from both supply lines, is referred to as the tristate state.

In a preferred embodiment, the light source has a short-circuit line with a fourth switch. The short-circuit line connects the first connection of the light-emitting diode to the second connection of the light-emitting diode, so that the light-emitting diode can be short-circuited when the switch is closed. However, the short-circuiting of the light-emitting diode takes place only if previously the push-pull circuit is switched to its third state.

In a further preferred embodiment, the light source comprises a measuring unit or voltage monitoring unit which measures the open-circuit voltage applied to the light-emitting diode when the push-pull circuit is switched to the third state. Preferably, the quiescent voltage is measured when the push-pull circuit has left the second state, so no more negative voltage is applied to the first terminal of the light emitting diode. Particularly preferably, the quiescent voltage is measured at the light emitting diode between two drive pulses. The measurement thus takes place when the light-emitting diode is no longer switched to the second state and has not yet been switched to the first state for the next measuring pulse. Ideally, the open circuit voltage at the LED is zero when the push-pull circuit has left the second state and the first terminal of the LED is disconnected from both supply lines, which corresponds to the third state of the push-pull circuit. The space charge zone of the LED is then completely cleared. If the space charge zone still contains charges, the rest voltage is different from zero. It is then controlled by adjusting the negative switching pulse at the output port of the push-pull circuit and thus at the first terminal of the light emitting diode. In a preferred embodiment, the quiescent voltage is regulated to zero or to a practically negligible value, preferably by fine-tuning or fine-timing of the charge or discharge pulses (positive voltage pulse or negative voltage pulse at the first terminal of the LED). This can be done, for example, by adjusting the pulse duration and / or edge steepness of the on-control pulses or by changing the voltage level of the control pulses, for example by using a charge pump or another, preferably controllable voltage increase unit. The control can be carried out by means of a controller or a control unit.

Alternatively and also preferably, the middle potential, ie the potential of the center potential line, can be shifted or changed.

In a particularly preferred embodiment, the switching duration during which the push-pull circuit is switched to the first state is at most 0.5 ns. The switching duration is particularly preferably not more than 0.2 ns, more preferably not more than 0.1 ns and particularly preferably 0.05 ns. This makes it possible to achieve a particularly steep rise in the light pulse which is emitted by the light-emitting diode. This is also a prerequisite for emitting the shortest possible light pulse from the light emitting diode.

In a preferred embodiment of the light source, the light emitting diode emits a short pulse of light emitted as electromagnetic radiation in Nanosecond range. The generated light pulse has a pulse duration of at most 1 ns. Preferably, the light pulse is at most 0.7 ns long. More preferably, the pulse duration of the light pulse emitted by the light-emitting diode is at most 0.5 ns, more preferably at most 0.3 ns and very preferably at most 0.1 ns. This leads to steep and extremely short light pulses, which are sufficient for a LIDAR system. Since the pulse duration is so short, the height of the light pulse can be very high, since only the entire energy content, ie the transmission power, is subject to certain limits. Thus, LIDAR systems can be realized with the light source according to the invention, which have particularly long ranges. The range is twice as large compared to conventional ranges, five times as large to ten times as large for very short pulse durations. With extremely narrow pulses even greater ranges can be achieved.

In a preferred embodiment, the light source has a charge pump between one of the first or second supply lines and the output port, so that the potential of the corresponding supply line is increased. The charge pump increases the value of the potential of the first and the second supply line. Depending on the design of the charge pump, a voltage doubling or multiple duplication can take place. It would also be conceivable to switch the polarity of the voltage. Of course, other DC voltage converters are possible. Preferably, the charge pumps are arranged between the respective supply line and the switching element in the respective line strand, so that the capacitances in the charge pump have no or only a negligible effect on the signal shape for driving the light-emitting diode.

The use of charge pumps in the light source results in a potential difference between the outputs of the charge pumps which is greater than the potential difference between the two supply voltages (first supply line and second supply line). The present object is also achieved by a method for generating a light pulse by means of a light-emitting diode, wherein the light-emitting diode can be preferably used for use in a vehicle. The method comprises providing a light source with a light-emitting diode for generating the light pulse and with a push-pull circuit for driving and powering the light-emitting diode, which has a first terminal and a second terminal. The first terminal of the light emitting diode is connected to an output port of the push-pull circuit. The second terminal of the light-emitting diode is connected to a center potential line. According to the invention, the push-pull circuit is switched to a first state, in which the output port of the push-pull circuit is connected to a first supply line and thus supplies the light-emitting diode with electrical energy. The potential of the first supply line is positive and greater than the potential of the middle potential line.

According to another step of the method, the push-pull circuit remains in the first state for a first time period. The first time period is usually at most 1 ns, preferably at most 0.2 ns.

In a further step, the push-pull circuit is switched from the first state to a second state, in which the output port of the push-pull circuit is connected to the second supply line. The connection of the output port to the first supply line is disconnected. The potential of the second supply line is negative and smaller than the potential of the middle potential line. In a further step, the push-pull circuit remains in the second state for a second time period, which is preferably also at most 1 ns, preferably at most 0.5 ns. The second time period corresponds to the time up to which the discharge current does not fall below a predetermined current limit value or the countervoltage at the light-emitting diode does not exceed a predetermined voltage limit value. The second time period can also be equal to a predetermined value, which can be determined or calculated with knowledge of all parasitic parameters of the overall configuration. The light source is designed and arranged such that the magnitude of the difference between the potential of the center potential line and the potential of the first supply line is smaller than the amount of the difference between the potential of the center potential line and the potential of the second supply line. In other words, the light source is switched such that the blocking voltage or clearing voltage, which is applied to the light emitting diode, is greater than the operating voltage of the light emitting diode, preferably by a multiple greater.

In a preferred embodiment, the first and second time periods of the method are selected such that the light emitting diode emits a light pulse whose pulse duration is at most 1.5 ns, preferably at most 1.0 ns. Further preferably, the pulse duration of the light pulse of the light-emitting diode is at most 0.7 ns, preferably at most 0.5 ns, more preferably at most 0.2 ns and particularly preferably at most 0.1 ns. The goal here is to generate a light pulse corresponding to the requirements of a measuring system by means of the light emitting diode of the light source.

In a further preferred embodiment of the method according to the invention, the following steps are carried out: switching the push-pull circuit into a third state, in which both supply lines are separated from the output port. In a further step, the closing of a third switch connects the first terminal of the light-emitting diode to a third supply line, the potential of the third supply line being positive. This results in a radiation of electromagnetic radiation of the light emitting diode for illumination purposes. The light-emitting diode or the light source can therefore be used in particular for illumination purposes, for example as a headlight of a vehicle. The potential of the third supply line may deviate from the potential of the other supply lines.

In a likewise preferred embodiment of the method, the push-pull circuit is switched to its third state, in which both suppliers supply lines are separated from the output port. In a further step, the closing of a fourth switch closes a short-circuit line between the first terminal of the light-emitting diode and the second terminal of the light-emitting diode and thus short-circuits the light-emitting diode. Of course, the third switch and the fourth switch must not both be closed, which is obvious to the person skilled in the art. The control of the light source according to the invention is designed accordingly.

Preferably, the switching of the push-pull circuit to the third state is done by disconnecting the supply line from the output port. This separation is carried out according to the invention by opening the switching elements of the push-pull circuit.

Preferably, the method comprises the following steps: monitoring the discharge current occurring at the light-emitting diode while the push-pull circuit is switched to the second state; Detecting an undershooting of a predetermined current limit value; Reducing the voltage applied to the first terminal of the light-emitting diode, preferably to a predetermined continuous-locking voltage value, particularly preferably to a voltage value lying below the predetermined continuous-locking voltage value.

Also preferably, the method may comprise the following steps: monitoring the voltage applied to the light-emitting diode while the push-pull circuit is switched to the second state; Detecting an exceeding of a predetermined voltage limit value; Reducing the voltage applied to the first terminal of the light-emitting diode, preferably to a predetermined continuous-off voltage value, particularly preferably to a voltage value lying below the predetermined continuous-off voltage value; or disconnecting the second supply voltage from the output port of the push-pull circuit.

In a preferred embodiment of the method, a measuring device is used for measuring the open circuit voltage of the light emitting diode. In one Step, the rest voltage is measured at the light emitting diode when the push-pull circuit has left the second state and the first state has not yet (re) occupied. The push-pull circuit is preferably switched to the third state in which the switching elements or transistors of the push-pull circuit block and preferably none of the supply lines is connected to the light-emitting diode.

Preferably, the method comprises the further step: adjusting the voltage at the first terminal of the light-emitting diode, preferably by means of a regulator, when the push-pull circuit is switched to the first state and / or switched to the second state, optionally until the Idle voltage at the LED is zero. The adaptation preferably takes place by changing the voltage at the output port of the push-pull circuit, particularly preferably by the use of a charge pump.

In a preferred further step, the control pulses are adapted in the second state of the push-pull circuit, preferably by changing the edge steepness or the pulse duration of the control pulses which are applied to the first terminal of the light-emitting diode.

For the sake of completeness and unambiguousness, it is pointed out that the light emitting diode emits electromagnetic radiation when it is supplied with positive electrical energy. Although it is theoretically correct that a LED also emits electromagnetic radiation to a small extent when it is biased in the reverse direction. This purely theoretical consideration was disregarded, so that the light-emitting diode is regarded here as an ideal insofar as it only emits light when energized in one direction, which corresponds to the practice-relevant case.

The invention will be described in more detail below with reference to a few selected exemplary embodiments in conjunction with the accompanying drawings. Show it:

Figure 1 shows a first embodiment of the light source according to the invention; Figure 2 shows a second embodiment of the light source according to the invention;

FIG. 3 shows a third embodiment of the light source according to the invention;

FIG. 4 shows a fourth embodiment of the light source according to the invention with charge pumps; FIG. 5 shows a further embodiment of the light source according to the invention;

 and

FIG. 6 shows the simulation of the current through an LED of the invention

 Light source compared to two LEDs with other attachments.

FIG. 1 shows a light source according to the invention with a push-pull circuit 2 and a light-emitting diode 3. The push-pull circuit 2 is used for driving and powering the light-emitting diode 3.

The light emitting diode has a first terminal 10, which is the anode. A second terminal 12 of the light-emitting diode 3 forms the cathode. The first terminal 10 of the light-emitting diode 3 is connected to an output port 20 of the push-pull circuit 2. The second terminal 12 is connected to a center potential line 14, which is also referred to as Ground (GND). Preferably, the center potential line 14 is the system ground.

The push-pull circuit 2 has a first input port 22 and a second input port 24. The push-pull circuit 2 has two switching elements 26. The switching element 26 between the first input port 22 and the output port 20 is a first transistor 28. Between the output port 20 and the second input port 24, the switching element 26 is a second transistor 30. The two transistors 28, 30 are each controlled via a control terminal 32 and 34. The control terminals are controlled by a control unit 36, which is used to drive the light source 1. Of course, contrary to the one implemented here with two transistors 28 and 30 Circuit also a more complex interconnection with multiple electronic components of the same function can be used.

The first transistor 28 of the push-pull circuit 2 can be switched via the first control terminal 32 by means of the first control electrode 38 in a first or a second state. In the first state of the first transistor 28, the first input port 22 of the push-pull circuit is connected to the output port 20 in a lower-impedance manner than in a second state. The low-resistance state in which the first transistor 28 turns on is referred to as on-state. In this case, the first input port 22 is connected to the first supply line 42. The potential of the first supply line 42, also called VCC, is positive, so that a positive voltage is applied to the anode (first terminal 10) of the light-emitting diode 3 and the light-emitting diode 3 electromagnetic radiation in the form of light (visible or invisible) or emit infrared radiation or ultraviolet radiation.

When the first control electrode 38 switches the first transistor 28 to high impedance, in any case higher impedance than in the first state, a second state of the first transistor 28 is reached, which is referred to as the off state. The first supply line 42 is then separated from the output port 20 of the push-pull circuit 2, in any case so high impedance that the LED 3 does not light and emits no or in practice only negligible electromagnetic radiation.

The second transistor 30 can also be switched by the control unit 36 via the second control terminal 34 and a second control electrode 40 into a low-impedance on state or a high-impedance off state. In the on state, the second transistor is lower impedance than in the off state, so that the output port 20 is connected to a second supply line 44 via the second input port 24. The second supply line 44 is also referred to as (-VCC) and has a potential which is lower than the potential of the first supply line 42. Preferably, the potential of the second supply line 44 is negative. The potential of the middle potential line 14 lies between the potential of the first supply line 42 and the potential of the second supply line 44.

In the off state, the second supply line 44 is connected to the output port 20 via the low-resistance switched second transistor 30, so that the negative potential is applied to the first terminal 10 (anode) of the light-emitting diode 3. The LED 3 is thus operated in the reverse direction.

In a first state of the push-pull circuit 2, the first transistor 28 is low-resistance, while the second transistor 30 is switched to high impedance. This is done by the control unit 36, which may be part of the light source 1, or a separate component. In the first state of the push-pull circuit 2, the light emitting diode 3 radiates electromagnetic radiation.

In a second state of the push-pull circuit, the second transistor 30 is switched to low impedance, while the first transistor 28 is switched high impedance. At the anode of the light emitting diode 3 is then the negative potential of the second supply line 44 at. The light emitting diode 3 is operated in the reverse direction, so that in the blocking capacity of the light emitting diode 3 located charge can be eliminated.

In a third state of the push-pull circuit 2, both transistors 28 and 30 are switched to high impedance, so that there is no connection to one of the two supply lines 42, 44. In order to solve the problem of a large diode capacitance of the light emitting diode 3, which leads to a large inertia of the light emitting pulse of the light emitting diode 3, the invention proposes that the amount of the potential difference between the potential of the first supply line 42 and the center potential of the Center potential line 14 is smaller than the amount of the potential difference between the potential of the second supply line 44 and the middle potential of the center potential line 14. This condition contradicts the statements to be found in the prior art that a high reverse voltage is life-reducing and therefore should be avoided. The push-pull circuit 2 can be switched to the second state only for a certain period of time, during which the potential of the second supply voltage 44 is applied to the first terminal 10 of the light-emitting diode 3. As soon as the space charge zone or the junction capacitance of the light-emitting diode 3 is emptied, ie if there are no more free charge carriers in the space charge zone, the second state of the push-pull circuit 2 must be terminated. For this purpose, for example, the discharge current in the light-emitting diode 3 can be measured or the voltage drop across the light-emitting diode 3. If all the parameters and parasitic parameters of the wiring of the light source 1 are known, the time duration for operating the push-pull circuit 2 in the second state can be determined and the second state can be ended after the predetermined time.

Figure 2 shows a preferred embodiment of the light source 1 according to the invention, in which the first terminal 10 of the light emitting diode 3 (anode) is connected via a feed line 46 to a third supply line 48. In the feeder 46, the switch 50 is arranged, which can also be designed in the form of a transistor. The closing of the third switch 50 establishes the connection of the anode of the light-emitting diode 3 with the third supply line 48. Preferably, when closing the third switch 50, the push-pull circuit 2 is switched to the third state. The LED 3 is then from the third

Supply line 48 is powered. This is the case when the light-emitting diode 3 is used for example in continuous operation for lighting purposes, such as a headlight of a vehicle. Preferably, the potential of the third supply line 48 is positive. In a preferred embodiment, the magnitude of the voltage difference between the potential of the third supply line 48 and the potential of the center potential line 14 is less than the magnitude of the voltage difference between the potential of the second supply line 44 and the potential of the center potential line 14. FIG. 3 shows a likewise preferred embodiment in which, in comparison to the embodiment according to FIG. 1, a short-circuit line 52 is additionally connected via the light-emitting diode 3. The short-circuit line 52 has a fourth switch 54, which is referred to as a short-circuit switch. By closing the fourth switch 54, the light-emitting diode 3 and its space charge zone can be normalized in order to prevent avalanche effects, in particular at the edge of the space charging zone. The "normalization" takes place after the removal of the charge carriers from the space charge zone or junction capacitance. Before the fourth switch 54 can be closed, the push-pull circuit 2 must be switched to its third state so that its output port 20 is not connected to any of the two supply lines 42, 44.

Of course, the embodiments of FIGS. 2 and 3 can be combined so that the short-circuit line 52 can also be provided if the light-emitting diode 3 is additionally connected to a third supply line 48.

FIG. 4 shows a further embodiment of the light source 1, in which a first charge pump 56 is arranged between the first input port 22 of the push-pull circuit 2 and the first supply line 42 in order to increase the potential of the first supply line 42. The charge pump 56 serves to increase the voltage, whereby the potential difference between the first input port 22 of the push-pull circuit and the potential of the middle potential line 14 is increased.

Between the second supply line 44 and the second input port 24 of the push-pull circuit, a second charge pump 58 is provided according to FIG. 4 in order to increase the magnitude of the potential at the second input port 24. Thus, the potential difference between the first input port 22 and the second input port 24 when using the two charge pumps 56 and 58 is greater than the potential difference between the first supply line 42 and the second supply line 44. Of course, it is also possible to use only one charge pump, for example, the first charge pump 56, when the fastest possible switching on the LED 3 is to be realized. Another possibility is to use only the second charge pump 58 when the light-emitting diode 3 is to be switched off particularly quickly and, for this purpose, a high reverse voltage must be present in the reverse direction at the light-emitting diode 3.

Since charge pumps generally typically have only a small charge storage capacity, they are typically unsuitable for permanent illumination. In a mixed operation for metering and lighting purposes, therefore, the push-pull circuit 2 should be operated in its third state, for example by using a multiplexer.

Of course, the use of the charge pumps 56 and 58 may be combined with either or both of the embodiments of FIG. 2 or 3. Figure 5 shows a specific preferred embodiment of the invention. The control unit 36 signals via a status and / or synchronization signaling 61 to a controller 60 in which state the device (light source 1) is located. This may be a first state in which the first transistor (T1) 28 conducts and the second transistor (T2) 30 blocks. This may be a second state in which the first transistor 28 blocks and the second transistor 30 conducts. This may be a third state in which the first transistor 28 is off and the second transistor 30 is off. After switching on the LED (light emitting diode 3) in the first state for a first time period Ti, the second state follows for a second time period T ₂ and then the third state for a third time period T ₃ . Preferably, a measuring device or the controller 60 now measures the residual LED voltage at the first connection 10 at a measurement time in the third time period T ₃ in which the push-pull circuit 2 and thus the light source 1 is in the third state the light-emitting diode 3 against the reference potential (center potential line 14 or system ground or GND). If this LED residual voltage is positive, not all charge carriers of the space charge zone of the light-emitting diode 3 have been cleared out. The controller 60 then increases the charge removal in the second state or decreases the charge storage in the first state. The increase in charge removal is preferred. A first possibility is that the controller 60 extends the second period T ₂ to increase the charge removal. For this purpose, the controller 60 signals via a first signaling line 62, this extension of the second time period T ₂ to the control unit 36th

A second possibility is that the regulator 60 further lowers the negative voltage at the second input port 24 of the push-pull circuit 2, thus increasing the amount of the negative voltage, in order to increase the charge drainage. For this purpose, the controller 60 signals, for example via a second signaling line 63, this reduction to the second charge pump 58 or another suitable voltage regulation of the potential of the second input port 24.

A third, less preferred option is that the regulator 60 reduces the positive voltage at the first input port 22 to reduce charge storage. For this purpose, the controller 60 signals, for example via a third signaling line 64, this reduction to the first charge pump 56 or another suitable voltage regulation of the potential of the first input port 22.

If the residual LED voltage is negative, then too many charge carriers of the space charge zone of the light-emitting diode 3 have been removed. The controller 60 then decreases the charge removal in the second state of the push-pull circuit 2 or increases the charge storage in the first state of the push-pull circuit 2. The reduction of the charge removal is preferred.

A further preferred possibility for regulating the open circuit voltage of the light-emitting diode 3 is that the regulator 60 shortens the second time period T _{2 in order} to reduce the charge removal. For this purpose, the controller 60 signals This shortening of the second time period T ₂ to the control unit 36 via the first signaling line 62.

Another preferred possibility is that the controller 60 further increases the negative voltage at the second input port 24 in order to reduce the charge removal, that is, reduces the amount of the negative voltage. For this purpose, the regulator 60 sigals, for example via the second signaling line 63, this increase to the second charge pump (58) or another suitable voltage regulation of the potential of the second input port 24.

A third, less preferred option is for the charge storage increase regulator 60 to increase the positive voltage at the first input port 22. The controller 60 signals, for example, via the third signaling line 64, this increase in the voltage to the first charge pump 56 or other suitable voltage regulation of the potential at the first input port 22. Preferably, the measurement time before the end of the third period and after the end of the third Period T ₃ and after the settling of the potential at the first terminal 10 of the LED 3.

Preferably, the controller 60 is a PID controller or a controller with integrating control characteristic, which controls the residual LED voltage to zero. Of course, the adaptation and regulation of the quiescent voltage of the light-emitting diode 3 as well as the components necessary for this according to FIG. 5 can be combined with one or more of the embodiments according to FIGS. 2 to 4. It is also possible to combine all the embodiments of FIGS. 2 to 5. FIG. 6 shows a time diagram of a simulation of three different transistor circuits. Here, the current is removed by the light emitting diode 3 according to Figure 1 over time. When using a current driver with 20 mA current instead of a push-pull circuit results for the light emitting diode 3, the current curve c shown in Figure 5. The use of a voltage driver (3.3 V) leads to a current curve b. The push-pull circuit 2 according to the invention with a maximum voltage of 40 V generates the curve a. As can be clearly seen, the proposed method and the use of a push-pull circuit 2, in which the switching off of the light-emitting diode 3 by applying a negative voltage from the second supply line 44, produces a significantly shorter pulse LED 3 and for a quick shutdown.

Claims

claims

1. Light source for generating light pulses with a short pulse duration in the nanosecond range, in particular for use in a vehicle, comprising a light emitting diode (3) for generating light pulses and a push-pull circuit (2) for driving and for energy supply the light-emitting diode (3), the light-emitting diode (3) having a first terminal (10) which is connected to an output port of the push-pull circuit (2) and a second terminal (12) which is connected to a center potential lead (10). 14), the push-pull circuit (2) has a first input port (22) connected to a first supply line (42) and a second input port (24) connected to a second supply line (44). is connected, the potential of the center potential line (14) between the potential of the first supply line (42) and the potential of the second supply line (44), the push-pull circuit (2) gesc in a first state can be maintained, in which at the output port (20) positive electrical energy of the first supply line (42) is applied, and in a second state can be switched, at the output port (20) negative electrical energy of the second supply line (44) is applied, the light emitting diode (3) emits electromagnetic radiation when the

Push-pull circuit (2) is switched to the first state, the magnitude of the difference between the potential of the center potential line (14) and the potential of the first supply line (42) is less than the amount of the difference between the potential of the center potential line (14) and the potential of the second supply line (44).

2. Light source according to claim 1, characterized in that in the second

State of the push-pull circuit (2) of the light emitting diode (3) occurring discharge current is monitored and falls below a predetermined current limit value, the voltage applied to the first terminal of the light emitting diode (3) voltage is reduced, preferably to a predetermined continuous blocking voltage value, particularly preferably to a voltage value lying below the predetermined continuous blocking voltage value.

3. The light source according to claim 1, characterized in that in the second state of the push-pull circuit (2) the voltage applied to the light-emitting diode (3) is monitored and the second supply voltage is exceeded when a predetermined voltage limit value is exceeded the output port of the push-pull circuit (2) is disconnected.

4. Light source according to claim 1, characterized in that the switching duration during which the push-pull circuit (2) is switched to the second state is not longer than a predetermined period of time, preferably at most 2 ns, more preferably at most 1 ns, more preferably at most 0.5 ns, further preferably at most 0.2 ns and very preferably at most 0.1 ns.

5. Light source according to one of the preceding claims, characterized in that the push-pull circuit (2) comprises two switching elements (26) by means of which the output port (20) with the supply lines (42, 44) are interconnected can, wherein the switching elements (26) are preferably switches, particularly preferably transistors (28, 30).

6. Light source according to the preceding claim, marked thereby, that the push-pull circuit (2) has two control terminals (32, 34), each of which controls a switching element (26).

7. Light source according to one of the preceding claims, characterized in that the push-pull circuit (2) can be switched to a third state in which the output port (20) of both supply lines (42, 44 ) is disconnected.

8. Light source according to the preceding claim, characterized marked, that the first terminal (10) of the light emitting diode (3) via a third switch (50) to a third supply line (48) is connected, so that the light emitting diode (3) electrical energy from the third supply line (48) can be supplied and used for lighting purposes.

9. Light source according to claim 7, characterized in that a short-circuiting line with a fourth switch (54) between the first terminal (10) and the second terminal (12) of the light-emitting diode (3) is provided, with the the light emitting diode (3) can be shorted.

10. A light source according to claim 7, characterized in that a measuring device for measuring the open circuit voltage of the light-emitting diode (3) is provided, which is designed and configured to measure the open circuit voltage at the light-emitting diode (3), preferably when Push-pull circuit (2) is switched to the third state.

1. The light source according to claim 1, wherein the switching period during which the push-pull circuit is switched to the first state is at most 1 ns, preferably at most 0.5 ns , more preferably at most 0.2 ns, more preferably at most 0.1 ns and very preferably at most 0.05 ns.

12. Light source according to one of the preceding claims, characterized in that the light emitting diode (3) emits light when electromagnetic radiation is emitted, and that the generated light pulse has a pulse duration of at most 2 ns, preferably of at most 1 ns, on preferably not more than 0.5 ns, more preferably not more than 0.3 ns and very preferably not more than 0.1 ns.

13. Light source according to one of the preceding claims, characterized in that the center potential line (14) is the system ground.

14. Light source according to one of the preceding claims, characterized in that between one of the supply lines (42, 44) and the output port (20) a charge pump (56, 58) is arranged, so that the potential of the corresponding supply line (42, 44) is increased.

15. Light source according to the preceding claim, characterized in that in each case between the supply line (42, 44) and the output port of the push-pull circuit (2) a charge pump (56, 58) is arranged, so that the potential difference between the outputs of the charge pumps (56, 58) is greater than the potential difference between the two supply lines (42, 44).

16. A method for generating a short light pulse by means of a light emitting diode of a light source, in particular for use in a vehicle, comprising the following steps:

Providing a light source (1) with a light emitting diode (3) for generating the light pulse and with a push-pull circuit (2) for driving and for supplying energy to the light-emitting diode (3), the first

Connection (10) and a second terminal (12), wherein the first terminal (10) with an output port (20) of the push-pull circuit (2) is connected and the second terminal (12) of the light emitting diode (3) a center potential line (14), Switching the push-pull circuit (2) in a first state in which the output port (20) of the push-pull circuit (2) with a first supply line (42) is connected and so the light emitting diode (3) with electrical energy supplied, wherein the potential of the first supply line (42) is positive and is greater than the potential of the center potential line (14),

Staying in the push-pull circuit (2) in the first state for a first period of time,

Switching the push-pull circuit (2) in a second state, in which the output port (20) of the push-pull circuit (2) is connected to a second supply line (44), wherein the potential of the second supply line (44) is negative and smaller than the potential of the center potential line (14),

Lingering of the push-pull circuit (2) in the second state for a second time period, wherein the amount of the difference between the potential of the Mittenototen- tialleitung (14) and the potential of the first supply line (42) is smaller than the amount of the difference between the potential of the middle potential line (14) and the potential of the second supply line (44).

17. The method according to the preceding claim, characterized by the step that the first time period and the second time period are selected such that the light emitting diode (3) emits a light pulse whose pulse duration at most 1, 5 ns, preferably at most 1, 0 ns, more preferably at most 0.7 ns, more preferably at most 0.5 ns, more preferably at most 0.2 ns and particularly preferably at most 0.1 ns.

18. The method according to any one of the preceding claims 16 or 17, characterized in that the duration of the first time period is at most 1 ns, preferably at most 0.7 ns, more preferably at most 0.5 ns, more preferably at most 0.2 ns, more preferably at most 0.1 ns and very preferably at most 0.05 ns and / or the duration of the second Time period is at most 1 ns, preferably at most 0.7 ns, further preferably at most 0.5 ns, more preferably at most 0.2 ns, more preferably at most 0.1 ns and very preferably at most 0.05 ns.

19. Method according to one of the preceding claims 16 to 18, characterized by the following steps: switching of the push-pull circuit (2) into a third state, in which both supply lines (42, 44) from the output port (20) are separated,

Closing a third switch (50) which connects the first terminal (10) of the light-emitting diode (3) to a third supply line (48), the potential of the third supply line (48) being positive,

Emitting electromagnetic radiation of the light-emitting diode (3) for illumination purposes, preferably for a duration greater than one second.

20. The method according to any one of the preceding claims 16 to 19, characterized by the following steps: switching the push-pull circuit (2) to a third state, in which both supply lines (42, 44) from the output port (20) are separated,

Closing a fourth switch (54) which closes a short-circuit line (52) between the first terminal (10) of the light-emitting diode (3) and the second terminal (12) of the light-emitting diode (3) and thus short-circuiting the light emitting diode (3).

21. The method according to claim 19 or 20, characterized by Switching the push-pull circuit (2) in the third state by disconnecting the supply lines (42, 44) from the output port (20) by opening the switching elements (26) of the push-pull circuit (2).

22. The method according to any one of claims 16 to 21, characterized by the steps:

Monitoring the discharge current occurring at the light-emitting diode (3) while the push-pull circuit (2) is switched to the second state;

Detecting a fall below a predetermined current limit value;

Reducing the voltage applied to the first terminal (10) of the light-emitting diode (3), preferably to a predetermined permanent blocking voltage value, particularly preferably to a voltage value lying below the predetermined continuous-locking voltage value.

23. The method according to any one of claims 16 to 22, characterized by the steps:

Monitoring the voltage applied to the light emitting diode (3) while the push-pull circuit (2) is switched to the second state;

Detecting an exceeding of a predetermined voltage limit value;

Reducing the voltage applied to the first terminal (10) of the light-emitting diode (3), preferably to a predefined permanent blocking voltage value, particularly preferably to a voltage value lying below the predetermined continuous blocking voltage value; or Disconnecting the second supply voltage (44) from the output port (20) of the push-pull circuit (2).

24. The method according to any one of claims 16 to 23, characterized by the steps:

Providing a measuring device for measuring the rest voltage of the light-emitting diode (3);

Measuring the open-circuit voltage at the light-emitting diode (3) when the push-pull circuit (2) has left the second state and has not yet assumed the first state.

25. Method according to the preceding claim, characterized by the further step:

Adjusting the voltage at the first terminal (10) of the light-emitting diode (3), preferably by means of a regulator (60), when the push-pull circuit (2) is switched to the first state and / or switched to the second state Optionally until the open circuit voltage at the luminous diode (3) is equal to zero, wherein the adaptation preferably takes place by changing the voltage at the output port (20), particularly preferably by the use of a charge pump (56, 58).

26. The method according to claim 24, characterized by the further step:

Adjusting the control pulses in the second state of the push-pull circuit (2), preferably by changing the edge steepness or the pulse duration of the control pulses which are applied to the first terminal (10) of the light-emitting diode (3).

27. The method according to claim 24, characterized by the further step: Shifting the potential of the center potential line (14), preferably until the rest voltage at the light emitting diode (3) is equal to zero.