EP0378650A1

EP0378650A1 - Process and circuit arrangement for compensating offset voltages in a focus and/or track-regulating circuit

Info

Publication number: EP0378650A1
Application number: EP89907726A
Authority: EP
Inventors: Günter Gleim
Original assignee: Deutsche Thomson Brandt GmbH
Current assignee: Deutsche Thomson Brandt GmbH
Priority date: 1988-07-15
Filing date: 1989-07-13
Publication date: 1990-07-25
Also published as: HUT53467A; GR3006012T3; MY104135A; US5148423A; HU894721D0; JPH03502979A; JP2726131B2; CN1020007C; ATE80960T1; KR0145299B1; DK67990D0; CN1039919A; WO1990000797A1; EP0350939A1; DE58902327D1; DK67990A; EP0350939B1; KR900702517A; HK8997A; DE3824039A1

Abstract

A method for compensating offset voltages selectively in a focusing circuit that focuses a beam from a source of light on a recording medium and in a tracking circuit that positions a beam of light on data storage tracks on a recording medium. A beam of light reflected from the recording medium is directed onto a photodetector which has a plurality of photodiodes. The difference of the output voltages from the photodiodes is taken for generating an error signal which is stored as a reference during a first stage in open or closed state of the circuit selected. The selected circuit is then closed and a compensation parameter is supplied in a second stage to controls in the selected circuit. The compensation parameter is then varied until the error signal is substantially equal to the stored reference. The compensation of the offset voltages is independent of the tracking circuit, and the offset voltages in the focusing circuit can be compensated when the tracking circuit is closed.

Description

Method and circuit arrangement for compensating offset voltages in a focus and / or tracking control loop.

The invention relates to a method for compensating offset voltages in a focus control loop, by means of which a light beam from a light source is focused on a record carrier, and / or in a track control loop, by means of which the light beam is guided on the data tracks of the record carrier, the light beam from Recording medium is reflected on a photodetector with a plurality of photodiodes, from whose output voltages the difference in focus and / or tracking error signal is generated by difference formation.

In devices for reproducing data which can be read from the data tracks of a record carrier by means of an optical scanning device, a light beam is focused on the record carrier by means of a focus control loop and guided on the data tracks of the record carrier by means of a track control loop. The optical scanning device of such devices as CD players, magneto-optical devices for playback and recording, recording and playback devices of DRAW discs or video disc players is equipped with a laser diode, a plurality of lenses, a prism beam splitter, a diffraction grating and a photodetector. Structure and function of an optical scanning device, a so-called optical pick-up, are in electronic components & applications, Vol. 6, No. 4, 1984 on pages 209-215.

The light beam emitted by the laser diode is focused on the CD disk by means of lenses and reflected from there onto a photodetector. The data stored on the CD disk and the actual value for the focus and the tracking control loop are obtained from the output signal of the photodetector. In the cited literature reference, the actual value for the focus control loop is referred to as focusing error, while the expression radial tracking error is selected for the actual value of the track control loop.

A coil serves as the actuator for the focus control loop, via the magnetic field of which an objective lens can be moved along the optical axis. By moving the objective lens, the focus control loop now ensures that the light beam emitted by the laser diode is always focused on the CD disk. By means of the track control loop, which is often also referred to as a radial drive, the optical scanning device can be displaced in the radial direction with respect to the CD disk. This allows the light beam to be guided on the spiral data tracks on the CD.

In some devices, the radial drive is made up of a so-called coarse and a so-called fine drive. The coarse drive is designed, for example, as a spindle, by means of which the entire optical scanning device comprising the laser diode, the lenses, the prism beam splitter, the diffraction grating and the photodetector can be moved radially. With the fine drive, the light beam can be tilted in the radial direction, for example, by a predeterminable small angle, so that the light beam can travel a small distance along a radius of the CD disk solely by this tilting movement. FIG. 1 shows the photodetector PD, the optical scanning device of a CD player, in which three laser beams L1, L2 and L3 are focused on the CD disk. Such a scanning device is called three-beam pick-up in the literature mentioned at the beginning.

The middle light beam L1 is the main beam, the two light beams L2 and L3 are the beams +1. and -1. Order that are generated from the main beam L1 by means of a diffraction grating.

In the photodetector PD, four square-shaped photodiodes A, B, C and D are assembled so that they in turn form a square. With regard to this square formed from the four photodiodes A, B, C and D, two further square-shaped photodiodes E and F are located diagonally opposite one another.

The middle light beam L1, which is focused on the four photodiodes A, B, C and D, generates the data signal HF = AS + BS + CS + DS and the focus error signal FE = (AS + CS) - (BS + DS). The two outer light beams L2 and L3, of which the front L2 strikes the photodiode E, the rear L3 strikes the photodiode F, generate the tracking error signal TE = ES-FS. AS, BS, CS, DS, ES and FS denote the photo voltages of the photodiodes A, B, C, D, E and F. Because an astigmatic collimator lens is provided in the optical path of the central light beam L1 in the optical scanning device, the central light beam L1 is circular when precisely focused on the large square formed by the photodiodes A, B, C and D, while at Defocusing takes elliptical shape.

Figure 1a shows the case of focusing and precise tracking, which will be discussed later. Because the light spot formed by the light beam L1 on the large square has a circular shape, the focus error signal results in FE = (AS + CS) - (BS + DS) = 0. At the zero value of the focus error signal FE, the focus control circuit recognizes that the focus is exactly.

1b shows the one case of defocusing, in which the objective lens is too far away from the CD disk. The focus error signal FE is negative: FE = (AS + CS) - (BS + DS) <0. The focus control loop recognizes from the negative value of the focus error signal FE that the distance between the objective lens and the CD disk is too great. Therefore, the objective lens is moved by the actuator of the focus control loop towards the CD disk until the focus error signal FE becomes zero.

The other case of defocusing, that the objective lens is too close to the CD disk, is shown in Figure 1c. The focus error signal FE has a positive value: FE = (AS + CS) - (BS + DS)> 0. The focus control loop recognizes from the positive value of the focus error signal FE that the objective lens is too close to the CD disk. The objective lens is therefore moved away from the CD disk by the actuator until the focus error signal al FE becomes zero.

It is now explained how the tracking is carried out by means of the tracking control loop.

In FIGS. 1a, 1b and 1c, the light beams L1, L2 and L3 exactly follow the track. The tracking error signal TE has the value zero. TE = ES - FS = 0.

FIG. 1b shows the case in which the light beams L1, L2 and L3 are shifted to the right of the track. The tracking error signal TE takes a negative value: TE = ES - FS <0. The actuator of the tracking control loop now moves the optical scanning device to the left until the tracking error signal TE becomes zero. In the opposite case, when the light beams are shifted to the left of the track, the track error signal is positive: TE = ES - FS> 0. Now the actuator of the track control loop moves the optical scanning device to the right until the track error signal TE becomes zero.

To ensure that the data is reproduced correctly, e.g. To achieve image and sound with a video disc player or just the sound with a CD player, in addition to precise focusing of the light beam on the video or CD disc, precise guidance along the data tracks of the disc is also required.

The control amplifier of the focus control loop, however, like any other control amplifier, also has an offset voltage, the size of which depends on the one hand on the temperature and on the other hand is subject to a long-term drift. The drift of the offset voltage and other parameters of an amplifier over time are caused by the aging of the amplifier.

The focus error signal FE = (AS + BS) - (BS + DS) is formed in a differential amplifier. Because this differential amplifier also has an offset voltage, and because the photodiodes A, B, C and D emit different voltages or currents than the ideal photodiodes with the same luminance, there is another source of disturbing offset voltages.

So that the data reproduction is not disturbed by offset voltages, compensation of all offset voltages that occur is necessary. By adjusting the adjustment potentiometers by hand, however, compensation can only be carried out approximately because changes in the offset voltages due to temperature fluctuations and due to aging of individual components are not taken into account. It is therefore an object of the invention to design a method for grain compensation of offset voltages in a focus and / or tracking control loop so that automatic compensation of the offset voltages is made possible.

The invention solves this problem by comparing the focus error and / or tracking error signal with a predefinable reference variable when the control loop is closed, and by supplying a compensation variable to the actuator of the focus and / or tracking control loop, which is changed until the focus error and / or tracking error signal coincides with the reference variable.

A second solution to this problem provides that in a first process step with an open or switched-off control loop and uniform illumination of the photodiodes to the focus error and / or tracking error signal, a first compensation variable is added and changed until the sum agrees with a first reference variable that then, in a second method step with a closed control loop, the focus error and / or tracking error signal is compared with a second reference variable and that the actuator of the focus and / or tracking control loop is supplied with a second compensation variable and is changed until the focus and / or tracking error signal matches the reference size.

A third solution to this problem is that in a first process step with the control circuit open or switched off and with uniform illumination of the photodiodes, the focus and / or tracking error signal is stored as a reference variable, that in a second subsequent process step with the control circuit closed, the actuator of the control circuit Compensation variable supplied and changed until the focus and / or tracking error signal matches the stored reference variable. Show it

Figure 2 shows a circuit arrangement for performing the method according to claim 1

Figure 3 shows a circuit arrangement for performing the method according to claim 3

Figure 4 shows a circuit arrangement for performing the method according to claim 4

5 shows a circuit arrangement for carrying out the method according to claim 5.

Using the circuit arrangements shown in the figures, the individual methods according to the invention will now be explained using the example of a focus control loop.

In FIG. 1 there is a voltage + U at the interconnected cathodes of the photodiodes A, B, C and D. The interconnected anodes of photodiodes A and C are connected to the addition input, while the interconnected anodes of photodiodes B and D are connected to the subtraction input of a differential amplifier DV, the output of which is connected via a resistor R1 to the input of a control amplifier RV and via a further resistor R2 is connected to the non-inverting input of a comparator VL. The non-inverting input of the comparator VL is at a reference potential via a capacitance C1. A reference voltage UR is present at the inverting input of the comparator VL, the output of which is connected to the input E1 of a microprocessor MP. The output A1 of the microprocessor MP is connected to the input of a digital-to-analog converter DA1, the output of which is connected to the output of the control amplifier RV and the one connection of the actuator SG is. The other connection of the actuator SG, which is designed as a coil, is at reference potential.

To make it easier to understand the circuit arrangement, it is initially assumed that the focus control loop is made up of ideal components which do not have any offset voltages.

When focused precisely, the main beam L1 forms a circle on the four photodiodes A, B, C and D, as shown in FIG. 1a. Because all four photodiodes A, B, C and D receive the same light energy and convert it into an electrical current, they emit the same output voltages or currents. Therefore, the voltage at the output of the differential amplifier DV is zero. Because the control amplifier RV is also assumed to be ideal, the voltage at its output and therefore also at one connection of the actuator SG is also zero. The actuator SG, often also called the actuator, therefore moves the objective of the optical scanning device until the voltage at the output of the control amplifier RV becomes zero. Assuming ideal components, the focus is then precise because the voltage at the output of the differential amplifier DV is also zero.

It is now assumed that the control amplifier RV has an offset voltage, while the differential amplifier DV and the photodiodes A, B, C and D are still to be considered ideal.

Again, the actuator SG will move the lens until the voltage at the output of the control amplifier RV becomes zero. In the case of the control amplifier RV which is now assumed to be real, however, the input voltage and thus also the voltage at the output of the differential amplifier differ from zero. In the position in which the lens is now held by the coil, the light beam L1 is therefore no longer circular, but how shown in Figure 1b or 1c slightly elliptical, which indicates that is not precisely focused.

In order to achieve precise focusing by compensating the offset voltage of the control amplifier RV, the voltage at the output of the differential amplifier DV is compared in the comparator VL with a reference voltage UR, which is chosen to be zero in the exemplary embodiment specified. The microprocessor MP now changes the digital values at its output A1, which the digital-to-analog converter DA1 converts into an analog voltage and feeds the actuator SG until the comparator VL at the input E1 of the microprocessor MP indicates that the voltage at Output of the differential amplifier DV has become zero. Because the light beam L1 is now imaged circularly by the lens onto the photodiodes A, B, C and D, the focus is precise. If the comparator VL shows the microprocessor MP that it is precisely focused because the voltage at the output of the differential amplifier DV has become zero, the microprocessor MP retains the value at its output A1, so that an analogue is constantly being transmitted due to the digital-to-analog converter DA1 Compensation voltage is present at actuator SG.

The device, e.g. a CD player is now ready to play. It is particularly advantageous to carry out the compensation each time the CD player is switched on.

If the offset voltage of the control amplifier RV changes, for example as a result of aging or temperature fluctuations, this has the consequence that the voltage at the output of the differential amplifier DV also changes and no longer corresponds to the reference voltage UR. Because the comparator VL indicates this to the microprocessor MP when the CD player is switched on, the microprocessor is able to readjust the offset compensation voltage and thus to ensure optimal compensation. A major advantage of the circuit arrangement shown in FIG. 2 is that the offset voltage of the control amplifier RV is automatically compensated each time the CD player is switched on.

The circuit arrangement shown in FIG. 3 for carrying out the method according to claim 2 will now be described and then explained.

The circuit arrangement from FIG. 3 differs from the circuit arrangement from FIG. 2 in that it is supplemented by a digital-to-analog converter DA2, the output of which is connected to the output of the differential amplifier DV and the input of which is connected to an output A2 of the microprocessor MP.

In the circuit arrangement in FIG. 3, it is assumed that, in addition to the control amplifier RV, the differential amplifier DV also has an offset voltage. The photodiodes A, B, C and D are also real, i.e. not considered completely identical components that emit different voltages or currents with the same lighting Therefore, in the case of focusing, if the lens images the light beam L1 in a circle as in FIG. 1a on the four photodiodes A, B, C and D, the voltage at the output of the differential amplifier DV does not become zero as desired, but a positive or negative Value, e.g. accept + a.

In a first process step, the four photodiodes A, B, C and D are uniformly illuminated when the focus control loop is open or switched off. This state can be easily achieved by switching off the light source, because then the photodiodes A, B, C and D are in the dark. When the light source is switched off, it also does not matter where the lens is located and whether it is moving because no feedback can take place. In this state - with the light source switched off - the voltage at the output of the differential amplifier DV is compared with the reference voltage UR in comparison with the VL.

The digital values which the microprocessor MP now outputs at its output A2 are converted into an analog voltage by the digital / analog converter DA2. The microprocessor MP now changes the digital values at its output A2 until the comparator VL indicates that the analog voltage at the output of the digital-analog converter DA2 has compensated for the voltage at the output of the differential amplifier DV. The digital value at this time at the output A2 of the microprocessor MP is retained. This measure ensures that the voltage at the input of the control amplifier RV is zero when the light beam L1 is imaged circularly onto the photodiodes A, B, C and D as shown in FIG.

In a second process step, the light source is switched on and the procedure is the same as for the circuit arrangement in FIG. 2.

Unfortunately, another previously neglected offset size, often referred to as optical offset, is due to the optics of the optical pickup. This means the following: If the light beam is precisely focused on the record carrier, the light beam does not become, as is the case with ideal, completely error-free optical components, due to the never-to-be-avoided optical defects of the optical components - the lenses, the prism beam splitter and the diffraction grating would be circular, but slightly elliptical on the photodetector with the four photodiodes A, B, C and D. When the light beam is precisely focused on the recording medium, the voltage at the output of the differential amplifier DV is therefore not zero, as desired, despite compensation for its offset voltage. Rather, it has a positive or negative value. How this offset voltage, which is caused by the optical offset, can also be compensated, is explained with the aid of the circuit arrangement shown in FIG.

It differs from the circuit arrangement of FIG. 3 in that the reference voltage UR can be changed. For this purpose an output A3 of the microprocessor MP is connected to the control input of the reference voltage source UR, which e.g. can be designed as a digital-to-analog converter.

In the first and second method steps, which take place as in the circuit arrangement from FIG. 3, a fixed value is selected for the reference voltage UR. In addition to the first and second process steps, a third process step to compensate for the optical offset mentioned is carried out during the production of the CD player, which proceeds as follows.

A CD test plate is inserted into the CD player. The digital values determined in the first and second method steps at the outputs A1 and A2 of the microprocessor MP are retained during the third method step and are not changed. With the light source switched on, the light beam is now focused precisely on the recording medium, the CD test plate. The exact focus is determined with the help of the CD test plate, because if the focus is precise, the jitter in the RF signal is lowest. However, the exact focusing can also be checked, for example, using a microscope. It is now determined by what value the reference voltage UR is to be changed, so that the optical offset is also compensated, because the offset voltage of the differential amplifier DV was already compensated in the first and that of the control amplifier RV in the second step. The reference voltage UR is therefore changed until the jitter in the RF signal assumes a minimum because the light beam is then focused precisely on the inserted test plate. The one on this The value of the reference voltage UR found in this way is fixed. The CD player is now ready for use.

If the offset voltage of the differential amplifier DV or the control amplifier RV changes in later game operation, they will e.g. compensated each time the device is switched on in accordance with the first and the second method step.

The circuit arrangement shown in FIG. 5 for carrying out the method according to claim 5 will now be described and explained.

It differs from the circuit arrangement from FIG. 4 in that the digital-to-analog converter DA2 is missing.

In a first process step, as in the circuit arrangement from FIG. 3, uniform illumination of the photodiodes A, B, C and D is ensured by switching off the light source. In this state, which corresponds to that of the exact focusing, when the light beam L1 is imaged circularly onto the photodiodes A, B, C and D, the microprocessor MP changes the reference voltage UR until the comparator VL1 indicates to it that the reference voltage UR with the voltage at the output of the differential amplifier DV, which, for example + a may be the same.

In order to also compensate for the optical offset already mentioned, the first method step is changed in a manner similar to the circuit arrangement from FIG. 3. With the focus control loop open or switched off, the light beam is precisely focused on the CD disk during production of the CD player and the exact focusing is checked with the aid of a microscope or by determining the jitter minimum in the HF signal using the CD test plate. Now the microprocessor MP changes the reference voltage UR until the comparator VL1 indicates that the ref limit voltage UR agrees with the voltage at the output of the differential amplifier DV, which may be + b, for example.

As in the circuit arrangements described above, the second method step takes place with the light source switched on.

Without further compensation measures, the actuator SG would hold the lens in a position in which the voltage at the output of the control amplifier RV becomes zero. In this case, however, the voltage at the input of the control amplifier RV will generally not be + a or + b as desired, as would be the case with precise focusing, but rather a positive or negative value different from zero depending on the size of the offset voltage of the control amplifier RV. It is therefore provided that the microprocessor MP changes the digital value at its output A1, which is converted by the digital-to-analog converter DA1 into an analog compensation voltage supplied to the actuator SG, until the comparator VL indicates to it that the voltage at the output of the differential amplifier DV corresponds to the reference voltage UR, which has the value + a or + b in the assumed numerical example. The digital value then at the output A1 of the microprocessor MP is retained, so that the correct analog compensation voltage is constantly applied to the actuator SG because of the digital-analog converter DA1. The CD player is now ready to play.

It is particularly advantageous with this circuit arrangement to carry out the two method steps described each time the CD player is switched on.

Manual compensation by adjusting a potentiometer during production is no longer necessary, as is subsequent adjustment due to temperature fluctuations or aging of the components, because the offset voltages are automatically compensated each time the device is switched on.

Claims

1. A method for compensating offset voltages in a focus control loop, by means of which a light beam from a light source is focused on a record carrier, and / or in a track control loop, by means of which the light beam is guided on the data tracks of the record carrier, the light beam from the record carrier is reflected on a photodetector with a plurality of photodiodes (A, B, C, D, E, F), from whose output voltages the focus error and / or tracking error signal are generated by forming the difference, characterized in that the focus error and / or tracking error signal when the control loop is closed is compared with a predeterminable reference variable (UR) and that the actuator (SG) of the focus and / or tracking control loop is supplied with a compensation variable which is changed until the focus error and / or tracking error signal matches the reference variable (UR).

2. Method for compensating off-set voltages in a focus control loop, by means of which a light beam from a light source is focused on a record carrier, and / or in a track control loop, by means of which the light beam on the data tracks of the record carrier leads, the light beam from the record carrier is reflected onto a photodetector with a plurality of photodiodes (A, B, C, D, E, F), from whose output voltages the focus error and / or tracking error signal are generated by forming the difference, characterized in that in one first process step with the control circuit open or switched off and with uniform illumination of the photodiodes (A, B, C, D and / or E, F) to the focus error and / or tracking error signal, add a first compensation variable and change it until the sum is increased by one the first reference variable agrees that the focus error and / or tracking error signal is then compared with a second reference variable (UR) in a second method step with a closed control loop and that a second compensation variable is fed to the actuator of the focus and / or tracking control loop and is changed as long as until the focus and / or tracking error signal with the second reference size matches.

3. The method of claim 2, d a d u r c h g e k e n n z e i c h n e t that the first and second reference variable are chosen to be the same size.

4. The method according to claim 2 or 3, characterized in that during the production of the focus and / or tracking control loop, a third method step follows the first and second method step, that in the third method step, the first compensation variable determined in the first method step and that in the second method step determined second compensation variable are maintained, that the light beam is precisely focused on the recording medium by means of a measuring device and that the reference variable is then corrected.

5. Method for compensating offset voltages in a focus control loop, by means of which a light beam from a light source is focused on a recording medium, and / or in a track control loop, by means of which the light beam is guided on the data tracks of the recording medium, the light beam from the recording medium is reflected on a photodetector with several photodiodes (A, B, C, D, E, F), from whose output voltages the focus error and / or tracking error signal are generated by forming the difference, characterized in that in a first method step with the control circuit open or switched off and with uniform illumination of the photodiodes, the focus and / or tracking error signal is stored as a reference variable, that in a second subsequent process step with a closed control loop, the control element (SG) of the control loop is supplied with a compensation variable and is changed until the focus un d / or tracking error signal matches the stored reference quantity.

6. The method of claim 5, d a d u r c h g e k e n n z e i c h n e t that in the production of the control loop in the first process step, the light beam is precisely focused on the recording medium and the exact focusing is checked by means of a measuring device.

7. The method according to claim 4 or 6, that a microscope is provided as a measuring device for checking the exact focusing.

8. The method according to claim 4 or 6, d a d u r c h g e k e n n z e i c h n e t that to check the exact

Focusing the light beam on the record carrier by means of a test record carrier the jitter minimum in the RF signal is determined.

9. The method of claim 2, 3, 4 or 5, d a d u r c h g e k e n n z e i c h n e t that the luminance is chosen to be zero to achieve uniform illumination of the photodiodes (A, B, C, D and / or E, F).

10. The method of claim 9, d a d u r c h g e k e n n z e i c h n e t that the photodiodes (A, B, C, D and / or E, F) are shielded from the light source by means of an aperture.

11. The method of claim 9, d a d u r c h g e k e n n z e i c h n e t that the light source is turned off.

12. Circuit arrangement for performing the method according to claim 1, characterized in that a voltage + U is at the interconnected cathodes of the photodiodes (A, B, C, D) of the photodetector that the anodes each have two photodiodes (A and C, B and D) are connected to each other and to an input of a differential amplifier (DV), the output of which is connected to the input of a control amplifier (RV) and to the one input of a comparator (VL), that at the other input of the comparator (VL ) there is a reference voltage (UR) that the output of the comparator (VL) is connected to the input (E1) of a microprocessor (MP), the output (A1) of which is connected to the input of a digital-to-analog converter (DA1), that the output of the control amplifier (RV) is connected to the output of the digital-to-analog converter (DA1) and to the actuator (SG).

13. Circuit arrangement for performing the method according to claim 2, characterized in that a voltage + U is at the interconnected cathodes of the photodiodes (A, B, C, D) of the photodetector that the anodes each have two photodiodes (A and C, B and D) with each other and with one input of a dif Limit amplifier (DV) are connected, the output of which is connected to the input of a control amplifier (RV) and to the one input of a comparator (VL), that at the other input of the comparator (VL) there is a reference voltage (UR) that the output of the Comparator (VL) is connected to the input (E1) of a microprocessor CMP), the first output (A1) of which is connected to the input of a first digital-to-analog converter (DA1) and the second output (A2) of which is connected to the input of a second digital Analog converter (DA2) is connected such that the output of the control amplifier (RV) is connected to the output of the first digital-analog converter (DA1) and to the actuator (SG) and that the output of the second digital Analog converter (DA2) is connected to the input of the control amplifier (RV).

14. Circuit arrangement for performing the method according to claim 4 and 13, characterized in that the other input of the comparator (VL) is connected to a controllable reference voltage source (UR) whose control input is connected to a third output (A3) of the microprocessor (MP) .

15. Circuit arrangement for performing the method according to claim 5, characterized in that a voltage + U is at the interconnected cathodes of the photodiodes (A, B, C, D) of the photodetector that the anodes each have two photodiodes (A and C, B and D) are connected to each other and to an input of a differential amplifier (DV), the output of which is connected to the input of a control amplifier (RV) and to the input of a comparator (VL), that the other input of the comparator (VL) is connected to a controllable reference voltage source (UR) is connected that the output of the comparator (VL) is connected to the input (E1) of a microprocessor (MP), the first output (A1) of which is connected to the input of a digital-to-analog converter (DA1) and its second output (A3) is connected to the control input of the variable reference voltage source (UR) and that the output of the Regle lve rstä rkers (RV) is connected to the output of the digital-to-analog converter (DA1) and to the actuator (SG).

16. Circuit arrangement according to claim 14 or 15, that the control reference voltage source (UR) is designed as a digital-to-analog converter.

17. Circuit arrangement according to claim 12, 13, 14, 15 or 16, characterized in that between the differential amplifier (DV) and the control amplifier (RV) is a first resistor (R1) that between the differential amplifier (DV) and the one input of Comparator (VL) is a series circuit of the first and a second resistor (R1, R2) that the one input of the comparator (VL) is connected via a capacitance (C1) to reference potential and that the one connection of the actuator (SG), the is designed as a coil, is connected to the output of the control amplifier (RV) and the other connection is at reference potential.