CH683462A5 - A circuit arrangement for generating an electric voltage command value in dependence on an electrical control voltage. - Google Patents

Abstract

An RC section (12, 13) connected between feed lines (+, 0) is connected to the first input of a comparator (9). The second input of the comparator (9) is connected to a fixed voltage divider (10, 11). The output of the comparator (9) is connected to the first input via another resistor (16). The capacitor (13) of the RC section is charged up via the resistor (12) of the RC section until the voltage at the first input reaches the fixed voltage at the second input. The output of the comparator (9) then discharges the capacitor (13) via the further resistor (16) whereupon the capacitor (13) is charged up again. The periodic exponential capacitor voltage is supplied to the first input of a further comparator (7), at the second input of which the adjustable control voltage is present. When the voltages are equal, a voltage change occurs at the output of the comparator (7) which is transferred to a switching transistor (23) via an optocoupler (19). The signal present at its output and smoothed forms a voltage reference value which quasi-logarithmically depends on the settings of the control voltage and can be used, for example, for controlling the brightness of low-voltage gas discharge lamps. <IMAGE>

Description

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description

The present invention relates to a circuit arrangement for generating an electrical voltage setpoint in a non-linear manner as a function of an electrical control voltage.

Circuit arrangements of this type are known and have been proposed and used for numerous applications. For higher demands on precision and reproducibility, however, the known circuit arrangements are complex and correspondingly expensive.

The object of the invention is to provide a circuit arrangement of the type mentioned, which requires only a few common electrical components in a simple construction and nevertheless generates a stable, reproducible voltage setpoint and is particularly suitable for use in an electronic ballast for regulating the brightness of low-pressure gas discharge lamps.

To achieve this object, the invention has the features stated in claim 1.

Details of the subject matter of the invention are explained for example with reference to the drawing. Show it:

Fig. 1 is a circuit diagram of a first circuit part of the circuit arrangement, and

Fig. 2 is a circuit diagram of a second circuit part which is operatively connected to the first circuit part.

The circuit arrangement according to the invention is explained below in the application in an electronic ballast for a low-pressure gas discharge lamp. In a specific embodiment of such a device, the task is to generate a setpoint voltage to be compared with a reference voltage, hereinafter referred to as setpoint, as a function of an externally adjustable control voltage. The comparison value of the target value and the reference voltage then serves to control an inverter bridge fed by an AC or DC network in such a way that the brightness of the discharge lamp connected to the inverter bridge changes in accordance with the value of the externally set control voltage. Since the perception of brightness of the human eye is quasi-lo-garithmic, it is not practical to base a brightness control of the discharge lamp on a linearly changing control variable. This results in the disadvantageous characteristic that with a low brightness a very small change in the control variable already causes a strong change in brightness, while with a high brightness a large change in the control variable is required in order to bring about even a slight change in brightness. This defect can be remedied by the circuit arrangement explained below.

1 shows a first circuit part of the circuit arrangement according to the invention. This circuit part has a positive supply voltage line labeled + and a zero line labeled 0. This stabilized

DC voltage supply of approximately 12 volts is independent, that is to say galvanically isolated from other parts of the device under consideration. The supply voltage is therefore generated, for example, by means of a transformer connected to an alternating current source, to the secondary winding of which a rectifier and stabilizing circuit is connected. Since such a feed circuit is irrelevant here, it is not shown in FIG. 1.

The first circuit part of FIG. 1 also has two terminals 1 and 2, to which an external, adjustable burden 3 can be connected via a control line, not shown. When the load 3 is connected, a voltage divider is formed together with a resistor 4 connected to the positive feed line. The resistor 4 is dimensioned such that a voltage which varies between 1 and 10 volts, depending on the setting of the burden 4, results in the voltage divider point 5. The voltage divider point 5 is connected via a high-resistance resistor 6 to the positive input of a first comparator 7, this input also being connected to the zero line via a capacitor 8. The resistor 6 and the capacitor 8 form a protective circuit for the comparator input against unintentionally high voltages, for example if the mains alternating voltage is accidentally connected to the terminal 2. The mains voltage resistance of the control line connected to terminals 1 and 2 is thus guaranteed.

A second comparator 9 also has its positive input connected to a voltage divider formed by resistors 10 and 11. The negative input of the comparator 9 is connected to the positive feed line via a resistor 12 and to the zero line via a capacitor 13. The output of the comparator 9 is connected on the one hand to the positive comparator input via a resistor 14 and to the negative comparator input via the series connection of a diode 15 and a resistor 16. Finally, the negative input of the comparator 9 is still connected to the negative input of the comparator 7.

The values of resistors 10 and 11 are relatively high, e.g. 100 kss and 330 kn, respectively. Resistor 12 is also close to 100 kß. The resistor 14 has a relatively low resistance, for example 6.8 kn. The resistor 16 is very low, for example 100 Q.

When the supply voltage is first applied to the positive supply line and the zero line, the positive input of the comparator 9 immediately assumes the value determined by the resistors 10 and 11. The capacitor 13 is charged via the resistor 12 with the time constant of these two components, so that the voltage at the negative input of the comparator rises exponentially. No current flows through the resistor 14, the diode 15 and the resistor, since the voltage at the positive input of the comparator 9 is higher than that at the negative comparator input and because the comparator output is open.

As soon as the voltage on the negative comparator

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When the input reaches the one at the positive comparator input, the comparator 9 switches, that is, its output practically assumes the voltage of the zero line. As a result, the capacitor 13 discharges rapidly via the resistor 16 and the diode 15, while there is a very low voltage at the positive comparator input, since the resistor 14 is connected in parallel to the resistor 11 in this state. The capacitor 13 can therefore discharge to this low voltage. If the voltage at the negative comparator input drops further, that at the positive comparator input is relatively higher. The comparator 9 thus again reaches the blocking state with an open output, which corresponds to the initial state, so that the capacitor 13 is charged again via the resistor 12.

At the negative input of the comparator 7 there is consequently a sequence of exponentially rising pulses with a steep edge, which, however, do not drop completely to the value zero, since the capacitor 13 cannot discharge completely because of the parallel connection of the resistors 11 and 14. As long as the voltage at the negative input of the comparator 7 is less than the voltage at the positive input set by the load 3, the output of the comparator is open. The series circuit of a resistor 17 and the diode 18 of an optocoupler 19 are connected to this output. With the output of the comparator 7 open, a current therefore flows through the diode 18. As soon as the voltage at the negative input of the comparator increases exponentially to the value of the voltage at the positive input, the comparator 7 switches, that is to say its output practically assumes the zero voltage. As a result, the diode 18 is short-circuited, and the current flowing through the resistor 17 goes directly to the zero line.

The transmission-side diode 18 of the optocoupler 19 is accordingly active as long as each of the exponentially increasing pulses generated by the comparator 9 has a lower voltage than the control voltage generated by the set burden 3. The width of the square-wave pulses emitted by the active diode 18 is a measure of the magnitude of the control voltage. However, as intended, the relationship between the width of the pulses and the magnitude of the control voltage is not linear. Because of the exponential course of the pulses of the comparator 9 controlling the diode 18, the width of the diode pulses for changes in the small control voltages of the burden 3 increases more slowly than for changes in large control voltages. In other words, a larger change in the control voltage is required for a certain change in the width of the diode pulses in the case of small control voltages than in the case of large control voltages. This is already a quasi-logarithmic characteristic of a target value, which in the present example is decisive for the brightness of the controlled discharge lamp.

To generate the exponentially increasing pulses and to compare them with the respectively set control voltage are described in the

Embodiment uses the comparators 7 and 9. However, it is also possible to provide other semiconductor components and other circuits for this purpose, for example operational amplifiers, etc.

A second circuit part, shown in FIG. 2, is provided to receive the square-wave pulses transmitted by the diode 18 of FIG. 1, to additionally deform and smooth them non-linearly, in order to generate a nominal value of low ripple. A receiver-side transistor 21 of the optocoupler 19 is connected via a resistor 22 on the one hand to a positive voltage line + and on the other hand connected to the associated zero line 0. The control electrode of a field-effect transistor 23 is connected to the transistor 21 of the optocoupler 19, the drain electrode of which is also fed by the positive voltage line via a resistor 24. The drain electrode is connected via a further resistor 25 to a terminal 26, at which, as explained below, the desired setpoint occurs. Terminal 26 is connected to the zero line via a capacitor 27.

If the diode 18 of the optocoupler 19 (FIG. 1) is conductive, a current also flows through the transistor 21 of the optocoupler 19 (FIG. 2). Then the field effect transistor 23 is blocked, so that the capacitor charges via the series connection of the resistors 24 and 25. If subsequently the diode 18 and thus also the transistor 21 of the optocoupler 19 are blocked, the field effect transistor 23 becomes conductive, so that the capacitor 27 can discharge via the field effect transistor 23 and the resistor 25. Since the resistor 25 has an approximately four times smaller value than the sum of the resistors 24 and 25, the capacitor 27 is discharged faster than its charging. As a result, the voltage at the terminal 26 rises considerably faster at a high control voltage than at a low control voltage, which significantly improves the desired quasi-logarithmic characteristic of the dependence of the voltage at the terminal 26 on the control voltage. However, since the capacitor 27 has a relatively large capacitance (for example approximately 3 nF), the ripple of the voltage at the terminal 26 is very low. Thus, the voltage at terminal 26 represents the desired setpoint with a quasi-logarithmic dependence on the adjustable control voltage provided by burden 3 in FIG. 1.

Despite its simple structure, the present circuit arrangement generates reproducible voltage setpoints. For example, in the described application of the circuit arrangement in an electronic ballast for a low-pressure gas discharge lamp with a single control voltage, the brightness of a large number of discharge lamps, the ballasts of which each contain an existing circuit arrangement, can be controlled without noticeable differences in the brightness set for the individual discharge lamps.

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Claims (10)

Claims 1. Circuit arrangement for generating an electrical voltage setpoint in a non-linear dependence on an electrical, adjustable control voltage, characterized by a signal generator (9 to 15) for forming a periodic signal voltage, which is non-linear and monotonous in the same way during each period, and by a Comparison circuit (4 to 8) which has inputs for the signal voltage of the signal generator and the adjustable control voltage and an output which is intended to emit a comparison signal when the signal voltage of the signal generator reaches the value of the adjustable control voltage, the comparison signal up to the beginning the next period of the signal voltage of the signal generator continues. 2. Circuit arrangement according to claim 1, characterized in that the signal voltage of the signal generator (9 to 15) has an exponential course. 3. Circuit arrangement according to claim 2, characterized in that in order to form the exponential curve of the signal voltage, the series circuit of a first resistor (12) and a first capacitor (13) is connected between the feed lines (+, 0) of a stabilized direct current supply. 4. Circuit arrangement according to claim 3, characterized in that the connection point of the first resistor (12) and the first capacitor (13) is connected to a first input of a first comparator (7), and that the control voltage to the second input of the first comparator ( 7) is supplied. 5. Circuit arrangement according to claim 3, characterized in that the connection point of the first resistor (12) and the first capacitor (13) is connected to a first input of a second comparator (9), that furthermore to the second input of the comparator (9) the connection point of a second (10) and a third (11) resistor, both of which form a voltage divider between the feed lines (+, 0), and that the first input of the comparator (9) is connected via a fourth resistor (16) and a diode (15) is connected to the output of the comparator (9). 6. Circuit arrangement according to claim 5, characterized in that the output of the second comparator (9) is also connected via a fifth resistor (14) to the second input of the comparator (9). 7. Circuit arrangement according to claim 4, characterized in that a voltage divider (17, 18) connected between the feed lines (+, 0) is connected to the output of the first comparator (7). 8. Circuit arrangement according to claim 4, characterized in that the output of the first comparator (7) with the control electrode of a switching transistor (23), at the output electrode of a charging and discharging circuit (24, 25) for one Smoothing capacitor (27) is connected, is connected. 9. Circuit arrangement according to claim 8, characterized in that the output electrode of the switching transistor (23) via a sixth resistor (24) with a feed line (+) and via a seventh resistor (25) with a connecting terminal (26) for the voltage Setpoint value is connected, the connecting terminal (26) being connected to the other feed line (0) via the smoothing capacitor (27), such that when the switching transistor (23) is blocked, the smoothing capacitor (27) is connected in series via the sixth and seventh resistor (24 , 25) is charged and discharged when the switching transistor (23) is conductive via the seventh resistor (25) and the switching transistor (23). 10. Circuit arrangement according to claim 8 or 9, characterized in that the output of the first comparator (7) with the control electrode of the switching transistor (23) is connected via an optocoupler (19), with a transmitter-side diode of the optocoupler (19) one Forms part (18) of the voltage divider (17, 18) arranged at the output of the comparator (7), and a receiver-side transistor (21) of the optocoupler (19) with the control electrode of the switching transistor (23) and a supply resistor (22) connected is. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th