DE3331200A1 - Electronic potentiometer - Google Patents

Abstract

An electronic potentiometer has an adjusting stage (6), to which a signal is fed at a signal input (68) and which sets the amplitude of this signal as a function of a (resulting) adjusting voltage, which is fed to an adjusting input (60) of the adjusting stage (6), while keeping its DC level constant and leads away the signal of set amplitude at a signal output (71). With such an electronic potentiometer, the amplitude of a signal can be set over a great modulation range with low signal distortion and low signal delay by at least the two control voltages with little circuitry, by the electronic potentiometer comprising at least one multiplying stage (4) which has two inputs (49, 50), to which an adjusting voltage is fed in each case, and one output (47, 48), from which an adjusting voltage, which is formed by the multiplying stage (4) by a multiplicative operation on the adjusting voltages fed to its inputs (49, 50), and is passed to an input of a following multiplying stage or to the adjusting input (60) of the adjusting stage (6). <IMAGE>

Description

Electronic potentiometer

The invention relates to an electronic potentiometer with an actuating stage to which a signal is fed to a signal input and which the Amplitude of this signal while keeping its level constant as a function from a (resulting) control voltage that is sent to a control input of the control stage is supplied, adjusts and the signal adjusted in its amplitude to a Signal output dissipates.

Electronic potentiometers of the type mentioned are known and are used, for example, in integrated circuits in color television technology Adjusting the amplitude of the color difference signals depending on the desired Image contrast. Or the desired color saturation is used.

For example, from DE-OS 22 62 580 is a circuit arrangement for electronic gain adjustment with two cross-coupled transistor differential amplifiers known that each contain a transistor in the emitter lead, of which the one to the differential amplifier connected to it a direct current and the other the differential amplifier connected to it a corresponding direct current as well as supplies a signal stream.

In this circuit arrangement, the gain is set by means of one applied to the cross-coupled bases of the differential amplifiers Control voltage, and the output signal is at two interconnected collector outputs detachable.

With the known circuit arrangements, the amplitude of a signal set as a function of a single control voltage. To influence of a signal through several control voltages, several actuating stages are then connected in series, which the signal traverses one after the other. Such arrangements can be found for example in the integrated circuits TDA 2800 and TDA 3500, which are included in the "Valvo Development Announcements" No. 75a of January 1979 and No. t5b of February 1979 are described.

The known circuit arrangements are relatively complex and also cause non-linear signal distortion and signal bandwidth limitations and signal delays, as the signals adjust their amplitudes by-several Control voltages have to go through several control levels.

The invention has the task of providing an electronic potentiometer To create the type mentioned above, with which the amplitude of a signal via a large dynamic range with low signal distortion and low signal delay can be set by at least two control voltages and it is simply structured is.

This object is achieved according to the invention in that an electronic Potentiometer according to the generic term at least one multiplying stage, the two inputs, each of which is supplied with a control voltage, and one output has, of which a control voltage, which is carried out by the multiplying stage a multiplicative combination of the control voltages fed to their inputs is formed, discharged and an input of a subsequent multiplying Stage or the control input of the control stage.

In the electronic potentiometer according to the invention are thus all control voltages with which the amplitude of the signal is to be influenced, first of all multiplicatively linked to a resulting control voltage and is with this resulting control voltage the amplitude in a single control stage of the signal.

When linking more than two control voltages to one resulting Control voltage is at least one of the inputs of the multiplying stage supplied control voltages regularly the output of a (preceding) multiplying Step must be taken, since to link more than two control voltages regularly to use more than one of the multiplying stages described with two inputs is.

The electronic potentiometer according to the invention is in its structure, i.e. in particular in the arrangement of the connections of the multiplying stages, easily modifiable and therefore universally applicable. It is characterized by one low circuit complexity and a large dynamic range for the signal minimal signal delay and distortion. The bandwidth of the signal is given by does not affect the electronic potentiometer according to the invention. These advantages are achieved in that the signal to be adjusted in its amplitude only one runs through a single setting stage, as a result of which falsifications are caused by the setting stage of the signal can be kept to a minimum. The setting stage can therefore if necessary meet lower quality requirements. Low distortion in the control voltages, which may be made possible by multiple links in several successive ones multiplying levels result, unless the multiplying levels are perfect working linearly, however, are essential for the proper functioning of the electronic Potentiometers are comparatively of minor importance. In particular, remains also the bandwidth of the signal through the electronic potentiometer according to the invention undisturbed.

According to a further development of the invention, there are several multiplying Stages in a rescue circuit arranged in such a way that the output each one multiplying stage with a first of the inputs of a subsequent multiplying Stage and that the output of a last subsequent multiplying stage only is connected to the control input of the control stage.

In this arrangement, two control voltages are initially connected to one another linked, the linkage product is then linked to a third control voltage etc., until all control voltages are linked to one resulting control voltage.

According to another embodiment of the invention, an electronic Potentiometer according to the generic term on at least two conversion stages in which a control voltage is generated, the control voltage generated by a conversion stage is fed to one input of a multiplying stage. The conversion stages supply the control voltages in the form in which they are used in the multiplying stages or the setting level are required. The control voltages can be used in the conversion stages can be derived from various, also non-electrical control variables. Only one control voltage is generated by each conversion stage; this control voltage is only fed to one input of a multiplying stage.

According to a further embodiment of the invention, the control voltages between two multiplying levels, between one of the multiplying Stages and the output stage or between a conversion stage and a multiplying Stage passed through a separation stage. These stages of separation cause repercussions of the input currents from a stage to the preceding stage are avoided.

The inventive electronic potentiometer thus has a modular structure, which is put together differently according to the respective requirements and can be expanded within wide limits. The basic structure of the electronic Potentiometer is done by the arrangement of the multiplying stages and their Connections between each other and the actuating stage determined. That of connections with other multiplying stages become free inputs of the multiplying stages Control voltages supplied by the conversion stages. In at least some of the connections between the conversion stages, the multiplying stages and the actuating stage Separation steps inserted.

According to a further embodiment of the invention, the actuating stage comprises a first differential amplifier made up of a first and a second transistor, their interconnected emitters form a signal (alternating) current and a direct current are supplied, and the actuating stage further comprises a second Differential amplifier from a third and a fourth transistor, whose with each other connected to the emitters of the first and second transistor supplied direct current is supplied identical direct current, the with each other connected base terminals of the first and the fourth transistor a first Connection of the control input and the interconnected base connections of the second and the third transistor form a second connection of the control input, and the collectors of the first and third transistor together and with a connection of a working resistor and the second and fourth Transistor are connected to each other and to the supply voltage, the in the amplitude set signal is tapped over the load resistance whose second connection is connected to the supply voltage. Such a setting stage has a simple structure and guarantees a linear signal even with high signal amplitudes Modulation and a constant level of the signal.

According to a further development of the invention, each conversion stage comprises a differential amplifier made up of two emitter-coupled transistors, their collectors A supply voltage is supplied via a diode each, with a control input, to which a control voltage is fed, a reference input, to which a reference voltage is supplied, as well as a first and a second, each with one of the collectors connected output terminal, between which the conversion stage outputs the control voltage. Such a conversion stage supplies from a control voltage that is asymmetrical a reference potential, e.g. ground potential, a control voltage at which the The voltages supplied to the output connections are symmetrical to a fixed one Reference potential are and thus adapted to the control stage described above is.

. Between the control voltage and the control voltage there is a linear Connection. The reference voltage specifies the value for the control voltage, at which the control voltage becomes zero.

According to a further development of the invention, the emitters are the differential amplifiers of the conversion stages are connected to one another via an ohmic resistor each. With the by the size of these inserted into the emitter branches of the differential amplifiers Let resistors a determinable voltage drop the control ranges the conversion stages, i.e. the range of values of the control voltages at the control inputs, pretend. In addition, the input characteristics are determined by the resistances mentioned of the transistors of the differential amplifier linearized.

According to another development of the invention, there are particularly simply structured and the conversion steps described above adapted multiplying Stages from j two transistors, whose interconnected emitters a current, which corresponds to the control voltage output by one of the conversion stages, from Collector of one of the transistors of the conversion stage (high resistance) is fed, whose Base connections another of the control voltages is fed and to their collectors, each of which is supplied with a supply voltage via a diode, one to the product control voltage corresponding to the control voltages mentioned can be obtained.

According to a further embodiment of the invention, the separation stage formed by a transistor connected as an emitter follower. This allows in the outputs of the conversion stages are simply terminated with high resistance and the control voltages are passed on with low resistance, so that they are affected by the load with the input currents subsequent stages are not noticeably changed.

According to another embodiment of the invention, there is one control input at least one further setting stage, which in its structure is the (first) setting stage equals, each connected to a control input of the (first) control stage and becomes each A further signal is fed to another setting stage, the amplitude of the further signal. set in the further setting stage and the set in its amplitude further signal taken from the further output stage. In this way the amplitudes several more independent Signals with a control voltage can be set. The conversion stages, separation stages and multiplying stages are then used to set all signals together.

It can also multiply from any connection between two Levels a control voltage can be derived, which is the linkage product of the control voltages which are fed to the multiplying stages before the connection, from which said linkage product is derived.

According to another development of the invention, in which the electronic Potentiometer a first and a second conversion stage, a multiplying stage as well as having at least one setting stage, is the control input of the first conversion stage a control voltage determining the image contrast and the control input of the second Conversion stage is supplied with a control voltage which determines the color saturation at least one signal to be adjusted in amplitude is a color difference signal. For example, at the output of the multiplying stage there is one control stage connected for one of the color difference signals (R-Y) and (B-Y). One of those trained electronic potentiometer is used in a color television receiver as combined contrast and saturation adjuster.

With this adjuster, the control voltage can be applied to the connections between the first conversion stage and the multiplying stage, which is a measure only for the represents the image contrast to be set, a further setting stage for setting the amplitude of the luminance signal, i.e. the contrast of the black and white component of the color television picture. This can be a very effective Achieve utilization of all modules used.

The invention is illustrated below with reference to one in the drawing Embodiment explained in more detail. 1 shows a block diagram of a electronic potentiometer according to the invention, Fig. 2 is a detailed circuit diagram for an electronic potentiometer according to the invention.

1 is a block diagram of an example of one according to the invention Circuit arrangement shown to explain its basic structure. One first multiplying stage 4 has two inputs 49, 50, each of which has one Control voltage is supplied. In the multiplying level 4 it becomes one resulting control voltage and an input 49 'via an output 80 fed to a second multiplying stage 4 '. Additionally, the resulting Control voltage can optionally be derived via an output 32 '.

The circuit arrangement also has a third multiplying Level 4 "with two inputs 49", 50 "to which two additional control voltages are supplied will. A third resultant formed therefrom in the third multiplying stage 4 ″ Control voltage is taken from an output 80 "and a second input 50 'of the second multiplying stage 4 'supplied.

From the first and the third resulting control voltage it becomes in the second multiplying 'stage 4' a second resulting control voltage formed and derived via an output 80 '. This control voltage is immediate or for linking with further control voltages via further, not shown Multiplying stages fed to a control input 60 of a control stage 6. Of the Actuating stage 6 is also activated via a signal input 68 signal fed and after adjusting its amplitude according to the input 60 fed Control voltage derived at a signal output 71. If necessary, the control input is 60 connected to a control input 60 'of at least one further control stage 6', with which the amplitude of at least one further signal can be adjusted.

Fig. 2 shows a detailed example of an electronic potentiometer according to the invention, which is used to adjust the amplitude of a signal by means of two control voltages is set up and, for example, to adjust the amplitude of a color signal in a color television display device depending on a control voltage for the contrast and the color saturation can be used. The illustrated electronic Potentiometer consists of a chain circuit from a first conversion stage 1, a first separation stage 2, a second conversion stage 3, a multiplying Level 4, a second separation level 5 and an adjustment level 6.

The first conversion stage 1 has a control input 11, -dem a first Control voltage, for example to adjust the contrast of a color television picture, is supplied, and a reference input 12 to which a first reference voltage is fed. The first conversion stage is made up of a differential amplifier by a first and second transistor 13, 14 formed, the emitter of which over each an emitter resistor 15, 16 is connected to one terminal of a current source 17 at the other connection of which a fixed reference potential, in particular ground potential, is laid. The collectors of the two transistors 13, 14 are each one Diode 18, 19 connected to a terminal 20 of a voltage source, the opposite a positive supply voltage leads to the ground potential. The diodes 18, 19 in the collector branches of the transistors 13, 14 are forwarded by the voltage source biased. The transistors 13, 14 are of the npn type. The basis of the first Transistor 13 is with the control input 11, the base of the second transistor 14 with the reference input 12 connected.

The first conversion stage essentially serves to turn off. the control input 11 supplied, with respect to the ground potential asymmetrical first control voltage one. to generate a first control voltage symmetrical to a reference potential. the To this end, the first conversion stage has an output with a first connection 21, the with the junction of the cathode of the diode 18 and the collector of the first Transistor 13 is connected, and to a second terminal 22, which is connected to the connection point the cathode of the diode 19 and the collector of the second transistor 14 are connected is. The first generated by the first conversion stage 1 from the first control voltage Control voltage is used as the voltage between the first and the second terminal 21, 22 submitted.

To avoid repercussions of the following levels 3 to 6 on the first conversion stage 1 and the first control voltage it emits the output terminals 21, 22 of the.

first conversion stage 1 with the base connections of one transistor each. 25, 26 connected, the emitter of which each have a current source 27, 28 with a fixed Reference potential, in particular ground potential, are connected. The transistors 25, Like the transistors 13, 14 of the conversion stage 1, 26 are of the npn type. The collectors of the transistors 25, 26 are connected to one another and to a terminal 29 of a voltage source connected, through which the transistors 25, 26 a positive with respect to the ground potential Supply voltage is supplied. The transistors 25, 26 and the current sources 27, 28 together form the first separation stage 2.

To derive the first decoupled from the first conversion stage 1 Control voltage, the first isolating stage 2 has two output connections 30 and 31, each with the connection points between the emitters of the Transitors 25, 26 and the power sources 27, 28 are connected. The transistors -25, 26 are thus connected as an emitter follower, the output from the first conversion stage 1 Leave the first control voltage unchanged in size for the following stages but form a control voltage source with low internal resistance.

Of the output connections 31 and 30 of the first separation stage 2 is the first control voltage to the base terminals of a first transistor 45 or a second transistor 46, the emitters of which are connected to one another and the form the multiplying level 4. This is connected to the second conversion stage 3, which comprises a differential amplifier having a first transistor 37 and a second Transistor 38. The base of the first transistor 37 is connected to a control input 35 for supplying a second control voltage, for example for adjusting the color saturation of a color television picture, the base of the second transistor 38 is connected to a reference input 36 connected to supply a second reference voltage. The emitters of the first and the second transistor 37, 38 are each connected via an emitter resistor 39, 40 one terminal of a power source 41 connected, the other terminal with a fixed reference potential, for example ground, is connected. This part of the second Conversion stage 3 has the same structure as that of the first conversion stage 1, preferably the said components of the second conversion stage 3 are consistent with the corresponding components of the first conversion stage 1 dimensioned.

The collector of the first transistor 37 of the differential amplifier of second conversion stage 3 is connected to the interconnected emitters of the transistors 45, 46 of the multiplying stage 4 connected. The collectors of the first transistor 45 of the multiplying stage 4 and the second transistor 38 of the differential amplifier the second conversion stage 3 are connected to each other and via a diode 43 one Terminal 44 of a supply voltage that is positive with respect to the ground potential supplying voltage source connected. The collector of the second transistor 46 of the Multiplying stage 4 is also connected to the terminal via a further diode 42 44 connected to the voltage source.

The diodes 42, 43 are due to the voltage at terminal 44 in the flow direction biased.

In the second conversion stage 3, the control input 35 is supplied from the second control voltage generates two currents, the sum of which is due to the current source 41 electricity fed into the grid. The current in the collector of transistor 38 flows directly through the diode 43 ,, the current in the collector of the transistor 37 is in the multiplying stage 4 corresponding to that supplied by the separation stage 2 first control voltage on the diodes 42 and 43 divided. Through the diodes 42, 43 Currents that are dependent on both control voltages flow. The difference between the Currents in the diodes 42, 43 produced voltages is the product of the Resulting control voltage corresponding to the control voltages. To derive the resulting The control voltage is the connection point of the collectors of the second transistor 38 of the differential amplifier of the second conversion stage 3 and of the first transistor 45 the multiplying stage 4 with a first output terminal 47 and the collector of the second transistor 46 of the multiplying stage 4 with a second output terminal. 48 tied together.

The one between terminals 47 and 48 of the multiplying stage The resulting control voltage lying 4 is first fed to the second separation stage 5. For this purpose, one of the output connections 47, 48 is in each case of the multiplying stage 4 connected to the base terminal one of two transistors 51, 52, whose Emitter each via a current source 53, 54 with a fixed reference potential, in particular Mass, and their collectors with each other and with a connection 55 a supply voltage that is positive compared to the ground potential Voltage source are connected. The connection points between the emitters of the Transistors 51 and 52 and current sources 53 and 54 are also -with output terminals 56 or 57 connected ,. via the resulting control voltage of the following Level 6 is supplied.

The structure of the second separation stage 5 is similar to that of the first separation stage 2 and is preferably dimensioned identically.

Of the output connections 56, 57 of the second separation stage 5 is in each case one with a first connection 61 and a second connection 62 of a control input 60 connected to the setting stage 6. The setting stage 6 consists of four transistors that are coupled in pairs to form a first and a second differential amplifier. The first differential amplifier includes a first transistor 63 and a second Transistor 64, their emitters with each other and with a signal input 68 for feeding the signal current to be set in its amplitude, for example a color television signal, are connected. The second differential amplifier includes a third transistor 65 and a fourth transistor 66 whose emitters are connected to one another and to one terminal a DC power source 67 are connected. The other connection of the power source 67 is connected to a fixed reference potential, in particular ground potential.

The bases of the first transistor 63 and the fourth transistor 66 are with each other and with the first control input connection 61, the base connections of the second transistor 64 and the third transistor 65 are.

connected to one another and to the second control input connection 62. Via the setting input 60, the two differential amplifiers of the setting stage 6 receive the resulting Control voltage supplied.

The collectors of the first transistor 63 and the third transistor 65 continue to have a signal output 71 at which the amplitude is set Signal is discharged, as well as via a working resistor 70 with a connection 69 connected to a voltage source, the one with respect to the ground potential positive Supply voltage supplies. The collectors of the second transistor 64 and des Fourth transistor 66 are directly connected to terminal 69. The amplitude the signal voltage drop across the load resistor 70 depends linearly on the product the first and the second control voltage.

The power supplied from the DC power source 67 becomes the level of the signal current supplied to the signal input 68, which is one of the Setting the amplitude of the signal should have an independent value. Is for example to adjust the amplitude of a television signal, the direct current source 67 to a current corresponding to the black level of the current supplied to the signal input '68 Current set. The level of the derived at output 71 corresponding to the black level Signal is then independent of the setting of the amplitude of the television signal constant.

The connections 20, 29, 44, 55 and 69 for supplying the supply voltages the individual stages are separated in the figure for the sake of clarity shown.

However, all stages preferably receive their supply voltage from a voltage source. If necessary, this is the one supplied to connection 6-9 Supply voltage to ensure a sufficiently large signal modulation range greater than the supply voltage fed to the connections 20, 44. Farther the reference voltages fed to the reference inputs 12, 36 can also be set derive advantageous from the common supply voltage.

In the present exemplary embodiment, the output 30, 31 is the first separation stage 2 additionally connected to two taps 32. About these taps 32, the first control voltage can be derived for other use, for example for contrast-dependent - but independent of color saturation - adjustment of the amplitude of the brightness signal in a color television receiver. In a corresponding manner can at the output 56, 57 of the second separation stage 5 the control input of at least one further setting level in addition to setting level 6 can be connected.

In both cases, several signals are set by a control voltage. As a result, the circuit complexity is kept low and the amplitudes of all that need to be set are kept low Signals changed evenly.

The electronic potentiometer described above is for Adjusting the amplitude of a signal formed by two control voltages. If the amplitude of the signal is to be influenced by more than two control voltages, the arrangement described can be expanded in a simple manner in that, for example the connections between the first separation stage 2 and the multiplying stage 4 along the line 81 or the connections between the second separation stage 5 and the actuating stage 6 are separated along the line 82. At these separations at least one assembly can then be inserted, each with a conversion stage, the structure of which is identical to that of the second conversion stage 3, a multiplying Stage, the structure of which is identical to that of the multiplying stage 4, and one Separation stage, the structure of which is identical to that of the second separation stage 5, where this multiplying stage, this conversion stage and this separation stage on the in the same way with each other and with the previous stage in each case (e.g. the second separating step 5 when the additional steps are inserted at the separating line 82) as well as the following stage (e.g. control stage 6) are connected like the Steps 2 to 6 shown in the figure.

An electronic potentiometer according to the figure has e.g.

the following dimensions: The emitter resistors 15, 16, 39, 40 are 2.5 kOhm, the working resistance 70 is 6 kOhm, the currents of the power sources 17, 27; 28, 41, 53 ', 54 are set to 0.4 mA and the current of the direct current source 67 set to 1 mA, the supply voltage at connections 29, 55, 69 is 12 V, at terminals 20 and 44 7 V, the reference voltages at the reference inputs 12, 36 are 3 V and the control voltages at the control inputs 11, 35 include a range of values from 2 to 4 V. All voltages are positive compared to the ground potential specified.

In the embodiment described, all transistors are from NPN type, but the circuit arrangement can also be carried out in an analogous manner with PNP transistors be constructed.

Claims (11)

Claims: 0. Electronic potentiometer with one setting stage, to which a signal is fed to a signal input and which the amplitude of this Signal while keeping its level constant. depending on a (resulting) Adjusts the control voltage that is fed to a control input of the control stage and carries off the signal adjusted in its amplitude at a signal output, marked by at least one multiplying stage (4; 41; 4 "), the two inputs (49, 50; 49 ', 50'; 49 ", 50"), each of which is supplied with an actuating voltage, and one Output (47, 48; 80; 80 '; 80 "), of which a control voltage, which is of the multiplying level (4; 4 '; 4 ") by a multiplicative combination of their Inputs (49, 50; 49 ', 50'; 49 ", 50") supplied control voltages is formed, discharged and an input (49 ', 50') of a subsequent multiplying stage (4 ') or the control input (60) of the control stage (6) is fed. 2. Electronic potentiometer according to claim 1, characterized in that that several multiplying stages (4, 4 ') arranged in a chain circuit are such that the output (47, 48; 80) each of a multiplying stage (4) with a first (49 ') of the inputs of a subsequent multiplying stage (4 ') and that the output of a last subsequent multiplying stage only is connected to the control input (60) of the control stage (6). 3. Electronic potentiometer according to claim 1, characterized by at least two conversion stages (i; 3), in each of which a control voltage is generated, with only the control voltage generated by a conversion stage (1; 3) in each case to one input (49, 50) is fed to a multiplying stage (4). 4. Electronic potentiometer according to claim 1, 2 or 3, characterized characterized in that the control voltages between each two multiplying stages. (4; 4 '), between one of the multiplying levels (4; 4'). and the setting stage (6) or between a conversion stage (1) and a multiplying stage (4) in each case are passed through a separation stage (2; 5). 5. Electronic potentiometer according to claim 1, characterized in that that the actuating stage (6) comprises a first differential amplifier (63, 64) from one first (63) and a second (64) transistor, their interconnected emitters a signal (alternating) current forming the signal and a direct current are supplied (68), and that the control stage (6) also has a second differential amplifier (65, 66) comprises a third (65) and a fourth (66) transistor, their interconnected associated emitters one with which the emitters of the first and. second transistor supplied direct current identical direct current is supplied (67), the interconnected base connections of the first (63) and the fourth (66) transistor have a first connection (61) of the control input (60) and the interconnected base connections of the second (64) and the third (65) transistor form a second connection (62) of the control input (60), and the collectors of the first (63) and the third (65) transistor with each other and with a connection of a working resistor (70) and the second (64) and the fourth (66) transistors are connected to one another and to the supply voltage (69), wherein the signal, which is set in amplitude, is tapped via the working resistor (70) whose second connection is connected to the supply voltage. 6. Electronic potentiometer according to claim 3, characterized in that that each conversion stage (1; 3) has a differential amplifier (13, 14; 37, 38) from two emitter-coupled Transistors whose collectors each have a supply voltage via a diode (18, 19; 42, 43) (2.0; 44) is supplied, comprises with a control input (11; 35), - which a control voltage is fed to a reference input (12; 36) to which a reference voltage is fed as well as a first (21; 33) and a second (22; 34) each with one of the collectors connected output terminal, between which the conversion stage (1; 3) the control voltage gives away. 7. Electronic potentiometer according to claim 6, characterized in that that the emitters of the differential amplifiers (13, 14; 37, 38) of the conversion stages (1; 3) are connected to one another via an ohmic resistor (15, 16; 39, 40) each. 8. Electronic potentiometer according to claim 6, characterized in that that the multiplying stages (4) each consist of two transistors (45, 46), whose interconnected emitters produce a current, which is that of one of the conversion stages (3) corresponds to the output voltage from the collector of one of the transistors (37) the conversion stage (3) (high-resistance) is fed, the base connections of which a further the control voltages is supplied and at their collectors, each of which has one Diode (42, 43) a supply voltage is fed (44), one of the product of the The control voltages mentioned can be taken from the corresponding control voltage. 9. Electronic potentiometer according to claim 4, characterized in that that the separation stage (2; 5) by a transistor connected as an emitter follower (25.26; 51.52) is formed. 10. Electronic potentiometer according to one or more of the preceding Claims, characterized in that a control input at least one further Control stage, which has the same structure as the (first control stage (6)) with the control input (60) of the (first) setting stage (6) is connected to each other setting stage further signal is supplied, the amplitude of the further signal in the further The output stage is set and the amplitude of the further signal of the is taken from another setting stage. 11. Electronic potentiometer according to claim 6 with a first (1) and a second (3) conversion stage, a multiplying stage (4) and at least an actuating stage (6), characterized in that the control input (11) of the first Conversion stage (1) a control voltage determining the image contrast and the control input (35) of the second conversion stage (3) a control voltage which determines the color saturation is supplied and that at least one signal to be adjusted in amplitude Color difference signal is.