DE1252260B - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY GERMAN WjKW PATENT OFFICE

EDITORIAL

Int. Cl .:

H03g

H04r; H03f German class: 21 a2 -18/07

Number: 1 252 260

File number: A 42320 VIII a / 21 a2

Filing date: February 12, 1963

Opened on: October 19, 1967

The invention relates to a circuit arrangement for remote volume control of an alternating signal voltage, which is fed to an AC amplifier circuit, with an adjustable electronic Device to which an output impedance element is connected to which the signal alternating voltage occurs with an amplitude dependent on the impedance value, the impedance value by a Direct current controlled and between the electronic device depending on the voltage two electrodes of the electronic device is delivered, as well as by a remote control device for changing the voltage between adjustable with the electrodes.

For remote control it is often desirable to use an alternating signal voltage, namely the audio frequency voltage to set in a device for volume control from a location that is from the Amplifier is removed. Provide a volume control for the amplifier at the control point, is out of the question, however, since the audio frequency voltage would then be fed to the operator station got to. However, this leads to difficulties mainly because of the shielding.

It is a circuit for a remote controlled volume adjustment known with the help of a thermistor (Electronics, 1961, No. 4, p. 112), in which the grid a triode serving as an amplifier stage is preceded by a voltage divider, one of which is a resistor is an externally heated thermistor. The current through the heating coil is from the control point adjusted by means of a variable resistor. Flows in the line leading to the control point thus only direct current. The disadvantage, however, is that to adjust the current through the heating coil a special voltage source is required and that such a thermistor with an insulated heating coil is relatively expensive and sensitive to interference and temperature.

The object on which the invention is based therefore consists in the circuit arrangement to simplify the remote volume control of the signal alternating voltage as described above, by eliminating the special voltage source in the remote control line and creating a more appropriate one Component is used in place of the externally heated thermistor.

The object on which the invention is based is achieved according to the invention in that the output impedance element one directly into the collector circuit of one of the electronic devices Transistor switched on, current-dependent circuit arrangement for remote volume control an alternating signal voltage

Applicant:

Neumann Electronics G. m. B. H., Mühlheim / Ruhr-Broich

Named as inventor:

Dipl.-Ing. Kurt-Henry Mindermann, Stockholm

Claimed priority:

Sweden 13 February 1962 (1502)

Resistance is the resistance value of which is different from that used to amplify the signal alternating voltage on the same side serving transistor is dependent. This gives the advantage that the output impedance is current-regulated directly by the amplifier stage and is a simple current-dependent resistor. The incoming signal alternating voltage is amplified in the transistor, and the current-dependent one The output impedance can be set using the remote control device. Thus flows in to the remote control point leading line only direct current, which is also used to control the transistor. Circuits with temperature-dependent resistors are known per se. This is how it is, for example known to use a thermistor to keep an output voltage constant (German patent 743 025) or a current-dependent resistor in negative feedback circuits (German patents 849 860, 1003 801).

The invention is described in more detail below with reference to the drawing, which shows a circuit diagram shows an embodiment of the invention.

The primary winding 2 of a transformer 1 is connected to a symmetrical line 3 which for example from a microphone or a repeater connected to a microphone comes. One end of the secondary winding 4 of the transformer 1 is connected to the base 5 of the transistor 6 connected. The other end of the secondary winding 4 is connected to a capacitor 7 of high Capacity, for example of 100 microfarads, for AC voltages to ground. The emitter electrode 8 of the transistor 6 is connected via a parallel

709 678 «04

direction of a resistor 9 and a capacitor through the output impedance element 13 flowing 10 of high capacity, for example 50 micro-currents somewhat weaker. As each of the resistances farad, but still a very high value at the positive pole of a DC voltage source 11 19a and 19 ft connected whose negative pole has a negative, this decrease in the strength of the through the stood 12 at one end of an output impedance 5 output impedance element 13 flowing current to element 13 is connected. The other end of the next relatively insignificant. As a result of the entered output impedance element 13 is connected to the collector to reduce the current intensity, but the electrode 14 of the transistor 6 is connected. The temperature of the output impedance element 13, so Voltage source 11 is across a capacitor 15 that its resistance value and with it the Ausvon high capacitance to ground. Another capacitor output voltage at terminals 24 and 25 increases, Sator 16 of high capacity is between ground and the junction between the resistor 12 resistor 19 a and 19 ft is its resistance and the impedance element 13 switched on. With the value and with it the strength of the last called junction is flowing through a sistor and the output impedance element Resistance 17 of the order of 18 kilograms of current reduced so that the impedance value of the ohm, the junction between the secondary output impedance element also increases. this leads to Därwickung 4 and the capacitor 7 connected. a further increase in the output voltage The resistor 17 forms part of a voltage to the terminals 24 and 25.

divider, the other part of which is a fixed counter- As can be seen from the drawing, the two are

stood 18 on the order of 100 kilo ohms and 20 conductors 21 and 22 through capacitors 7 and 15

a number of variable resistors 19 a, 19 b formed high capacity for signal frequency voltages' full-

which is permanently blocked at various control points and therefore completely unresponsive.

are ordered. Each of these resistances is in series borrowed from atmospheric disturbances. As a result-

with an on / off switch 20 a, 20 b, between two conductors, the volume controls 19 a, 20 a and

tern 21 and 22 turned on, one of which, 25 19 ft and 20 ft at considerable distances of

21, to be provided at the junction between the secondary and the amplifier without winding 4 and the capacitor 7 and the other, special precautions are required. Remote

22, and any number of such clauses can be connected to the positive pole of the voltage source 11 is. connect the power registers in parallel in order to

The output voltage of the device is taken from 30 systems a volume control from any two terminals 24 and 25, from which a large number of places to enable
the one through a capacitor 23 to the collector Since the output impedance element 13 of a

electrode 14 of transistor 6 and the other is formed on the temperature-dependent resistor, The positive pole of the voltage source 11 is connected, its impedance value does not fluctuate with the and that at the input of a force value (not shown) that is applied to the impedance element Amplifier can be connected. Signal frequency alternating voltage. The impedance

According to the invention, however, an output impedance element 13 does not need to be made from a uranium element 13 is used, the impedance value of which depends on the dioxide resistance with a negative temperature coefficient of the current flowing through it, but one can also have one or the span resistor with a positive temperature coefficient between its ends is dependent. Preferably the impedance is to be used, i. H. with a resistance value, value of the output impedance element 13 of that when the temperature at the resistor increases of the impedance element. As the tension increases. Examples of for this For example, an impedance element 13 on the purpose suitable resistors are a thin one Based on uranium dioxide can be used. 45 tungsten wire in an evacuated housing or

Each of the resistors 19 a, 19 ft can with a thin iron wire, for example in a Switches 20 a or 20 ft are combined so that the housing filled with hydrogen gas is arranged. When turning the control knob of the resistor If the output impedance element 13 has a posistandes in which has temperature coefficients corresponding to the lowest volume, the sounds become The switch is automatically switched off will. Operation between the conductors 21 and 22 in series

The arrangement works as follows: When all switched. Each of the switches 20a, 20ft should then switch 20a, 20ft be open, the base electrode 5 of the transistor 6 should be switched in parallel with the associated resistor 19a, 19ft via the secondary and be arranged in such a way that it is the winding 4 and the resistor 17 with the minus 55 resistor short-circuits when this is connected in the pole of the voltage source 11. A fairly strong current flows through the position, which is the lowest volume entTransistor, speaks. If each of the resistors 19 a, 19 ft through so that the resistor 13 is heated considerably its own actuator can be short-circuited, and has a low resistance value and the switches 20 a, 20 ft can be omitted.
Output terminals 24 and 25 have a low output 60 when resistors 19 a, 19 b the lowest output voltage is obtained. If you have a resistance value, the output voltage obtained between the control points at which the devices input terminals 24 and 25 of the described pre-19 a, 20 a and 19 ft, 20 ft are provided, the device has a mini-control button such a facility for the purpose of painting value. When the resistance value increases, the output voltage rotates, one of the resistors 19a and 196 rises first, the switch 20a or 20ft is closed, so that the pedance value of the output impedance element 13.
The potential of the base electrode 5 of the transistor 6 in a uranium dioxide resistor is suitable, however, being changed in a positive direction. This makes the especially good as an output impedance element because it

Claims (5)

at a given change in its temperature experiences a greater change in its resistance value than a temperature-dependent resistor of any other type and because, due to its negative temperature coefficient, the volume controls 19 α, 20 α and 19 b, 20 b used for remote control can be connected in parallel. Several modifications of the subject matter of the invention are possible within the scope of the patent claims. ίο patent claims: 1. Circuit arrangement for remote volume control of an alternating signal voltage that one AC amplifier circuit is supplied, with an adjustable electronic device, to which an output impedance element is connected to which the signal alternating voltage occurs with an amplitude dependent on the impedance value, where, the impedance value controlled by a direct current and dependent on the electronic device the voltage is output between two electrodes of the electronic device, as well as by a remote control device for changing the voltage between the electrodes is adjustable, characterized in that the output impedance element is a direct switched into the collector circuit of a transistor (6) representing the electronic device, current-dependent resistor (13), whose resistance value is different from that of the simultaneous Amplification of the signal alternating voltage serving transistor is dependent. 2. Circuit arrangement according to claim 1, characterized in that the emitter (8) of the transistor (6) and the current-dependent resistor (13) to a direct voltage source (11) and the base (5) of the transistor to the signal alternating voltage and to a tap of a Voltage divider (17, 18, 19) connected in parallel to the DC voltage source and having an adjustable resistor (19) connected between the tap and the pole of the DC voltage source connected to the emitter (8) of the transistor, which resistor is at a remote location is arranged and is connected to ground via capacitors (7,15) of high capacitance. 3. Circuit arrangement according to claim 2, characterized in that a resistor (9), a capacitor (10) with high capacitance is connected in parallel between the emitter (8) of the transistor and the pole of the DC voltage source is connected in series. 4. Circuit arrangement according to claim 2, characterized in that an adjustable resistor (19 a, 196) each with a switch (20 a, 20 b) is provided in parallel to each other at different control points. 5. Circuit arrangement according to one of claims 1 to 4, characterized in that the Current-dependent resistor (13) is a uranium dioxide resistor with a negative temperature coefficient is. Considered publications:
German patents No. 707 488, 743 025,
059, 849 860; German Auslegeschrift No. 1003 801;
J. IEE, 93/1946, pp. 304, 305;
Funkschau, 10/1956, pp. 407 to 410;
Bull. SEV, 53 (1962), 8, p. 421;
Elektronik, 4 (1961), p. 112. 1 sheet of drawings 709 678/304 10. 67 © Bundesdruckerei Berlin