DE1271174B - Astable multivibrator controllable with DC voltage - Google Patents

Description

Astable multivibrator controllable with direct voltage In measurement technology, in particular telemetry, there has long been a requirement for a direct voltage frequency converter in which the frequency generated depends linearly on the variable direct voltage control. The known astable multivibrator, which supplies a pulse frequency that is essentially determined by the time constant of the RC coupling, can be used as a frequency converter. Such multivibrators have two amplifier elements, in which the output of each amplifier element is coupled to the input of the other amplifier element via an RC combination. It is known that the pulse frequency can be varied by means of a direct voltage applied to a specific point in the multivibrator circuit. Up to now, however, one had to accept the disadvantage that in multivibrators of the type mentioned above, the pulse frequency does not change linearly with the DC control voltage. This law can also be seen from the following formula for the frequency of the multivibrator, in which U "= charging voltage; U;" = Recharging voltage = control voltage is: Under these conditions, there has been no lack of attempts by experts to eliminate the disadvantage of non-linearity by means of special circuitry measures.

So is z. B. a multivibrator is known in which the relationship between a DC voltage and the oscillation frequency controlled by this is represented in a certain range by a linear function. However, this multivibrator requires at least one magnetic core made of highly permeable sheet metal and several windings, so that its production is relatively expensive .

In another known multivibrator, a linear relationship is used between frequency and control voltage for very specific parameters of the multivibrator circuit achieved. It is therefore only possible to a very limited extent with this multivibrator that The tendency of the frequency-control voltage characteristic to change; without the linearity to go forfeit.

It is also a DC controlled multivibrator with two Vcrstarkkerclcmcntcn known in which the input of the first amplifier element via the parallel connection of a resistor and a capacitive network with a Input terminal is connected to a control voltage for the frequency of the Multivibrators in their height is variable DC voltage.

Finally, another multivibrator circuit is in the control path of the multivibrator transistors another transistor has been switched, whereby a constant capacitor charging current is achieved, so that the charging voltage is linear depends on the time.

The invention is now based on the object of creating a direct voltage frequency converter with a linear dependence of the frequency on the direct voltage control voltage, which, despite the prejudice of experts, uses a simple, astable multivibrator consisting only of the necessary basic components. The object of the linear dependence of the frequency on the DC control voltage is achieved according to the invention in that the recharging voltage U ", or U" and Us, is greater than the charging voltage U ". In development of the invention a multivibrator circuit is constructed so that two opposite to an auxiliary supply voltage U ,, voltage dividers are provided, to each of which one of the multivibrator transistors is turned on so that a voltage divider resistor is connected in parallel with the collector-emitter path and the other voltage divider resistor to Collector resistance of the transistor forms. Further features and details of the invention are described in more detail below with reference to two exemplary embodiments and illustrated in the drawing.

F i g. 1 shows an astable multivibrator whose frequency is with Can be changed using a potentiometer; F i g. 2 shows a similar circuit, in which the frequency can be controlled with the help of a variable voltage.

According to FIG. 1 the astable multivibrator is constructed in a known manner from two transistors T, the coupling capacitors C, the collector resistors R, and the base resistors R. The auxiliary voltage Uh is greater than the charging voltage Uo, so that the values for U "and the bias voltage are within the range of the auxiliary voltage U "varies as required by dividing the voltage with the aid of the voltage divider R1, R2, R3 and can be set. The bias Ui must to achieve a possible small linearity error greater than U, be. So you are also outside that area in which a change in sign of the frequency change occurs. With this circuit there is a simple possibility of using the frequency of the potentiometer R1. Fluctuations in the auxiliary voltage cause Uh no changes in frequency emerge, provided that the residual transistor sizes are negligible are. The load resistance for the potentiometer R1 is about 1/2 R.

In Fig. FIG. 2 shows a multivibrator circuit which, compared to that shown in FIG. 1 shown has been modified in some points. Here, the voltage division for generating the charging voltage U "is carried out by the resistors R, and R6, which form a voltage divider for each transistor T which is connected to the auxiliary voltage Uh . The voltage divider resistor R6 is parallel to the emitter-collector path of the transistor, while the other voltage divider resistor R represents the collector resistance at the same time. This gives a steeper rising edge with the same current consumption, since the time constant relevant for this is reduced. A switching stage consisting of the transistor TZ is connected downstream to increase the switching capacity Base and emitter are parallel to the voltage divider resistor Rb and to the collector-emitter path of the transistor R. The two capacitors Cl are also used in the circuit, which are located between the base and emitter of the transistors T. They prevent incorrect switching of the multivibrator by et wa interference pulses affecting the input or the control lines.

The setting of the bias voltage U "or the initial frequency takes place via a separate voltage divider Ri, P1, R2, which is also connected to the auxiliary voltage Uh between points A and B are balanced by the setpoint value by a further voltage divider P2, RE. In this circuit, the frequency of the astable multivibrator can either - as in the circuit according to FIG. 2 specified -be controlled by a variable DC voltage U "or, after minor circuit changes, by a potentiometer (not shown). When using a potentiometer, fluctuations in the auxiliary voltage Uh have only a very slight influence on the frequency, the change of which is possible over a wide range The amplitude of the output voltage always remains constant.

Should the frequency be controlled with a separate voltage source U " it is connected to one pole of the two base resistors and to the other pole to the voltage divider.Ri, P1, - R? switched. With this circuit the sum of both voltages of U, and Ui, becomes effective, where Um is approximately equal to U " is.

By inserting the voltage source U "with its internal resistance Ri, this resistance Rill RE is added to the resistance of R, whereby the initial frequency becomes lower. If the previously determined values are to be retained, R must be reduced by the amount of Rill RE The lower limit of the oscillation frequency is independent of the properties of the transistors T, and it is determined solely by the insulation resistance of the capacitors C. The upper limit of the oscillation frequency is essentially determined by the (3 limit frequency of the transistors, provided that the switch-on time of the rising edge is still allows.

The smaller the available control voltage U, for a change in the frequency, the smaller the charging voltage U "must also be. The absolute value of U, must, however, be at least large enough that the resulting differential voltage U, - Ue # Es ., - UB Es "", which must block the respective transistor, is still large enough to ensure this function.

The high linearity between control voltage and pulse frequency is again essentially determined by the fact that the charge reversal voltage (U "+ U",) is selected to be greater than the charging voltage Uo, the best results being achieved when U ", (F i g. 1) or (U ,, + U ";) (F i g. 2) is equal to or greater than 1.5 times the voltage of U".

A conversion of the symmetrical rectangular shape of the generated voltage A sinusoidal shape can be easily converted into a relatively small frequency change Perform wisely because the harmonics don't start until the third harmonic. In the case of telemetry systems based on the frequency variation method, the usual Frequency deviation only 15% of the initial frequency, so that the multivibrator according to the invention is also suitable for telemetry purposes and despite its simple structure a number has advantageous properties. With suitable dimensioning of the electrical Switching elements can with the astable multivibrator in a practically linear Frequency range from 5 to 15 Hz can be generated, with one being realized Switching the linearity error with a maximum of 0.36%, based on 10 Hz frequency: iz change, was established. The temperature error is also negligibly small, because it was in a temperature range from -20 to + 60 ° C with about 0.6% per 10 ° temperature change established. This error can be reduced considerably with very simple means be e.g. B. with the help of a temperature-dependent resistor in the voltage divider, which is used to generate the preload.

The invention is not limited to that in the drawing shown Embodiments limited. Among other things, it is also possible to use the npn or Replace pnp transistor in such opposite conductivity type and the To reverse the polarity of voltages.

Claims (7)

Claims: 1. With direct voltage controllable astable multivibrator for generating a pulse frequency which is linearly dependent on the control direct voltage, in particular as a direct voltage frequency converter for telemetry purposes, because the recharge voltage (U "or U" + U "); ) is greater than the charging voltage (U,) of the multivibrator transistors (T). 2. Multivibrator according to claim 1, characterized by two connected to an auxiliary supply voltage (U ,,) Voltage divider (RjR6), each of which has one of the transistors (T) connected in this way is that the one voltage divider resistor (R ,,) parallel to the collector-emitter path and the other voltage divider resistor (R,) is the collector resistance of the Transistor (T) forms. 3. Multivibrator according to claim 1 or 2, characterized by a third voltage divider (Ri, P1, R2), one pole of a control voltage source at its potentiometer tap (US,) is connected, while the other pole is connected via a resistor (R) connected to the bases of the transistors (T). 4. Multivibrator according to claim 3, characterized in that the control path is connected to the collector of one of the transistors (7) of a switching transistor (TZ) is connected, in whose collector circuit the load resistance (RL) lies. 5. Multivibrator according to claim 1, characterized by a potentiometer (R1) containing voltage divider (R1, R2, R3), in which the adjustable potentiometer tap via the base resistors (R) connected to the bases of the transistors (T), while the collectors of the transistors (T) via the collector resistors (RJ to a lower potential of the voltage divider are connected (Fig. 1). 6. Multivibrator according to claim 1, characterized in that that a capacitor (Cl) is connected in parallel to the control path of the transistors (T) is. 7. Multivibrator according to claim 3, characterized in that the control voltage (US,) is connected to a voltage divider formed from a resistor (Re) and a potentiometer (P2), such that the one pole (B) of the control voltage with the tap of the potentiometer (P1) and the tap of the voltage divider potentiometer (P2) is connected to the base resistors (R). Considered publications: German Auslegeschriften Nos. 1093 818, 1 105 987, 1 119 331, 1 131729; U.S. Patent No. 2,338,395; Swiss Patent No. 251761; P uek 1 e, "Time Bases", 1951, pp. 32, 33; Electronics, April 26, 1963, pp. 64, 65; Elektronik, 1966, issue 11, pages 337 to 340.