DE1121112B - Astable multivibrator circuit with transistors - Google Patents

Description

Astable Multivibrator Circuit With Transistors The invention relates to an astable multivibrator circuit with transistors to achieve a high Working frequency and a rectangular output pulse shape.

Astable multivibrator circuits in which transistors are used instead of electron tubes are known. The maximum operating frequency that can be achieved in this way differs depending on the type of transistor. It amounts to z. B. with the transistor OC 76 only about 15 kHz and with the transistor OC 44 about 120 kHz. The method of operation, in particular the behavior of the transistors used in the circuit, of a normal astable multivibrator is briefly explained below. As is known, an astable multivibator contains two active electronic switching elements, either electron tubes or transistors, which are alternately blocked once and conductive once. If transistors are used, only a negligibly small reverse current flows through them in the blocked state, while a relatively large collector current flows in the conductive state. A steadily larger fed-in base current Ib > il causes no further increase in the collector current beyond a certain value Oce due to the saturation of the transistor, so that the transistor carries a constant collector current in its saturation area regardless of the size of the respective input current. When the two transistors in the multivibrator circuit work together, the changes in the collector potentials are each fed to the base of the other transistor via capacitors. When the multivibrator is static, one transistor is conductive and the other is blocked. As a result of the feedback during the tilting process, the collector current of the conductive transistor decreases, its collector potential becomes more negative and is transferred via one capacitor to the base of the blocked transistor, so that it now becomes conductive, etc. The capacitor of the blocked transistor is recharged the flip-over process, the base current of the conductive transistor being equal to the sum of the capacitor charging current and the current flowing through the base resistor. After the capacitor charging, which is dependent on the time constant of the capacitor and the collector resistance of the blocked transistor, the capacitor charging current ceases to flow and the base current of the conductive transistor now corresponds to the current flowing through its base resistance. The base resistance is chosen so large that the current flowing through it causes the saturation of the conductive transistor. The collector current of the conductive transistor flows on the one hand through its collector resistance and on the other hand as a discharge current through its capacitor to the base resistance and to the base of the transistor which is still blocked. Since the base resistance is much greater than the collector resistance, the discharge of the capacitor of the blocked transistor also takes longer than the charging of the capacitor of the conductive transistor, so that the blocked transistor remains blocked until its capacitor is discharged. It follows that the level of the working frequency of the multivibrator depends on the time constants or the values of the coupling capacitors and the base resistances. The smaller the selected time constant, the higher the working frequency will be. The level of the operating frequency to be achieved with transistors is, however, set a limit insofar as charge carriers must be present in the base space of the transistor so that a collector current can flow at all. If you suddenly switch off the base current in a conducting transistor, the collector current cannot disappear immediately, rather the charge carriers must first flow away from the base space. The number of charge carriers present depends on the type of transistor used and on the type of circuit in which the transistor is operated, as well as on its mode of operation. Was z. If, for example, a transistor saturates before switching from the conductive to the blocked state, the number of charge carriers present in the base current is many times greater than if the transistor had worked in the linear range. You can therefore switch a transistor from the conductive to the blocked state more quickly if it is not in saturation before the toggle process, so that a transistor of the same type operates at four to five times the operating frequency when it does not come into saturation. In itself, by appropriate selection and dimensioning of the individual circuit components, it would be possible to operate the transistors in such a way that they do not come into saturation in order to achieve a higher operating frequency. However, this has the great disadvantage that the multivibrator is very dependent on the intrinsic characteristics of the transistors, which in particular has a considerable effect and has a very adverse effect on the value of the current amplification factor of the transistors.

Circuits are known in which the transistors are not in the saturation range work and despite the high frequency of work that has been achieved, those just mentioned Do not have disadvantages, but this circuit requires more circuit elements.

The invention relates to an astable multivibrator circuit equipped with transistors, in which the transistors without significant additional expenditure on circuit elements compared not the currently known astable multivibrators at the moment of switching come to work in the saturation range and in addition, their output pulses have a perfect rectangular shape over the entire frequency range.

According to the invention, this is achieved in that each of the two transistors between its hasis and its collector is connected in parallel with a coupling resistor and that the collector resistance of each transistor consists of at least two series-connected circuit elements, which consist of two ohmic resistors or one ohmic resistor and consist of a diode, at the connection point of which a feedback line leading via a capacitor to the base of the other of the two transistors is connected.

Further features of the invention and details of the advantages achieved by it emerge from the description of the embodiment of an astable multivibrator according to the invention shown in the drawing. 1 shows an astable multivibrator and FIG. 2 shows an astable multivibrator according to a different circuit variant.

1 shows an astable multivibrator circuit with two transistors 1 and 2, the collector resistance of which is subdivided into two series resistors 3, 4 and 5, 6 , the resistance values of resistors 3 and 5 being greater than those of resistors 4 and 6 are. The base of the transistor 1 is connected via a capacitor 7 to a connection point 8 of the two resistors 5, 6 and the base of the transistor 2 is connected via a capacitor 9 to a connection point 10 of the two resistors 3, 4. The emitters of the two transistors 1 and 2 are connected to ground 11. The transistor 1 has a coupling resistor 12 connected between its base and its collector, and the transistor 2 has a coupling resistor 13 connected directly in parallel between its base and its collector. These two coupling resistors 12 and 13 each form a parallel negative feedback for the transistors 1 and 2 associated with them. The output of the multivibrator is formed by a terminal 14. To operate the multivibrator, a DC voltage source is connected to terminals 11 and 15. As a result, the transistors 1 and 2 become conductive and, if the two coupling resistors 12 and 13 are correctly dimensioned, begin to oscillate as a result of the positive feedback.

The effect of the parallel negative feedback is as follows: Due to the parallel negative feedback caused by the coupling resistors 12 and 13 , neither of the two transistors 1 and 2 can come into saturation. B. of the transistor 1, the connection point 16 between the collector of the transistor 1 and the resistor 3 becomes more positive when the transistor 1 would come into the saturation region. This has the consequence that the base current becomes smaller and makes the transistor 1 less conductive. The parallel negative feedback also ensures that the spread of the current amplifier factor xe cannot have a disadvantageous effect on the multivibrator. The current gain is therefore stabilized by the negative feedback, and the ratio of the collector current change dI,: I, is not directly proportional to the ratio of the change in the current amplifier factor dae: Xe, but in the ratio 1 1 R, + ae R, + RI) dI, smaller. is therefore where R, the resistance of the series connection of the resistors 3 and 4, Rb the resistor 12 and Ic the collector current of the transistor 1 means.

It is noteworthy in the multivibrator circuit described that the base-collector voltage when the transistor is blocked, for. B. transistor 2, is lower than in the known circuits. In the latter, in which the transistors operate in the saturation range, the base-collector voltage is equal to the voltage Ub of the DC voltage source and the capacitor voltage of the capacitor 7 or 9. Since the capacitor voltage corresponds almost to the voltage Ub, the base-collector voltage is Voltage equal to 2 Ub. According to the present circuit, in which the transistors 1 and 2 do not work in the saturation range, the collector-emitter voltage of the conductive transistor, in this case the transistor 1, counteracts the capacitor voltage of the capacitor 9 , so that the base-collector voltage Voltage corresponds to the value of the battery voltage Ub plus the capacitor voltage of the capacitor 9 minus the collector-emitter voltage of the transistor 1 . This increases the operational safety of this astable multivibrator. Another feature of this astable MultMbmW circuit is the subdivision of the collector resistance associated with each transistor 1 and 2 into at least two resistors 3, 4 and 5, 6 . When the values of the resistors 3 and 5 are measured in relation to the resistors 4 and 6 , a very short time constant is achieved by the resistors 4 and 6 and the capacitors 7 and 9 , so that the output pulses have a pronounced rectangular shape with a steep gradient over the entire frequency range Have rear flank.

The mode of operation is as follows: If the transistor 1 becomes conductive, the capacitor 9 discharges to a voltage which corresponds to the battery voltage Ub minus the product of collector current I times the partial collector resistance of resistor 5 , i.e. Ub - I, - R4, where R4 is identical to resistor 4. At the beginning of this discharge, the reverse voltage between the base and the emitter Ub of the transistor 2 is equal to U, - (Ub + I, -R4), where U, corresponds to the discharge voltage on the capacitor 9 , which is very low. After the tilting process, after the transistor 2 is conductive and the transistor 1 is blocked, the capacitor 9 is only recharged up to the level of the battery voltage Ub, so that the charging current also remains small. As a result, the base-collector voltage Ut of the respective blocked transistor has only approximately the same size as the battery voltage Ut "since the blocking voltage Ub, is equal to the difference U, - (Ub + I, - R,) The lower base current as well as the lower base-collector voltage Ub and the lower reverse voltage Ub result in a significantly higher level of operational reliability.

A further improvement of the pulse shape, in particular the slope, is achieved in that, as the circuit in FIG. 2 shows, in which the same reference numerals as in FIG. 1 have been used for the same parts, instead of the two resistors 4 and 6 in each case a diode 17 or 18 is used because, due to the non-linearity that exists between the current and voltage curve in diodes, their forward resistance is smaller than for an ohmic resistance. Due to the resulting decrease in resistance, the time constant, which is essentially decisive for the steepness of the edge of the pulses, is correspondingly smaller. Since, as has just been explained, the operating voltage is lower when using diodes than when using ohmic resistors, the battery voltage itself can also be lower than with a normal multivibrator circuit.

It is also advantageous that the multivibrator when the DC voltage is switched on begins to oscillate independently because the transistors work outside of it of the saturation range can practically not be overdriven statically.

Claims (1)

Claim: Astable multivibrator circuit with transistors, characterized in that a coupling resistor (12 or 13) is connected directly in parallel to each of the two transistors (1 and 2) between its base and its collector and that the collector resistance of each transistor (1 and 2) is connected at least two circuit elements lying in series, which consist of two ohmic resistors (3, 4 or 5, 6) or of one ohmic resistor and a diode (17 or 18) , at their connection point (8 or 10) each a feedback line leading via a capacitor (7 or 9) to the base of the other of the two transistors (1 and 2) is connected.