DE1275602B - Electronic frequency divider with an astable multivibrator in the output circuit and a capacitor connected to the multivibrator as the source of a reference voltage that determines the output frequency - Google Patents

Description

Electronic frequency divider with astable multivibrator in the output circuit and a capacitor connected to the multivibrator as a source of a die Reference voltage determining output frequency The invention relates to an electronic Frequency divider with astable multivibrator as a generator of the output frequency, as well with a capacitor connected to the multivibrator as the source of a die Output frequency determining reference voltage and with a to the source of the input frequency connected and fed back to the multivibrator phase comparator whose Output is connected to the capacitor and the state of charge of the capacitor determined depending on the phase position of the input to the output frequency. The term "Frequency divider" should also include the term "frequency multiplier" as both terms only express opposite tasks bring that with the help of facilities built according to the same construction principles can be solved.

A frequency multiplier of the type mentioned above has already become known (U.S. Patent 2,824,229). This known frequency multiplier has the disadvantage that its frequency comparator is relatively complex and not for comparing the frequencies of sinusoidal waves with those of binary pulses suitable and that the entire circuit could by no means be integrated, even if the electron tubes were replaced by semiconductor elements.

It has also already been proposed (German interpretation 1246 031), a flip-flop as a frequency divider with a division ratio greater to be used as 2 and with this flip-flop the relative bandwidth of the division ratio by additional voltage dividers provided for the DC coupling provide decoupled resistors. The decoupled resistors should be as proposed the correct function of the RC elements stabilize the phase length of the output frequency and at the same time help determine the frequency division ratio.

Quite apart from the fact that the proposed frequency divider circuit would consume a lot of energy, it also has the disadvantage that the operating voltage must be kept very constant for the circuit, because the operating voltage next to the dimensioning of the RC elements has a decisive influence on the output frequency. Finally, there is an additional disadvantage of the proposed frequency divider circuit in that this is likely to be reliable only with low division ratios works and at constant input frequency and high frequency division ratio would produce an entire frequency band at the output. The present invention lies in contrast, the task underlying to overcome the disadvantages mentioned and a to create a frequency divider that can be integrated in the smallest of spaces, which is particularly important for works reliably with low energy consumption.

Based on the circuit of the known frequency multiplier with bistable multivibrator as a generator of the output frequency, also with an on The capacitor connected to the multivibrator as a source of the output frequency determining reference voltage and with a connected to the source of the input frequency and phase comparator fed back to the multivibrator, the output of which corresponds to the Capacitor is connected and the state of charge of the capacitor depends The solution is determined by the phase position of the input frequency and the output frequency the task according to the invention in a triode, preferably a transistor in the phase comparator, its input to the output of the multivibrator and its output to the source the input frequency on the one hand and with the mentioned capacitor on the other hand in Connection. At the input of this triode of the phase comparator can be in the frame the invention an RC element in which the input signal to the triode time-limiting Circuit are located.

A multivibrator has also become known, which is known as the Oscillator is intended to generate square-wave oscillations in particular. With this well-known Multivibrator a transistor is provided, the one at the exit of the multivibrator is connected and a reference voltage on a capacitor controls. The reference voltage is intended to balance the amplitudes of the produce mutually opposite signals of the multivibrator, so that the known Circuit for generating low frequencies is suitable.

The transistor mentioned does not belong to the known circuit a phase comparator and there is no coupling between this transistor and an input frequency. The known circuit is therefore not suitable as Frequency divider or frequency multiplier.

Further details of the invention are given below with the aid of Drawings of exemplary embodiments explained in more detail. In the drawings represents FIG. 1 shows a schematic diagram of the circuit, FIG. 2 is a diagram showing the Functioning of the in F i g. 1 explains the circuit shown, and FIG. 3 to 6 four different exemplary embodiments in detail.

The in F i g. 1 has an astable multivibrator M, which supplies a periodic signal u2. The frequency of this signal is F2 adjustable with the aid of a control voltage u, stored in a capacitor C.

An electronic switch I, which in each period of the signal u2 is closed for a short period of time, which connects the internal resistance R1 having the source of the periodic input signal u1, which has the frequency F1, to the terminals of capacitor C. This causes the latter to have a voltage u3 is loaded, which is dependent on the relative phase of the signals u1 and u2. In other words, the voltage u3 at equilibrium is equal to the value of ui at the times when the signal u2 passes through a precisely defined phase, in the one shown in FIG. 2 case at the times when the multivibrator from one state to the other. The middle part in FIG. 2 gives the position of switch 1. At 0 the switch is open, at F it is closed. In the three parts of FIG. 2 t denotes the time axis.

With suitable dimensioning it is possible to set the output frequency F2 to be coupled to a sub-multiple of the input frequency F1. The two frequencies remain coupled within certain limits when the frequency F1 changes slowly will. Indeed, changing F1 changes the relative phases of the signals ui and u2, i.e. a change in the control signal u2. This signal works to the frequency F2 of the signal u2, so that F2 follows the changes in F1.

In the case of FIG. 2 is the ratio n of the frequencies F:, / F2 three.

The circuit allows ratios of several hundred to be achieved.

F i g. 3 shows the detailed diagram of a first embodiment.

The multivibrator Ma has two transistors T "" T3, of the NPN type, the base of one transistor being connected to the collector of the second transistor via a capacitor 1a and the base of the second transistor being connected to the collector of the first transistor via a capacitor 2a is. The emitters of the two transistors are connected to the minus pole of a voltage source, while the collectors are connected to the positive voltage source via resistors 3 a and 4 a.

From the theory of the multivibrator it is known that its frequency can be changed by changing the voltage u3 a.

The switch I a has a transistor T1 a of the PNP type, the base of which is connected to a circuit Rda-Cda, which allows current pulses to be obtained at the base of T1 a which are derived from those at the collector of T ", The source of the input signal ui a is connected to one terminal of the capacitor Ca and the collector of T1 a, the other terminal of the capacitor Ca and the emitter of T1 a are connected to the positive pole of the voltage source mentioned.

The circuit works as follows: The multivibrator Ma generates square-wave pulses, the repetition frequencies of which are dependent on the voltage u ". The circuit Cda-Rda supplies a short current pulse to the base of the transistor T1 a, which for this reason becomes conductive and the source of the Input signal ui a connects to the terminals of the capacitor Ca , which is charged to a voltage u., Which tends towards the instantaneous value of u1 a at the moment of the impulse. This voltage u ", which is stored until the next differentiated impulse appears fed to the connection point of the resistors at the base of the transistors T2 a and T3 a and in this way controls the frequency of the multivibrator.

In the following exemplary embodiments, the same elements as in FIG. 3 to abbreviate the description have the same reference numerals, but instead of the index “a” the index “b” for F i g. 4, the index "c" for F i g. 5 and "d" for F i g. 6th

The in F i g. 4 differs from that described above in that it only has transistors of the same type NPN. For this reason, a reverse circuit I v is provided which has a transistor T ¢ b and two resistors 7 b and 8 b and which is connected between the multivibrator Mb and the differentiating element Cdb-Rdb of the switch I b, the collector of the transistor T1 b is fed through a diode 10 b. The source of the input signal ui b is connected to the minus pole of the supply source, which forms the earth, and the connecting capacitor 9 b. Regardless of the use of transistors of the same type, this embodiment has the advantage that a source of the input signal u1 b can be used, one pole of which is connected to ground.

In the embodiment according to FIG. 5 were in the multivibrator Mc two resistors 11 c and 12 c and two diodes 13 c and 14 c connected to his Stabilize frequency against changes in supply voltage or temperature.

The modifications shown make it possible to save the reversing transistor T4 b of FIG. 4. On the other hand, the terminal voltage of the capacitor Cc is fed to the multivibrator by means of an additional transistor T. This allows a source of ui C with a high internal resistance and a small capacitance Cc to be used.

A fourth embodiment is shown in FIG. 6 shown. The circuit in the base of the reversing transistor T $ d has been improved, so that a signal with an even steeper positive edge at the collector and thus a more precise measure is obtained, as is required for a high input frequency. This improvement consists in that there is provided in said base, a parallel circuit of a resistor 7d, a diode 15 and a capacitor 16 d d.

The use of a common output amplifier stage d T5 equipped with an increased internal resistance R1 of the source to operate d u1 and d with a small capacity 9 d, with the advantage over the circuit of F i g. 5 that the mean level of the control signal us d is not lowered, which is very important if the circuit has to work with a low supply voltage. This simultaneously compensates for the effects of temperature and supply voltage fluctuations.

The collector of the transistor T1 d is fed by means of a voltage divider 17 d, 18 d, that of the transistor T5 d by means of two resistors 19 d and 20 d.

Claims (7)

Claims: 1. Electronic frequency divider with an astable multivibrator as the generator of the output frequency, also with a capacitor connected to the multivibrator as the source of a reference voltage determining the output frequency and with a phase comparator connected to the source of the input frequency and fed back to the multivibrator, the output of which with the capacitor is in connection and determines the state of charge of the capacitor depending on the phase position of the input frequency to the output frequency, characterized by a triode, preferably a transistor (TA) in the phase comparator (1), whose input is connected to the output of the multivibrator (M) and whose Output is connected to the source of the input frequency (u1) on the one hand and to said capacitor on the other hand. 2. Frequency divider according to claim 1, characterized by an RC element (Cd, Rd) at the input of the triode of the phase comparator in which the input signal to the triode time-limiting circuit. 3. Frequency divider according to claim 1 or 2, characterized by a diode (10 b) between the current source and the one output pole of the triode (T1 b) of the phase comparator (FIG. 4). 4. Frequency divider according to one of the claims 1 to 3, characterized by a phase converter (I vb) between the output of the multivibrator and input of the phase comparator (Fig. 4). 5. Frequency divider according to one of the claims 1 to 4, characterized in that said capacitor (Cc) is connected to the input a voltage modulating triode, preferably a transistor (T "), connected whose output is connected to the input of the multivibrator (F i g. 5 and 6). 6. Frequency divider according to one of claims 1 to 5, characterized by Diodes (13 c, 14 c) in the feedback of the triodes (T ", T") of the multivibrator and by a special coupling of the inputs of these triodes of the multivibrator to a DC voltage source via resistors (11 c, 12 c in FIG. 5). 7. Frequency divider according to one of claims 1 to 6, characterized by a resistor (7 d), a Diode (15d) and a capacitor (16d) connected in parallel between the output of the multivibrator and the input of the phase comparator (FIG. 6). Into consideration Extracted publications: German Auslegeschrift No. 1246 031; U.S. Patent No. 2,997,665.