DE1151875B - Circuit arrangement for converting a frequency into a direct current proportional to it - Google Patents

Description

Circuit arrangement for converting a frequency into a direct current proportional to it. The application of the pulse frequency method to telemetry technology entails the task of converting a low frequency (1 to 20 Hz), which represents the measured value transmitted, into a proportional direct current in the telemetry receiver. This is measured with a moving-coil instrument or recorded with a moving-coil recorder. A number of methods of frequency measurement which are applied to telemetry receivers of the above type are already known. For the most part, they are based on either a capacitor being recharged or an inductance being remagnetized in the rhythm of the frequency.

In the capacitor charging process, impulses with the surface are created T is the period, C is a constant, U is the voltage after charging, U is the voltage before charging and Q is the amount of charge. After rectification, the desired direct current is obtained Correspondingly, with the magnetization reversal process, pulses with the area are obtained (w = number of turns; 0, = saturation flux).

Furthermore, the current is obtained after rectification (R, is a fixed resistor).

It was assumed that the respective pulse had died down before the next one began. These two methods have the following disadvantages with regard to their use in telemetry devices: 1. In both methods, the energy of the impulses is usually not sufficient to control a recording instrument directly. One is therefore forced to use measuring amplifiers.

2. The current i. high alternating amplitudes of lower frequencies are superimposed, which in ordinary measuring mechanisms cause the pointer to tremble. That's why sieve means must be used, which bring further disadvantages, z. B. increased response time.

3. In the capacitor charging process, the current 1. is within certain limits independent of the resistance R of the measuring loop, but (U, - U,) must be constant, which usually requires special stabilization measures.

On the other hand, the latter is not necessary in the magnetization reversal process, if the inductance used has a core with a magnetization curve that is as rectangular as possible owns. However, this method has the disadvantage that the current i. of the resistance R in the measuring loop is dependent.

The invention avoids all of the stated disadvantages of the processes mentioned. It relates to a circuit arrangement, in particular for Femmeß receivers, for conversion a frequency into a direct current proportional to it, at which the voltage trains with the frequency to be measured after possible amplification a differential transformer are fed. According to the invention, the output pulses bring of Differentiating transformer a bistable transistor circuit for flipping, the emerging Square wave voltage controls a saturation transformer from a saturation induction to the other, and the square pulses emanating from the saturation transformer apply a constant voltage-time area after rectification to a counter-magnetized Compensation transformer, in which there is a difference between the rectified Output voltage of the saturation transformer and the counter voltage of the compensation transformer a frequency proportional DC voltage results, which is used to control an amplifier serves whose output current the counter magnetization of the compensation transformer and thus displayed as an impressed, frequency-proportional direct current can be.

A frequency meter has already become known, its input pulses can also be converted into pulses with a constant voltage-time area, however This frequency meter differs quite considerably from the subject of the present one Invention-. The frequency meter circuit has a transistor stage with positive Feedback made possible by a feedback transformer. As soon a pulse of suitable polarity arrives, the currents in the transformer increase and the transistor to saturation. The collector-emitter voltage of the transistor drops to approximately zero. The circuit arrangement remains in this state, until a new impulse arrives. The measured mean collector current is the input frequency of the pulses proportional, because the voltage-time area of the output pulses is constant Supply voltage is also constant. For modulating the frequency meter impulses with a steep rise are required. With such an arrangement can it is preferable to measure the frequency of sawtooth generators.

Furthermore, frequency meter circuits are made using a transistor stage and a feedback transformer became known after the so-called Capacitor charging method work. These circuits require special screening means in the starting circle and, in contrast to the subject of the invention, are for low frequencies not suitable. In addition, the display depends on the operating voltage of the device.

The invention is illustrated using an exemplary embodiment with drawings explained.

Fig. 1 shows the principle of the circuit arrangement, in Fig. 2 pulse trains are shown; FIG. 3 shows the equivalent circuit diagram and FIG. 4 shows a magnetization curve.

According to FIG. 1 , the demodulated signal is fed to the input terminals 1 and 2 and amplified with the aid of the transistor T 1. In the differentiating transformer DU , short pulses are formed therefrom in each zero crossing, as shown in FIGS. 2a and 2b . The two pulse series are offset from one another by half a period. These pulses cause the bistable circuit of the two transistors T, and T, to tilt. With G, and G ', rectifiers are designated, which determine the direction of passage of the pulses. The bistable transistor flip-flop circuit also includes the resistors R, R, R, and R, Z denotes a Zener diode which is used to generate a bias voltage. U "and Ub are the pulse voltages which cause the transistor circuit to flip. The output currents of the transistor flip-flop are fed to the primary winding W of the saturation transformer SU via the resistors R and R. The course of the primary flow in the saturation transformer is shown in FIG. 2c The saturation transformer has two secondary windings W2 and W, which are followed by the rectifier arrangements G, and G. The secondary windings of the saturation transformer feed the windings W, and W, a counter-magnetized compensation transformer K. With R, is a coupling resistance between the windings W2 and W. The resistor R "is used in conjunction with the capacitor C to prevent self-excitation of the circuit. The winding W, of the compensation transformer is in series with the resistance of the measuring loop R ″, the display instrument A and a transistor T, UB is the operating voltage of the circuit. The saturation transformer SU is designed in such a way that rectangular pulses of a defined area are created (see Fig. 2d), which are all positive as a result of the rectification. At the output of the rectifier arrangement G, there is the pulse voltage U, 1, the direction of which is shown by the arrow. Fig. 2e). The difference between these two voltages is denoted by Uf (Fig. 2f). This voltage controls the transistor T i. It can be seen from FIGS. 2d, 2e and 2f that the difference between the voltages Uj and U is a direct voltage Uf. The secondary pulses of the saturation transformer are translated in the compensation transformer K so that the diflerence between the voltage of the saturation transformer rectified with the help of G and G and the voltage of the compensation transformer results in a frequency proportional DC voltage. Since this DC voltage modulates the transistor T4, the output current IA »of the amplifier is also proportional to the frequency. This current flows through both the counter magnetization winding W of the transformer and the display instrument A.

In summary, it can be said that the primary winding of the saturation transformer is connected to the operating voltage UB with alternating polarity due to the bistable multivibrator. When loaded with an ohmic resistor, the equivalent circuit diagram shown in FIG. 3 can be used, which serves to better illustrate the individual processes. The contact in the equivalent circuit corresponds to the transistor flip-flop that applies the operating voltage UB to the circuit. The current! L in the inductance4: t L is determined by According to the law of induction, the following applies to the function t = t (B): 0 is the flux, FE is the iron cross-section and B is the induction.

For the function u = u (H) , according to the law of flow, the following applies: The induction B is a function of the field strength H. This parameter representation for t and u means that the magnetization characteristic is mapped approximately proportionally during the switch-on process. In order to obtain rectangular pulses at the output, a material with a rectangular magnetization characteristic is used for both the saturation transformer and the compensation transformer. The magnetization characteristic shown in FIG. 4 is traversed between points 1 and 2 . The area of the resulting voltage pulse can be seen from FIG. 2d. This voltage pulse results in a flux change A 0 in the counter-magnetized compensation transformer, which occurs when the curve is traversed from point 3 to point 4. It is It is assumed that the winding g W of the compensation transformer is not loaded and that the counter magnetizing current IK is impressed. This change in flux J, 0 is reversed again during the pulse gap by the counter magnetizing current IK if this is the size C Has. After inserting equation (7), we get This expression corresponds to equation (4), although it should be noted that IK is free from AC components and R is a defined coupling resistance. The resistance of the measuring loop (R ") does not appear in the equation. It can therefore be varied within certain limits without changing the counter magnetizing current IK can be chosen large so that any type of displaying or writing DC current meters can be operated.

Claims (1)

PATENT CLAIM: Circuit arrangement, in particular for telemetry receivers, for converting a frequency into a direct current proportional to it, in which the voltage trains with the frequency to be measured are fed to a differential transformer (DU) after any amplification (T,), characterized in that the output pulses of the differential transformer a bistable transistor circuit (T " T.) to tilt, that the resulting square wave voltage controls a saturation transformer (SU) from one saturation induction to the other and that the square pulses emanating from the saturation transformer with a constant voltage-time area after rectification (G, G,) a counter-magnetized compensation transformer (K), in which the difference between the rectified output voltage of the saturation transformer (U, 1) and the counter voltage of the compensation transformer (U,) results in a frequency-proportional direct voltage (Uf), which is used to control an amplifier kers (T,) whose output current (IK) causes the counter-magnetization of the compensation transformer and can thus be displayed as an impressed, frequency-proportional direct current . Documents considered: French Patent No. 1 181981.