DE1516266A1 - Circuit arrangement for a frequency-current converter, in particular receiver circuit for remote pulse frequency measurement - Google Patents

Description

Circuit arrangement for a frequency-current converter, in particular Receiver circuit for remote pulse frequency measurement.

The invention relates to a circuit arrangement for a frequency-current converter with a circuit part which, controlled by the frequency to be converted, generates pulses constant amplitude-time area generated. These impulses are also given in the following referred to as normalized impulses. The circuit arrangement also includes FIG as is known, a measuring instrument used to measure the arithmetic mean the series of standardized pulses capacitors are connected.

In particular, but not exclusively, one Receiver circuit intended for remote pulse frequency measurement.

Known circuit arrangements of this type are, for example, in the archive for technical measuring, V 3844-2, delivery 317, described in detail, so that # its structure need only be discussed here alone.

In the circuits, the pulse sequence to be converted is first converted into a ole converted normalized impulses, i.e. a sequence of impulses whose voltage-time area or their current-time area has a constant value. A circuit part is used for this purpose, for example, a capacitor charging circuit with relays or transistors, one monostable multivibrator or a saturation-controlled converter with square hysteresis can contain and is controlled in such a way by the pulses to be converted, because # he at each zero crossing of these pulses or at each. Peak value of the same emits a normalized pulse. In the case of the known form-T arrangements, these are normalized impulses are then fed directly to the measuring insturment for the purpose of recording of the arithmetic mean value of the sequence of normalized pulses, which is directly a Represents the measure of the frequency and thus the measured value, interconnected with t capacitors is. Usually there is a capacitor in parallel with the input terminals of the measuring instrument.

It has now been shown that on the one hand the normalized impulses are burden-dependent and that, on the other hand, the desired conversion of the impulses into a current as a result the effect of the capacitor lying parallel to the instrument with a linearity error is afflicted. In particular when using the circuit arrangement as part of a Fernme # receiver, these disadvantages are particularly serious since one often uses the Wants to connect the instrument via a long-distance line and, if necessary, there is a wish to to feed multiple instruments.

The invention is based on the object of a circuit arrangement of the type described and provide that the stated disadvantages of known arrangements does not have, This task is solved by a circuit arrangement not having the identifier cta :: e-; nc ',;, iigeg, er, ;;, das., -. ,,,, -,. ,, rt "" Ct' ir Kre ".e e" njr an additional DC voltage source containing transistor circuit is, which, controlled by G the standardized impulses, drives an impressed current through the Me @ instrument.

Badurch, who practically used the transistors as current sources for the Me # instrument is a retroactive effect of the respective load resistance the generation of the standardized pulses is excluded. So it is also possible to have a Me # instrument or several, if necessary, to be connected via longer long-distance lines. The limit for this 35, rde is only in the resilience of the additional Voltage source. for the same reason, the one lying parallel to the measuring instrument has Capacitor has no influence on the characteristics of the frequency-current converter, i.e. the linearity of the implementation is not adversely affected by it.

The preferred embodiment of the invention is characterized by this off, because # the transistor circuit is a bridge circuit, --an, cteren one Diagonal the additional direct voltage and in the other diagonal the measuring instrument lies, through which two complementary transistors lying in adjacent bridge branches, one of which is from the normalized impulses and the other from a constant one DC voltage is controlled, driving two applied currents; the one of these two Currents is linearly proportional to the fresuence of the normalized pulses, during the Other than compensation current, the display of the pulse frequency assigned to the value zero prevents. This embodiment of the invention also solves the problem of compensation the pulse frequency that was already valued at the Me # Zero occurs and otherwise cause an undesired display of the Me # instrument would. The transistors are conveniently located with their emitter-collector-S stretch in the bridge branches and the normalized impulses are the basis of one Transistor, i.e. the B of that transistor which corresponds to the frequency of the normalized impulses drives linear proportional current through the measuring instrument. Of the resulting current through the measuring instrument, de4 also causes the display of the same, is therefore equal to the difference between the frequency-proportional current and the means of the other transistor generated constant compensation current.

The base of the other transistor is in the case of the last one described Embodiment of the circuit arrangement according to the invention expediently with connected to a voltage divider fed with the additional DC voltage, which contains at least one Zener diode. : This zener diode is used to keep it constant the base-emitter voltage of the other transistor and thus determining its Operating point, so the compensation current also assumes a constant value. At least one diode can be connected in series with the Zener diode, to compensate for the Temperature response of the Zener diode taking into account the temperature range of the base-emitter voltage serves the other transistor.

The emitter circuits of the transistors are used to balance the bridge Provide resistances. 3in advantage of the circuit arrangement according to the invention in its preferred embodiment as a bridge circuit is in the simple option the adjustment of the same can be seen by changing the named emitter resistances can be done.

Understandably, multistage transistors can also be used instead of individual transistors Transistor circuits should be provided.

Figures 1 and 3 show embodiments of the preferred embodiment of the circuit arrangement according to the invention, while FIG arithmetic mean value reproduces essential quantities of the normalized impulses. The input E of the bridge circuit shown in FIG. 1 is standardized Pulses supplied, in a not shown in the figure, from the to be converted Pulse-controlled circuit part are generated. Contains this circuit part one monostable multivibrator or a saturation converter, this is how the standardized pulses have Rectangular shape (Curvea.) Be. Capacitor discharge you have specified be b,) Over time. The base-emitter circuit forms the input circuit of the bridge arrangement of the transistor T 1. 1. In the adjacent branch of the bridge, on one diagonal the additional direct voltage UB and its other diagonal the measuring instrument M with the capacitor connected in parallel, the other transistor is located T 2.

It can be seen that # the two transistors are of the complementary conductivity type are. During the first transistor T1 (npn) immediately from the normalized pulses is controlled, the base precaution for the other transistor T2 (pnp) is off the constant DC voltage U3 by means of the resistors R4 and R5 as well as the Zener diode D1 for stabilization and the voltage divider containing normal diode 02 won. It is therefore a matter of a highly constant 2asis preload, which in the essentially has the value Uz, the voltage drop across the diode D2 increases.

The brackets are supplemented by the resistors R3 and R which are also direct can be replaced by voltage sources, such as the voltage sources U1 and U2 do in the embodiment of FIG.

The transistor T1 has a practical effect with its emitter-collector path as a power source and drives the impressed S-current T1 through the measuring instrument M with the parallel connected capacitor 0. This current I1 is linearly proportional the frequency of the base of the transistor! Normalized pulses fed to T1. In contrast to this, the other transistor T2 drives a constant current I2 by the Me @ instrument, which as a result of a suitable choice of the working point of the other Transistor i is so big. there, the dei measurement value zero blunted reauence of the impulses just compensated, i.e. a display with a measured value of zero is prevented.

If I1 is the arithmetic mean value of the collector current of the transistor T1 and the current gain of the transistors is sufficiently large, it can be shown that, taking into account the values shown in FIGS. 1 and 2, the value I1 follows the following relationships (2j la, For the mean value I2 of the collector current of the other transistor T2, which is identical to the duration value, (4) I2 = UZ / R2 er, denoted by 1D in FIG. 1, of the measuring instrument 7; The diagonal current flowing through the bridge results from the difference between the two current values I1 and I2 to (5) ID = I1 - I2 (6) ID = 2f / R1 (Ui ## i - UBE1 ## i) - UZ / R2 The diagonal current ID is thus made up of two parts, the first of which contains the bracket.

Part directly proportional to the frequency of the impulses to be converted is. The first product in brackets is nothing other than the stress-time area of a normalized pulse, as can be seen in FIG. 2. The second part of the current value ID is the compensation component, i.e. the current component that is used to generate a To prevent display when the measured value is zero.

Fig. 3 shows a complete implementation of a remote control receiver Use of the circuit arrangement according to the invention. In this embodiment it is assumed that # the pulses to be converted via the transformer Tr and the Circuit arrangement U that converts the pulse to actuate a bistable multivibrator suitable short pulses unformed, the bistable containing the transistors I and II Toggle switch supplied. will. The construction of a detailed bistable trigger circuit is known per se, so that the individual circuit elements are not discussed needs to become. The bistable multivibrator works on the saturation converter SW, which has as rectangular a hysteresis loop as possible, in its titigungsgebiet is operated and at its terminals a and b in the lower left part of Fig. 3 reproduced pulses emits. These pulses provide ntch rectification by means of The rectifier arrangement 1 represents the normalized pulses that of the invention Bridge circuit are supplied. This bridge circuit contains again as in Embodiment of FIG. 1 transistors T1 and T2, which are in adjacent bridge branches lie. In this embodiment it is assumed that instead of a single Transistor T1 two transistors T1 and T1 are used, which e in Darlington-scarf tion summarized are to achieve a greater current gain. In the diagonal of the bridge circuit lies the measuring instrument M, which as a result parallel connection of the Kendensators CL, the arithmetic mean of the described in Wise composite differential current s ID brings to the display.

While in accordance with the circuit arrangement according to FIG 1 again emitter resistors? 1 and t2 are provided for simple bridge balancing sInd, the bridge resistors R3 and R4 according to the embodiment of Fig. 1 replaced by two voltage sources U1 and U2.

The base bias and thus the operating point of the other transistor T2, which is used to compensate for the frequency when the measurement value is zero, is switched off via the the resistor R5 on the one hand, the Zener diode D1 and the ordinary diodes D2 and D2 'on the other hand determined voltage divider formed. it Z is a Zener diode, to stabilize the total voltage of the voltage source U1 in parallel is connected to the voltage divider described.

When using the circuit arrangement according to the invention, it is possible in the DiZcnalweI0 the rce any length of trunk line and any number of consumers to provide; a limit is only given by the resilience of the given additional DC voltage source. Also the formation of sums and differences Due to the interconnection of several converters of this type on the output side, there is an additional error possible, 7 claims 3 figures

Claims (1)

P a t e n t a n s p r ü c h e 1. Circuit arrangement for a frequency-current converter with a circuit part which, controlled by the frequency to be converted, impulses constant amplitude-time-area (normalized impulses) generated, as well as a measuring instrument, to measure the arithmetic mean: the pole standardized impulses capacitors are switched on, in particular receiver circuit for. remote pulse frequency measurement, characterized in that the measuring instrument is connected to an additional DC voltage source containing transistor circuit, which, controlled by the normalized pulses, drives an impressed current through the measuring instrument. 2. Circuit arrangement according to claim 1, characterized in that the transistor circuit is a bridge circuit, on one diagonal of which the additional equal voltage and in whose other diagonal the measuring instrument lies, due to the two complementary transistors in adjacent bridge branches, of which the one from the normalized impulses and the cattle from a constant DC voltage is controlled, drive two impressed currents, from which de is linearly proportional to the frequency of the normalized pulses and the other than the compensation current, the display of the pulse frequency assigned to the Ke value zero prevents. 5. Circuit arrangement according to claim 2, characterized in that the transistors flit their emitter-collector paths in the bridge branches and the normalized pulses are fed to the base of the one transistor. 4. Circuit arrangement according to claim 3, characterized in that # the base of the other transistor with one with the additional DC voltage fed voltage divider is connected, which contains at least one Zener diode, 5. Circuit arrangement according to claim 4, characterized in that; 3. in series with the Zener diode has at least one ordinary diode to compensate for the temperature variation is switched. 6. Circuit arrangement according to one of claims 1 to a, characterized in that that the emitter circuits of the transistors contain resistors for bridge balancing. 7. Circuit arrangement according to one of claims 1 to 6, characterized in that that instead of individual transistors, multi-stage transistor circuits are provided are..