DE2135802B2 - Voltage controlled relaxation oscillator - has integrator and comparator both switchable to one of two ref. volts - Google Patents

Abstract

The voltage controlled relaxation oscillator consists of an integrator coupled by its inputs to a reference and by its output to the input of a comparator whose output drives an electronic changeover switch. The switch applies one of two voltages to the input of the integrator. The comparator (K) has only two inputs one connected to the integrator and the other, the reference input, to a second switch output. The second switch (S2) switches one of two voltages to the comparator and is synchronised with the first switch (S1) at the integrator (V1) input. The advantage lies in high precision whilst allowing the use of relatively cheap components.

Description

55

The invention relates to a relaxation oscillator with one or more external voltages controllable • Frequency, consisting of an integrator with an input and a reference input and a Kompaoreinrichtung whose input is connected to the output of the egrator and whose output controls a ctronic switch that controls the input 5 integrator each one of two voltages <> s ^r ührt.

In frequency-analog measuring systems, in which there is a need for interference immunity and simple digitization availability instead of the amplitude of an electrical quantity whose frequency or period length carries the measurement information, are used to transform a voltage or of a current into a frequency, especially special relaxation oscillators are used as transducers. In relaxation oscillators, the Parameters of active elements (e.g. threshold switches) have a significant influence on the oscillation frequency. The inconsistency of these parameters (e.g. temperature drift Aging) requires complex measures (thermostats, compensation circuits) if high precision of the deformation characteristic is desired.

There are already circuit arrangements for relaxation oscillators known with which at low SchaltungsaufwaiKi these undesirable influences in can be eliminated to a large extent. However, they are limited to impedance-controlled oscillators.

Relaxation oscillators with a voltage controllable frequency are already known (FR-PS 15 27 133 or FR-PS 15 86 096), where the input of the integrator via an internal switch made of transistors or field effect transistors alternately to one of two voltages is placed. These switches are controlled by a comparator device for the upper and the The lower end point of the triangular voltage each contains a comparator, however, it is not practical possible or very expensive to build two completely identical comparators, but they will always be in the gain or especially in the offset, also depending on temperature and aging differentiate. This causes a shift of the endpoints of the triangular voltage to each other and thus a change in frequency. With the known circuits it is not possible to always do one to generate reproducible conversion of voltage into frequency.

The aim of the present invention is to improve the controllability of the frequency or the period duration by means of a c_ _.._ "". <". ": _ _Nn c." ~. - .. ".- ,; ~ i ~~" u ".. y ~ n j:"

t? paU ": Ullg UUl-I%" Itl ", ll auuitl *." viuvibil, v, "t,%, www \ At \.

additional required functional elements due to their non-ideal properties Cause errors. The aim is to achieve high-precision, environmentally independent voltage or current-controllable measuring oscillators with extensive use of conventional, inexpensive components and with the use of integrated and hybrid technologies.

This is achieved in a relaxation oscillator according to the invention in that the comparator device has a comparator with one input and only contains a reference input that is activated both when the The voltage at the input changes its output state compared to the voltage at the reference input, and that the reference input of the comparator has a parallel with the switch in front of the input of the integrator controlled changeover switch is connected upstream, which this reset input each one of two voltages feeds.

Embodiments of the invention are explained with reference to the drawing. It shows

F i g. 1 the basic circuit diagram on which the invention is based,

Fig. 2 the associated voltage-time diagram,

F i g. 3 and 4 more detailed circuit diagrams of a relaxation oscillator,

F i g. 5 the application in a bridge circuit.

l ±

The relaxation oscillator in FIG. 1 consists of an integrator, which is formed by a wired with input resistance R, and feedback capacitor C operational amplifier Vi, and a comparator E The input of the integrator with a switch Si between the two voltage sources U \ and LV switch The output voltage Ui of the integrator is the Comparator device supplied, which contains a comparator K with ^ inem input unä only one reference input A ι ο such a comparator is z. B. also represented by an operational amplifier, which may be followed by a Schmitt trigger to steepen the edges of the output voltage or which can be given such properties th through appropriate sound reinforcement. The reference input is switched with a second switch Si between the voltage sources Lh and Lh '. The two switches each form a double-ended switch which is controlled by the output signal of the comparator device £.

This circuit only works if the following conditions are met:

t /, <0, LV> 0, L / ₂ > U ₂ '.

In the case of the in FIG. 1, the output voltage Ui of the integrator is a positive ramp because of the negative integrator input voltage L'i (oscillation phase Ti in FIG. 2). When U _{1 reaches} the reference voltage of the comparator K, which is now U ₂ , the comparator device switches over the switches Si and S ₂ . The input of the integrator is now connected to the positive voltage LV and the reference input of the comparator K is connected to the voltage LZ ₂ '. The positive integrator input voltage generates a negative ramp of the output voltage U ₁ (oscillation phase Ti in FIG. 2). The comparator switches back when U ₁ has reached the voltage U 2 at the reference input of the comparator. The output voltage U ₁ thus carries out a triangular oscillation between the limit values U ₂ and U ₂ . Their period To is a function of the voltages Ui, LV, LZ ₂ and U ₂ and the integrator time constants R ■ C:

T.-

This oscillator is insensitive to voltage and current offset of the amplifier. An offset between the inputs of the comparator K only shifts the two limits of the triangular oscillation at the same time, but does not affect its amplitude and thus its period; an offset of the integrator amplifier is then approximately eliminated when the oscillation is symmetrical, that is, when L'i = - LV.

In Fig. 3 shows how the changeover switches S \ and Si can be implemented with little effort in such a way that the non-ideal properties of the components used have practically no influence on the oscillator frequency. The switches S \ and S ₂ are (> o in each case two field-effect transistors Fi, F ₁ 'and F _2, F ₂ (z. B. formed MOSFETs), wherein of a drive circuit 5 in the comparator E transistors F, and F are driven _two opposite Fi 'and F _2' in push-pull. field effect transistors (■>% do not generate offset voltages, but have considerable internal resistance in the conductive state. Thus, the input current of the integrator does not flow through the switch, producing an input voltage falsifying voltage drop, the switch S ₁ , i.e. the field effect transistors Fi and Fi ', is decoupled from the integrator by an amplifier V ₂ with a high input resistance. This can be an operational amplifier, as shown in FIG switched so that the voltages U \ and LV can practically always be chosen to be sufficiently large. Even an offset thick amplifier only leads to a k There is no asymmetry of the triangular oscillation and thus only leads to a second- order error.

Similarly, the reference input of the comparator, an amplifier V3 with a high input resistance are connected upstream, if this reference input high impedance enough An offset of this amplifier V ₃ is not only causes a shift of the absolute position of the triangular wave and therefore has no influence on the period. However, if the oscillator is controlled by very small voltages U ₂ , the resulting triangular oscillation has only a very small amplitude. In order to ensure exact switching of the comparator, a preamplifier is expediently connected upstream of it. For this purpose, the amplifier V ₃ may be a further amplifier connected downstream of the amplifier or V _3, even by a corresponding counter-coupling with the resistors Ri and A ₄ with a gain> 1 will be equipped. An amplifier offset has no effect in these cases either. If, on the other hand, a preamplifier were to be inserted between U ₂ and the switch, as is known from other controlled oscillators, then U ₂ would be falsified by its offset.

This oscillator can be controlled linearly in its period T ₀ by the voltage U _2. The voltage U ₂ can be used for the zero point shift or it can be zero. The two reference voltage sources U ₁ and L'i 'have approximately the same voltage in terms of magnitude, but different polarity. The conversion characteristic is only determined by two passive components R and C. The properties of the active components, such as amplifiers and switches, have no effect on the period of the oscillator if they are kept within the usual tolerances.

The in F i g. 4 only requires a single reference voltage source L'i. The reference input of the integrator amplifier Vi is not connected to the circuit zero point as usual, but is at the potential via the voltage divider Ri, R ₂

·, LZ ₁ . Depending on the switch position, will alternate

-, U ₁ -U] and, L7i - 0 integrated and thus the

The symmetry of the triangular oscillation is preserved. The resistances R ₁ and R ₂ only have to be approximately the same. A deviation in the integrator reference voltage., U ₁ leads to an asymmetry of the

Vibration and thus only to an error / further order. This oscillator can also be controlled linearly in its period by the voltage U:. Since the oscillator according to FIG. 4 only requires one reference voltage source, a linear control of the frequency is easily possible in that U \ acts as the input voltage and U ₂ as the reference voltage. Tolerates the voltage source L'i due to its

Internal resistance does not reduce the load caused by the voltage divider R \, R ₂ , then R ₃ can be connected to the common node of Ui and F \ via an impedance converter. Inaccuracies in this impedance converter (offset or gain 1) only cause errors of the second order again.

Control by a current is achieved by using one of the controlling voltage sources an ohmic resistor is replaced at which the control current has a proportional voltage drop generated.

F i g. 5 shows the use of a relaxation oscillator for the linear conversion of a bridge detuning into an oscillation period. The bridge B is fed from the reference voltage sources U \ and Ui to di "instead of the voltages U ₂ and W takes the Brückendia gonalspannung. In this way, the oscillation period is independent of the bridge supply voltage LJ and Ui '. When the amplifier V ₃ as ready; has been described, by appropriately dimensioning the resistors A ₃ and Ra, in addition to the impedance conversion, it is also used for amplification, a simple way of adjusting the zero point by means of a resistor Äs between the output of the amplifier V ₂ and the common node of the resistors R] and A4 .

For this purpose 4 sheets of drawings

Claims (6)

Patent claims: 1. Relaxation oscillator with controllable frequency by one or more external voltages, consisting of an integrator with an input and a reference input and a comparator device whose input is connected to the output of the integrator and whose output controls an electronic switch that drives the ι ο input of the integrator feeds one of two voltages, characterized in that the comparator device (E) contains a comparator (K) with one input and only one reference input, which both when the voltage (Ui) is exceeded and when it falls below the voltage (Ui) at the input compared to the voltage (U ₂ or U ₂ ) at the reference input changes its output state, and that the reference input of the comparator (K ) is preceded by a switch (S2; F2, Fj) controlled in parallel with the switch (Si; Fu Fi ') in front of the input of the integrator , which each feeds one of two voltages (U ₂ , U ₂ ) to this reference input 2. Relaxation oscillator according to claim 1, characterized in that the changeover switches (Su S ₂ ) each consist of two field effect transistors (Fi, Fi '; F ₂ , F ₂ ) , the control of which takes place in push-pull with both changeover switches 3. Relaxation oscillator according to claim 1 or 2, characterized in that an amplifier (V ₃ ) with a high input resistance is connected directly upstream of the reference input of the comparator (K). 4. Relaxation oscillator according to claim 1 or one of the following, characterized in that an amplifier (V ₂ ) with a high input resistance is connected directly upstream of the input of the integrator 5. Relaxation oscillator according to claim 1 or one of the following, characterized in that the two voltages (Ui, LV) alternately supplied to the input of the integrator are at least approximately symmetrical to the voltage at the reference input of the integrator. 6. Relaxation oscillator according to claim 1 or one following, characterized in that the two voltages (Uu Ui) alternately supplied to the input of the integrator are the supply voltage of a bridge circuit (B) , the other diagonal of which is alternately supplied to the reference input of the comparator (K) supplies both voltages (U ₂ , U ₂ ').