DD146728A5 - VIENNA ROBINSON OSCILLATOR HIGH FREQUENCY STABILITY - Google Patents

Abstract

The invention relates to a Wien-Robinson oscillator high Frequenzstabilitaet containing an Operationsverstaerker with a phase rotation of 90 degrees, the Operationsverstaerker is provided with a frequency-dependent positive and an amplitude negative feedback. The frequency-dependent feedback branch includes a voltage divider consisting of a series RC element and a parallel RC element whose division point is connected to the non-inverting input of the operational amplifier. The amplitude-dependent feedback branch also contains a voltage divider whose partial point is connected to the inverting input of the operational amplifier. The amplitude-dependent feedback branch also contains a voltage divider whose division point is connected to the inverting input of the operational amplifier. The one element of the amplitude-dependent feedback branch voltage divider consists of two oppositely polarized parallel-connected diodes with a resistor in series and a resistor connected in parallel. The other element of this voltage divider consists of a resistor, one in series

Description

163 * 2 - "-

Wien-Robinson-Oscillator high frequency stability

Field of application of the invention:

The invention relates to a RC oscillator with YJien-Robinson bridge, which contains an operational amplifier.

Characteristic of the known technical solutions.

Purely numerous fields of application require audio frequency oscillators of relatively high frequency stability (10-.mu.m), which are generally used for this purpose in quartz oscillators. However, the use of audio frequency quartz oscillators has numerous disadvantages. Firstly, it is not possible to generate any frequency with the help of a particular oscillator, because the frequencies of commercially available quartz crystals have to be taken into account Audio frequency quartz crystals because of their large dimensions

^mm 2? · "

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disadvantageous. As a result, tone frequency crystal oscillators are replaced by generating the required tone frequency from the frequency of a high frequency crystal oscillator by frequency division. Another possibility is the use of RG oscillators. However, the frequency and amplitude stability of the known RO oscillators is several orders of magnitude lower than that of the quartz oscillators with changes in temperature, supply voltage and load.

In an RC oscillator with Wienschera bridge branch is. the stability according to HU-PS Hr. 162 974 increased by inserting a plurality of operational amplifiers into the positive feedback branch. However, this solution is very complicated and costly, while still only a frequency stability of 10 "* · * can be achieved.

In the known Wien-Robinson oscillators with operational amplifier, a positive and a negative feedback branch are connected to the operational amplifier, wherein the positive feedback branch includes a selective RC circuit and the negative feedback branch comprises a level-dependent circuit. In the known solutions, the limitation in the level-dependent circuit by diodes or a, thermistor. A negative feedback circuit with a thermistor is described in DE-PS Ur. 1 196 722 described. However, this solution only stabilizes the amplitude in a relatively narrow range, while the problem of frequency stabilization remains unsolved.

In principle, none of the known solutions is suitable for stabilizing both the frequency and the amplitude over a wide temperature range.

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Object of the invention:

With the invention, a cheap R0 oscillator circuit with a simple structure is to be created, which has a high frequency and amplitude stability in a wide temperature range,

Explanation of the essence of the invention:

The present invention is based on the recognition that a high frequency and amplitude stability can be achieved by using an operational amplifier having a phase rotation of 90 ° at the oscillation frequency, wherein the frequency-independent feedback is realized by a voltage divider which Boundary diodes, a thermistor and with them in series or · parallel-connected resistors. By the thermistor the Teniperaturabhängigkext the characteristic of the Begrenzerdioden is compensated, while this temperature compensation by means of the in series or parallel resistors is set such that when changes in temperature a small level change to stabilize the frequency occurs · The RC value of the frequency-dependent selective positive The feedback branch and the dividing ratio of the frequency-independent branch are chosen to be based on the fundamental gain of the operational amplifier, and the frequency of the first breakpoint and the temperature dependence are set such that the oscillation frequency does not change in the given temperature range.

More particularly, the invention relates to a Wien-Robinson oscillator of high frequency stability, which includes an operational amplifier with a phase rotation of 90 °, the operational amplifier having a frequency-dependent positive, and an amplitude-dependent negative feedback.

is provided coupling. The frequency-dependent feedback branch comprises a voltage divider consisting of a series RG element and a parallel RC element whose division point is connected to the non-inverting input of the operational amplifier. The amplitude-dependent feedback branch also contains a voltage divider whose division point coincides with the inverting input of the operational amplifier The essence of the invention is that the product of the resistance and the capacitance of the RG-elements located in the frequency-dependent feedback branch

RC

u ff _r - ³ * ⁹ ' ^for Y ι A - f'

^A o-

is, where

R is the value of the stator, C is the value of the capacitor, F is the frequency to be produced,

A _{0 is} the basic gain of the operational amplifier and f _{0 is} the first breakpoint of the characteristic (Bode diagram) of the operational amplifier.

designated.

The one part of the amplitude-dependent feedback branch forming voltage divider consists of two with a resistor in series and oppositely poled parallel-connected diodes and a diode connected in parallel resistor. The other term of this voltage divider consists of a resistor, one with this resistance.

T3.tand thermistor connected in series and preferably a resistor connected in series with the thermistor and a parallel geschal to this series connection ended resistor. The dividing ratio of the voltage divider constituting the amplitude-dependent feedback path is as follows:

V ^f o

In an advantageous embodiment of the oscillator according to the invention, the output of the oscillator is connected to the load via a separating stage, which is zeta-foldwise an amplifier.

Execution aapiel ·:

To further explain the invention, reference is made to the drawing, in which da3 circuit diagram of an advantageous embodiment of the oscillator according to the invention is shown.

As can be seen from the drawing, the output U ,. of the operational amplifier E fed back to both inputs, and positive by means of a consisting of resistors R and capacitors C frequency-selective circuit, and negative by means of a diode D ^, D ₂ resistors R ₁ , R ₂ , R *, R ^, R ₁ -, Thermistor I containing circuit. The selective feedback circuit consists of a series RO element and a parallel RC element, which together form a voltage divider. The division point of the voltage divider is connected to the non-inverting input of the operational amplifier E. The selective feedback branch of the oscillator can be rated according to the following equation:

215362

RO «

Af ^A O * ¹ O

R is the value of the resistance in the feedback circuit,

C is the capacitance value of the capacitor in the feedback circuit,

JL _{1 is} the frequency to be generated,

A _{Q is} the basic amplification of the operational amplifier,

f _Q 'is the first breaking point of the characteristic curve (Bode diagram) of the operational amplifier

In the case of the operational amplifier E, the basic gain A ₀ or the frequency f o of the first breakpoint can be set very easily. The type of adjustment depends on the type of operational amplifier used. However, it is to be noted that the basic gain A ₀ must be set at a frequency f, the _Q is the first break point is orders of magnitude smaller than the frequency f. Furthermore, it is important to choose the frequency f to be generated so that it is orders of magnitude higher than the frequency f _{Q of} the first break point, and that the frequency of a possible second break point of the amplifier must be orders of magnitude higher than the frequency f to be generated _r · the operational amplifier e is fed by means of an amplitude-dependent feedback path also to the inverting input. The feedback branch comprises the series resistors R _1, R ₂ and the resistor R ₂ in parallel antiparallel connected diodes D ^, D _2, the one limb of a chipboard

forming a divider. The division point of the voltage divider is connected to the inverting input of the operational amplifier S. The other member of this voltage divider consists of the resistors R, -, Ra and the resistor R * parallel to the thermistor T, and connected to the thermistor T in series Y / iderstand R _3rd The voltage dividers have a common grounding point. With suitable dimensioning, the frequency-dependent feedback branch behaves like a temperature- and amplitude-independent voltage divider. The frequency-independent feedback branch can be dimensioned on the basis of the following formula.

^A o * ^f o

the resistance of the thermistor at the mean temperature of the temperature range i to be compensated

R2, _R3, R4, Rc, the values of that are available in the feedback branch resistors and

the division ratio of the frequency-independent feedback branch

The amplitude of the output signal of the oscillator can be adjusted by changing the ratio R- ,, R2. The oscillator according to the invention is only slightly sensitive to variations in the supply voltage, and if it is ensured that the supply voltage range during

the operation of the Yerstärkers is always sufficiently large, so that the amplitude of the oscillating signal is not limited by the amplifier, the frequency and the amplitude of the oscillator of the supply voltage are practically independent.

If a greater frequency stability (10 ** - *) is required, a same common temperature for all components of the oscillator (resistors, capacitors, operational amplifiers) must be ensured. This can be achieved, for example, by providing a heat-insulating enclosure for the entire circuit and pouring out the space within the enclosure with a material of relatively good y / c conductivity. It is of course auc.h possible, for example, to incorporate all components in a common aluminum block and provided with a heat-insulating sheath.

As already mentioned in the introduction, the oscillators are also sensitive to changes in the load impedance. An oscillator can be protected against variations in the load impedance in a known manner by switching a disconnect stage, for example a follower amplifier, between the load and the oscillator. If a square wave is required, the function of the separation stage can be fulfilled by a comparator.

It can be seen that with the help of the circuit arrangement according to the invention with relatively simple means can build an RC oscillator, which has a frequency stability of 10 "* ^, as well as a high amplitude stability and accuracy within a very wide temperature range, even over long periods.

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Claims (1)

Invention claim: Wien-Robincon oscillator of high frequency stability with an operational amplifier, which is provided with a frequency-dependent positive and an amplitude-dependent negative feedback, wherein the frequency-dependent feedback branch is a consisting of a series RC element and a parallel RC element voltage divider whose division point " is connected to the non-inverting input of the operational amplifier, while the amplitude-dependent feedback branch is also a voltage divider whose division point is connected to the inverting input of the operational amplifier, characterized in that the operational amplifier at the oscillation frequency, and in the vicinity of the oscillation frequency, a phase rotation of 90 ° has the product of resistance and capacitance of the RG elements lying in the frequency-dependent feedback branch 2 ir (f _r - _2iiif, i V ^f o is, where R is the value of the resistance,
C is the value of the capacitor,
f _{r is} the frequency to be generated, A _{0 is} the fundamental gain of the operational amplifier, f _{Q is} the first breakpoint of the operational amplifier characteristic is that the one member of the amplitude-dependent feedback 'coupling branch forming. Voltage divider of two resistors connected in series (R ^, R2), as well as - 10 - 216362 two resistors (R ₂ ) connected in parallel and with opposite polarity connected diodes (D ^, Dg), while the other member of this voltage divider consists of a resistor (Rc) connected in series with a thermistor (T) and preferably one with the resistor (Ro) connected in series with the thermistor (T) and a resistor (R /) connected in parallel with this series circuit (Ro »T), the division ratio of the voltage divider forming the amplitude-dependent feedback branch is. 2, oscillator according to item 1, characterized in that the output of the oscillator is connected via a separating stage, preferably via a follower amplifier, with the load. '. For this purpose / f page. drawing - 11 -