DE1541391A1 - Self-stabilizing oscillator - Google Patents

Description

Self-stabilizing oscillator The invention relates to oscillators and more particularly relates to a stabilized oscillator that in its entirety given frequency range provides a constant output voltage. Oscillators are known in various designs. There are also different measures known to limit or stabilize their output voltage. With the present Invention for the first time a new one, every stabilization of oscillators is trodden and shown as an exemplary embodiment of an oscillator, which is a complete new Building block in circuit technology. According to the in the last Years of progress in the field of integrated semiconductor technology can be made usable not only in digital technology, but also in analog technology. From the integrated semiconductor technology is z.8. the op amp as a versatile component known. This fully transistorized amplifier can have more than 20 transistor functions and a voltage amplifier factor of up to to have 105. It can of course not make sense in connection with the invention be the number of transistor functions as a measure of economy and reliability to look at and investigate. But it is the aim of the invention for the construction of a self-stabilizing oscillator one. Operational amplifier to use and to use all of its properties to create a new building block. This objective now results in circuit variants that were previously in circuit technology with discrete components as inefficient and also unconventional which, however, represent an optimum in the integrated technology and can thus point the way.

The invention is in this field. The structure of an operational amplifier is assumed to be known. The object of the invention is therefore to provide a Combine operational amplifier with a bridge circuit so that a self-stabilizing An oscillator is created, the output of which is a constant sine wave, in one Area that depends only on the dimensioning of the circuit, with the properties of an operational amplifier can be fully utilized.

The object is achieved according to the invention in that a Operational amplifier integrated in a bridge circuit with at least one non-inverting and one.

inverting input and an output that has a first Negative feedback path with an ohmic t .-) resistance for the transmission of an alternating voltage and via a second negative feedback path to the transmission of a direct voltage is connected to the inverting input of the amplifier and that the output voltage of the amplifier via a second .Grückkopplungspfad the gain factor of the oscillator. determining resistance of the with the inverting input of the Amplifier connected electrode path of a Pelde effect transistor controls in such a way, that the resistance of the non-inverting input increases by the same factor increases as the output resistance of the amplifier decreases and the open loop gain is kept constant.

An operational amplifier is therefore used for the oscillator circuit according to the invention uses one inverting and one non-inverting input as well an exit Has. It is known that the characteristics of an operational amplifier are significantly influenced by the negative feedback used and that the phase position the input and output signal is an important criterion and for the intended Frequency range must be very_accurately 180o.

The branch of the push circuit connected to the feedback is applied to the non-inverting input of the operational amplifier. The stabilization the output voltage takes place via the inverting input of the operational amplifier., In the case of an ideal operational amplifier, the input resistance should be infinitely large and the output resistance will be zero. The same condition, of course, soot also apply to the oscillator according to the invention. So it must be the initial resistance of the operational amplifier is reduced and its input resistance is increased accordingly will. According to the invention, this object is achieved with a negative feedback which comprises a field effect transistor which controls the amplification of the oscillator, as will be explained in detail later.

Assuming that the transfer function for the bridge circuit applies, the reduction corresponds to the oscillator frequency The output resistance .Tii of the operational amplifier and its input conductance 1 / Re add linearly to the resistances of the fractions and are included in the relationship for the oscillator frequency. From G: linden the frequency constancy, the following conditions should be fulfilled for the oscillator: Re>R> Ri.

According to the invention it was found that by means of a negative feedback path between the output and the inverting input of the operational amplifier the The condition shown can be met well. About the negative feedback path the no-load gain on that to stimulate and maintain the vibrations necessary amount reduced. Through this . will a. : the input resistance Re am non-inverting Input of the operational amplifier increased by the factor of the gain reduction, b. the output resistance Ri is reduced by the factor of the gain reduction and c. the constancy and linearity of the amplifier by the factor - the gain reduction improved.

It must also be ensured that the reduced gain always corresponds exactly to the reciprocal value of the resonance damping of the four-pole bridge. Will she smaller, the vibrations break off; if, on the other hand, it becomes larger, they grow Amplitudes until they reach the operational amplifier's control limit. The consequence of this is an impermissibly high deformation of the sinusoidal curve of the output voltage. This is achieved by a field effect transistor arranged in the negative feedback according to the invention prevented. Runs a field effect transistor with small voltages, like that the distance between two of its electrodes acts like an ohmic resistor, its Size can be changed with a control potential. This property; is found in exploited the oscillator according to the invention. For this purpose, the counter to be coupled Potential fed back via z "" ei negative feedback paths, both of which have a signal from the Feed the output of the amplifier back to the inverting y-4, .n` ,, ang. The one The negative feedback path includes one ear: ach resistor and the other leads through one Circuitry for the control electrode comprising rectifier, amplifier and smoothing circuits of a field effect transistor. One electrode of the field effect transistor is with connected to the inverting input of the amplifier, so that the field effect transistor is controlled with DC voltage signals, which are derived from the AC voltage signal of the increased output can be obtained. With the field effect transistor to the inverting The signal applied to the input of the operational amplifier is transmitted via the ohmic resistor AC voltage supplied to this input in the first negative feedback path accordingly degraded. Because the gain factor of an operational amplifier is reversed behaves proportionally to the reduction of said alternating voltage, he leaves change with a corresponding DC voltage that is generated via the field effect transistor is fed. In the circuit according to the invention of the self-stabilizing oscillator the control DC voltage is, as already mentioned, through rectification, amplification and smoothing the output arm voltage of the amplifier obtained so that a 'closed A control loop is created that regulates any deviation in the output voltage. The product of the oscillator according to the invention is finally a frequency and amplitude constant Sine wave that is independent of the dispersion of the operational amplifier and also of the field effect transistor. The self-stabilizing according to the invention The oscillator is described below with a preferred exemplary embodiment. The invention must of course not be restricted to this exemplary embodiment, because both the operational amplifier and the bridge circuit have a different one construction can own.

The accompanying drawings show: FIG. 1 a simplified circuit diagram of the self-stabilizing oscillator, Figure 2 circuit diagram of the self-stabilizing Oscillator, Figure 3 Resistance ratios of the electrode path of the field effect transistor and FIG. 14 family of characteristics of the resistance of the electrode path of the field effect transistor. .

As Figures _1 and 2 show, the bridge circuit is with the Resistors R3, R6 and capacitors C1, C2 on the non-inverting input NI of the operational amplifier V. In the non-inverting input PII of the amplifier V the RC element C8, R3 is connected. The output of the amplifier V is on the one hand fed back via the bridge members and on the other hand via a first negative feedback path connected to its inverting input I. In this path lies the ohnsche Resistor R7. A second negative feedback path connects output A of the amplifier V also with the 1 input I. It includes the circuits for generation and amplification and smoothing a DC voltage. As can be seen from Figure 2, the second comprises Negative feedback path the load resistor RL and as an input the series connection of Resistor R19 and capacitor C10. The rectifier consists of diodes D2, D3, D4 of the Zener diode D1 and the capacitor C9. The output of the rectifier passes through resistor R18 into the amplifier with transistors Q2 and R3, their interconnected emitter on the one hand with the negative pole of a voltage source via the resistor R16 and with the circuit - * of the rectifier via the resistor R17 are connected. Of the Connection point is between the resistor R18, which can be a variable resistor, and the cathode of the Zener diode D2. The collector electrodes the amplifier transistors Q2 and Q3 are also connected together and across the :: Y resistors R14 and R15 with the positive potential of the DC voltage source tied together. The base of transistor Q2 is connected to ground via resistor R13, and the base of the other transistor Q3 is connected to the variable resistor R18.

In order to reduce the brightness of the DC voltage supplied by the amplifier to the permissible value, a smoothing circuit is connected to the collector electrode of the transistor Q2, which consists of the resistors RO and R12 and via the capacitor C4, which is connected to the connection point of the two mentioned resistors is, on, mass is. This filter is connected to the control electrode E of the field effect transistor Q1 via the resistor RQ.

The field effect transistor Q1 is used in the circuit according to the invention for self-stabilization of the oscillator used in that the according to the invention established second negative feedback path of its control electrode supplied DC voltage signal continuously the j: resistance of the electrode path S-D from the dimensioning the oscillator circuit adjusts the resulting condition and thereby the input resistance of the inverting input of the oscillator keeps constant. Here is the electrode S of the field effect transistor With: connected to ground, and to its J electrode, the is connected to the inverting input I and includes the capacitor C3 the resistor R5 in parallel.

The resistance RD of the electrode path SD of the field effect transistor is shown in FIG. 3. This resistance corresponds The functional sequence for the illustrated embodiment of the invention is as follows: Assume that the oscillator vibrates and its idling gain is VUs = 105. A gain factor VU = 10 is required for the amplification and maintenance of the vibrations. So there must be a gain reduction, namely by the factor The gain VU must correspond exactly to the reciprocal value of the resonance damping. The alternating voltage at the output A of the amplifier is rectified on the one hand via the first negative feedback path with resistor R7 and on the other hand via the second negative feedback path, via the SD path of the field effect transistor Q1 to the inverting input I of the amplifier V, whereby a reduction of the over the first negative feedback path at the inverting input I AC voltage in the ratio of he follows. Since the gain VU is inversely proportional to the ratio behaves, the output resistance of the amplifier is increased by the factor of the gain reduction decreased and the input resistance Re at the non-inverting input; NI by the same factor elevated. This in turn influences the output voltage of the oscillator, so that a closed control loop is formed.

The family of characteristics in FIG. 4 shows the dependency of the Wide, ° stand RD of the electrode path S-D of the field effect transistor Q1 with different DC voltage values at the electrode section S-D. From this figure is also to see that a zero point shift in the inventive oscillator circuit not taking place. The output signal of the operational amplifier thus regulates via the resistor R7 in the first negative feedback path and rectified via the S-D path of the field effect transistor in the second negative feedback path all Fluctuations so that the output is a constant alternating voltage. Another The advantage of the circuit according to the invention is that:. by using a Field effect transistor as a control element in the opposite negative feedback path, the disruptive Influences of temperature and aging are compensated, so that the size of the output signal depends only on the dimensioning of the oscillator circuit.

Claims (2)

Claims 1. Self-stabilizing oscillator, d a d u r c h g e -k e n n n z e i c h n e t that in a bridge circuit as an integral part an operational amplifier (V) with at least one non-inverting (i1I) and an inverting (I) input and an output (A) is included, which is via a first Geöenkopplungspfad (GI) with an ohmic resistor (R7) for the Transmission of an alternating voltage and a second negative feedback path (GII) for the transmission of a direct voltage with the inverting input (I) of the amplifier (V) is connected, and that the output voltage of the amplifier (V) across the second Negative feedback path (GII) determines the amplification factor of the oscillator Resistance (RD) connected to the inverting input (I) of the amplifier (V) Electrode path (S-D) of a field effect transistor (0.1) controls such that the resistance of the non-inverting input (NI) increases by the same factor increases as the output resistance of the amplifier decreases and the open loop gain is kept constant. 2. Self-stabilizing oscillator according to claim 1, d a -characterized in that the direct voltage signal used to control the field effect transistor (a1) is obtained from the output alternating current signal of the amplifier. 3. Self-stabilizing oscillator according to claim 1 and 2, characterized in that the rectifier circuit (D2, D3, D4, C9) provided in the second negative feedback path (GII) comprises a Zener diode (D1) and a variable resistor (R1 $). 4. Self-stabilizing oscillator according to claim 1 and 2, characterized in that the rectifier in the second negative feedback path (GII) downstream amplifier circuit (Q2, Q3) with the base electrode of one of its transistors (Q3) is connected to the variable resistor (R1ß) of the amplifier circuit. 5. Self-stabilizing oscillator according to claims 1, 2 and 4, characterized in that the interconnected emitters of the transistors (Q2, Q3) of the amplifier circuit via the resistors (R15, R17) in the rectifier class are connected. . Self-stabilizing oscillator according to Claims 1 and 2, characterized in that the collector electrodes dQr transistors (Q2, Q3) are connected to the positive side of the voltage source via the resistors (R14,! 110). 7. Self-stabilizing Os :: -. I lator according to claim 1 and 2, characterized in that in a (? der '; cl lel: torelel: troden der Frans; disturb (Q2, Q3) des Amplifying circuit (R9, R12, CII) switches i .s t. ß. Selb st :: t <äbi ll.sici ° cnder t @ s :: il lato according to the demands 1, 2 and '! , because it is denoted by 4 el: that the Gl, ': ttungsk: @eis (:', @, T @ 12, C '@') with a Pcüel - @ - lider- stand -i # i -; escülossen sL. 9. Self-stabilizing oscillator according to claims 1, 2 and $, characterized in that the control electrode (E) of the field effect transistor (Q1) is connected to the control resistor (R9) of the smoothing circuit. 10. Self-stabilizing oscillator according to claims 1, 2 and 9, characterized in that one electrode (S) of the field effect transistor (Q1) is connected to ground. 11. Self-stabilizing oscillator according to claims 1, 2, 9 and 10, characterized in that a second electrode (D) of the field effect transistor (Q1) is connected to the inverting input (I) of the operational amplifier (V). 12. Self-stabilizing oscillator according to claims 1, 2, 9, 10 and 11, dadurchgekcnnzeich -net that in which the electrode (D) of the field effect transistor (A) rides the inverting input (I) of the Operationsverstürr: ers (V) connecting line is a capacitor (C3) in parallel with a resistor (R5) which is connected to ground. 13. Self-stabilizing oscillator according to claim 1, since - indicated that a branch the trigger circuit (C1, RG) with the output (A) of the Operati onsverstiriers (V) and the other branch of the Bridge circuit (:: 3, ;; 4, C2) via an RC element (R8, C3) with the non-inverting input (:; I) of the operational amplifier is connected. 111. Self-stabilizing oscillator according to claim 1, characterized in that the reduction of the first negative feedback path (GI) via the ohmic resistor (R7) i M to the inverting input (I) of the amplifier (V):; 'ec'_iselvoltage signal depends on the conditions that i: @. second negative feedback path (GII) for the arg output (A) of the amplifier (V) pending AC voltage signal can be provided. 15. Self-stabilizing oscillator according to claim 1 and 14, characterized in that the size of the negative feedback signal applied to the control electrode (E) of the field effect transistor N1) determines the resistance of the non-inverting input (iII) of the field effect transistor Oscillator according to Claims 1, 14 "and 15, characterized in that the magnitude of the signal fed to the control electrode (E) controls the resistance of the electrode path (SD) of the" field effect transistor N 1).