DE1566962C - Amplitude controlled oscillator - Google Patents

Description

The invention relates to an amplitude-controlled oscillator, which is characterized by high amplitude stability, which is particularly independent of temperature fluctuations. Such oscillators are required in particular for devices that are equipped with converter elements, such as differential transformers, work. There is also a need for oscillators that can produce high output currents without transformer coupling produce. In addition, for precision instruments and other devices, it is highly desirable that the oscillator very good frequency stability in particular without the use of a relatively expensive crystal control element owns. Accuracy in the variability of the amplitude is another desirable feature such an oscillator.

In summary, it is the aim of the invention to provide an oscillator with the following properties create:

(1) high amplitude stability,

(2) high output without using a transformer,

(3) very good frequency stability without the need for a crystal,

(4) precise variability of the amplitude.

From the USA patent specification 3179 900 an amplitude-controlled oscillator is known in which the oscillator output voltage is compared with a DC reference voltage and from the difference signal a DC voltage error signal in a conversion stage is generated, which controls the amplitude of a negative feedback signal influencing solid-state element with variable impedance. In the known circuit, the stage for converting the difference signal into the direct current error signal comprises an AC amplifier, a rectifier and a DC amplifier. This conventional type of conversion involves a considerable amount of switching elements connected for the three subcircuits mentioned.

This disadvantage is avoided in the oscillator according to the invention in that the conversion stage a first circle for generating rectangular pulses, the width of which is a function of the Difference signal is a second circle for generating triangular pulses, the DC voltage level of which is a function of the width of the square pulses and a third circuit for generating the DC voltage error signal by integrating the Includes triangular pulses; the solid-state element changes the negative feedback signal in direct proportion with the DC voltage error signal. The oscillator according to the invention therefore differs from the known circuit in the functional principle, which is an essential for the circuit structure Bringing savings in elements.

In a preferred embodiment of the invention, the oscillator has one between its output and its input switched on positive feedback circuit, one of the negative feedback circuit in essential independent Vienna bridge included.

In a further embodiment, the inventive Oscillator has a circuit for generating a push-pull output signal.

The body element used in the oscillator according to the invention is preferably a unijunction transistor.

Further details of the subject matter of the invention emerge from the description below of an embodiment with reference to the drawing. The oscillator circuit shown consists of a ' Series of subcircuits, which are initially mentioned in summary form, giving details of their respective functions and should then be described in detail.

(1) differential amplifier and rectifier circuit, which contains the transistors 7, 8, 9 and 21. Their function is to provide a DC error signal to generate, the amplitude of which represents a function of the amplitude of the oscillator to be controlled.

(2) Attenuation stage containing transistor 35. Its function is to control the amplitude of one of to control the negative feedback signal generated by the oscillator.

(3) The actual oscillator circuit whose amplitude is to be controlled and which the transistors 43, 59, 69, 77, 83 and 87 contains.

(4) Positive AC feedback in the form of a Wien bridge, consisting of the capacitors 65 and 91 and the resistors 63 and 85. The task of this subcircuit is the To maintain the function of the oscillator.

(5) Negative feedback circuit between the oscillator and the damping stage, consisting of the potentiometer 53, the resistor 49 and possibly the thermistor 47. The amplitude of the negative feedback signal fed to the oscillator and thus of the oscillator output signal is controlled by the attenuation stage with the transistor 35.

Differential amplifier and rectifier subcircuit

This subcircuit contains the transistors 7 and 8, their emitters with each other and via a Resistor 6 are connected to a circuit point 93 which is connected to a positive DC voltage source, such as a 12-volt battery. The collectors are connected to a negative DC voltage source, with des Transistor 7, a resistor 10 is connected to which a voltage drops when the transistor is switched on.

The base of the transistor 7 is connected to a node 5 on a suitable positive DC input voltage, approximately + 6 volts. The sinusoidal generated at a starting point 94 The output wave of the oscillator is fed to the base of the transistor 8. This output shaft for example, may oscillate between +6 and -6 volts. The transistor 8 is so except for the Locked times when the positive peak of the sinusoidal voltage at its base is equal to or stronger is positive than the reference voltage at the base of transistor 7. Every time the base voltage of the When the transistor 8 exceeds that of the transistor 7, the transistor 7 is switched on. Through this positive pulses are generated, which are amplified in the transistor 9. The one at the output of the transistor 9 resulting negative pulses are fed to a diode 11. The breadth of these impulses is in proportion to the size by which the peak of the output sine wave applied to transistor 8 of the oscillator exceeds the reference voltage at transistor 7.

3 4

From these square-wave pulses, an equation should now be achieved. A capacitor 45 provides a high frequency voltage, the amplitude of which is a shunt to the described oscillator-function of the pulse width. For this purpose, the device is shown. The direct current negative feedback via the individual pulses via a diode 11 and a resistor 49 causes the output DC voltage 12 to be fed to a capacitor 13. The voltage is kept at zero by 5, whereby a direct coupling of the capacitor 13 and the resistor 12 to the output of the oscillator without a detuned time constant is designed so that the turn of a transformer is established. The voltage on the capacitor is proportional to the pulse width of the alternating current negative feedback voltage. Attenuated in the intervals between the individual Im transistor 35. Every time in the outpulsing the capacitor 13 is almost every time a peak occurs, the attenuation is completely discharged; as a result, a short on at transistor 35 is regulated. The resistor 49 reaches talk time, which ensures stable operation of the has a size which is equal to the sum of the circuit. The voltage across the capacitor 41, the impedance of the transistor 35 sator 13 has the shape of a sawtooth wave, which is through and the impedance of the capacitor 39 is.
a resistor 19 and a capacitor 17 15 The transistors 43 and 59 lead the Basiselekintegrated. The integrated DC voltage is fed through the transistors 87 and 69 amplified to a transistor 21, which is used to achieve an output signal. The transistors 69 and 87 form a small output resistance as an emitter follower - a differential amplifier which is switched on at the collector of the. To act on the downstream transistor 69 has a single output. The high attenuation level, that is to say of the unipolar transistor 35, ae current through the transistors 77 and 83 is therefore available through large currents. The diodes 71 and 73 together with a resistor capacitor 25 and the resistors 27 and 29 89 are limited. A capacitor 79 and a resistor control the current flowing into transistor 35. 81 are designed in such a way that they prevent an unwanted oscilation lation by leading the error signal in phase. The transistors 77 and 83 are stabilized the entire circuit and the os- 35 ken as push-pull emitter follower stages, whose oscillator output signal is regulated in its amplitude. output voltage is supplied to terminal 94 without

that an output transformer - which is

Attenuation level stepping high power would be very large - required will.

The unipolar transistor 35 is in the unusual 30 ■ positive feedback circuit

Wise. He works essentially like an ^rr

DC voltage controlled variable resistor; d. i.e., to maintain the oscillation is to the

its resistance changes as a function of the input terminal 94 connected to a subcircuit that

output current. The emitter of the transistor 35 is a capacitor 91, a resistor 85, a

a fixed bias voltage via a variable capacitor 65 and resistor 63 includes.

Resistor 31 is supplied, which is connected via a resistor. This circuit represents a Wien bridge in which

33 with the positive DC voltage source at the no phase reversal at a certain frequency

Output terminal 93 is connected. The emitter- from the starting point back to the input of the oscil-

Current of the transistor 35 is from the output signal lators at the base of the transistor 59 occurs. at

of the transistor 21, which has the same polarity 40 of this frequency, the Wien bridge attenuates the

like its input signal. To the extent that the output shaft increases by 50%. This positive feedback circle is

in which the amplitude at the output of the downstream is separated from the negative feedback circuit, which creates a sta-

When the oscillator rises, the emitter frequency characteristic decreases and a lower one

voltage of transistor 21, and vice versa. Content of harmonics in the oscillator

If this emitter voltage decreases, a part 45 wave will result at the output. Since the positive feedback

of the current drawn from the emitter of transistor 35 is only 50Ve of the output signal, the

gen, since the resistance of the emitter-collector circuit amplifier (53, 59, etc.) has a gain

ses of transistor 21 decreases. If the input falls from 2 to maintain the oscillation,

current of the transistor 35, the resistance increases. The gain factor depends on the size of the

this transistor too. As a result, the 50 negative feedback resistances 41, 49 and 47 as well as the increases

Voltage in the properties of the unipolar transistor 35 (described below) is determined.

Negative feedback loop, so that the increase in the ampli A certain adjustability is possible through the potentio

tude of the oscillator output voltage compensated meter 53 and the resistor 51 given,

will. The thermistor 47 is a temperature sensitive one

Geeenkoopluneskreis ^{55 Resistance with} positive temperature coefficient; the

. Resistance of the .Unipolar transistor 35 changes

The damping transistor 35 is connected to the temperature in a predictable manner via a coupling capacitor 39 and a resistor 41 to the base of the transistor 43 in the amplitude of the oscillator output. The emitter signals cause a certain temperature drift, the transistors 43 and 59 are connected to one another and 60. This is compensated for by the compensating resistance via a resistor 57 with the change in the switching point of the thermistor 47.
95 connected to a negative DC voltage source of, for example -12 volts. Quantitative Considerations
is. A 100% DC voltage negative feedback

The control signal from the output terminal 94 is over 65. In a practical implementation of the

a potentiometer 53 and a resistor 49 (so-drawing shown oscillator circuit were

as, if applicable, via the dashed line with components with the following values and

Thermistor 47) of the base of the transistor 43 tensile properties achieved very good results:

Component no. Size or name 7th 2N404A 8th 2N404A 9 2N3638 21 2 N 3638 35 2 N 2646 43 2N3416 59 2N3416 69 2 N 3638 77 2 N 2270 83 2 N 2306 87 2N3638 10 39,000 ohms 12th 100 ohms 11th 1N34 13th 0.015 nF 14th 1000 ohms 15th 47,000 ohms 17th 2,, F * 19th 33,000 ohms 23 10,000 ohms 25th 0.22 μΡ 27 270 ohms 29 1800 ohms 31 5000 ohms 33 1000 ohms 37 IN 707 39 30 _t tF 41 7500 ohms 45 100 | tF 49 6800 ohms 51 3000 ohms 53 2000 ohms 55 4700 ohms 57 12,000 ohms 61 4700 ohms 63 10,000 ohms 65 0.015 uF 67 270 ohms 71 1N461 73 1N461 75 3900 ohms 79 0.03 | iF 68 22 ohms 81 10 ohms 86 22 ohms 85 5000 ohms 88 10 _t .F 89 15 ohms 91 0.03 [tF

The above values were used in a circuit operating at 1 kHz to produce a 40 ohm output to produce 6 volts at a current of 0.15 amps. It was a very high one Amplitude stability of the output signal, namely in the order of 1: 2000 over a wide area Temperature range achieved. At the same time, a very good frequency stability, namely in the Of the order of 0.1% achieved without the need to use a crystal.

The desired amplitude of the oscillating output wave could be achieved by regulating the reference input voltage at terminal 5 without further ado

ίο Stabilize to any desired voltage. Included However, it should be noted that this reference input or control voltage at terminal 5 is not a DC voltage needs to be. Rather, a signal with a variable amplitude can also be used.

with which the output signal of the oscillator is modulated. This may be desirable in certain cases, for example in which a signal representing the deflection of a transducer or sensor is transferred to a amplitude-modulated oscillation wave is to be implemented.

Claims (5)

Patent claims: 1. Amplitude-controlled oscillator in which the oscillator output voltage is matched to a DC reference voltage is compared and a DC voltage error signal is generated from the difference signal in a conversion stage, which a solid-state element influencing the amplitude of a negative feedback signal with a variable Impedance controls, characterized in that the conversion stage has a first Circle (9) for generating square-wave pulses, the width of which is a function of the difference signal is, a second circle (12, 13, 15) for generating triangular pulses, their DC voltage level is a function of the width of the square pulses, as well as a third circle (17, 19) for generating the DC voltage error signal by integrating the triangular pulses and the solid-state element (35) the negative feedback signal in direct proportion to the DC voltage error signal changes. 2. Oscillator according to claim 1, characterized by one between its output (94) and its input (59) switched on positive feedback loop, which is one of the negative feedback loop (53, 51, 49, 35) comprises essentially independent Vienna Bridge (91, 85, 65, 63). 3. oscillator according to claim 1, characterized in that that it is directly coupled. 4. Oscillator according to claim 3, characterized by a circle (77, 83) for generating a Push-pull output signal. 5. oscillator according to claim 1, characterized in that the solid-state element (35) is a unipolar transistor. 1 sheet of drawings