CS239475B1 - Connection of frequency modulator for reactance sensors - Google Patents

Abstract

My frequency modulator (29) is tuned oscillator (22) and capacitive or inductive feedback feedback reactance of, for example, condensers (15 and 16), connecting! rectal outputs sensors (28) interconnecting the first inductive coil 14), with a collector and over the other resistor (19), with second transistor base (17) amplifiers (6). His emitter is connected first through the resistors (20 and 7) to the first input of the output a frequency modulator terminal (9) (29), first through a third resistor (20) and a stabilizer (21) to the second input-output terminal (10) and on one of the condenser terminals (15 and 16) and on the basis of the first transistor (β) the separation stage (23) of which the emitter is connected to the first input-output a terminal (9), and whose collector is connected to a second input-output terminal (10). On the clamps (9 and 10) is provided with an output signal of the decayed oscillator (22) from its signal- output (12) and input-output (13) and second power is supplied to them from power input (II) and amplifier input-output (13) (6).

Description

BACKGROUND OF THE INVENTION The present invention relates to a frequency modulator for reactive transducers that allows connection to a circuit for processing their output signals through a single, usually coaxial, connection line.

When reactive transducers are used in the measurement technique, the transducer reactivity is converted to the instantaneous frequency of the output signal of the frequency modulator. The frequency modulator is usually located near the rectangular transducer and is separated from its own signal processing circuits.

The reactance transducer is connected to a frequency that determines the inputs of the frequency modulator. Correct operation of the frequency modulator circuits requires connecting the power supply to the tuned oscillator power supply terminals.

Hitherto known frequency modulator circuits consist of a tuned oscillator and frequency modulator output circuits. The reactive transducer is connected in parallel to the circuit elements of the resilient oscillator, which determine the magnitude of its carrier frequency, which circuit elements are connected to the collector of the transistor, which forms the amplifier of the tuned oscillator.

The output circuit of the frequency modulator is formed by a decoupling amplifier that reduces the influence of a load, such as a coaxial connection line, on the frequency of the tuned oscillator.

The supply voltage from the power supply is connected to the supply voltage terminals of the frequency modulator by special conductors. The connection between the output terminal of the frequency modulator and the input terminal of the processing circuits is typically made by a coaxial connection line.

A disadvantage of known frequency modulator connections for reactive sensors is that they require a connection to the power supply over separate separate wires via plug-in connections and a frequency modulator connection and its output signal processing circuits over a coaxial connection line, thereby reducing the reliability of the frequency modulator usage. The effort of connecting the frequency modulator to the measuring technology systems is increasing.

These disadvantages are overcome by the wiring of a frequency modulator for the reactance sensors according to the invention. The principle of the invention is that the first output of the reactance sensor is coupled to a first frequency determining input which is connected both to the output of the tuned oscillator amplifier and secondly to its first input coupled to its second input via the second feedback reactance; on the other hand, through the frequency determining the reactance to its second input and to the second frequency determining the input common to the frequency modulator and the tuned oscillator and connected to the second output of the reactance sensor. The supply voltage input of the tuned oscillator and amplifier is connected to the output stage of the decoupling stage, which is connected to one end of the first resistor, the other end of which is connected to the first vatup-output terminal common to the decoupling stage and frequency modulator. first transistor. Its base is connected to the signal output of the tuned oscillator and amplifier, and its collector is connected both to the other input-output terminal common to the isolation stage and the frequency modulator, and to the input-output of the tuned oscillator and its amplifier.

A first alternative embodiment of the invention distributes the internal circuit of the amplifier to the second transistor.

The second alternative has a first and a second feedback reactance formed by the first and second capacitors and a frequency determining the reactance of the first inductor.

A third alternative embodiment has both feedback reactances and a frequency determining reactance formed by four inductors.

The advantage of connecting the frequency modulator for the reactance sensors according to the invention is that by using a decoupling step, both the power and signal output of the fly-off oscillator and its amplifier are united at its first input-output terminal, and that together with the feedback reactances and the frequency determining The circuit of the fly-off oscillator is achieved by connecting the input-output of the fly-off oscillator and its amplifier to the second input-output terminal of the frequency modulator, thereby enabling its connection with the output signal processing circuits e with the supply voltage via a single two-line, usually coaxial connection line.

Examples of frequency modulator connections for reactive sensors, in particular capacitive sensors, are shown in the drawings, wherein FIG. 1 is a block diagram, FIG. 2 shows an alternate circuit with capacitive coupling of a fly-away oscillator, and FIG.

The first output of the reactive transducer 23 is coupled to a first frequency determining input 6 common to the frequency modulator 21 and its spun oscillator 21 * forming the first of its internal circuit blocks, the first frequency determining input 8 being connected to the amplifier output 8 of the spun oscillator 22. , on the one hand through the first feedback reactance na to its first input coupled to its second input through the second feedback reactance a and, secondly, through the frequency determining the reactance na to its second input and the second frequency determining the input 2 common to the frequency modulator 22 and the oscillator 22 and connected to the second output of the reactive transducer 22, and the power input 48 of the supply voltage of the amplified oscillator 22 e is coupled to the power output of the decoupling stage 22 forming the second of the internal modulator circuit blocks 22 ' The output output within the decoupling stage 26 is connected to one end of the first resistor 6, the other end of which is connected both to the first input-output terminal fi common to the decoupling stage 22 and the frequency modulator 22 to the emitter of the first transistor fi. Its base is connected to the signal output £ of the spun oscillator 22 and amplifier fi, and its collector is connected both to the other input-output terminal £, common to the decoupling stage 22 and the frequency modulator 22, and to the input-output £ 22 and its amplifiers fi.

The output of the amplifier f1 is connected within its internal circuit to the collector of the second transistor 60, whose base is connected, FIG. 2, in parallel via the second resistor F2 and the third capacitor 18 both on the second input of the amplifier f1 and on the other And whose emitter is connected both to the first input of the amplifier fi and to its signal output £ 2 and not to one end of the third resistor 20, the other end of which is connected both to the power input input £ of the amplifier fi and or a fourth capacitor P1 at its input-output P1.

In the third alternative of the inductive coupling of the tuned oscillator 22 ' Fig. 3, the fourth capacitor 24 is connected between the second input of the amplifier fi and its input-output fi before the second resistor 11fi and the stabilizer 21 are not connected. In the embodiment of the invention, the first capacitor £, the second feedback reactance je is formed by the second capacitor f, and the frequency determining the reactance fi is formed by the first induction coil £. The first feedback reactance 6 according to the third alternative embodiment of the invention consists of a third induction coil 2fi, a fourth induction coil 2fi and a mutual inductance M1 between them, one end of the third induction coil fi fi connected to the output of the amplifier fi and its opposite end connected to its input - exit ££. The second feedback reactance je is formed by the second inductor £, the fifth inductor 21 and the mutual inductance M 2 therebetween, one end of the second inductor £ being connected to the first input of the amplifier fi and its opposite end connected to its second input. The frequency determining the reactance fi is formed by a fourth induction coil 20 and a fifth induction coil 21, which are interconnected at one end thereof.

239475 4

Rozlaďovaný feedback oscillator 22 »Fig. 1, the frequency designated by the frequency oacilační determining reactance of the reactance impedance sensor GA 2 g> is connected to a frequency determining inputs 1 and 2, ^b y ^{and b} y ^la observed phase condition of oscillation. The amplitude condition is ensured by the ratio between the feedback power J and i so that from the output of the amplifier g via feedback feedback jai to the input voltage applied after amplification in the amplifier &, it is sufficient to replace the energy dissipated at the frequency Jg to maintain the oscillation of the tuned oscillator 22 ·

The output voltage from the signal output 12 is applied to the first input-output terminal g through a first transistor g in which the output voltage of the tuned oscillator 22 is interpolated to the supply voltage such that the power supply current flows through the first port X, the input 11 and the input. The output current of the tuned oscillator 22 flows through the first transistor g and through the output terminals 2 and Jg to the processing circuits.

The capacitive divider, Fig. 2, works by applying a certain amount of voltage from the collector of the second transistor 17 to the emitter so that even a random noise causes the tuned oscillator 22 ^to oscillate ^{at a} frequency determined by the inductance of the first inductor Jg and . The supply voltage for the second transistor JX is stabilized by a stabilizer 21 in the form of, for example, a Zener diode. The capacitor 22 represents an alternating short circuit at the operating frequency of the tuned oscillator 22 mesi by the power input H and the input-output 13. wherein the second input of the amplifier g is connected directly to its input-output Jg. The second resistor 19 and the third resistor 22 set the operating point of the second transistor Jg.

For rozlaďoyanáho oscillator 22 ⁸ inductive feedback, Fig. 3, produces a voltage induced to the fourth inductor 22 * third inductor 22 current that usavře through reaktančnl sensor 22 ⁸ via the fifth inductor 21 · When ^{tonnes 8e 8 of} the fifth inductor 21 to the second inductor 22 induces a voltage which, after amplification in the second transistor IX, induces a suitable phase voltage in the fourth inductor 22 and returns the emitter of the second transistor IX as described above, thus giving positive feedback and oscillating the tuned oscillator 22 In the second transistor IX, the voltage generated by the tuned oscillator 22 is converted via the first transistor g to the first input-output terminal g.

The impedance of the reactive sensor 2g> used for this alternative must be capacitive. The capacitor gg represents an alternating short circuit at the operating frequency of the tuned oscillator 22 between the second input of the amplifier g and its input-output Jg, the second input of the amplifier g being connected to its power input Jg.

The connection of the frequency modulator according to the invention is particularly intended for capacitive sensors in measuring technology. Another application is in the transmission of an output signal from a condenser microphone, possibly for reactance sensors, which are sensitive to the approach of foreign objects.

Claims (4)

1. Connection of a frequency modulator for reactive sensors, consisting of a tuned oscillator connected by its input to the output of the reactive sensor and of a decoupling stage connected by its input to the output of the tuned transmitter and its output via coupling interference to the frequency modulator output signal processing circuits; characterized in that the first output of the reactive transducer (28) is connected to a first input (1) common to the frequency modulator (29), and its rejuvenated oscillator (22) forming the first of its internal circuit blocks, the first input (1) connected to the output of the tuner (6) of the tuner (22), through the first feedback rectality (3) to its first input connected to its second input via the second feedback rectangle (4), and through the reactance (5) and a second input (2) common to the frequency modulator (29) and the difference the oscillator (22) and connected to the second output of the reactance sensor (28), while the power supply input (11) of the tuned oscillator (22) and the amplifier (6) is connected to the power output of the isolation stage (23) a frequency modulator circuit (29), the power output inside the isolation stage (23) being connected to one end of the first resistor (7), the other end of which is connected to the first input terminal (9) common to the isolation stage (23) and frequency a modulator (29) and, on the other hand, an emitter of a first transistor (8) whose base is connected to the signal output (12) of the tuned oscillator (22) and the amplifier (6) and whose collector is connected to the second input-output terminal (10) , common to the decoupling stage (23) and the frequency modulator (29), and to the input-output (13) of the tuned oscillator (22) and its amplifier (6). Frequency modulator circuit according to claim 1, characterized in that the output of the amplifier (6) consists of a collector of a second transistor (17) whose base is connected via a second resistor (19) to the second input of the amplifier (6) and to its input. - outlet (13), whose emitter is connected both to the first input of the amplifier (6) and to its signal output (12) and to one end of the third resistor (20), the other end of which is connected to the power input (11) the amplifiers (6) are, on the one hand, parallel to the input-output (13) via the stabilizer (21) and / or the fourth capacitor (30). 3. The frequency modulator circuit according to claim 1, wherein the first feedback reactance (3) is formed by the first capacitor (15), the second feedback reactance (4) is formed by the second capacitor (16), and the frequency determining the reactance (5) is formed. the first induction coil (14). 4. The frequency modulator circuit according to claim 1, characterized in that the first feedback reactance (3) is formed by a third inductor (25) and a fourth inductor (26) with mutual inductance M 1 therebetween, one end of the third inductor (1). 25) is connected to the output of the amplifier (6) and its opposite end is connected to its input-output (13) and the second feedback reactance (4) is formed by the second inductor (24), the fifth inductor (27) and the mutual inductance M 2 between them, wherein one end of the second inductor (24) is connected to the first input of the amplifier (6) and its opposite end is connected to its second input, while the reactance (5) is formed by the fourth inductor (26) and the fifth inductor (27), which are interconnected at one end.