DE1289887B - Oscillator switching with a transistor with an electromechanical oscillator that stabilizes the frequency of the high-frequency electrical oscillations to be generated in the oscillator circuit and with an electrical resistor that stabilizes the DC operating point - Google Patents

Description

The invention relates to an oscillator circuit with a transistor, with an electromechanical transducer that adjusts the frequency of the oscillator circuit to be generated high-frequency electrical oscillations stabilized, and with a The electrical resistance stabilizing the DC operating point.

It is known, frequency-stabilized oscillator circuits with transistors and to build up quartz crystals. These circuits have the property that they when switching on and off because of the high quality of the oscillating crystals an intended Change of the vibration energy only with a delay, d. H. with one corresponding to the quality Follow up and decay process.

The object of the invention is to provide a simple electrical circuit arrangement to generate high-frequency, frequency-stabilized electrical energy, when entering rectangular or almost rectangular direct current pulses emits at least approximately the same rectangular output pulses.

Another object of the invention is dialing pulses, in particular such a well-known dial of a telephone self-dialing device, into equivalent pulses of high-frequency, frequency-stabilized, electrical power to convert.

Another object of the invention is to provide an electrical circuit arrangement specify with which both low-frequency signals of limited bandwidth are amplified as well as direct current square-wave pulses, in particular dial pulses, with a repetition frequency less than the frequency of the low-frequency signals with low distortion in the carrier frequency position a stabilized frequency can be implemented.

These tasks are performed individually or together by an electrical Oscillator circuit solved, which is characterized according to the invention in that for converting these predetermined pulses in the frequency-stabilized oscillator circuit parallel to the resistor an R-C element with a series connection of capacitance and ohmic resistance is provided, their electrical values depending on the specified electrical values of the other switching elements of the circuit and depending on the predetermined pulse repetition frequency F, are dimensioned so that the edges the envelope of the high-frequency pulses at least almost the edges of the input, reproduce the pulses to be converted and that the operating bandwidth d f of the electromechanical Schwingers is damped so that J f is greater than 2F.

In particular, the R-C element is electrical in the invention Circuit arrangement only a series connection of capacitance and resistance. Preferably is the electrical circuit arrangement according to the invention with only a single one Transistor equipped. For the preferred carrier frequency range of the invention Arrangement above about 1 MHz is the mechanical one that stabilizes the frequency The oscillator is preferably an electric oscillating crystal.

From "Flug-Modell-Technik", issue 48, p. 26, a circuit is known, in which a resistor and a capacitance are connected in parallel to one another in the emitter circuit are. Apart from the fact that in this known circuit there is no rectangular keying whatsoever according to the objects underlying the invention is provided is also on Hand of the parallel connection and the dimensions specified there to recognize that these tasks are not even inadvertently achieved by the known circuit would be.

The US Pat. No. 2,639,387 in FIG. 1 specified circuit contains, among other things, a capacitance and one labeled 3 in the cathode circuit Resistance that can be seen as connected in series. However, there are also these Patent specification neither a reference to: the tasks underlying the invention, it can still be seen that the circuit according to the aforementioned F i g. 1 such Could solve the task at least inadvertently. As stated there, the designated 3 has Resistance together with the resistance marked 4 expressly has the task of To make stray capacitances in the area of the quartz crystal harmless.

The arrangement known from US Pat. No. 3,227,968 is for a frequency modulation of the oscillator frequency is determined. It also contains a circuit with resistance and capacitance in the emitter circuit. One problem according to the invention and / or teaching can not be found in the patent specification.

The invention is based on the following considerations and studies from: The aim was to use the least amount of electrical components possible a device for the carrier-frequency combination of many individual low-frequency ones Voice channels for transmission on a coaxial line or a pair of coaxial lines build up. So that the individual adjacent channels are in the carrier frequency position in Operation never overlap, provision was made for the individual oscillators that were used to Generation of the carrier frequency signal are provided, each for itself alone with one Sufficient frequency-constant electromechanical oscillators, such as a quartz oscillator, to stabilize. Quartz crystals are for the frequency range above about 1 MHz with the frequency accuracies required for this transmission system of approximately ± 1 kHz without great effort.

The task now remained, not just for each individual Voice channel, but also the dialing signals of the individual subscriber, d. H. DC square-wave pulse trains for transmission on the coaxial line in the same carrier frequency position. So that these carrier-frequency dialing pulses at the receiving location from the conventional facilities can be processed without errors, it is necessary that with this Implementation in the carrier frequency position no disturbing character distortion occurs, d. H. there is no impermissible smoothing of the pulse edges.

It was intended as a first special step, this impulse implementation by changing the oscillation amplitude of the oscillator in a controlled manner between .the desired amplitude value of the carrier-frequency pulses and a on the other hand to make a much smaller resting value. The amplitude value of the pulses is also chosen to be equal to the carrier amplitude of the converted LF signal. It turned out However, difficulties in the implementation due to the fact that the edges of the pulses were still unacceptably heavily ground in spite of the rest oscillation. This lack but could according to the task by a measure that is not very complex in itself be remedied by the operating point stabilization, d. H. DC stabilization of the transistor of the oscillator provided emitter series resistor according to the invention was bridged by a series connection of capacitance and resistance. By selection of the cheapest capacity in each case, which can be made without difficulty and resistance values, for example by calculation or, much more simply, by trial and error, can completely eliminate the character distortion in the carrier-frequency pulses according to the task satisfied.d be eliminated. The exact rated values depend on the In individual cases, not only from the desired sequence of pulses, e.g. B. 20 to 20 msec = 25 Hz or 50 to 50 msec = 10 Hz pulse frequency, but also from the respective size of the emitter series resistor, which in turn is essentially in turn depends on the transistor used in each case.

The DC operating point is to be selected so that the oscillation amplitude for the respective collector load resistance always on the voltage axis (collector current = 0) and a modulation up to the range of the current axis (collector voltage = 0) is avoided. By crossing the current axis, in particular the transistor will be destroyed.

Due to the effect of the R-C element to be provided according to the invention, among other things, the working point is continuously shifted during the scanning process. Of the The time course of this shift results from the method as described above according to the invention electrical values to be selected for the two quantities of the R-C combination.

Further details of the invention emerge from one in the figures illustrated, particularly preferred embodiment of the invention.

1 is a transistor, e.g. B. of the type 2 N 247, with for the intended carrier frequency, which in the case of this example is in the range of about 1 to 10 MHz, in the emitter circuit still sufficiently high cutoff frequency. 2 are connection terminals for a direct current source of, for example, about 24 V. The base bias voltage for the quiescent oscillation was set for quiescent operation, ie if no carrier frequency signal is to be picked up, with a collector current of about 0.7 mA. 4 is also the terminating resistor for the bandpass filter and is therefore dimensioned accordingly.

Resistor 7 is provided with about 1 kOhm to stabilize the operating point. A higher collector current of around 2.5 mA is provided for operating the circuit arrangement as an oscillator, amplifier and modulator, in the example for converting the low-frequency signal of a carbon microphone sent to terminals 8 into the desired, corresponding carrier-frequency signal to be sent to terminals 9. It is set by shifting the operating point. This shift of the operating point is brought about by an additional voltage drop across the resistor 10 with, for example, 100 ohms. This drop occurs when the circuit 10, 11, 2 is closed with a resistance value at 11 which allows a direct current of about 20 mA to flow through the resistor 10. In the present case, this resistance value is made up of the microphone direct current resistance and an additional series resistor that stabilizes the direct current. The operating values of the circuit are dimensioned in such a way that the vibrations are limited on the voltage axis of the characteristic field.

For the above-mentioned application of the special one described here In the exemplary embodiment, terminals 8 and 11 were connected in parallel with one another. Capacitors in bandpass filter 12 for the incoming low frequency signal and chokes at 11 separate direct current and alternating current paths in the input of the circuit from one another.

21 is an oscillating circuit, consisting of a coil and capacitor, the together on the desired carrier frequency, here z. B. about 2 MHz, are tuned. 22 is an output transformer for adaptation to the characteristic impedance of the transmission system. In the present example, the resonant circuit had a bandwidth of about 10 up to 20 kHz, sufficiently wide for the 300 Hz to 4 kHz bandwidth of the band pass 12. 23 is the one in the feedback circuit of the circuit with 24 to the resonant circuit 21 coupled quartz. When a DC voltage as provided is applied to 2, it oscillates the circuit as an oscillator at the intended frequency. 13 and 26 are capacities to short circuit 7 and 2 for the high frequency.

For the intended operation of the circuit both as an amplifier and modulator for a low frequency signal with a certain minimum frequency of z. B. about 300 Hz as well as for the independent generation of carrier-frequency pulses, in the present case the dialing signal pulses, with a pulse repetition frequency that is less than the minimum frequency value of the above low-frequency signal, a very specific dimensioning of the crystal with its circuit connected to it is provided. As a series resonant circuit, the quartz 23 normally has a quality factor of over 105. According to the invention, an additional series resistor 25 dampens it for operation in the circuit so that on the one hand it still has a bandwidth that is so small that it encounters the sidebands in 21, which are from originate from the low-frequency signal at 8 , practically no longer feeds back to the base of transistor 1, but on the other hand allows the sideband frequencies, which correspond to the pulse repetition frequency at 11, to pass to the base of 1 as undamped as possible.

Resistors in direct electrical connection with an oscillating crystal include British patent 644 086, French patent 907 944 and U.S. Patent 2,639,387, already cited above. These patents but there is no indication that the resistances are used for damping purposes of the transducer would be provided.

The British patent relates to a self-controlled generator for generating a periodic sawtooth voltage, using the provided Quartz stabilizes the exact use of each increase in voltage independently is.

For the USA. Patent, the meaning is the one in question here Resistors have already been explained above.

The resistor in question in the circuit according to the French Patent specification is provided to avoid excitation of undesired frequencies. He has, as far as recognizable, essentially due to the size ratio specified there no dampening effect.

Avoiding the feedback of the sidebands of the low-frequency signal has proven to be advantageous for stabilizing the input operating point. The feedback of the sideband power from the pulse repetition frequency, on the other hand, turned out to be necessary in order to achieve the task-related rapid oscillation of the oscillator when the voltage drop across the resistor 10 is pulsed. The measures described so far were by no means sufficient to avoid the character distortions of the carrier frequency pulses emitted at 9, which are inevitable due to the quality of the quartz, as described above, which should correspond to the direct current square pulses applied to 11. To solve this problem, according to the invention, an RC element 31 is provided in the emitter circuit, the capacitance and resistance value of which is calculated as a function of the other values of the circuit, in particular as a function of the pulse repetition frequency, the bandwidth of the quartz and of the resistor 7, as well as, which is essential is simpler and completely sufficient, can be determined by practical experiment.

The F i g. 2 and 3 respectively show the image of the oscillograms which are connected to 9 in the circuit described above for a square-wave pulse train of 10 Hz and 25 Hz respectively. The figures give the envelopes of the high frequency again. In the area 51 the oscillator oscillates at about 0.7 in its rest position mA collector current. When the external circuit is closed as indicated above 11 is set by changing the operating point based on the then occurring at 10 additional voltage of about 2 V in the steady state a collector current of about 2.5 mA. This collector current corresponds to that shown in the figures Amplitude height of area 52. Without the R-C element provided according to the invention 31, however, this amplitude value would only increase slowly, like that entered in 52 Line 55 indicates can be reached. But this distortion of characters would be in many Use cases, e.g. B. to control a voter, intolerable. Through the R-C link is achieved, in the present example with 2 gF and 150 ohms, that it increase of the carrier-frequency pulse is practically perpendicular compared to the pulse duration. The figures show a slight overshoot at the beginning of the impulse, which is adjustable in size by the R-C link and that with about 5 to 100 / a is dimensioned particularly advantageous for the application. Then at the end of the Pulse 52 is a gap in the oscillation at 53 due to the effect of the R-C link. This gap is just like the minor overshoot advantageous because it means that the end of the Impulse is particularly clearly effective. This is advantageous when the circuit device, z. B. a relay, when transitioning from the high to the lower vibration level would not fall off safely yet. A lack of the R-C link in the inventive Circuit would, however, a fading of the pulse, as the line 56 indicates, have as a consequence. For the task and according to the invention functioning of the arrangement of the invention, the oscillation in the idle state of the circuit is essential because through it ensures the exact timing of the onset of the pulse. The resistance 27 with about 300 ohms and the capacitance 28 with about 1 nF form a high frequency Short circuit of resistors 3, 4 and 10, which is responsible for the decay of the oscillating Vibration has an advantageous effect when reducing the collector current. 29 is under among other things, a blocking resistance of about 100 ohms for the high frequency.

Claims (9)

Claims: 1. Oscillator circuit with a transistor, with an electromechanical oscillator that stabilizes the frequency of the high-frequency electrical oscillations to be generated in the oscillator circuit, and with an electrical resistor that stabilizes the direct current operating point, characterized in that for converting predetermined pulses with steep edges and with a predetermined pulse repetition frequency into corresponding pulses of the frequency-stabilized, high-frequency electrical oscillations in this oscillator circuit parallel to the resistor (7) an RC element (31) with a series connection of capacitance and ohmic resistance is provided, the electrical values of which depend on the specified electrical values of the other switching elements of the circuit and depending on the predetermined pulse repetition frequency F, are dimensioned so that the edges of the envelope of the high-frequency pulses at the output (9) at least almost the edges of the input, umzuwa Play changing pulses (14) and that the operating bandwidth d f of the electromechanical oscillator is damped so that d f is greater than 2 F. 2. Oscillator circuit according to claim 1, characterized in that it contains only one transistor (1) . 3. oscillator circuit according to claim 1 or 2, characterized in that that the R-C element (31) only consists of a series connection of capacitance and ohmic Resistance exists (Fig. 1). 4. oscillator circuit according to claim 1, 2 or 3, characterized in that the mechanical oscillator (23) is a quartz oscillator. 5. oscillator circuit according to claim 1, 2, 3 or 4, characterized in that the operating bandwidth of the oscillator by adding an electrical resistor (25) is damped. 6. Oscillator circuit according to one of claims 1 to 5, characterized characterized in that the frequency of the high-frequency electrical oscillations is greater than about 1 MHz. 7. Oscillator circuit according to one of claims 1 to 6, characterized characterized in that a voltage divider (3, 4) is dimensioned in the input so that in the pause between two consecutive pulses before the start of the pulse high-frequency oscillation is present, the amplitude of which is several times smaller than that Amplitude of the impulses of the high-frequency oscillations. B. Oscillator circuit according to one of Claims 1 to 7, characterized in that for amplification and conversion of an additional low-frequency signal (at 8) with a lowest frequency greater than the pulse repetition frequency F in the frequency position of the high-frequency oscillations, the operating bandwidth d f of the mechanical oscillator (23) is selected to be less than twice the lowest frequency of the low-frequency signal. 9. Use of an oscillator circuit according to one of claims 1 to 8, characterized in that the pulses to be converted into pulses of frequency-stabilized, high-frequency electrical vibrations are signals (14) of a self-selection device.