DE944021C - Overlay receiver for frequency shift telegraphy with automatic frequency correction - Google Patents

Description

Overlay receiver for frequency shift telegraphy with automatic Frequency correction The invention relates to a heterodyne receiver for Frequency shift telegraphy, a local oscillator and a frequency corrector to automatically correct the receiver tuning according to the transmission frequencies which contains telegraph signals.

It is known in such receivers the received telegraph signals to generate a control voltage for the frequency corrector two biased Feed limit frequency detectors for the resting or working frequency, their response frequency ranges narrowly enclose the nominal frequency shift range.

The invention aims at a simple and reliable frequency conversion circuit for such heterodyne receivers in which the frequency correction when receiving of signal signs is essentially independent of the ratio of the times, during which the work and rest frequencies occur, and also for long periods. Pauses, i.e. if the resting frequency occurs for a long time, the receiver tuning automatically is corrected.

According to the invention, the initially controlled with heterodyne receivers mentioned type the telegraphic characters demodulated by frequency demodulation Delays responsive, unresponsive to the normal telegraphic character sequence Break relay that, when responding, biases the frequency detector for the working frequency restricted so that the response range - the same is shifted in the direction of the rest frequency.

The frequency files to be used for the work or rest frequency can be equipped with tuning circuits that are tuned to frequencies, which closely enclose the nominal resting and working frequencies of the signal signs; the Frequency detectors only deliver an output current because of their bias voltages or an output voltage if. .the deviation of the work or rest frequency of the receiver tuning frequency exceeds the maximum nominal value. Züni correct The WiTkui'ngsbereicih can then tune the receiver during a signal pause of the frequency detector for the working frequency by means of the Pawsenretai @ s to the Be shifted near the idle frequency.

In a receiver according to the invention, which has proven itself in practice the biased detectors each contain one normally biased Blocked, grid-controlled electron waves and the demodulated telegraph characters were fed to the control grids of these tubes in push-pull.

Using the Fiig. i and 3; the advantageous design of an overlay receiver represent according to the invention, and a frequency diagram according to Fig.2, the Invention explained in more detail, for example.

According to Fig. I control the m-it a receiving antenna i received Vibrations via a tunable high-frequency pre-amplifier 2 to a tunable first local oscillator 4 connected mixer 3 The extracted intermediate frequency is transmitted via a permanently tuned dual frequency amplifier 5 to a stage 7, with one connected to a second local oscillator 6 second mixer, a second intermediate frequency amplifier and a frequency demodulation circuit .guided. The output circuit of stage 7 contains two resistors connected in-line 8 and 9, on which the received demodulated telegraphy pulses in push-pull appear.

The telegraphy pulses appearing at resistor 8 are practiced one below. described reversing switch io and a GiiterstrombegTenzungswidemstand i i led to a pentode amplifier with pentode 12. The. the pentode 12, taken amplified telegraphic pulses are sent to a trigger circuit for further amplification of in itself. known type out, the two triodes 13 and 14 with a common Cathode resistance. 15 contains. When receiving the - working frequency and a. - resulting Increasing the anode current of the pentode 12 becomes the s @ euergitter of the triode-13 one this blocking negative grid voltage is pressed, und.dieTriode 14 leads the full anode current; when receiving the quiescent frequency, the anode current is the pentode 12 low, and the control grid of the triode 13 receives such a potential that the triode 13 carries the full anode current and the triode 14 is blocked. The anodes: -the triode 13. and 14 are in push-pull to exciter windings of a polarized Relay 16 switched on. The relay 16 controls, as shown schematically, one pen 18 arranged above a movable recording beam 17, to reproduce the received telegraphic impulses.

For the automatic correction of the receiver tuning according to the central frequency of the received characters, a frequency corrector of the type without restoring force is coupled to the frequency-determining circle of the local oscillator 6. This has a regulating capacitor. The frequency corrector 19 is provided with excitation windings 26 and 21, of which, depending on the required correction, either one or the other is excited. The magnetic field of these windings influences the position in the axial direction in a liquid-filled glass tube 22, movable, piston-shaped metallic control element 23 with a centrally arranged soft iron ring 24 Movement is unable to follow the sign rhythm. The metallic regulating element 23 forms a dummy electrode in a regulating capacitor with coatings 25, 26 arranged on the glass tube 22; this regulating capacitor is z. B. connected in parallel to the frequency-determining circuit of the local oscillator 6 and has a capacity dependent on the position of the control element 2.3 in the pipe 22.

In order to keep the receiver tuning automatically in line with the transmission frequencies of the telegraph signals, the frequency corrector i9 is controlled in accordance with the telegraph pulses received. Those occurring at the output resistors 8 and 9 of stage 7. Telegraphic pulses are demodulated via the Umpolsohalter io. in push-pull to two control grids of the triodes 27 and 28 which are normally blocked by a bias voltage. The. Reverse biasing of these tubes is tapped off by a voltage divider 29 which is located in a cathode line common to the two tubes and is connected to the positive pole of the anoid voltage source via a resistor 30. When telegraphic pulses are received, the cathodes of the two triodes a7, 28 are connected to the connection point of the resistors 29 and 3o.

The locking bias of the triodes 27 and 28 is related to the size of the voltages occurring in push-pull across resistors 8 and 9 selected, because B when receiving telegraphic signals and when the receiver is correctly tuned. none of the triodes carries anode current. As soon as, but by an annoyance of the recipient in the direction of the rest frequency of the received -Telegrap @ hieimpulses at the resistor 8 at. Receipt of the working frequency an abnormally high voltage occurs while this time the reverse bias of the triode 27 is overcome, and this thus leads to anode current during the occurrence of the operating frequency. this carries out the excitation of a relay 31 located in the anode circuit of the triode 27. Working contact 32, via which the excitation winding 2o of the frequency corrector i9 is connected to the anode voltage source lies. The excitation of the frequency corrector i9 by means of the excitation winding 21 causes a change in the receiving mood in the direction of the working frequency of the received Telegraphy pulses, which leads to a reduction in the working frequency voltage occurring at the resistor 8 leads. As soon as the working frequency voltage at resistor 8 up to its nominal maximum value drops, the triode 27 no longer carries an anode current, the relay 31 drops out, and the normally open contact 32 is opened. There will then be no further change in the recipient vote on.

Similar to the above in connection with the reception of the working frequency of the telegraphic impulses, a correction of the receiver tuning occurs in the opposite direction as soon as the nominal value of the resistor 9 occurs Idle sequence voltage is exceeded. The triode 28 is then energized and a relay 33 located in its anode line responds to its normally open contact 34 turns on the excitation winding 21 until the quiescent frequency voltage on Resistance 9 has dropped to its nominal maximum value.

To a rattle of in that. Anode circles of the triodes 27 and 28 lying Relays 31, 33 to beware, these relays are equipped with a short-circuit winding, as shown schematically in the drawing.

For a more detailed discussion of the above-described effect of the correction means for receiver tuning, reference is made to FIG. 2a. In this figure, f "represents the central frequency of the received telegraphic pulses and also the correct tuning frequency of the receiver. The nominal working and resting frequencies of the received telegraphic characters are denoted by f," and f, respectively. The triodes 27 and 28 connected in the opposite contact to the common frequency demodulation circuit in stage 7 form biased detectors for the working or resting frequency, their response frequency ranges F, "and F, in . f., closely enclose. Once from incorrect receiver tuning either the Ansprechfrequenzbereich F, or Arnsprechfrequenzbereich F, "f in the nominal frequency shift range, -f" device, a correction of the receiver tuning until the biased Frequenzdietektoren Ansprechfrequenzber-oak the displacement range of the received telegraphic impulses again.

To the bias of the. Frequency detectors, with the triodes 27 and 28 to adapt to the nominal frequency shift of the received telegraphic pulses, the resistor 29 is designed to be controllable by means of a displaceable end contact 35. To an optionally occurring transmitter side Vertaüschung the rest position and the operating frequency of the tele @ g. Raphischen mark at the receiver Fig naich to follow i, 27 and 28 of Umpolschadter io is provided in the control grid of the triode leads.

During a signal pause, the resting frequency of the telegraphic pulse is constant received, and here the receiver shown in Fig. i is subject to a tuning correction, As a result, the received noise frequency is within the response range of the resting frequency detector with triode 28 falls. A correction of the receiver voting in the opposite However, the direction would only occur if the received rest frequency was in the response frequency range of the working frequency detector arrives. But this is where the deviation of the recipient vote eats already inadmissibly large.

To eliminate this disadvantage, there is a triode in the anode circuit 13 a delayed response, not to the normal telegraph character frequency responsive pause relay 36 switched on. With uninterrupted reception of the resting frequency The triode 13 of the flip-flop circuit 13, 14 carries uninterrupted anode current, and that Break relay 36 is energized. It is provided with a contact 37, which when excited is switched from the position shown and therefore the cathode 'of the triode 27 connects to a tapping point 38 of the voltage regulator 29. This will make the Reverse bias of the triode 27 is considerably reduced and therefore the claims frequency range of the working frequency detector containing the triode 27 in the direction of the quiescent fire frequency postponed. As shown in Fig. 2b, the - response frequency ranges then close F, and F ", the rest frequency f narrowly. By using the pause relay, achieves that even during a signal signal pause in which the fire comfort is uninterrupted is received, the automatic frequency correction of the receiver tuning is reduced remains effective. 'In the reference to' Fig. The training described i provides the Frequency demodulation in stage 7 push-pull output voltages. Practically Frequency derodulation circuits that use a single pole are often used Transfer output voltage. In Fig. 3 the invention is applied to a receiver of the Type of Fig. I applied, but in which the stage 7 by a stage 7 'with a Frequency demodulation; sehadtung is replaced by a single-pole output voltage supplies.

In Figure 3, the preamplifier stage with the amplifier tube 12 are and the final amplifier stage with the tubes 13, 14 in the low frequency part of the receiver shown at 39 in the block diagram; just the circuit to correct the receiver tuning is closer to aws. The twofold local one coupled to the receiver stage 7 ' Oscillator 6 - is the same as in Fig. I, and also is the one coupled to it Frequency corrector i9 is provided with excitation coils 2o, 2i in the same way. With the single-pole output of stage 7 'is connected in parallel to the control grids two triodes 40, 41 via grid current limiting resistors 42 ,. 43 connected. The Trioderi4o, - 41 each form a part of a flip-flop circuit of a known type Type with two triode systems. - One tilt shadow contains triodes 4o and 44, the other triodes 41 and 45. The triodes 40 and 44. have a common cathode resistance 46; the control grid of triode 44 is connected to a tap point of a voltage divider. 47, 48 and 49 connected. This voltage divider is between the anode of the triode 4o and earth switched. The triodes, 4i and 45 have the second flip-flop a common 5o. The control grid of the trioid 45 is with a tap point a voltage divider with resistors 51, 52 -connected; this voltage divider is connected to earth between the anode of the triode 41-.

Of the two flip-flops, the control grids of the left triodes are connected to voltage dividers 47 to 49 or 51, 52 and receive a positive bias voltage. In the absence of an input control voltage, the left triodes 44, 45 de.r.Kippsohaltur7, en current and the right triodes 40, 41 are blocked by the voltages appearing at the terminal resistors 46 and 50 to an extent that of the left Triads lying positive bias voltage is dependent: These bias voltages are selected differently, whereby also the reverse bias voltages, which in the .Steuergitterkreise the right. Triodes 40, 41 are effective, are different.

To simplify the explanation of the mode of operation, refer to a numerical example Reference is made to which the invention is not limited.

It is assumed that at the central frequency of the telegraphic pulses received at the output of the stage, pure single voltage of -I- 60 V occurs and when the nominal working frequency is received, d = the output voltage of stage 7 '-1- 65 V,. when receiving the nominal quiescent frequency is + 55 V. The pre-tensioning of the flip-flops 4o, 44 and 41, 45 is se selected that the first-mentioned flip-flop: schalltung responds when the control grid of the triode 4o is supplied with a positive signal that is a little greater than 65 V and z. B. 65 V contributes, while the second flip-flop 41, 45 responds when the control grid of the triode 41 a z. B. 54.5 V exceeding Spammng is supplied. As soon as the mentioned limit value voltages for the different flip-flops are exceeded, the flip-flops respond, the right triodes 40 and 41 being energized and the left triodes 44 and 45 blocked. The flip-flop circuit 4o, 44 responds as soon as the operating frequency received exceeds its nominal value. The triode 40 then conducts anode current, which brings about a reduction in the voltage at its anode; This reduced voltage is transmitted via a voltage divider located at the anode with resistors 53, 54 to a multivibrator with triodes 55, 56 serving as an amplifier. From the latter. Flip-flop triode 55 normally conducts current, while triode 56 is blocked: is. As soon as the above-mentioned reduced anode voltage is fed to the control grid of the triode 55, this flip-flop 55, 56 flips over, and the triode 56 conducts anode current. The anoderikTBiS of the anode. 56 contains the excitation coil .51 of F.requerizko@rrek, tors i9. The appearance of. Anode current in the triode 56 caused by. the frequency corrector i9 a frequency change of the oscillator 6 in such a direction that the output voltage of stage 7 'for the operating frequency of the received telegraphic signals drops approximately to its nominal value of 65 volts. The flip-flop 40, 44 then returns to the starting position, whereby the excitation winding 2i of the frequency corrector i9 is de-energized. As mentioned above, when the nominal quiescent frequency is received, the output voltage of stage 7 is 55 V. At this voltage, the flip-flop circuit 41, 45 is able - in which the right triode current carries and the left triode 45 is blocked. As soon as the output voltage of stage 7 'drops below 55 V when receiving the resting frequency and z. B. drops to 54 V, the right triode 41 of the flip-flop 41, 45 is fed while the triode 45 is live. The anode de-T 'Tri = ode 44 then receives. a lower potential than before; this ni = edder potential is fed via a voltage divider with resistors 57, 58 to the input control grid of a further flip-flop circuit with triodes 59 and 6o used as an amplifier. From this toggle switch, the triode 59 is initially energized; while the triode 6o is blocked. But as soon as the last-mentioned lower voltage at the anode of the triode 45 is fed to the control gate of the triode 59 , the triode 59 is blocked and the triode 60 becomes live. In the anode circuit of the triode 6o, the excitation coil ao of the frequency corrector i9 is switched on, whereby when the triode 6o is energized, the Frequemzkorrektor i9 is excited in such a way that the consequent change in frequency of the local oscillator 6 increases the output voltage of the stage 7 'when the quiescent frequency is received. If, as a result, the output voltage of the stage 7'-rises to the limit value of 55 V for the quiescent frequency, the described initial state occurs again in that the triode 41 of the input flip-flop circuit conducts current and the corresponding value. Triode 45 is blocked, while triode 59 carries current from the next tilting shutter 59, 6o and triode 6o is blocked. The frequency corrector i9 is then no longer excited via the excitation winding 2o connected to the triode 6o.

As described above, the frequency corrector i9 is excited in the opposite contact by means of the flip-flops 40, 44 and 44 45 located in the Parad1el circuit at the output of the stage 7 ': As shown in FIG In the other direction, the more excited the further the working or idle frequency gets into the response range of the flip-flop circuit 40, 44 or the Iup circuit 41, 45.As with the embodiment shown in Fig. 1, the response ranges of the two input flip-flop circuits 40, 44 and 44 close 45 narrowly restricts the nominal range for the received telegraphy signals.

Delayed excitation of the frequency corrector is by bridging of the resistors 54, 58 with capacitors 61, 62 can be achieved.

Corresponding to the embodiment according to FIG. 3, the: low frequency receiver unit139 a pause relay 36 connected, which is excited as soon as for some time exclusively the resting frequency is being received. This excitation leads to the closing of a normally open contact 63, the parallel to the resistor 49 of the flip-flop circuit 4o, 44 assigned Voltage divider 47 to 49 tot: chaUerf is. When short-circuiting the resistor 49 of this voltage divider is the positive bias voltage for the triode 44 of this Toggle switch reduced, which also. the reverse bias for the triode 4o sinks. With the aforementioned. Numerical example is z. B. by energizing the pause relay the voltage of the flip-flop 40, 44 is reduced from 65 V to 55.5 V. The response ranges of the toggle circuits 40, 44 and 41, 45 'are just closing the voltage value at the output of stage 7 'for the resting frequency closely, as shown in Fig. 2 b shown.

In the circuit according to FIG. 3, as in FIG. i shown is, a swap of the idle and working frequency at the transmitter end is taken into account will. For this purpose, a polarity reversal io is provided in FIG. in the Training according to Fig. 3 can when VeTbausch the rest and working frequency Preload positions for 40, 44 and 41, 45 by changing the ones assigned to them Voltage dividers 47 to 49 or 5 i, 52 are swapped.

Claims (7)

PATENT CLAIMS: i. Overlay receiver for frequency shift telegraphy, the one local oscillator with a frequency corrector for automatic KoTrigierm the receiver coordination according to the transmission frequency of the telegraphy signals contains and in which the received telegraph signals for generating a control voltage for the frequency corrector two preloaded limit frequency detectors for the rest or working frequency are supplied, the response frequency range of which the nominal frequency shift range closely include, characterized in that the demodulated by frequency demodulation Telegraphic character a delayed response to the normal telegraphic character frequency Control non-responding pause relay which, when responding, increases the bias voltage of the Frequency detector for the _ working frequency limited, so that its Anspreohfrequenzbereioh in the direction of the resting frequency ve, rsch # -ben. 2. Overlay receiver according to claim i, characterized in that the two limit frequency detectors are each a grid-controlled Electron tubes, whose control grids contained the demodulated telegraph signals has been fed in push-pull while a negative grid bias is applied to them which is taken from an expediently adjustable voltage divider, which is shown in a cathode line common to the two tubes lies. 3. Overlay receiver according to claim 2, characterized in that the cathode of one of the tubes over the rest side of a changeover contact of the break relay with one end of the voltage divider connected and on the working side of the changeover contact with a tapping point of this Tension divider can be connected. 4. Overlay receiver according to claim 3, characterized in that the von.dem signal character in the control grid leads A polarity switch is located in the push-pull controlled tubes. 5. Overlay receiver according to claim i, characterized in that the two limit frequency detectors each contain a gi, uter-controlled electron tube, whose control grids demodulated the Telegraph: the signs equip # has-ig are supplied, while at them the different strongly blocking negative grid biases. 6. Overlay receiver according to Arnsprualr 5, characterized by the fact that the normally by means of grid prestressing blocked electron tube of each cut-off frequency detector. the entrance tube of a Flip-flop with two grid-controlled ones that have a common cathode resistor Forms electron tubes, and that the control grid of every second Kippschaltumigs-tube to achieve. a positive bias at a tap point of one of the entering Flip-flop associated voltage divider is connected. 7. Superimposition receiver according to claim 6, characterized in that that pause relay bridges a resistor with a normally open contact, which forms part of one of the earwähnten, each Kippschailtung associated voltage divider and between the control grid of the second. Tube of the flip-flop in question and the common cathode lead of the tubes. Documents considered: German Patent No. 897 433; . USA.-Patentschhriften No -2423229, 2541128; French patent specification no. i oig io6.