DE380627C - Receiver circuit for message transmission by means of unattenuated waves - Google Patents

Description

The invention relates to a device for the electrical transmission of signals or messages by telephone, telegraph or other means Waves of high frequency that either pass through a line between the two 'Stations, but preferably in the form of electrical radiation through a natural one Medium. The invention aims to use the effects of natural Electricity, e.g. B. atmospheric disturbances, static electricity, stray Currents and the like of disturbing electrical phenomena rendered harmless and completely switched off will.

For this purpose it has already been proposed to use the oscillation circuit of the antenna to couple with two transmission circuits, which in turn with the receiver circuit are coupled in such a way that one circuit applies the antenna oscillations to the latter transmits in the opposite direction as the other, so that the antenna oscillations So do not directly affect the receiver circuit, but that in each of the transmission circuits Local vibrations are excited, which form vibrations with the antenna vibrations, the latter in have the same effect on the receiver circuit. In the circuit proposed for this purpose each of the transmission circuits contains a special one that generates local oscillations Cathode tube. In order to establish the necessary synchronism between them, the antenna circuit between antenna and earth was divided into two branches, each with one of the transmission circuits was inductively coupled. These branches were connected in series by the current induced by the local oscillations, flowed through by the antenna vibrations in parallel connection. the

S80627

Antenna must be connected to the two branches via a resistor, which is in the Relation to the resistance of the branches was great.

According to the invention, the circuit is significantly simplified and the difficulty To get the two local oscillations in sync, eliminates the local oscillations not from two separate vibration generators in the transmission circuits, but can be generated by a single vibration generator in a special circuit that is connected to the transmission circuits is coupled. The division of the antenna circuit into two branches and the inclusion of a high one There is no resistance in the antenna.

The invention further comprises an ao circuit, 1> egg in which the antenna vibrations initially form primary beats with local vibrations, the frequency of which is so high that they do not affect the receiving apparatus. These primary beats then form secondary beats with further local vibrations, which are recorded in the receiving apparatus. Here, too, the arrangement is again made that each of the local oscillations is generated in a special circuit which is independent of the two transmission circuits. Γη is the drawings
Fig. Ι a schematic representation of a receiver according to the invention: Fig. 2 to 4 are parts of the receiver according to Fig. 1 in a different arrangement:

Fig. 5 is another arrangement of the receiver.

In Fig. Ι A is a collecting device, for. B. an antenna with an open or closed circuit, a coil or a line connecting the stations. An adjustable load inductance L and the adjustable primary coil P of a vibration transformer, to which an adjustable capacitor C can be connected in parallel to tune the frequency of the waves to be intercepted, are connected in series between this and the earth or another capacitance E.

An adjustable secondary coil S is coupled to the primary coil P , with which a tuning capacitor C ₁ and two adjustable, identical primary coils F ₁ and P of oscillation transformers are connected in series in such a way that a current flowing through them has the same magnetic fields in both Strength and same direction generated. Γη at a certain moment are the poles on the right side of both coils P ₁ , P ₁ . at the same time, for example, south ■ pole. With the two primary coils P ₁ . P., two adjustable secondary coils ^ ₁ and S "are coupled by induction, each of which is connected in series with a tuning capacitor C and an adjustable inductance coil L _1. The latter coils are arranged in such a way that they are not influenced by the primary coils P ₁ , P ".

V a hot cathode tube is designated with a cathode f of filament, g two gratings and g \ and α two anodes and a _v The wire / is in a known manner by the current of a battery b made to glow, the intensity of adjusted r by a control resistor can be. The hot cathode is connected to an occupancy of each of the two capacitors C., g the grating, g \ are each connected to the other configuration and thereby simultaneously each with one of the coils 8c, S _1, S ₂ in combination. The arrangement of the coils S ₁ , S ₂ and their position in relation to the coils P ₁ , P " is such that they always charge the grids g and ^ ₁ at the same instant with voltages of the same sign.

The anode currents of the hot cathode tube V are taken from the same battery. A primary coil P ₃ is connected to the circuit of the anode α and a primary coil P _{4 is} connected to the circuit of the anode O _1. Both primary coils have the same number of turns and are otherwise identical to one another. They are connected in such a way that their magnetomotive forces counteract each other. They act together with or without the use of an iron core c on a secondary coil S _s . A controllable capacitor C ₃ and a conventional telephone receiver are connected in parallel with this. The latter is, however, preferably, as shown in the drawing, connected with a battery B ₁ in the circuit of the anode a _{2 of} an amplifier V ₁ whose grid g 1 and hot cathode Z _{1 are} in the circuit of the secondary coil S _x .

Furthermore, two identical primary coils F _n and P ₁₁ act on the aforementioned secondary coils S ₁ and S _2, have the same electromagnetic effect and are connected in such a way that at the moment when the left end of the coil P- acts as the north pole, the left end of coil F ₁ . represents a south pole. They are connected in series with an adjustable tuning _{capacitor C 1} , an adjustable secondary coil .T ₄ and an adjustable inductance coil L ₂ .

V ₂ denotes a cathode tube with a hot cathode / ", a grid g _{: i} and an anode a _3. The circuits of the grid and the anode are by induction ^ - coils L-. and L ₄ coupled. The latter is with a battery B., together, to the one

adjustable capacitor C _{5 is} connected in the anode circuit. The grid g _s and the hot cathode f i are connected by an adjustable capacitor C ₆ . Between the coil L _% and the grid g _s there is a primary coil P ₇ to which the already mentioned coil S _{4 represents} the secondary coil.

The hot cathode tube V ₂ generates undamped oscillations in a known manner, the frequency of which can be set as desired by adjusting or inductance and the capacitance of the oscillating circuit. For the present case, they are allowed to generate undamped oscillations, the frequency of which is above the audibility limit and is somewhat different from the frequency of the oscillations picked up by antenna A. The vibrations thus created in the primary coil P generate vibrations of the same frequency in the secondary coil S _t , the circuit of which is tuned to this frequency by setting the induction coil L ₂ and the capacitor C _4. In the primary coils P ₅ and P ₀ , therefore, vibrations of the same frequency arise, which, however , affect the secondary coils L ₁ , S ₂ in the opposite direction to one another. At a given moment, an oscillation in the oscillation circuit P ₅ , P ₆ in the secondary coil S ₁ generates an oscillation which is directed in the opposite direction to the oscillation induced at the same time in the secondary coil S _2.

The antenna circuit is tuned to the undamped vibrations to be received, the frequency of which is above the audibility limit. These are transmitted by induction into the secondary circuit with the primary coils P ₁ , P ₂ , which is matched to them by means of the variable capacitor C ₁ or in some other way. In the secondary coil S ₁ , two types of vibrations of different frequencies are induced, one by the coil P ₁ vibrations at the frequency of the captured and second by the primary coil P ₅ vibrations at the frequency generated in the transmitter tube V _2. In the secondary coil S ₂ , vibrations of the captured frequency are induced in the same way by the primary coil P ₂ and vibrations of the frequency of the transmitter tube V _{1 are} induced in the primary coil P 6. In the circuit S ₁ , S " , therefore, beats occur, the frequency of which is equal to the difference between the oscillations of the antenna circuit and those of the transmitter tube V ₂ . But since the coils S ₁ and S _{2 are influenced} by the primary _{coils P 1} and P ₂ in the same sense and by the primary _{coils P 3} and P ₀ in the opposite sense, the beats in the circle of the coil S ₁ are opposite to those in the circle of the coil S ₂ shifted in phase by 180 °, and a beat in the first circle reaches its maximum when the beat in the last circle is equal to zero. The amplifier V therefore generates alternating currents in the two primary coils P ₃ and P _4! stream from the frequency of the beats: which are 180 ° apart in phase. Since the coils P ₃ and P ₄ are connected in such a way that their induction effects on the secondary coil S _z are opposite to one another, the effect of the oscillations shifted by 180 ° from the frequency of the beats with respect to the coil S _{s is} added up in them. The beat frequency is chosen so that it is within the audible limit. B. 1000 beats per second.

As will be explained in more detail below, the differential _{effect of the coils P 3} and P ₄ on the secondary coil S is of importance for eliminating the effects of atmospheric disturbances. Apart from this, it is also advantageous when picking up signals in the form of beats, since it has an increased effect on the telephone that cannot be achieved in any other way. Would you z. If, for example, the circuit of the coil P _{4 is} opened while the transmitter tube V _{2 is} in operation, the vibrations picked up by means of the other anode circuit of the amplifier V would also generate vibrations in the telephone, but when using both coils P ₃ and P ₄ and both Anode circuits the excitation of the telephone significantly more.

The oscillating circuit of the secondary coil S ₃ is set to the frequency of the beats by adjusting the capacitor C ₃ and the current is further amplified by the frequency of the beats through the amplification tube V _1. A tone of the number of vibrations of the beats can then be heard in the telephone T.

Static discharges, stray currents, atmospheric disturbances and the like, which prevent the reception of weak signal waves, usually initially generate vibrations of large amplitude, but these are strongly damped and quickly decay. In the antenna circuit and the circuit of the coils P ₁ , P ₂ , oscillations arise from the frequency of the signal waves, since these circuits are matched to these, but strongly damped and quickly decay. Regardless of whether the transmitter tube V _{2 is} switched on and local oscillations are generated or not, the oscillations caused by the disturbance phenomena are transmitted to both circles of the secondary coils S _{1 and} S ₂

induced in the same strength and in the same sense. The vibrations generated in them have the same frequency as the signal waves. Under this influence, the reinforcement tube V _{sends the same anode currents to the primary coils P and P 4} , but the latter do not affect the secondary coil S _x due to their differential circuit. As long as the transmitter tube V .. ίο is not in action, practicing this fault vibrations, as well as the collected signal waves, no effect on the telephone T out.

If the transmitter tube V., is in operation, its tendency to generate vibrations with the local vibrations is only slight in the case of strong disturbance vibrations. On the other hand, the direct influence of strong perturbation oscillations on the potentials of the grids g and g _{x is} the same as when they are effective as detectors, and the telephone is therefore not influenced by them. If there are beats between the disturbance oscillations and the local oscillations of the transmitter tube V .. , these are so irregular that their C ^v transfer to the listener circuit is more or less complete due to its coordination by means of the inductance S ₃ and the capacitor (. '.. In this way, only the regular beat frequency, which _{arises from the interaction of the captured vibrations with those generated by the transmitter tube F 2} , and which is amplified by the cathode tube F ₁ , comes into its own in the telephone Signal waves on and not on strong disturbance oscillations.

Weak static discharges tend to form vibrations with the vibrations generated by the cathode tube F. However, these influences are only noticeable as a soft hissing that does not interfere with the recording of the characters, their effect directly produced in the detector is al > it compensates in the coils P _x and P _4.

The formation of beats through strong as well as weak perturbation vibrations can also be influenced by regulating the strength of the local oscillations of the cathode tube F. In general should not increase the strength of the local oscillations when weak signal oscillations are picked up in the case of strong disturbance oscillations large, but be adapted to the signal oscillations.

So that the effect of the disturbance oscillations on the detector V in the coils P ₃ and P, cancels itself sufficiently and does not affect the coil S _x and the telephone 7 *, the current oscillations in the transformer coils P _x and P _{4 must} be in phase with each other and both have the same waveform with the same amplitude at all points. The primary _{coils P 1} and P ₂ therefore have the same dimensions and the same number of turns, and the coupling coefficients between the coils P ₁ , S ₁ and P ₂ , S., are precisely matched. The circuits of the coils S ₁ and S ₂ should also have the same inductance and capacitance as well as the same decrement. It is also desirable that in the cathode tube F the structural parts of the grid circuits between the hot cathode / and the grids g and ^ ₁ as well as the distances between the cathode and the anodes α and (Z _{1 are} exactly the same. Damped oscillations that occur in both circuits. S ₁ and S ₂ decay in the same way, always transferring the same potential to the grids g, g _x , so that the anode currents always change in the same way and induce the same but oppositely directed electromotive forces in the secondary coil S _:: To achieve complete symmetry of the two anode currents, it is useful if the hot cathode with the two grids and the two anodes is in the same vacuum as shown.

In practice, in the case of small differences in the currents in the primary _{coils P ... P 4,} a compensation can be brought about by which the effects of disturbance oscillations on the secondary coil are made to disappear by changing the coupling coefficients of the coils / '"and P _{4 changes} with the coil S ₃ . If they are not adjustable so can cause the lattice of the cathode tube F is a slightly higher potential than the other, by changing the coupling between P and S _{1 3} or P., and S., or both.

If the circuits of the secondary coils S ₁ and S., a.if the oscillations to be absorbed are matched, they are in resonance with the antenna circuit and each intermediate circuit, and the power factor of each of the secondary circuits is therefore equal to one. Such a favorable design of the power factor is very advantageous, since the currents of the frequency of the signal waves then reach their greatest possible amplitude and therefore the vision wounds caused by their interference with the local oscillations also assume their maximum value. The coordination of these circuits is therefore advantageous, especially where the local vibrations a are generated separately from the detector vibrations.

In Fig. Ι the primary coils P ₁ and P _{2 are} inductively coupled to the antenna circuit, but they can also be directly connected to this, as Fig. 2 shows. Further, 1 the electric circuit of the vibrator V ₂ with the circuit P _0, P ', C _4, S ₂ is coupled in Fig.. However, these two circuits can also be combined to form one circuit without individual parts. This case is shown in Fig. 3. The primary coils P ₅ , P _s are located directly in the anode circuit of the vibration exciter V ₂ .

As indicated in the description of Fig. 1, it is advantageous that the grids and anodes of the detector V are in the same tube, but you can also use a special cathode tube V _a and with each of the circuits of the secondary coils S ₁ and S ₂ Vi, connect, of which a cathode f, a grid g and an anode α and the other a cathode f, a grid ^ ₁ and an anode a _± contains (Fig. 4). In this case, the design of the two cathode tubes must be such that the symmetry and the same degree of efficiency, which are required according to the description of Fig. Ι, are preserved.

For example, it should be mentioned that with the arrangement according to Fig. 1 it was possible in Lancaster in Pennsylvania to pick up weak signals from the stations in San Diego in California, Nauen in Germany, Carnarvon in Wales, etc. If one of the circuits P ₃ or P _{4 was} opened when these signals were picked up, no more signals could be heard and only a cracking noise, caused by static discharges, could be heard in the telephone T.

Fig. 5 shows an arrangement in which both primary and secondary beats are generated. In this case, a variable inductance L ₅ is connected to the secondary coil 6 ″ and the tuning capacitor C ₁ in a circuit which is tuned to the frequency of the waves to be picked up. The grid G ₄ , a cathode tube V ₃ , its hot cathode is connected to this circuit with f ₃ and its anode with a _4. In its anode circuit there is a variable capacitor C ₇ shunted to the anode battery B ₃ and two primary coils P ₁ and P ₂ connected in series with this, which have magnetizable cores C ₁ , c " The anode circuit is coupled to the grid circuit by an inductive coupling L ₀ , with which a variable capacitor C ₈ is connected in parallel.
Two of the coils P _1, P ₂ coupled secondary coils S ₁ and S _2, the iron cores c _3, may contain C _4, are each with a clip at the thermionic cathode / and with their other terminals, depending on a grid ^ or J ₂ "an amplification tube V.

A second oscillation generator V ₄ , with a hot cathode / ₄ , a grid g _Tl and an anode a _s is arranged in a similar manner to the previous oscillation generator V ₂ . There is a battery in its anode circuit! The anode circuit and the grid circuit are coupled by an inductance L ₇ and a three-phase capacitor C _{9 connected in parallel therewith.} In the grid circuit there are primary coils P ₃ and P _{0 connected in series} , which can contain iron cores C ₅ and C _{0. A variable capacitor C 10} is shunted to the inductance of the grid circuit. The primary coils P ₁ , P ₂ act in the same way and the primary coils P ₅ , P ₆ . in the opposite sense to the secondary coils S ₁ and S ₂ , similar to the circuit according to Fig. 1.

In this arrangement, the intercepted vibrations, together with the somewhat different local vibrations of the cathode tube V ₃ , generate beats whose frequency is above the audible range, e.g. B. 15,000 to 20,000 beats per second. Through the primary coil P _1, P ₂ of the AnodenstronTmit also mounted beat oscillations is in this case ,, different from the arrangement of Fig. 1, in which the -Coils P _1, P ₂ were flowed through only vibration on the frequency of the signal current. The local oscillations of the transmitting tube V ₄ have one frequency above the audible range and create in the secondary coils S ₁ and S _2, a second beat of audible frequency, but the beat oscillations in the secondary coils S ₁ and S ₂ are shifted by i8o ° to each other in the phase . The anode currents are therefore given the same phase shift, so that their _{effects exerted in the coils P 3} and P ₄ on the secondary coil S ₃ and the telephone T add up.

The intercepted vibrations thus initially result, together with local vibrations, vibrations with which a second series of local vibrations generate secondary vibrations that are within the audible range and can be heard in the telephone T.

If now! If strong static discharges or the like act on the antenna circuit A , the vibrations generated by them with the local oscillations of the cathode tube V ₃ , regardless of how great the tendency to form such is, are always influenced by the simple detector effect of the cathode tube V ₃ superimposed and obscured. Therefore arise in the primary coils P ₁ , P ₂

Currents of a lower frequency, within the audibility limit. These low-frequency currents are _{not influenced by the vibrations generated by the transmitter tube F 4 in} such a way that they generate beats of audible frequency in the secondary coils S ₁ and S _s. Strong static disturbances therefore have no influence on the telephone I. These low vibrations in the primary coils P ₁ , P ₂ generate, regardless of whether the transmitter tube F _{4 is} in operation or not, in the secondary coils S ₁ and S _{2 the} same currents and the same charges of the grid g, g _lt so that the anode currents in the primary coils P, and P _{4 are} repetitions of the slow oscillations of the coils P _{: 1} , P ₄ . These anode currents are in phase with one another and, since the primary _{coils P .. and P 4} are connected to one another, their effect on the secondary coil S _: . and thus have no effect on the telephone T. !

Strong static interference form the [local vibrations of the cathode tube F _3: no beats, but appear in j circuit P _1, P ₃ as a weak, lying in the audible vibrations and stimulate \ ^T erstärkungstätigkeit the cathode tube F, but then neutralize in their effect on the coil S ...

On the other hand, weak static disturbances develop; with the local vibrations of the cathode tube F .. beats outside the hearing limit, as well as the intercepted signal vibrations. These weak, inaudible vibrations caused by the disturbance vibrations interfere with the vibrations generated in the circuit P- ,, P ₁₁ by the transmitter tube F ₄ and form with them partial, audible secondary visual vibrations, which are all very weak and do not interfere with the reception of the signals .

The strength of the vibrations from the cathode tube F., .Tzengten is decisive for the ratio of the potentials that the grids of the cathode tube on the one hand by the detector effect and on the other hand, are pushed on by the beats. From the strength the local vibrations of the cathode tube F .. it still depends on the strength lie disturbance vibrations that no longer vibrate with the local vibrations form.

As detectors are in the arrangement according to the invention, hot cathode tube, such as is preferable, but it is also possible to use crystal detectors and instead of the same others to use. Furthermore, instead of the specified transmission tubes, another wave of a suitable frequency emitting device are used.

By means of the arrangement described, it is possible to carry out weak signal oscillations to transmit and receive strong static discharges or the like. Weak static Discharges and the like produce, similar to He, signal oscillations, beats, but which do not have a disruptive effect on the receiver.

Claims (5)

Patent Claims: i. Receiver circuit for message transmission by means of undamped waves, in which the antenna circuit is coupled to the receiver circuit by circuits containing detectors in such a way that the direct effect of the antenna vibrations on the circuit of the recording apparatus in these circuits is canceled, while the vibrations formed from the antenna vibrations and local vibrations add up with regard to their effect on the circuit of the recording apparatus, characterized in that the local vibrations are generated by a single vibration generator (V ") in an electrical circuit <P-, P ₀ 1 that is independent of the transmission current circuits. 2. A circuit according to claim 1, characterized in that the antenna circuit offers an undivided path for the captured vibrations. 3. A circuit according to claim 1 and 2, characterized in that the oscillations of the antenna circuit are transmitted to the circuits of the detectors by a single coupling (S). 4. A circuit according to claim 1, 2, 3, characterized in that the antenna circuit contains no further resistance than the resistance of the antenna and the. of voting machines. 5. Receiver circuit for undamped waves, characterized in that the Collected vibrations with local vibrations form primary beats, which then affect the circuit of the recording apparatus (Ti are transmitted so that they cancel each other out in this, while local vibrations form secondary beats with the primary beats, their effects on the circuit of the Recording apparatus add up. 1 sheet of drawings.