DE1086762B - Transmitter circuit with means for frequency modulation and with a weakly damped antenna circuit - Google Patents

Description

GERMAN

In sender arrangements with a weakly attenuated antenna circuit, which means one in the antenna circuit In relation to the radiated power, high reactive power oscillates, difficulties arise in the Modulation with the signal to be transmitted. The large storage effect of the circle makes fast Changes in the oscillation amplitude, because the circle does not have to increase this amplitude only the energy emitted during the sampling time, but also the oscillating power to be stored can be supplied as electrical work, while this stored work reverberates during the blanking time and so with telegraphic transmitters to character distortions, with voice-modulated transmitters to a circumcision of the transmittable frequency band leads. As a result, efforts are made to reduce the attenuation of the antenna circuit to increase as much as possible. This can be done by 'switching on ohmic resistors, whereby however, the efficiency of the antenna, i.e. the ratio of the radiated power to that of the transmitter supplied power, significantly reduced. will. However, it is also possible to use a suitable coupling circuit between the antenna circuit and the transmitter output stage make the internal resistance of the transmitter end tubes in the antenna circuit effective in a suitable manner and in this way achieve the desired faster onset and decay. However, this means a higher burden for the tube, as this is essential during the period of up-sampling the oscillation in the antenna circuit Must deliver more power and this power partially decreases again during the time of the reduction of the oscillation amplitude and in anode power loss implements. The keying speed of A1 keyed telegraphy transmitters and the modulation capability of voice-modulated telephony transmitters is significantly improved in this way without reducing the continuous wave efficiency of the antenna is reduced.

It is also known to increase the effect described by the fact that the high-frequency output stage * o is operated with negative voltage feedback, which reduces its internal resistance and the aforementioned Effect is supported. It is also known to effect an amplitude modulation in that with loose coupling of the transmitter output circuit to the antenna circuit in the latter a shunt is changed to the coupling coil in the cycle of the modulation. Similarly, in a known, Circuit for frequency shift keying the antenna circuit via separate inductive couplings two oscillations different frequency supplied. In each case one of them is driven by an inductive, the associated one Antenna coupling coil parallel shunt rendered ineffective by the shunt transmitter connection

with means for frequency modulation
and with weakly attenuated ■■
Antenna circle

Applicant:

Telefunken _GmbH;
Berlin NW 87, Sickingenstr. 71

Dr.-Ing. Alfred Ruhrcnann, Berlin-Teinpelhöf,
has been named as the inventor

Inductivities changed in opposite directions by changing the premagnetization of their iron cores in the cycle of the keying will.

While with amplitude modulation or amplitude keying despite weakly attenuated antenna circles' relatively satisfactory due to one of the specified options Solutions are achievable, they do not bring any significant relief in terms of frequency modulation, lation or Frequency shift keying. With frequency shift keying, the (continuous wave) operating frequency of the "transmitter" is during the pause step by a certain amount to one side, and during the drawing step by the same amount to the other side shifted from the resonance frequency of the antenna, so that inevitably Blmdkoniponenten in the high frequency end stage are effective, which significantly reduce the efficiency of the same. Here too it is possible to use compensation circuits (broadband matching; bandpass circuits) to achieve the effect to improve, but the area can be based on a general principle of the filter circuit theory does not extend significantly beyond the frequency range

009 570/288

stretch, in which without these means a phase shift of about 45 ° occurs to both sides. The frequency ranges that can be achieved in this way are, despite great effort, with long-wave transmitters, i.e. transmitters with Operating waves over 1000 m in length, for example, are still too small, so that the difficulties with this method cannot yet be considered resolved.

In a known arrangement (Electronics, 1954, No. 12, pp. 148 to 151) remedy is provided by a relative tried a lot of additional circuit parts. A Coil with ferromagnetic core switched on, which has a special winding by means of a dem Course of the tactile characters is premagnetized according to changed direct current. This will make the The inductance of the coil varies and the resonance frequency of the antenna circuit in each case at least approximately brought into agreement with the instantaneous frequency of the vibration supplied by the transmitter. Such a retuning of the antenna circle corresponding to the tactile sign enables the achievable Significantly increase the scanning speed and increase the efficiency of the transmitter. Besides the elevated one Circuit complexity for the two frequency change processes to be operated in synchronism occur functional difficulties. Namely, it is not easily possible to find the exact one Establish synchronization between the transmitter frequency and the tuning frequency of the antenna circuit because the means to be used for both functions are fundamentally different from one another - if only with regard to their size - and accordingly have different action characteristics. In the case of synchronism errors, So if the resonance frequency of the antenna circuit deviates from the transmitter frequency, this are unavoidable, extremely disruptive phase changes and transient processes occur, which affect the mode of operation unsafe and make the situation very confusing.

The invention is based on the object of creating a transmitter circuit which, in its structure is simple and clear and free of the shortcomings mentioned in the known circuit. In a transmitter circuit with means for frequency modulation and with a weakly attenuated antenna circuit, for example in a long-wave transmitter circuit is, according to the invention, the antenna circuit itself or that with the antenna circuit firmly coupled output tube stage in such a way in the feedback loop provided for the generation of vibrations included that the antenna circuit as a result of its in relation to the reactive power ratios of all other oscillation circuits involved in the feedback loop with a high reactive power ratio, the exciting frequency to one essential part is determined, and the means for frequency modulation are as resonance-determining Parts formed on or in the antenna circuit.

A transmitter circuit designed according to the invention is much simpler in construction than the one mentioned known transmitter arrangement with frequency modulation, because it is only necessary to use the resonance frequency of the antenna circuit in the rhythm of the signals to be transmitted. The broadcast Frequency then corresponds to this resonance frequency at every moment. So the transmitter is working always with an antenna circuit tuned to resonance with the exciting oscillation, i.e., its load resistance always has the character of an Ohtn resistance. The efficiency of the As a result, the transmitter is always equally good and high, and disturbing transient processes as with the known Sender arrangement does not occur.

The change in the resonance frequency of the antenna circuit can be carried out as in the known arrangement a coil arrangement of controllable inductance (with ferromagnetic core) take place, or it can also be effected in that a capacitor arrangement with electrically changeable in the antenna circuit Capacity, e.g. B. with ferroelectric dielectric, is turned on, the capacitance by means of to a voltage following the course of the drawing.

Since in the transmitter circuit designed according to the invention, the antenna circuit is essentially alone is frequency-determining, all undesirable influences have a frequency-changing effect. Such undesirable Frequency changes can be caused, for example, by fluctuations in the antenna conductor in the wind Ice formation on the ladders and similar inevitable influences can be caused. It is therefore advantageous to provide a frequency control device to stabilize the mean operating frequency. This can easily be combined with the arrangement according to the invention. One is required Arrangement which a variable with the generated frequency electrical control variable, preferably a control voltage, which, together with the electrical quantity corresponding to the signal oscillation brought into effect on the part of the arrangement which controls the resonance frequency of the antenna circuit will. Such arrangements are known in principle (Frequency or phase discriminators with or without crystals, with or without previous frequency conversion, with or without comparison [normal] frequency). With F3 modulation, i.e. voice modulated Frequency modulation, as is customary with VHF FM transmitters, arrangements can be used, soft have an integrating effect and only react to the mean frequency (temporal linear mean value) and this Keep the value constant. With keyed transmitters (F 1 monoplex or duoplex operation), each single frequency or use similar circuits for individual ones, e.g. B. with the incoming Touch characters are switched and are thus effective in each case -when the frequency in question should be broadcast. The arrangements described can work quickly, i.e. with purely electrical ones Means to compensate for rapid fluctuations in the center frequency, e.g. those caused by the influence of the wind are caused, or they can be slow, i. H. frequency-determining by means of motorized adjustment Components, work and in this way compensate for slow changes, e.g. those that are due to the antenna conductors are iced up.

The invention will be explained on the basis of the two circuit diagrams.

Fig. 1 shows a simple self-excited tube circuit with frequency-determining antenna circuit and associated control circuit for constant control of the both frequencies in frequency shift mode;

Fig. 2 shows a self-excited tube circuit fed back over several stages without additional control devices.

In Fig. 1, 1 is a transmitter tube, which in a known manner by means of its anode circuit 2 with the weak, attenuated antenna circuit 3 and 4 is connected. The antenna coil 3 essentially causes the Matching the capacitance of the antenna 4 and is in series with the two windings 6 and 7 by means of of winding 8 in its inductance value ferro-

magnetically influenceable coil arrangement 5. The anode circuit 2 is so tightly coupled to the antenna coil 3 and dimensioned so that the reactive power in the anode circuit 2 is small compared to that of the antenna circuit, so that the antenna circuit alone determines the frequency. The key 9 is used for keying the frequency of the transmitter arrangement; The voltage tapped at the potentiometer 11 is connected in series with another voltage tapped at the potentiometer 13 by means of the wiper 14 from the power source 12 at the input of the (direct current) amplifier 15, which feeds the magnetizing winding 8 on the coil arrangement 5. At the input of the DC amplifier 15 is in this way the character voltage given by the key and the bias voltage taken from the potentiometer resistor 13, which determines the quiescent frequency of the transmitter, the size of which is only influenced by the setting of the wiper 14 of this potentiometer by means of the control device. Two discriminator arrangements of the same type, which are coupled to the antenna circuit with the aid of the coupling coil 16, are provided for frequency control. This coil 16 feeds the input coil 17 and 18 of the two frequency discriminators. The secondary circuits of the discriminators with the coils 19 and 20 and the capacitors 21 and 22 or 23 and 24 are each matched to the symbol frequency and the pause frequency. The rectifier arrangements 25 and 26 rectify the voltages arising at the terminals of the secondary circuit. These voltages are equal to one another if the frequency of the transmitter corresponds to the natural frequency of the secondary circuit of the discriminator, so that no control voltages arise at the outputs 27 and 28 of the discriminator circuits. However, if there are deviations from the two setpoint values in one direction or the other, positive or negative voltages occur. The winding of the relay 29, which has the purpose of switching the control device over to one or the other of the two discriminator circuits, is parallel to the potentiometer 11 of the sensing circuit. In the position shown, the button is open, the winding of the relay 29 is de-energized and the normally closed contact 30 a of the relay 29 is closed. The winding of the polarized relay 31 is connected via the normally closed contact 30 α to the output of the discriminator circuit, which is assigned to the pause frequency of the transmitter. If this pause frequency deviates from the set frequency specified by the discriminator circuit, a control voltage occurs at the output 28 of the discriminator circuit, which actuates the polarized relay 31 and brings the contact 32 into position α or b , whereby the motor 33 is switched to clockwise or counterclockwise rotation and the wiper 14 of the potentiometer 13 is adjusted via the magnetic coupling 39, which can be reversed by means of the magnet 40, in the sense that the deviation of the transmitter frequency from the setpoint frequency of the discriminator is reduced. If the key 9 is closed, the relay 29 picks up and switches the polarized relay 31 to the output 27 of the discriminator circuit corresponding to the character frequency, so that the comparison of the transmitter frequency ⁶ S with the setpoint frequency specified by the second discriminator circuit is now carried out. In this case, the motor 33 works via the now switched clutch 39 to the wiper of the potentiometer 11. The clutch 39 is switched over in the same rhythm as the relay 29 by means of its expensive magnet 40, the winding of which is connected to the ends of the resistor 11 .

In Fig. 2, a multi-stage transmitter circuit is shown. 1 and 1 'are the end tubes of the transmitter, the anode circuit 2 of which is fixed to the antenna circuit from the Antenna 4, the antenna tuning coil 3 and the electrically controllable coil 5 is coupled. A feedback voltage is taken from the antenna circuit by means of the coupling coil, which is fed via line 36 to the input of the preamplifier and amplified at the grid of the output stage tubes takes effect. Here, too, the dimensioning can be carried out very easily so that the in the antenna circle 3, 4, 5 oscillating reactive power is large compared to that of the anode circuit 2, so that the antenna circuit is the only frequency determinant. The phase relationships in the feedback loop are the same for long-wave transmitters easy to miss and do not cause any difficulties. If necessary, compensation options can be used to a large extent.

Claims (5)

Claim 1. Transmitter circuit with means for frequency modulation and with a weakly attenuated antenna circuit, for example long-wave transmitter circuit, characterized in that the antenna circuit itself or the power tube stage that is firmly coupled to the antenna circuit in this way provided for the generation of oscillations feedback loop is included that the antenna circuit as a result of its in relation to the reactive power ratios of all others in the Feedback loop e included oscillation circuits with a high reactive power ratio Exciting frequency is largely determined, and that the means for frequency modulation are designed as resonance frequency-determining parts on or in the antenna circuit. 2. A circuit according to claim 1, characterized in that in the antenna circuit, preferably in Series with the inductance (3) or parallel to part of the same, a coil arrangement (5) variable inductance is provided with a ferromagnetic core whose bias is changed by a current that changes with the course of the drawing. 3. A circuit according to claim 1, characterized in that in the antenna circuit, preferably in Series with the inductance or parallel to a part of the same, a capacitor arrangement changeable Capacitance is provided with a ferroelectric dielectric, the capacitance value is changed by a voltage that changes with the course of the drawing. 4. Circuit according to claims 1 to 3, characterized in that a device for Frequency control is provided, which one with the generated frequency or with its time Average variable electrical controlled variable, preferably control voltage, emits which together with the electrical quantity corresponding to the signal oscillation to one of the resonance frequency-determining parts of the antenna circuit is brought into action. 5. Circuit according to one of claims 1 to 4, characterized in that in the case of frequency-keyed transmitters, the character frequency or the pause frequency by itself, or both frequencies with assigned Frequency standards (z. B. discriminators) are compared and that the resulting electrical control variables via one or more motor actuators in such a Set direction in motion that undesirable Frequency deviations from the setpoints. be matched. Considered publications: British Patent No. 196 062; U.S. Patent No. 1,648,711. 1 sheet of drawings © 009 570/288 8.60