DE711593C - Device for receiving amplitude-modulated vibrations - Google Patents

Description

The present invention relates to the reception of amplitude-modulated vibrations, an additional, unwanted frequency modulation in the beat of an audible Have low frequency lying in the range.

It is known that in the amplitude modulation of high frequency transmitters Simultaneous frequency or phase modulation is often not easy to avoid expresses in it that the carrier wave of the transmitter in the low-frequency cycle around a mean value fluctuates. These frequency fluctuations are generally only a small fraction of the mean carrier frequency. Of the The scope of the transmitted frequency range can, however, be considerably greater than the normal, The bandwidth given by the low-frequency amplitude modulation is increased will. Apparatus with an exceptionally large bandwidth are required to receive these vibrations, otherwise correspondingly the limited permeability of the selection means a mostly non-linear and undesired conversion of the frequency modulation into amplitude modulation occurs, which often makes reception impossible.

Apart from that, there is the use of band filters with subsequent rectification In general, the requirement that the carrier frequency always coincides with the mean pass frequency, because otherwise an asymmetrical phase shift of both sidebands is to be expected, which occurs in the Rectification leads to non-linear distortion. The reception of amplitude modulated For this reason, too, oscillations of fluctuating frequency cause particular difficulties.

When it comes to the reception of short waves, however, selection circles can be used Easily produce with the required large bandwidth, since this bandwidth in comparison with the very high tuning frequencies is still small. But it is obvious that with these large

Bandwidths also disturbances of various origins, the frequency of which falls within the wide pass band of the selection circuits, are also received in an unnecessary manner. _; In the case of heterodyne reception, the amplification of the very large frequency range due to the fluctuating carrier frequency causes considerable difficulties, since this range is usually no longer small compared to the mean intermediate frequency. For this reason, a superimposed reception of short waves is often not possible, while it can generally no longer be carried out with ultra-short waves. The • 5 special advantages of frequency transformation with subsequent amplification can no longer be exploited in the case of the shortest waves, where, as is well known, there are special difficulties in direct ao amplification anyway.

The difficulties mentioned when receiving amplitude-modulated vibrations, whose carrier frequency is subject to rapid fluctuations as a result of additional frequency or phase modulation avoided in the method according to the present invention. Selection circles can be used, their bandwidth no longer significantly exceeds the scope given by the low-frequency amplitude modulation, and a superimposition reception even the shortest waves are possible.

According to the invention, one of the instantaneous detuning of the receiver is now made always generates a tuning control voltage corresponding to the instantaneous frequency of the received oscillation, which the coordination of at least part of the receiver with one of the period of the highest frequency modulation corresponding time constant is influenced in such a way that the detuning of this part always remains small.

It is known, in receivers, in which the message to be played back by frequency detection an intentionally frequency modulated carrier wave is recovered, a fast acting tuning control of the local oscillator, although there is a negative feedback to the To remove distortions. Since the recipient voting according to the invention constantly follows the instantaneous frequency of the received wave, this is referred to in the following as tracking voting.

In this rapid control of the vote, the changes even at very rapid rate ^ of the received wave mitfolgt, is a fundamental difference over the known arrangements for automatic frequency which a subsequent correction of the receiver tuning in original inaccurate · waste _(^ mood to be received Carrier wave e | In contrast to this, however, according to the above and the following explanations, a regulation of the recipient voting that acts at least a thousand times faster, as it occurs in the method of concurrent voting characterized according to the invention, offers completely new advantages.

FIGS. 1 to 3 show the profile of the carrier frequency and the sideband frequencies at an amplitude-modulated high frequency as a function of time.

In Fig. 1, the carrier frequency 13 is constant, i.e. there is no additional frequency modulation; also the sideband frequencies 11 and 12 are constant in this case. Selection means whose bandwidth corresponds to the narrow range of the band filter curve are sufficient for reception 16 may correspond. The interference frequencies identified by 14, for example are therefore completely eliminated by the selection circles.

Is the carrier frequency itself for some reason, e.g. B. low frequency modulation, Subject to rapid fluctuations, the conditions correspond to FIG. 2. Through 23 is the variable carrier wave and represented by 21 and 22 the sideband frequencies in that by the low frequency given distance from the carrier frequency. Reception by normal means is only possible if the recipient's selection circles match the total Include the frequency range, as shown by the broad band filter curve 26 is. The interference frequencies 24 are also received in this case.

However, according to FIG. 3, reception is also possible when the receiver coordination always follows the instantaneous frequency of the carrier wave 33, as indicated by the variable Band filter curves 36 ,,, 36 ^ and 36 ,, shown will. The interference frequencies 34 are not received in this case because of the current position of the band filter curve 36 ^.

To generate the detuning-dependent tuning control voltage, an apparatus whose characteristics correspond to the diagram in FIG. 4 is required. According to the instantaneous difference A ω between the received instantaneous frequency ω and

the natural frequency ω _{0 of} this circle, a tuning control voltage u is generated, which is characteristic of this deviation in magnitude and sign at every moment: the incident high frequency 41, which is slightly above the natural frequency ω ₀ , for example, leads to a corresponding positive control voltage, which in causes the required short time "the necessary tuning change. If the incident wave as a result of low-frequency modulation in the two sidebands 42 and 43 are divided, so the same control voltage will arise, as these naturally not _c is to be dependent on the instantaneous amplitude modulation state. this is the case, if the characteristic Fig. 4 is not curved in the area of the occurring carrier and sideband frequencies, an approximately straight course is required between points 46 and 47, which corresponds to the greatest deviations between the received frequencies and the instantaneous natural frequency of this circle chen. Outside of these points, a rapid drop in the curve towards the zero line is generally desired so that, for example, no control voltage is generated that would interfere with the tuning due to interference frequencies that may be amplified.

In order to generate the control voltages in accordance with FIG. 4, it is possible to use circuits such as are already known in apparatus for the automatic adjustment of receivers. A suitable circuit is illustrated by FIG. 5, for example. The high-frequency current of variable frequency is applied to the circuit L ₁ , C ₁ via terminals 1 and 2, which is loosely coupled to L ₂ , C _2. The phase difference between the primary and secondary voltage of this band filter depends on the frequency deviation from the mean pass frequency and is between ό ° and i8o °. By connecting the primary

4-5 circle with the center point of the secondary circuit, the sum and difference of both voltages is formed, so that subsequent rectification - z. B. with the double diode G a detuning-dependent: tuning control voltage is generated, which is taken from terminals 3 and 4. The fixed capacitors C ₃ and C ₁ are used to separate this control voltage from the resonant circuit and the resistors R ₃ and i? ₄ for deriving the same, while R ₅ and R ₀ in connection with C _{5 are provided} for the suppression of the high frequency. For reasons of the sufficiently rapid control voltage change corresponding to the rapid frequency changes, the time constants of R _3j C ₃ , R ₄ , C ₄ and of (R ₅ -j- R ₆ ) C _{5 must be} sufficiently small.

An amplitude-proportional control voltage can also be taken from terminals 5 and 6 via the two resistors R ₁ , R ₂ , which is suitable for automatic loss compensation or for the special amplitude control described below. .

This circuit is only to be regarded as an example. Various circuits are known which, with suitable dimensioning of the switching elements, also meet the specified purpose.

For influencing parameters that are used to tune oscillating circuits are decisive (inductance, capacitance) depending on the tuning control voltage, Various methods are also known, which are particularly in the case of arrangements are already used for the automatic focus adjustment of radio receivers. For example, it can be the dynamic Capacitance of an electron tube can be controlled, which leads to a tuning capacitor parallel, or it can reduce the inductance of tuning coils by changing the bias of suitable coil cores to be influenced.

The basic structure of the apparatus for carrying out the process according to the invention is apparent from FIGS. 6 and 7.

In FIG. 6, a tuned amplifier is represented by 61, by means of which the input voltage e _x of variable frequency is amplified to the value e _2. In the frequency control circuit 62, which can be constructed, for example, according to the circuit according to FIG. 5, a control voltage U _{1 is} generated which corresponds to the momentary detuning of the tuning circuits with respect to the high frequencies e _x and e _2. If necessary, this control voltage U _{1 is} calmed down in the calming circuit 63, which must be permeable to the low-frequency control voltage changes. The tuning _{control voltage M 2} ', which fluctuates in low-frequency cycles according to the frequency modulation of ^ ₁ and e _2, acts on the tuned circuits in 61 and 62 in such a way that their detuning with respect to the current high frequency and thus the control voltage U ₂ itself is always at a minimum is held. The voltage e ₂ can be rectified and is free from interference, the frequency of which is outside the instantaneous pass band of the tuned amplifier 61.

In this case of straight-ahead amplification, the tuning of the control circuit 62 is constantly readjusted at the same time and in the same way as the tuning of the receiver amplifier 61 i »o.

The situation is different for over-

Position reception, as shown in FIG. 7, for example. The input voltage e ₀ of variable frequency is modulated in the modulation circuit 70 of a circuit and structure known per se with the auxiliary _{frequency e 4 of} the oscillator 74. The difference frequency or sum frequency e _i is amplified in the intermediate frequency amplifier 71 to the value e _s.

The tuning of the frequency control circuit 72 is invariable and corresponds to the likewise invariable mean pass frequency of the bandpass filter in the intermediate frequency amplifier 71. The control voltage Zi ₁ generated in 72 therefore always corresponds to the instantaneous deviation of the intermediate frequency from a constant setpoint. After settling in 73, which may be necessary, the tuning control voltage M ₂ acts on the tuning of the oscillator 74 in such a way that the intermediate frequency e _t or e obtained by superposition always deviates only minimally from the prescribed setpoint value. This intermediate frequency can be further amplified and rectified as required. If necessary, the preselection circuits that may be present can of course also be regulated by the same tuning control voltage UI. If this is not the case, these selection circles must have a correspondingly large bandwidth.

There are certain conditions regarding the dimensioning of the amplifier and the Frequency control circuits, if the self-excitation of oscillation processes in the frequency control is to be avoided and if, furthermore, a sufficiently rapid operation of the regulation even with very rapid frequency fluctuations the incident frequency-modulated high frequency is required.

This requirement can be expressed by the fact that the phase difference between any periodic frequency changes in question and the changes made by the corresponding tuning control voltage changes The generated tuning changes always remain smaller than i8o °.

In a particularly expedient manner, the behavior in the case of rapid frequency changes can be determined and examine the tendency to oscillate, assuming a single sudden change in frequency.

On the one hand, the so-called control factor R is decisive, which is understood to mean the quotient of a specific frequency deviation and the tuning change, the latter being generated by a tuning control voltage corresponding to this frequency deviation. Furthermore, the so-called transit time ^ ₁ and the transition time U within the entire control loop are important, with t _{t being} the time which elapses after a sudden change in frequency until the tuning control starts, while the transition time t _{2 is} for the duration of the control activity is characteristic, which corresponds to a certain sudden and permanent detuning in the frequency control arrangement 62 and jz in Fig. 6 and 7, respectively. The time-dependent course of the tuning change is expediently replaced by a straight line which roughly coincides with the real curve in the steepest x section, and t is defined. ₂ as the duration of this linear increase until the constant end value is set. The stability condition can then be expressed with a fair approximation by the following inequality:

R>

h + k

(I)

When choosing these determinants, the following aspects are decisive: The control factor R is characteristic of the reduction in the upsets caused by the control activity. It is essentially determined by the sensitivity of the frequency control circuit 62 and 72 in FIGS. 6 and 7, the gain and the tuning change which corresponds to a specific tuning control voltage. An original detuning V is caused by the ^y s regulating activity on the value

(2)

reduced.

The transit time t _t is specifically determined by the transit time of the amplifier for a specific high-frequency signal and depends essentially on the bandwidth of the selection circuits (band filter). This running time is> »5 determining for the fastest frequency changes, for which a voting regulation is still to be expected. In the interests of effective tuning control in the event of rapid frequency fluctuations, the transition time t _a should also be as short as possible, which is mainly related to the time constants of the frequency control circuit 62 or yz and the calming circuit 63 or 73 in FIGS. 6 and 7, respectively.

Since the bandwidth of the selection circles in and 71 in Fig. 6 and 7 according to the above for the purpose of sufficiently short transit times, under certain circumstances, considerably larger than that due to the low-frequency Modulation must be the given minimum bandwidth, it may be advisable to use special amplifiers with a lower band

wide to be provided for the high frequency or intermediate frequency intended for normal demodulation, so that the reception of interference frequency is optimally avoided. Such amplifiers with the output voltage e ₃ are shown in dashed lines in FIGS. 6 and 7 and denoted by 65 and 75, respectively.

In the conventional circuits for automatic sharp tuning of radio receivers, the tuning control voltage, which is dependent on the tuning, is, as is known, very much calmed down. Time constants of the order of 1 second are common. In the present case of the rapid tuning control, which also has to follow the rapid frequency changes in frequency and phase modulated oscillations, time constants generally have to be provided which are a few thousand times smaller. As a result, the transition time i ₂ is generally of the order of magnitude smallest occurring low-frequency oscillation period.

It is advisable to take the following aspects into account when calming the tuning control voltage To be considered: With strong frequency fluctuations of the received high frequency it can happen that the Control process through a brief absence of this high frequency or through a brief one Interference frequency is interrupted or disturbed. In this case, the recipient can be reconciled remain at any particular value, and reception is generally interrupted. It takes so long • long until a wave of the same instantaneous frequency is received again which takes place again. It may possibly be another higher station or lower medium wavelength. This skipping to other wavelengths is expediently prevented in such a way that the recipient reconciliations after each interruption the entrainment is automatically guided to the middle frequency of the wave to be received, so that within a short time again and the whole interruption is hardly noticed. This can by suitable switching of the control voltage transmission circuit 63 in FIG. 73 in FIG. 7 can be achieved as shown in FIGS. 8 and 9.

The input terminals 1 and 2 of the circuit of FIG. 8 are connected to the frequency control circuit 62 in FIG. 6 and 72 in FIG. 7, and the tuning control voltage is fed from the output terminals 3 and 4 to the tuning circuits to be controlled. The condenser. C ₁ transmits the rapidly changing tuning control voltages, which correspond to a frequency-phase modulation of the received oscillations, without significant weakening, since a derivation of these frequencies via the large resistance / ^ is negligible. The capacitor C ₂ , the capacitance of which is significantly greater than the capacitance of C ₁ , is, on the other hand, charged via R ₂ and the even larger resistor R ₁ with a voltage which corresponds to the mean tuning control voltage. Is interrupted and the receiving the control activity due to some fault, "the momentary charge of the small capacitance C ₁ is discharged in a short time on R _1, and between the terminals 3 and 4, the voltage of the capacitor C _2, a, dh a control voltage which corresponds to the central frequency of the receivable shaft. in this manner, after a short time again carried entrainment by the receivable radio frequency. ■ 'by R ₁ in combination with C ₂ is thus in the usual way, a very strong calmed control voltage for automatic sharp tuning, while _{a rapidly changing control voltage is transmitted via C 1} for automatic tracking tuning, which according to the invention causes the rapid tuning changes in the case of frequency or phase-modulated high frequency

The control voltages can naturally also be transmitted separately, for example in a circuit according to FIG. 9, where the control voltages for slow sharpening are routed via the circuit R ₁ C ₁ , while the rapidly changing control voltages for rapid tracking via the circuit R ₂ C ₂ be transmitted. ■

The circuits 8 and 9 are only an example of suitable control voltage transmission circuits to consider which ones do justice to the purpose described. In particular, it can also be used in the transmission path the rapidly changing tracking control voltage suitable for passage limiting means be provided so that too high frequencies of the control voltage, which are caused by any disturbance processes like and are not desired for the voting regulation, and in particular also possibly. high frequency components contained therein are suppressed. Furthermore, the slow and fast regulation in the case of heterodyne reception, for example, are separated in this way be that with two-fold frequency transformation of an auxiliary oscillator for sharp tuning with the rapidly changing Tuning control voltages is controlled.

A certain difficulty in follow-up voting arises from the fact that that the received high frequency in general

common is amplitude modulated. Accordingly, the tuning control voltage fluctuates in the cycle of the low frequency assuming a certain constant detuning. If the instantaneous amplitude of the received high frequency is very small, the tuning control will temporarily be very ineffective. This phenomenon manifests itself in undesirable low-frequency fluctuations in the detuning, which equates to an additional frequency modulation of the received wave with unchangeable tuning. This can be remedied by the fact that the high frequency or intermediate frequency is regulated to constant amplitude by a rapidly acting amplitude control before it is fed to the tuning control circuit (62 in FIG. 6 or 72 in FIG. 7). Such a rapid amplitude regulation, by means of which the low-frequency amplitude fluctuations of the amplified high frequency are to be compensated, is represented by 78 in FIG. 10, which otherwise corresponds to FIG. The amplitude-proportional control voltage V ₁ is taken from the tuning control circuit 72 or a special rectifier circuit. All high interference frequencies are filtered out in the filter 76. The gain of the amplifier 78 is regulated as a function of the control voltage V ₂ . The circuit and structure of such an amplitude control device can be adopted from the known shrinkage compensation devices and offer nothing new according to the current state of the art, apart from the unusually small time constants, which are to be selected according to the highest occurring low frequencies by a few tens of percent smaller than with the normal ones Shrinkage compensation circuits is common.

Such an amplitude compensation circuit can be combined with a device for normal shrinkage compensation, as shown in FIG. 11 based on FIGS. 7 and 10. The capacitor line 76 is permeable to the higher frequencies V _{2 of} the amplitude control voltage V ₁ , which constantly control the gain of 78 in such a way that the low-frequency amplitude modulation at its output disappears to a minimum.

The mean value V _{3 of} the control voltage V ₁ , on the other hand , is fed to the amplifier in a known manner via a calming line yy, the circuit and time constant of which may correspond to the normal fading compensation circuits, so that its gain is automatically regulated in the sense of the known fading compensation control. In this case, the intermediate frequency e _{t can be used} after appropriate amplification in 75 to obtain the low frequency by demodulation, since the low-frequency amplitude modulation is only compensated in 78. The amplitude of e ₂ can also be limited to a constant value by transmission with a kinked characteristic.

The basic circuits 6, 7, 10 and 11 give only examples of the basic application of the inventive concept, whereby naturally all auxiliary equipment unnecessary for the explanation is intentionally left out as their inclusion in the circuits according to the current state of the art Knowledge is possible without particular difficulties. There are numerous extensions and modifications of these basic circuits are possible, in which the follow-up vote is always the characteristic Characteristic is also taken over.

The new quick tuning method can also be introduced in particular in circuits for ultra-short wave reception with multiple superimpositions, the tuning control being transferred in a suitable manner to one or more of the auxiliary oscillators. Multiple regulation is particularly recommended in the manner shown in principle with the basic diagram in FIG. The incident high frequency e ₀ is in the modulation circuit 120 with the auxiliary frequency e _t ■. of the oscillator 124 is modulated. The first Zwischenfreqüenz e _t thus formed is in an amplifier 121 of a very large bandwidth, z. B. aperiodic amplifier, amplified to the level required for the first frequency control circuit 122 (W) The detuning- dependent first tuning control voltage U ₁ generated in 122 reaches the bias-dependent selection means of the oscillator 124 after the high interference frequencies have been filtered out in 123, if necessary. A very large bandwidth of the amplifier 121 is required as a result of the very large and rapid frequency fluctuations of the received high frequency and the very short settling time of this amplifier which is required for this reason. tio

Since the first intermediate frequency is already considerably smaller as a result of this first regulation Is subject to frequency fluctuations, the first intermediate frequency amplifier can have a correspondingly smaller bandwidth are provided, which at least the by the low-frequency amplitude modulation still far exceeds the given passband. Far outside of the received Interference frequencies at the instantaneous frequency result in intermediate frequencies that are probably transmitted via 121 and

Speaking errors result in the tracking of the first intermediate frequency oscillator. However, these tuning errors are compensated for by a similar tracking tuning of the second intermediate frequency oscillator 134. Such interference frequencies are irrelevant and are largely eliminated due to the narrow pass band of 129. The remaining frequency fluctuations of the first intermediate frequency, and in particular the mentioned frequency fluctuations caused by disturbances, are again largely compensated for after another superimposition of e ₅ in 130 with the regulated auxiliary frequency e _{g of} the oscillator 134. In the amplifier 131, the bandwidth of which is again to be dimensioned to be relatively large for the purpose of a short settling time, amplification to the level required for the frequency control circuit 132 takes place again. The second control voltage u _s controls the frequency of the oscillator 134 after the filtering in 133 that may be required, so that frequency fluctuations of the second intermediate frequency are reduced to a minimum. Accordingly, the amplifier 139 can also be dimensioned with a relatively very narrow bandwidth, as a result of which the remaining interference frequencies are also eliminated in an optimal manner.

After the amplification in 139, if necessary, another superimposition with or without tuning control or direct demodulation can take place in a known manner.
Reference has already been made to the possibility of separate sharpening and tracking by different auxiliary oscillators.

Claims (1)

Patent claims: i. Device for receiving amplitude-modulated vibrations that have a additional, unwanted frequency modulation in time with one in the audible range have lying low frequency, characterized in that one of the instantaneous Detuning of the receiver with respect to the instantaneous frequency of the received oscillation always corresponding Tuning control voltage is generated, which the tuning of at least a part of the receiver with one of the period duration of the highest frequency modulation frequency corresponding time constant influences such that the The detuning of this part always remains small. 2. Radio receiver without frequency transformation (straight-ahead receiver) with device according to claim 1, characterized in that the tuning control voltage always the momentary detuning of a frequency control circuit compared to the received one High frequency corresponds, and that the tuning of this control circuit as well of the other coordinated circles of the. The receiver is always influenced as a function of this control voltage in such a way that that the detuning of the receiver against the rapidly changing high frequency always remains a minimum. 3. Overlay receiver with device according to claim 1, characterized in that that the tuning control voltage is always the detuning of a frequency control circuit in the intermediate frequency section compared to the instantaneous intermediate frequency, and that the tuning of the superimposed by, this control voltage is always influenced in such a way that the deviation of the intermediate frequency given by the fixed tuning of the intermediate frequency amplifier and the frequency control circuit Setpoint always remains a minimum. 4. heterodyne receiver with frequency transformation more than once according to claim 3, characterized in that at least one intermediate frequency part a tuning control voltage is generated which corresponds to the instantaneous deviation of the intermediate frequency of this part corresponds to the setpoint given by the fixed tuning of this part, and that the control voltage is at least a local oscillator influenced so that the frequency fluctuations of the last Intermediate frequency remain a minimum. 5. heterodyne receiver according to claim 4, characterized in that the individual auxiliary oscillators independently of one another by means of tuning control voltages are influenced which of the deviation · the each by superposition formed new intermediate frequency compared to the fixed tuning of the associated intermediate frequency amplifier correspond to the given setpoint frequency. 6. Apparatus according to claim 1, characterized characterized in that at least one tuned circuit is controlled by a tuning control voltage is influenced, which was passed through such a high-pass filter that the tuning of this Circle in the absence of the rapidly changing control voltage components is brought to a certain mean value. 7. Apparatus according to claim 1, characterized in that at least one coordinated circle of the recipient by one over one. Low-pass filter calmed tuning rule clamping is influenced, which is dimensioned so that the mean detuning of this circle on a Minimum is kept and the receiver coordination in the event of short-term reception disruptions is guided to the mean frequency of the vibration to be received. 8. Apparatus according to claim i, characterized in that the amplitude of the vibrations conducted to the frequency control circuits is kept at a constant value by a special amplitude limiting circuit, through which in particular the amplitude fluctuations of these vibrations corresponding to a low-frequency amplitude modulation are compensated. G. Device according to claim i, characterized in that the amplitude of the oscillations fed to the frequency control circuit is regulated to a constant value by a special gain control circuit by influencing the gain of a control tube by an amplitude-dependent control voltage, and that the time constant of this control circuit corresponds to the fastest changes in amplitude the low-frequency amplitude modulation is chosen to be sufficiently small. 10. The device according to claim 1, characterized characterized that the vibrations via special tuning circuits and amplifiers, their frequency passband is greater than the bandwidth of the tuning circuits and amplifiers for the transmission of the same oscillations to the demodulation circuits, the frequency control circuits are fed. 11. The device according to claim 1, characterized characterized in that the bandwidth of the tuning circuits is greater than the frequency difference of the outermost sidebands given by the low-frequency modulation, but smaller than that by the simultaneous frequency modulation of the received wave caused frequency range. 12. Overlay receiver according to claim 3, 4 or 5, characterized in that that the pass bandwidth of the intermediate frequency circuits after each frequency transformation by superimposition with a regulated auxiliary frequency is smaller than the bandwidth of this superimposition stage preceding voting circles. 1 sheet of drawings