DE2358459C3 - Switching on the receiver side for the detection of the attenuated residual carrier of shipments - Google Patents

Description

The invention relates to a receiver-side circuit for detecting the attenuated residual loads of broadcasts, the residual carrier being filtered out of the surrounding sideband signals by a narrow-band filter and tied to a fixed reference frequency with an automatic frequency control (AFC).

Receivers with automatic frequency control designed to receive sideband signals generally work according to the following principle The carrier, whose frequency expediently in the Intermediate frequency position is implemented by means of a local oscillator, is isolated from the sidebands. His Frequency is then after filtering with the fixed frequency of a reference oscillator in a phase or Frequency discriminator compared. An error voltage is obtained, which is used to regulate the Frequency of the local oscillator is used. The reference oscillator signal is also used for demodulation of the sidebands, which are filtered out by means of a sideband filter, is used. Such a receiver circuit is for example from the company publication »Telefunken ... single-channel single sideband device type BP 102/2 «from 1955 known.

When receiving broadcasts with attenuated residual carriers, the carrier is filtered out of the stronger sideband signals surrounding it in the intermediate frequency position by a narrowband filter. The pass band of such filters is a few 10 Hz. In order to be able to detect the carrier and connect it with an automatic frequency control (AFC) , the receiver must be tuned very precisely. To illustrate the tuning process, Fig.l is used, in which the two sidebands SBi and 5ß2 framing the residual carrier 7 "are shown over the frequency / '. The residual carrier 7 differs from music and speech signals in the sidebands SBi and SB2 by two essential

Properties. For one thing, the change in its frequency over time is very small

There are no other signals around others in their immediate vicinity if the reception is free of interference, i.e. the modulation is limited downwards. When tuning the receiver a frequency band B passes over according to the bandwidth of the residual carrier filter the frequency spectrum of Fig. 1. detects the frequency band B of the filter, the area around the carrier T, so there is only one spectral line, namely that of the carrier 7 itself is in the range of the frequency band B. The so-called zero beat method is known for recognizing this state, in which the receiver is acoustically tuned. The beat frequency that occurs when comparing the frequency of the reference oscillator and the residual carrier frequency is used as the evaluation variable, which is also used to regulate the frequency of the local oscillator.

The object of the invention is to provide an optical display of the state in which only the carrier is in the range of the frequency band of the residual carrier filter, ie an optical tuning aid and tuning control for the carrier connection in the receiving circuit with automatic frequency control (A FC) so that the tuning state during reception constantly by an optical display device, e.g. B. a lamp is displayed. According to the invention, which relates to a circuit according to the type mentioned, this object is achieved in that a first input of a phase bridge is connected to the filter via an oscillating element, the equivalent circuit diagram of which is formed by the parallel connection of a damped series oscillating circuit and a capacitor , so that there are two resonance frequencies, between which the impedance is inductive (positive phase rotation φ) and outside which the impedance is capacitive (negative phase rotation φ), that a second input of the phase bridge is also connected to the filter via an ohmic resistor, that the Phase bridge is designed so that with a positive phase rotation (φ> 0) by the oscillating element at a first output of the phase bridge a signal and with negative phase rotation (φ <0) by the oscillating element at a second output of the phase bridge a signal and daD to a the outputs of the phase bridge have a signal response existing optical display device is connected with the interposition of a monostable multivibrator. The phase criterion clearly distinguishes the transmission carrier from modulation bands and impulse interferers. With an optical display of the correct coordination on the transmission carrier for the ^ FC operation, an optical display for the operating status of the Λ FC circuit is connected.

From the arrangements according to Swiss patent specification 2 37 708 and the US patent specification 25 94 091 it is known to obtain a voltage, the size of which is proportional to the frequency deviation of a high frequency voltage of a selected setpoint frequency and its sign with the meaning of Frequency deviation changes. The voltage obtained is in accordance with the Swiss patent specification 2 37 708 for regulating and, according to US Pat. No. 25 94 091, for controlling a display device used. The control voltage obtained with the aid of a piezoelectric oscillating crystal is included Always negative above the setpoint frequency and always positive below the setpoint frequency, or vice versa.

The situation is different with the circuit according to the invention, since it works as a phase rotator. Inductive behavior prevails between the two resonance frequencies of the oscillator and outside of the capacitive behavior at both resonance frequencies. The inductive behavior has a positive and the capacitive one Result in a negative phase shift. It is not the case here that the one resonance frequency a negative control voltage and a positive control voltage at the other resonance frequency of the oscillator is produced. If there is a positive phase shift, i. H. an inductive oscillator behavior, so is only the carrier frequency in the area of the residual carrier filter. If there is a negative phase shift, i. H. one capacitive behavior of the oscillator, the filter area of the carrier filter covers part of a sideband, Noise or constant interference spectra. The mode of action and the necessary structure of the Oscillators in connection with the phase bridge are therefore of a completely different type than with the state of the Technique according to the two aforementioned patents.

The monostable multivibrator used in the circuit according to the invention is not insignificant. on The reason for the delay in this flip-flop are also short-term, simulating a carrier Signal distributions in the filter area of the residual carrier filter prevented the presence of a carrier to display.

Further details and advantages of the invention are shown in figures on the basis of FIG Embodiments explained in more detail. It shows

F i g. 2 shows a basic block diagram of a circuit for residual carrier detection in AFC according to the invention for use in shortwave receivers,

F i g. 3 the equivalent circuit diagram of a vibrating element, F i g. 4 the course of the complex resistance of the vibrating element as a function of the frequency,

5 shows a block diagram of a phase bridge and the connected circuit elements according to the invention and

F i g. 6 shows an interference protection circuit using the detection circuit according to the invention.

According to the principle block diagram in FIG. 2, the received frequency band converted into the intermediate frequency position is fed to a residual carrier filter 1, the bandwidth of which corresponds to frequency band B according to FIG. 1 is. An amplifier is connected to the residual carrier filter I, the output of which is connected on the one hand via an oscillating element 6 to a first input 7 of a phase bridge 5 and on the other hand via an ohmic resistor 3 to a second input 4 of the phase bridge. The phase bridge 5 has two outputs 8 and 9, of which the output is led via a monostable multivibrator 10 with an inverting output to a lamp 11 serving as an optical display device. If the frequency band of the residual carrier filter 1 covers the area around the received carrier, then due to the spacing of the sidebands in the undisturbed state there is only one spectral line, namely that of the carrier, in the range of the frequency band of the residual carrier filter.

are recognized and displayed by means of the lamp 11.

An essential element of the circuit according to FIG. 2 is formed by the oscillating element 6. Quartz oscillators and mechanical oscillators with ceramic excitation, both of which can be used as oscillating element 6, are represented by the equivalent circuit diagram according to FIG. 3 described. This equivalent circuit has a damped series resonance circuit consisting of an inductance Ll, a capacitance Cl and an ohmic resistor Ri , to which a total capacitance CO is connected in parallel. The course of the complex resistance of the oscillating element 6 according to FIG. 2 as a function of the frequency / ″ is shown in FIG. 4. The real component R of the complex resistance can be read off on the abscissa and its imaginary component X on the ordinate , two resonance points, namely at the frequencies fr and fa, the frequency fr being the lower of these two resonance frequencies It can be seen that the complex resistance of the oscillating element 6 shows inductive behavior only in the range fr <f <fa.

The phase rotation φ of the voltage compared to the current is positive in this area (φ> 0). No phase rotation φ takes place when the vibrating element 6 is operated with the two resonance frequencies fa and fr, ie φ = 0. For frequencies that are higher than the frequency fa and lower than the frequency fr, there is a capacitive behavior of the complex resistor, da φ is negative, ie φ <0. The frequency bandwidth Δ F over which the vibrating element 6 exhibits an inductive behavior can be given by the following approximation equation. ^.

IF = la -fr * , _ro -Jr.

The frequency band width AF is for crystals with a resonance frequency of, for example, 30 kHz (corresponds to the intermediate frequency) and low quality, e.g. B. with a pull-crystal, a maximum of about 40 Hz. With mechanical oscillators of the same frequency, values for the frequency bandwidth AF of over 100 Hz can easily be achieved. For known reasons, the two frequencies fr and fa show high constancy in oscillating elements 6 of this type, so that the frequency bandwidth AF remains well in the range of the frequency band of the residual carrier filter 1 even in the case of mechanical oscillators. Since the frequency bandwidth of AF (g F i. 3) by increasing the Kapazitä "CO was slightly narrowed, but only moderately and can be increased with great effort, provide mechanical oscillator in the frequency range to 30 kHz, which corresponds to a typical intermediate frequency of short-wave receivers, decisive advantages over quartz in this application.

From Fig. 2 shows the connection of the oscillating element 6 to a phase bridge 5 advantageously designed as a TTL (transistor-transistor-logic) circuit. The oscillating element 6 rotates the phase of the signal voltage after the amplifier 2 and sends it to the input 7 of the phase bridge 5. The ohmic resistor 3 conducts the signal without phase rotation to the input 4 of the phase bridge 5. The phase bridge 5 gives positive values of the phase rotation φ , ie φ> 0, at the output 8 of the phase bridge 5 pulses, with negative values of the phase rotation φ, ie φ <0, at the output 9 of the phase bridge 5. If the signal after the amplifier 2 contains many and rapidly changing frequencies, the result There are pulses at both outputs 8 and 9 of the phase bridge 5. If there are 8 pulses at the output, no pulses are emitted at the output 9 of the phase bridge 5 and vice versa. Since the signal-inverting output of the monostable multivibrator 10 is used to control the lamp 11, the lamp 11 lights up whenever there are 8 pulses at the output. If, on the other hand, the output 9 emits pulses when the vibrating element 6 has a capacitive effect, the monostable multivibrator 10 is triggered,

ίο and at its inverting output there is a zero signal. The lamp 11 therefore goes out in this case. A capacitive effect of the oscillator 6 and thus a regular retriggering of the monostable multivibrator 10 causing the constant shutdown of the lamp II occurs when the filter area B of the carrier filter 1 detects part of a sideband, noise or constant interference spectra. Due to the delay of the monostable multivibrator IO, even brief signal distributions simulating a carrier in the filter area B of the residual carrier filter 1 are prevented from illuminating the lamp 11 and thus indicating the presence of a carrier. Further details, in particular in connection with the function and the structure of the phase bridge 5, are given with reference to FIG. 5 described.

5 essentially shows the block diagram a phase bridge expediently designed in TTL technology and the circuit elements connected to it. A pulse shaper 12 is attached to each of the oscillating element 6 and the ohmic resistor 3 or 13 connected, which form square-wave pulses from the incoming oscillations.

The pulse shapers 12 and 13 can be implemented, for example, by means of threshold value circuits such as Schmitt triggers. The inputs of the two pulse formers 12 and 13 each also form an input 7 or 4 of the phase bridge. At the output of the pulse shaper 12 is the reset input r of a first two-edge counting flip-flop (master-slave flip-flop) 14 and the clock input Cl of a second two-edge counting flip-flop (master-slave flip-flop) 15. The basic position output 16 of the first counting flip-flop 14 is via a the monostable multivibrator 10 in FIG. 2 corresponding monostable multivibrator 17 with an inverting output at the input of an AND gate 18. The other input of the AND gate 18 is triggered by the basic position output 19 of the second counting flip-flop 15 via a non-inverting output of a monostable multivibrator 20. However, as will be explained later, this latter connection can be omitted in some cases. The first output of the phase bridge (output 9 in FIG. 2) is formed by output 16 of counting flip-flop 14 and the second output of the phase bridge (output 8 in FIG. 2) by output 19 of counting flip-flop 15. The optical display device in the form of a lamp 11 is connected to the output of the AND gate 18. If the carrier converted into the intermediate frequency level lies only in the filter area B and at the same time in the inductive area AF of the oscillating element, the output 16 of the counting flip-flop 14 remains constant at a high level. At the output 19 of the counting flip-flop 15 is a pulse with the frequency of the

f> 5 carrier. The monostable multivibrator 17 will not triggered. However, since its output is inverted, the associated input of AND gate 18 is the logical state "one". The other monostable

Multivibrator 20 is from output 19 of the counting flip-flop

15 triggered, so that the logic switching state "one" is also at the second input of AND gate 18 is applied. The lamp 11 is controlled by switching through the AND gate 18 so that it lights up. the Lamp It thus lights up in the respective case in which the output 16 of the flip-flop 14 remains without a pulse signal and only the output 19 of the flip-flop 15 Emits pulse signals.

If there is no received signal, the noise is at the input of the circuit according to FIG. 5 in the same The link between the outputs 19 and

16 of the counting flip-flops 15 and 14 are omitted. This means that the counting flip-flop 15, the monostable multivibrator 20 and the AND gate 18 are not required. In this case the output 16 of the counting flip-flop 14 emits statistical signals. The display by the lamp 11 remains switched off as long as no carrier occurs in the filter area B and the noise is suppressed. If the part of a sideband, noise or interference spectra are detected by the filter area B , the monostable multivibrator 17 switches off the display constantly due to its output-side inversion, since it is continuously retriggered. The delay duration of the monostable multivibrator 17 prevents short-term signal distributions in the filter area B, which could simulate a wearer, from bringing the wearer display through the lamp 11. The monostable multivibrator 17 thus evaluates the constancy of the frequency of the carrier over a longer period of time, while the oscillating element 6 and the phase bridge 5 according to FIG. 2 evaluates the condition for the singular occurrence of a frequency in a limited frequency range.

If interference is superimposed on the carrier in the coordinated case, the monostable switches Multivibrator 17 also turns off the display.

A known disadvantage of previously used AFC circuits is that a strong interferer takes over the frequency connection and pulls the receiver away from the desired signal when the frequency drifts. The circuit according to FIG. 2 and FIG. 5 prevents this.

As soon as the interference signal falls into the pass band B of the carrier filter 1, the A FC function is interrupted and the last frequency state is fixed. In the same way, disturbances of a different character are also kept away from the synchronization system.

An example of this is shown in the block diagram in FIG. 6th

The phase control loop in FIG. 6 that im more usual Way with a phase comparison stage 21, a memory in the form of a shunt capacitor 22 and a tunable oscillator 23 is provided, also has an electronically controlled switch

24 on. Those coming via the residual carrier filter 1 and the amplifier 2 are in the intermediate frequency level converted signals are on the one hand the phase comparison stage 21 and on the other hand the in F i g. 2 recognition circuit 25 shown in principle, i. H. the vibrating element 6 and the ohmic Resistor 3 supplied. From the detection circuit

25 next to the lamp 11, the switch 24 is controlled. The storage capacitor 22 of the control loop has at the same time a short loading time and a long unloading time in order to avoid running away during the selective carrier fading the frequency of the oscillator 23 to avoid.

The phase control loop in Figure 6 follows this Residual carriers at a low speed of, for example, 10 Hz per second. Since the detection switch 25 malfunctions within the time of about one Detects the period duration of the carrier frequency (<0.1 ms) and the switch 24 opens, the oscillator 23 is not affected by disturbances. The fault assessment according to the phase criteria described enables far more effective interference protection than amplitude criteria it is possible.

The display method for the carrier according to the invention can be compared to the beat zero method, in which the receiver is tuned acoustically, a visual display for the completed vote. The tuning status is continuously indicated by a simple lamp during reception. This can can be used well for control functions. If the lamp turns on and off, there will be interference blanked. If the lamp remains dark, no more carrier is detected.

For this purpose 2 sheets of drawings

«09 616/309

Claims (10)

Patent claims: 1. Receiver-side circuit for detecting the attenuated residual carrier of broadcasts, the residual carrier being filtered out of the surrounding sideband signals by a narrow-band filter and tied to a fixed reference frequency with an automatic frequency control (AFC) , characterized in that the filter (1) a first input (7) of a phase bridge (5) is connected via an oscillating element (6), the equivalent circuit diagram of which is formed by connecting a damped series oscillating circuit (Li, Ci, Ri) and a capacitor (CO) in parallel, so that rs two resonance frequencies (fa, fr) , between which the impedance is inductive (positive phase rotation φ) and outside which the impedance is capacitive (negative phase rotation φ), that a second input (4) of the phase bridge (5) is also connected to the filter (1) an ohmic resistor (3) is connected, that the phase bridge (5) is designed so that with a positive phase rotation (φ> 0) through the Sc hwingelement (6) at a first output (9) of the phase bridge (5) a signal and in the event of a negative phase rotation (φ < 0) by the oscillating element (6) at a second output (8) of the phase bridge (5) a signal is present and that a signal-responsive optical display device (11) is connected to one of the outputs (8, 9) of the phase bridge with the interposition of a monostable multivibrator (10). 2. A circuit according to claim 1, characterized in that the vibrating element (6) is a mechanical one Schwinger is provided. 3. A circuit according to claim 1, characterized in that an oscillating crystal is used as the oscillating element (6) is provided. 4. Circuit according to one of the preceding claims, characterized in that the filter (l) an amplifier (2) is connected downstream. 5. Circuit according to one of the preceding claims, characterized by a previous one Implementation of the residual carrier with its sidebands on the intermediate frequency level. 6. Circuit according to one of the preceding claims, characterized in that as. Phase bridge two series circuits, each consisting of a pulse shaper (12, 13), z. B. a threshold value circuit (Schmitt trigger), and a two-edge counting flip-flop (master-slave flip-flop) (14, 15) controlled by this at its reset input (r) , the clock pulse input (Cl) of each counting flip-flop (14, 15) is connected to the reset input (r) of the other counting flip-flop (15, 14) so that the first input (7) of the phase bridge through the input of the first pulse shaper (12) connected to the oscillating element (6) and the second input ( 4) the phase bridge is formed by the input of the second pulse shaper (13) connected to the resistor (3), and that the first output of the phase bridge through the basic position output (16) of the with its reset input (r) at the output of the first pulse shaper (12 ) lying counting flip-flops (14) and the second output of the phase bridge is formed by the basic position output (19) of the other counting flip-flop (15). 7. A circuit according to claim 6, characterized in that at each output of the phase bridge a monostable multivibrator (17, 20) is that dii output signals of the monostable multivibrator (17. 20) an AND gate (18) supplied with which the first output (16) de Phase bridge downstream monostable MuI tivibraior (17) ent the inverted output signal is taken, and that at the output of the AND gate (18) the display device (Il connected. 8. A circuit according to claim 7, characterized by the use of a lamp (U) al Display device. 9. Circuit according to one of the preceding claims, characterized in that the Pha sensor bridge (5) in TTL (transistor-transistor-logic-technology is executed. 10. Use of the circuit for residual carrier recognition according to one of the preceding claims before as an interference protection circuit, characterized in that in a usual / 4FC phase control loop < an electronic switch (24) is provided, dei from the output of the residual carrier detection circuit (25) is controlled in such a way that it opens when there is no: display signal and when there is a: Display signal is closed.