DE2409240A1 - Noise suppression cct. for radio LF signals - has dynamic limiter and regulator with feedback to op. amp. at limiter input - Google Patents

Abstract

The noise suppression circuit, for LF signals in radio receivers, has a dynamic limiter in the path of the signal which limits the amplitude of signal components with sudden spikes. The limited signal is coupled back to the non-inverting input of an operational amplifier at the limiter's input. A regulating stage is connected after the limiter and reduces signals that fall within its regulating range by amounts proportional to the amplitude of the operational amplifier's output, i.e. the lower the output, the greater the reduction. Several limiters with different time constants may be connected together in a chain.

Description

Circuit arrangement for suppressing interference in a GF signal The invention relates to a circuit arrangement according to the preamble of the patent claim 1.

ei radio receivers of all types there is the problem that in addition in addition to the waves emitted by broadcasting stations, waves can also be received, that come from electromagnetic fields that are generated by the operation of motors, Switches etc. arise. Such additional waves can be audible in the receiver Disturbances appear. This problem is particularly relevant for recipients which are installed in motor vehicles, because there interference waves constantly during normal operation available.

Line remedy was first sought in that as possible all disturbances devices causing interference are suppressed. This procedure then helps to a partial one Success when all interfering devices are fixed to the recipient, as is the case with a motor vehicle and are practically not exchanged. However, you can use it via the antenna interspersed disturbances are not eliminated. Plus there is the effort for this Type of interference suppression very high because it requires expensive components and for each individual Receiver and the interfering devices must be carried out individually.

For these reasons it is beneficial to completely eliminate interference to be carried out in the recipient itself.

These are. already known circuits that use fault detectors work and, if a fault occurs, the received signal briefly switch off. So that the blanking gaps are nic, h-l; made strongly disturbing noticeable, is according to the DOS 2.051.891 with the help of a storage capacitor and pulse formers in the blanking interval switched a fill signal, which is from the reception signal directly before the control and an additional component generated with pulse shapers is obtained.

This procedure reduces the disturbances considerably, but leads in particular with continuously occurring disturbances to distortion of the received signal, because then a high proportion of the reproduced signal is reshaped.

The present invention is based on the problem of interference suppression to develop, which does not have the basic flat parts of the known circuits having.

According to the invention, the object is achieved with a circuit arrangement the characterizing part of claim 1 solved.

The advantage of this solution is that the received signal is always remains in the signal path, i.e. is not blanked at any time. So there are no replicas of signal parts necessary, the resulting distortions do not occur.

The subclaims provide further developments and implemented circuits to the principle of claim 1. Your advantages are obvious from the description.

The invention is explained in more detail with reference to FIGS.

1 shows a basic circuit diagram of a radio receiver the circuit according to the invention, Fig. 2 is a block diagram of the circuit according to the invention with a control, FIG. 3 is a basic circuit diagram of the Circuit according to the invention with the use of a limiter as a control voltage generator, FIG. 4 is a basic circuit diagram of a further developed circuit according to FIG. 3, FIG. 5 is a circuit diagram of a dynamic limiter, FIG. 6 is a circuit diagram of a dynamic limiter with additional devices, Fig. 7 is a circuit diagram of a dynamic limiter with a blocking device for pilot frequencies, Fig. a Circuit diagram for switching off the control for pilot frequencies, FIG. 9 is a circuit diagram another dynamic limiter.

Fig. 1 shows a basic circuit diagram of the circuit according to the invention within a common radio receiver.

The received PF signal reaches a receiver part via an antenna 1 2 and is converted into the ZF. This is followed by an IF section 3 and a demodulator 4 at. The LF signal obtained in this way is usually amplified in a Ni1 output stage 5 and at least one loudspeaker 6.

Between the demodulator 4 and the LF output stage 5 is the inventive Circuit inserted. It consists of a dynamic limiter t3 and an upstream operational amplifier 7. The output signal of the dynamic Limiter 8 is fed back to the inverting input of the operational amplifier. The dynamic limiter 8 has an amplitude-limiting effect on signal components that suddenly occur occur and have a steep slope. The normal hat signal components are not influenced by the dynamic limiter 8. Since disturbances are practically always Suddenly occurring very steep signals are, they are with this circuit principle effectively suppressed. In order not to lose sound quality and eventual Compensating for distortions caused by the limiter is a negative feedback via the Operational amplifier provided, which causes the llutzsignal at the terminal D corresponds to the useful signal component at terminal A.

Since the dynamic limiter 8 due to its mode of action always a certain residual interference is let through, especially with small useful signals can have a disruptive effect, a circuit is shown in Fig. 2, which the signal at the input the limiter 8 brings to an approximately constant, high level.

Printer the operational amplifier 7 a signal is picked up that a control stage 9 via a control voltage generator 10 is supplied.

The control stage 9 divides the useful signal down the more the weaker it is the signal at the input of control stage 9 is. The divided signal determines the gain of the operational amplifier 7. The operational amplifier raises so a weak signal is stronger than a strong one, so that at the limiter an approximately constant signal level is present, which is chosen so high that the residual interference become imperceptible.

In Fig. 3, the control voltage generator stage is at the same time as the second Limiter 1i used. The second limiter 11 has a much larger one Time constant as the limiter 8 and is connected upstream of it. Through the interconnection two delimiters with different time constants becomes the - delimiting effect much improved.

A limiter with a small time constant can add to the IF signal follow well and limit disturbances that occur very briefly. A dynamic one Limiter with a large time constant, on the other hand, follows the envelope of the useful signal. Disturbances that extend beyond the envelope are so limited that they only still have parts that are below the envelope. The dynamic limiter with a small time constant is able to deal with the previously limited interference components final limit. The pre-limiter prevents the dynamic limiter with the small time constant is overloaded by very large interference signals.

The combination of two or more limiters with different ones Time constants therefore lead to significant improvements in the interference suppression effect.

A limiter with a large time constant involves rectification and integration of the IT user signal, so it can be used to generate control voltage will.

Fig. T. shows a further developed circuit in which a special 1-measure to prevent vibrations caused by the strong negative feedback the circuit can occur is realized. To regulate the degree of negative feedback the signal fed to the control stage 9 is used to control the gain factor at the same time of the operational amplifier 7 used so the gain within the negative feedback loop remains approximately constant. Vibration processes can be soin do not arise.

In Pig. 5 shows a dynamic limiter 8. The received The HF signal is converted into the LF in the device. The amplified LF signal is then available at terminal A 'and reaches the base of an impedance converter via a resistor RE T3 in collector circuit. The output signal of the dynamic J3 limiter 8 is present via an emitter resistor RA of the impedance converter T7 at the terminal B '. The impedance converter On the collector side, T3 is directly connected to a positive supply voltage terminal UB and on the emitter side to ground via the emitter resistor RA. At the base of the impedance converter T3 is the base of a first transistor T1 and a second transistor T2. The first transistor T1 is an npn transistor, which has its collector over with t a collector resistor R11 is connected to the positive supply voltage terminal U i.

A resistor R1 and R1 are connected in parallel to the emitter a capacitor Cl connected, the other end of which is connected to ground.

The second transistor T2 is a pnp transistor. His collector is lying via a collector resistor R22 to ground. A capacitor is also connected to ground C2, the other end of which is connected to the emitter of transistor T2 is. The emitter is connected to the positive supply voltage terminal via a resistor R2 Ug connected.

The two transistors T1 and T2 act in the same way, however for different slope polarities of the LF signal. You own at normal Slopes due to the negative feedback via the emitter resistors R1 and R2 2 high input resistance, so that they do not represent a burden for the signal sweep. Via the base-emitter path of the first transistor T1 and your capacitor Ci finds for relative peak rectification takes place at high frequencies. At low frequencies, the capacitor follows the useful signal with its charge.

The interference signals with their steepness of the pulse edges are passed through the condenser Ci directly to the wet. When interference pulses occur namely, the emitter of the transistor 11 can because of the through the collector resistance R11 limited collector current no longer follow the signal and the transistor Ti gets saturated. This gives it a low input resistance. Consequently it represents a high load on the signal path. At the base of the impedance converter At this point in time, T3 receives a reduced control signal, so that the interference pulse is effectively limited and not significantly via the undisturbed useful signal can increase. The second transistor T2 works analogously to the first transistor Ii for signal components with a different slope polarity.

An improved circuit of a dynamic limiter 8 is shown in FIG. 6th

The collector resistance R11 and R22 of the transistor T1 and 12, respectively replaced by a current source 14 or T5 that switches on with a delay.

If an interfering signal occurs, the current through the relevant Transistor T1 or T2 delayed by the fact that the base bias for the associated Current source 14 or 15 via the charging of a voltage divider R4, C4 or R5, C5 located capacitor C4 or C5 must build up. The voltage divider R4, C4 is connected to the positive supply voltage terminal with its capacitor C4 UB and connected to the collector of the current source 14 with its resistor RX1.

The connection point between the resistor R4 and the capacitor C4 is at the base of the power source 14.

The voltage divider R5, C5 is connected analogously to the current source T5, however, the capacitor C5 is grounded. Due to the delayed release of the current flow the respective capacitor is charged by the transistor T1 or 12 Ci or C2 by the glitches causing a residual disturbance is delayed and thus reduced.

Fig. 7 shows a circuit of a dynamic limiter which is advantageous is used for programs with pilot tones (e.g. £. stereo programs). The Pilo frequencies act as interference in the ITF signal and would reduce the interference suppression capacity of the dynamic Limiter claim. Since the pilot tones cannot be heard, they interfere with playback not. For this reason, the interference suppression with the help of this circuit is for certain Frequencies made ineffective.

behind the capacitors C1, G2 of the two emitter followers Ti, T2 parallel circles towards ground Lp, Cp; Lp ', Cp' switched that the interference suppression function and prevents the dynamic charging of the capacitors C1, C2 for the frequencies to which the parallel circles Lp, 0 and p Lpt, Cp 'are matched.

Another way to avoid the effects of pilot tones FIG. 8 shows the interference suppression circuit. The circuit follows the basic circuit diagram 2. As mentioned there, the control stage 9 consists of a controllable resistance divider. The signal is divided down here with the help of a field effect transistor (FET) 13, which, as a controllable resistor, applies part of the useful signal to ground. The resistor divider is supplemented by a fixed resistor 14. In the ratio, in which the signal is divided down, it is transmitted by the operational amplifier 7 reinforced again. This means that the signal at terminal B is the same size as that at terminal A at.

The subdivision is overridden for the pilot frequencies, since the FEI 13 has trap circuits Lp, Cp; Lp ', Cp' is due to mass. Thus, no current for the pilot frequencies can flow via the FET 13. The pilot frequencies are applied to the inverting input of the operational amplifier 7 counter-coupled, so no longer reinforced. This means that the : Limiter 8 the pilot frequencies only with a low amplitude relative to the reset signal on, since only the residual signal is amplified by the operational amplifier 7, and hinders the interference suppression no longer.

bb. 9 shows an alternative circuit of a dynamic limiter 8 represents.

The signal present at terminal A 'passes through a low-pass filter, consists of a first resistor 101 and a capacitor 102 on which not inverting input of an operational amplifier 103. To the inverting input of the operational amplifier 103, the signal comes from the terminal A 'via a second Resistance 104.

There are two parallel positions at the output of the operational amplifier 103 a resistor 105 or 105 'and a capacitor 106 or

106 ', one of which is connected to the cathode of a first Diode 107, the other is connected to the anode of a second diode 108. the Diodes 107, 108 are connected to the inverting input at their respective other ends of the operational amplifier 103 is connected.

The output signal is at the inverting input of the operational amplifier 103 removable. The operation of this circuit is similar to that of the Circuit in Fig. 5. Depending on the type of signal gain, one or one acts the other parallel connection 105, 106 or 105 ', 106' via the corresponding diode 107 or 108 would be limiting if the parallel positions instead of the output of the operational amplifier 103 switched against hasse, the threshold voltages of the diodes 107, 108 voltage surges remain in the signal.

When a fault occurs, the potential at the output of the operational amplifier 103 shifted in the direction that an immediate displacement of the diode concerned 107 or 108 in the conductive state causes a signal with high frequency components because of the passport 101, 102 a difference in the signals at the inverting and non-inverting input.

The voltage jump, which would otherwise cause a disturbance in the signal due to the diodes takes place in this circuit at the output of the operational amplifier 103 and affects the signal.

Claims (11)

Claims 1. Circuit arrangement for suppressing interference in an LF signal a radio receiver, characterized in that in the signal path a dynamic Limiter (8) is built in to reduce the amplitude of suddenly occurring signal components high steepness with a low limiting level with respect to the residual signal and that the limited signal on the nichl; inverting input of an operational amplifier (7) is fed back. '. S circuit arrangement according to claim 1, characterized in that that behind the limiter (3) a control stage (9) is provided, which the signal The smaller the amplitude, the more subdivided it is within a control range of the output signal of the operational amplifier (7). 3. Circuit arrangement according to claim 2, characterized in that a limiter (11) also serves as a control voltage generator. 4. Circuit arrangement according to one of the preceding claims, characterized characterized in that several limiters (8, 11) with different time constants are connected in series. 5. Circuit arrangement according to one of claims 2 to 4, characterized characterized in that a control voltage generator (12) the gain of the operational amplifier (7) regulates. 6. Circuit arrangement according to one of the preceding Snsprüche, thereby characterized in that the limiter (8) consists of at least two transistors (T1, T2) exists, which are of different polarity, whose bases are driven by the useful signal and their emitters are connected directly to ground via capacitors (C1, C2) are on the other hand via an associated emitter resistor (111, R2) with the relevant Supply voltage terminal are connected and their collector current is limited. 7. Circuit arrangement according to claim 6, characterized in that between the collectors of the transistors (T1, T2) and the relevant supply voltage terminals depending on the current source (T4, T) that is switched on with a delay is switched. 4 2 8. Circuit arrangement according to claim 6 or 7, characterized in that daa the limiter (3) for pilot frequencies through blocking circuits in the capacitive connection of the emitter of the transistors (T1, T2) and ground is ineffective. 9. Circuit arrangement according to one of claims 1 to 5, characterized in that that the limiter (8) with a differential amplifier (103) with a high gain factor is constructed, which has an inverting and a non-inverting input, that a low-pass filter is connected in front of the non-inverting input, that the input signal from the limiter to the inverting input of the differential amplifier (103) and is connected to anti-parallel connected diodes (107, 108), each via one Parallel connection of a resistor (105, 105 ') and a capacitor (106, 106t) are at the output of the differential amplifier (103) and that the output signal of the limiter at the inverting input of the differential amplifier (103) can be removed is. 10. Circuit arrangement according to one of claims 2 to 9, characterized characterized in that the control stage (9) is ineffective for pilot frequencies. 11. Circuit arrangement according to one of claims 2 to 10, characterized characterized in that the control stage (9) consists of a voltage divider with a fixed resistor (14.) and an adjustable resistor (13) ordered and the adjustable resistor is due to the wet. T2. Circuit arrangement according to Claim 1, 1, characterized in that that between = the adjustable resistor (13) and ground blocking circuits (Lp, Cp; Lp ', Cp ') which are tuned to the pilot frequencies.