DE2642755A1 - Noise suppression gate circuit for AM radio receiver - has second gate and second demodulator to fill breaks when first noise gate opens - Google Patents

Abstract

The noise suppression circuit, for an AM radio receiver, has a gate in the LF signal path opened, when a noise pulse is detected. The gate is connected to the output of the mixer/filter stage andis followed by a bandpass filter, amplifier and the AM demodulator. The amplifier output is gated by a second gate operating out of phase in relation to the first one, to a second bandpass filter and a second AM demodulator. The outputs of the two demodulators are added and the sum used to drive the loudspeaker output stage. The second demodulator compensates for the break caused by the opening of the first gate due to noise.

Description

Circuit arrangement for suppressing interference pulses in an AEf receiver

The invention relates to a circuit arrangement for suppression of interference pulses in an AM receiver, which are arranged in the RF signal path Has gate circuit, which is detected by an interference voltage detector upon receipt Interference pulse is supplied with a blocking pulse.

With such circuit arrangements should be prevented that with The interference pulses picked up by the received signal reach the LF amplifier. This problem occurs in particular with receiving devices that have electrical facilities in Vehicles are operated.

It is known to use the RF input section of a receiver to convert interference pulses detected by an interference voltage detector into blocking pulses and to use these to sample the composite signal to be transmitted in the RF signal path. Here Although the actual interference pulses are largely blanked out, the resulting ones However, blanking intervals generate perceptible noise. The one in a blanking which corresponds to a 100% square-wave AM modulation, the resulting pulse edges also cause the resonant circuits downstream of the blanking stage to be triggered.

A bridging of the blanking time by the ringing of an HF storage circuit, which is located behind the gate circuit would only make sense if on a clearly selected RF carrier would be present at this point. The blanking takes place before the actual selection stage, the storage circuit can use neighboring frequencies are excited, which leads to incorrect level values. Arranging the gate circuit at points with a higher selection does not make sense either, because of the narrower ones Bandwidth too long blanking times are required.

The invention is based on the object that by blanking gaps to reduce the background noise caused.

This object is achieved according to the invention in that one in the IF signal path arranged first gate circuit is followed by a first IF selection block, its output via an RF amplifier with the input of a first AM demodulator and via a further RF amplifier with the input of an inverse to the first gate circuit switching second gate circuit is connected, the output of which has a second IF selection block is connected to the input of a second AM demodulator, that the outputs of the AM demodulators via an adder with the input of a LF amplifier are connected and that the switching means are dimensioned such that one occurring as a result of an interference pulse at the output of the first AM demodulator Residual interference signal resulting from a constriction of the IF amplitude after the first Selection block results from a correction signal that can be taken from the second AM demodulator is compensated, which the during the duration of a noise blanking over the second gate circuit excited second selection block is removed.

The advantages achieved with the invention are in particular: that the blanking intervals are not perceptible as interference and that the compensation the LF signal components are independent of the phase position of the IF signal.

An embodiment of the invention is shown in the drawing as a block diagram and is described in more detail below.

An RF input stage 1 of an AM receiver is known per se Way with a mixer 3 connected to an oscillator 2 as well as with a Interference voltage detector 4 connected. The output of the interference voltage detector 4 is with the control input of a first gate circuit 5 and an inverting switch member 6 with the control input of a second gate circuit 7 connected.

The actual IF signal path starts from mixer 3 Via a delay element 8 acting as a low-pass filter, the first gate circuit 5, a first IF selection block 9 and via an RF amplifier 10 to a first AM demodulator 11. The output of the RF amplifier 10 is adjustable in its gain via a HF amplifier 12 is connected to the input of the second gate circuit 7. A second IF selection block 13 connects the output of the second gate circuit 7 with one second AM demodulator 14. The outputs of the first AM demodulator 11 and the second AM demodulator 14 are connected via an adder 15 to the input of an LF amplifier 16 connected.

If an interfering pulse is received at the same time as a useful signal, so This arrives together with the useful signal via the mixer 3 and the delay element 8 to the input of the first gate circuit 5. The one in the RF input stage 1 occurring interference pulse responsive interference voltage detector 4 leads the first Gate circuit 5 to a blocking pulse, which briefly interrupts the IF signal path. The IF signal having a blanking interval is sent to the first IF selection block 9 fed.

The blanking interval causes a flat one in the first selection block 9 Constriction of the amplitude of the IF signal, which is behind the first AM demodulator 11 occurs as a perceptible residual interference signal. The relatively sluggish reaction of the first IF selection block 9 for blanking intervals is used to generate a signal at the output of the RF amplifier 10 removed IF signal operated with the help of the inverse of the first gate circuit 5 second gate circuit 7 dem.

second IF selection block 13 to be supplied. The second IF selection block 13, which is the same as the first IF selection block 5, is only for the duration of one Interfering pulse via the second gate circuit 7 excited. That at the exit of the second Selection block 13 occurring IF signal has an envelope curve that opposes the envelope curve of the IF signal exhibiting a constriction, which is on Output of the first IF selection block 9 or at the output of the RF amplifier 10 occurs. With the adjustable RF amplifier 12, the amplitude of the am Set the output of the second AM demodulator 14 removable correction signal in such a way that that it corresponds to the amplitude of the residual interference signal which can be removed at the output of the first AM demodulator 11 equals. Since the two signals have opposite polarities, in the adder 15 fully compensates for that caused by the blanking interval Residual noise.

L e r s e i t e

Claims (2)

Claims 29 Circuit arrangement for suppressing interference pulses in an AM receiver, which has a gate circuit arranged in the RF signal path has, which upon receipt of an interference pulse detected by an interference voltage detector a blocking pulse is supplied, characterized in that one in the IF signal path arranged first gate circuit (5) is followed by a first IF selection block (9) is, the output of which via an RF amplifier (10) to the input of a first AM demodulator (11) and via a further RF amplifier (12) with the input of an inverse to first gate circuit (5) switching second gate circuit (7) is connected, the Output via a second IF selection block (13) with the input of a second AM demodulator (14) is connected that the outputs of the AM demodulators (11, 14) are connected to the input of an LF amplifier (16) via an adder stage (15) and that the switching means are dimensioned such that a result of a noise blanking pulse residual interference signal occurring at the output of the first AM demodulator (11), which results from a constriction of the IF amplitude after the first selection block (9), compensated by a correction signal that can be taken from the second AM demodulator (14) which the during the duration of a noise blanking pulse via the second gate circuit (7) excited second selection block (13) is removed. 2. Circuit arrangement according to claim 1, characterized in that the further RF amplifier connected upstream of the input of the second gate circuit (7) (12) is adjustable in its gain value.