DE2602908A1 - Control circuit for squelch suppressor - is for FM broadcast receiver and uses AFC voltage generated during tuning process - Google Patents

Abstract

The AFC voltage is delivered by the demodulator whose bottom side is held at half the supply voltage, to two terminals of a diode bridge, whose other two terminals are connected to the inputs of a differential amplifier. Its output is connected to a first input of a switch in the 1.f transmission channel. This switch is also controlled through a second input by the receiver AVC voltage. The circuit arrangement includes a four diode rectifier bridge (6) connected to an operational amplifier (9) with its output leading to an operational switch. The power supply voltage (UB) is fed to the amplifier input through two equal resistors (7,8).

Description

DESCRIPTION Circuit for obtaining a switching signal for a Squelch in an FM receiver As a qualitative measure of sensitivity of an HF receiver, the signal-to-noise ratio at the output applies, based on a certain input voltage. In order to have the lowest possible input voltages To obtain a sufficient signal-to-noise ratio, this must be due to the fully effective high signal amplification also increases the inherent noise of the receiver appropriate circuitry measures - such as

described in DOS 1 939 422 - be reduced0 at very low Input signal (remote transmitter) or during the tuning process between the Transmitters, the acoustic disturbances are caused by the highly amplified noise so strong that a suppression of useful noise voltage also takes place mustO Such a suppression is usually implemented by one in the receiving circuit integrated squelch made by a switching signal, the zaBo the noise voltage was derived, switched on or off.

There are different1 more or less laborious methods of extraction of a signal for a usable squelch has become known.

A well-known very simple way from the circuit of a EM mono or stereo receiver to derive the switching criterion for a squelch, consists, for example, in the use of the direct voltage on the hade electrolytic capacitor of the ratio detector, which is usually used for an AVC0 The disadvantage here is what remains Tuning noise on the flanks of the pass curveX especially in receiving circuits with high IF gain.

In the case of stereo receivers, the noise components that are above are used of the NF useful signal range between 20 and 100 kHz arise, Such Circuits - as they are known z0B0 from DOS 1 948 009 - do work a reduction of the tuning noise on the pass flanks, speak under certain circumstances but also on the useful signals that are on both sides of the stereo subcarrier as Difference signals in the frequency range from 23 to 53 kIlz are included. Because of this, Very intensive signal spectrum, especially with inverse modulation of the stereo channels , the transmitter signal-independent noise voltages are partially covered, and it can also with optimally tuned receivers and one with sufficient energy incoming transmitters cause an undesired response of the squelch, The The invention described below relates to a circuit for generating a switching signal for controlling a squelch in a BM broadcast receiver, the said does not have disadvantageous holding of the circuits known in this regard, task the invention is to use the existing AVC and APO voltages from the demodulator clean up in a simple and inexpensive circuit arrangement so that they, independently of one another, always interrupt the NS signal path when the Signal-to-noise ratio over the entire tuning range a certain (adjustable) Value falls below 0 The inventive solution to this problem is based on the Bigo1 explained The circuit arrangement 1 contains an electronic component combination for generating a switching signal for closing or opening a NP signal path 2 from DC voltages, the level and polarity of which are dependent in a known manner the receiver tuning in the ratio detector 3 forming the essential characteristics the invention is limited to the arrangement 1, needs here to the closer Details of the circuit complexes 2 and 3 connected to it are not discussed in greater detail zu werden0 As a result of the base point of the ratio detector 5 set to Ub / 2 the voltage at the connection points 4 and 5 exactly in each case Plus UB / 2, when the transmitter to be received is tuned to the maximum in the receiver. So is the diode matrix 6 consisting of the diodes D 1 - D 4 blocked and the one in series Resistors 7 and 8 connected to the supply voltage UB determine this DC voltage potential at the two inputs of the operational amplifier 9 in the way that the plus input (+) is on itinus potential and the ninus input (-) is at plus potential the voltage at the output 10 of the operational amplifier equals zero 0 is the transmitter tuning the output voltage on the demodulator characteristic of the ratio detector is not optimal non-zero and has either a positive or negative amount opposite the base point 5 to 0 This creates a potential shift at the input of the Operational amplifier 9, because with an increase at point 4 in the positive direction the diode D 2 shifts the (+) - input to the potential + UB0 This means that the two are Input voltages at the operational amplifier are unequal and the output potential drops by leaps and bounds to the value fU. The process is the same if the demodulator is at a detuning at point 4 creates a negative voltage. Then moves the positive potential at the (-) input in the direction of to the negative potential, which is also the potential position + UB of output 10 This output voltage has the consequence in the disadvantageous switching electronics 2 an interruption of the NP transmission path at line point 11o with the changeable Resistor 12 can adjust the switch-on range of the squelch depending on the Detuning of the receiver can be set 0 Detuning by the amount af (Fig0 25 causes a potential shift at point 4 that is less than that Threshold value Us, whereby the squelch does not open yet, reaches the detuning f = fo-f 1 and / or = f2-fo, is the potential shift at the input of the operational amplifier 9 by increasing the potential at point 4 by + Us or (-Us) so large that the output voltage at point 10 jumps to + UB and this opens switch 11, expediently the detuning bandwidth B = f2-f1 is chosen so that the linear part of the demodulator characteristic can be used optimally0 The circuit is in the above-described Porm the two The flanks of the transmission curve are very noiseless initiate transition into or out of the locked state, but the squelch between take the transmitter out of the puncture again, as there is no ABC voltage for control there is more of the diode matrix. FM receivers can be used to remedy this deficiency AVO voltage that is almost always present, e.g. from the IF section, can be used is used in a known manner to display the field strength. For this AV0 voltage, only if the transmitters are sufficiently strong, such as a correspondingly high one positive, but has a low value between the transmitters, in suitable Way via the connection 13 in the squelch, in which it is the contact 14 controls, the reception noise between the transmitters in the frequency range The two control variables modified according to the invention are suppressed The AFC voltage and the AVC voltage are practically two variables that make up the squelch always operate independently of one another if as a result of a receiver misunderstanding or weak transmitter field strength, there are no reception conditions, the functional Correlations in the manual coordination between the transmitters are f01 ... f011 shown in Fig. 3. Above a fixed detuning, the modified one opens AFC voltage switch 11, doho the squelch is turned on. So be the tuning noise suppressed at the passage flanks. Where the converter curve furthermore goes to zero, there is no longer any ASC voltage available, the Switch 11 closes. However, now the AVC voltage is below a certain level Threshold value, whereby the switch 14 is opened, dçh. the squelch kicks in in function in the frequency ranges Zw. The squelch is only inoperative when both switch contacts 11 and 14 are closed 0 This is the Pall in the frequency range Bo The circuit of FIG. 4 shows an embodiment of the actual squelch 3, which can be controlled by the circuit arrangement 1 according to the invention. at Plus potential at input 10, i.e. AFC voltage ## Us, (see Fig. 1) the transistor T2 switches through via the diode D1 and closes the LF voltage At point A against Nasse, the voltage of the AFC is the same for a short time between the transmitters zero, and thus no voltage at the input 104. The transistor T2 would be blocked and so that the LF path is switched through, if not the missing voltage of the AVC in the frequency range Zw bring the collector of T1 to positive potential via terminal 13 and thus the transistor T2 would also switch on via T1, with the adjustable resistor 15 the response threshold of the AVC control can be set.

The method of the circuit preparation according to the invention the AVC and APO voltage to control a squelch, can be in a Further development of the invention for switching on the APO voltage as a function of voting to take advantage of the retuning elements.

As is well known, leads in FM radio receivers with APO, which are not optimal coordination of the receiving circuits on the transmitter to be received Retuning voltage from the demodulator on the one hand to an early capture, on the other hand too large a fold area of the sender unwanted behavior of the APO is prevented by a so-called AFC button in the Way that the AFC voltage during the manual tuning process from the tuning circuits is switched off and switch on ersU after the most favorable manual vote by reiter carries out an electronic readjustment process. This additional operation and the additional button is bypassed in more complex device designs, that switching electronics to switch off the AFC is always activated when the voting device is touched (touch control). Such facilities require however, an increased effort, since, among other things, the mechanical contact element, e.g. the tuning button, mounted isolated in the chassis and with a failure-prone Sliding contact must be provided.

Using the circuit arrangement 1 shown in FIG. 1 can be derived from the voting-dependent criteria of the APO uo AVC in very simple, but practically very convincing way without additional manual initiated processes or the use of tuning components, the tasks of a Fulfill the AFO connection to the voting circuits.

This solution according to the invention is explained with reference to FIG. 5.

The RDT network shown in Fig. 4 is with its connection 10 connected to the operational amplifier output A in the circuit of FIG. Of the Transistor T2 gives the supply loop of the APC voltage over the distance 16-1 ?, i.e. from the ratio output to the voting circles only free if either one is sufficient high AVC voltage switches transistor T1 through or the voltage at point 10 is so low that it is not sufficient to switch transistor T2 through via diode D2 This means that the ABC voltage automatically drops out in area B of the converter characteristic according to Zig. 2 is switched to the voting circuits, and - bypassing one usually always existing bang area - the transmitter catch point exactly at + Us resp. - Us (s0Pig0 2) lies. This guarantees that the residual detuning is very high low is 0 The drag end of a transmitter captured by the ABC voltage is also f1 or f2 depending on the voting direction.

Overloading the received transmitter fo1 over the possibly

weaker transmitter fo2 is no longer possible.

Since a correction voltage is within the frequency range B = f2-f1 will come into function that the ABC voltage occurs with the greatest possible accuracy the reception frequency fo pulls, a tuning display instrument is unnecessary. These Pointer instruments are used under a wide variety of names (vote or Tuning) built into FM radio receivers and serve as a tuning aid or Voting indicator. By doing without such a mostly quite expensive component, the if there are still slight detunings, it is also quite insensitive and - because of the coincidence of the mechanical zero point and the pointer position with optimal coordination - is not very accurate, the circuit arrangement is after Fig. 4 from connection point A with a simple circuit addition according to Pig. 6 one Arrangement created simultaneously with switching on the ASC and squelch a signal lamp Al lights up, which shows the operator the Optimal station tuning signals 0 The tuning display circuit is working as follows: If a positive potential appears at output A of the circuit according to FIG. if the vote is outside of range 3, the transistor will T3 through in the circuit of Fig. 6 and thereby connected to the collector Block transistor T4. The La lamp does not light up. Only within the tuning range B (see Fig. 2 and 3) the lamp lights up and signals that the vote has "clicked into place" on the receiving frequency.

This circuit according to the invention can be used as a function of any other switching processes depending on the position of the transmitter tuning in the receiver trigger, e.g. switching on a stereo decoder or start-stop of a station search In all cases, the two present in each PM receiver are variable AFC and AVC voltage are the control variables of the circuit arrangement according to the invention 1 according to FIG. 1, these switching operations in the advantageous manner described initiate optimally.

Claims (1)

P A T E N T A N S P R Ü C H E 1. Circuit arrangement for control a blockage barrier in FM radio receiving circuits, characterized in that the AFC voltage from the demodulator that forms during the tuning process, whose base point is raised to half the operating voltage, one on 2 connections Diode bridge is led, and that the other two connections of the diode bridge n lead the two inputs of an operational amplifier, and that its output with the first input of an electronic switch located in the LF transmission path is connected and this switch at the same time via a further second input is controlled by the AVC voltage of the receiver, 20) circuit arrangement according to Claim 1, characterized in that the contact path to be switched of the electronic Switch is inserted into the AFC lead to the transmitter tuning elements. 3o) circuit arrangement according to claim 1 and 2, characterized in that that the output of the operational amplifier with an electronic lamp or Instrument display circuit connected 0