EP0767553A1 - Circuit for generating short muting impulses in a car radio receiver - Google Patents

Abstract

The arrangement includes a bandpass filter (1), logarithmic operator (2), diode (3), and low pass filter (4). The input signal (MPX) is passed through these to produce a signal (S2). This signal is then operated on separately by an adder (5), which increases the signal level (pref. by 0.6V), and by two independent time-constant delay circuits (6,7). The outputs of each of these circuits are fed to respective inputs of a level comparator (8) with the adder output being fed to the reference input (A). The comparator output (S6), which is essentially a negative pulse of short time span (pref. about 8 ms), is then fed to a radio muting circuit.

Description

The invention relates to a circuit arrangement for a car radio according to the preamble of claim 1.

Such a circuit arrangement is useful, for example, in the case of a mobile RDS receiver (radio data receiver) with which alternative transmitters are briefly checked for their reception quality. So that interference signals that occur during the duration of the check cannot reach the loudspeaker, it is necessary to briefly mute the LF signal by means of a blanking pulse. However, since an abrupt muting during an existing LF level causes cracking noises that are perceived as disturbing, measures are necessary to reduce them to such an extent that they are as imperceptible as possible.

To reduce such interference, it is known, inter alia, to generate the control pulses for blanking and transmitter checking when the LF signal has modulation pauses. Since uncovered alternative frequency tests (AF tests) can also be heard during modulation pauses at lower field strengths, it has proven to be expedient to have a blanking signal of approximately 8 ms followed by a prohibition time of approximately 1 to 2 s. From the manual "Tonstudiotechnik", 2nd edition, pages 101 and 102, Johannes Webers, Franzis-Verlag Munich, it is known that when a constant tone of constant intensity is suddenly applied, the full volume is only perceived by the ear after a certain time. The settling process, which has an exponential character, has a time constant of approximately 23 ms. The situation is similar with the hearing decay process, which is also exponential and has a time constant of around 25 ms.

The invention has for its object to provide a circuit arrangement for a car radio, with the control pulses for short-term alternative transmitter checks are generated with simultaneous muting, the muting should not be perceived by the human ear as noise.

This object is achieved by the measures specified in the characterizing part of claim 1.

The advantages achieved by the invention are, in particular, that the short-term muting takes place within the hearing shadow recognized by the circuit arrangement and caused by the decaying process of the hearing. Since frequent testing of alternative transmitters with large reception field strengths and with modulation can take place, a control provided for the selection of transmitters with a decreasing reception field strength is already informed of the transmitter landscape, so that alternative frequency tests do not have to be carried out hastily.

Advantageous embodiments of the invention are specified in the subclaims. The inclusion of the mean signal level according to claim 2 prevents an interference spectrum resulting from relatively steep signal blanking edges from taking effect. A pulse shaper stage according to claim 3 prohibits a further pulse output after the control pulse for a predetermined period of time. With arrangements and dimensions according to claims 4, 5 and 6, logarithmic levels corresponding to the amplitude profile of the LF information can advantageously be generated. With an arrangement according to claim 7, the response point can be determined, which guarantees sufficient coverage of the noise within an auditory shadow. The formation of the time constant elements according to claim 8 ensures that different volume (modulation stroke) of the transmitter has no effect on changed behavior of the system. The criterion for the control of the short-term alternative frequency blanking is exclusively the dynamics of the modulation.

An embodiment of the invention is shown in the drawing and is explained in more detail below.

Fig. 1

ein prinzipielles Blockschaltbild einer Schaltungsanordnung für die Erzeugung kurzzeitiger, zur Stummschaltung und Senderüberprüfung dienende Steuerimpulse und

Fig. 2

einen NF-Signalverlauf und weitere daraus abgeleitete Signalverläufe.

Show it:

Fig. 1

a basic block diagram of a circuit arrangement for the generation of short-term, for muting and transmitter control serving control pulses and

Fig. 2

an LF signal curve and further signal curves derived therefrom.

The output of an LF bandpass filter 1 provided with an amplifier stage is connected to the input of a double-path logarithmizer 2, the output of which is connected via a double-path rectifier 3 to the input of a second-order low-pass filter 4 having an amplifier stage, which has a cutoff frequency of approximately 23 Hz. The output of the low pass 4 is connected to the input of an adder 5, to the input of a first time constant element 6 and to the input of a second time constant element 7. The output of the adder 5 is connected to the first input A of a level comparison stage 8 designed as a logic circuit. The output of the first time constant element 6 is connected to the second input B of the level comparison stage 8 and the output of the second time constant element 7 is connected to the third input C of the level comparison stage 8, the output D of which is connected to the input of a pulse shaper stage 9. The adder 5 adds a DC voltage level to the input level supplied to it of, for example, 0.6 volts. The first and the second time constant elements 6, 7 are designed such that their output levels change largely linearly as a function of time. A rate of change of, for example, 18 volts per second is provided for the first time constant element 6 and, for example, 1 volt per second for the second time constant element 7. The pulse shaper stage 9 is designed such that it outputs a control pulse (S6) with a duration of, for example, 5 ms when it receives an input signal from the comparison stage and is then blocked for a further period of time equal to or greater than 100 ms.

It is assumed that a multiplex signal (MPX signal) is available in a car radio (not shown) which is known per se and that a control pulse with a duration of approximately 5 is used for muting and for a transmitter check to be carried out during this muting time of, for example, 8 ms ms should be generated.

The LF signal S1 filtered out of the MPX signal by means of the bandpass filter 1 is fed to the second-order low-pass filter 4 via the two-way logarithmizer 2 and the two-way rectifier 3. 2 shows the course of such an LF signal S1 on a linear scale. At the output of the low pass 4, a signal S2 can be taken, the course of which corresponds to an envelope of the rectified and screened LF signal, the logarithmic signal S2 being amplified to a value of 1 volt per 10 dB level change. The envelope signal S2, which is raised by a DC voltage level of 0.6 volt, is fed to the first input of the logic circuit 8 as a reference value level S3. The second input B of the logic circuit 8 is fed via the first time constant element 6, the time constant of which largely corresponds to the time constant for swinging-in and swinging-out processes of the human ear, as a hearing-related signal level S4. The The third input C of the logic circuit 8 is supplied with the signal taken from the second time constant element 7 as the mean value level S5.

As can be seen from FIG. 2, the levels S2 and S3 represent the envelope curve profile of the LF signal S1. If, as shown, the level S3 at the first input A of the logic circuit 8 is lower than the level S4 at the second input B at point a and the level S3 at point b is lower than the level S5, output D of the logic circuit 8 is produced a signal that starts the pulse shaper stage 9. This in turn now emits a control pulse with a duration of approximately 5 ms and is then blocked for further controls for a duration of equal to or greater than 100 ms. So that the short-term AF blanking also takes place in the hearing shadow, it is necessary to measure the level increase by means of the adder 5 in such a way that the envelope level S2 is on the one hand about 6 dB below the ear curve level S4 and on the other hand about 6 dB below the mean level S5. The level increase of 0.6 volts selected in the present exemplary embodiment can be generated in a practical circuit by means of a base-emitter threshold of a transistor.

The logarithmization of the LF signal ensures that the different volume (modulation deviation) of the transmitter has no effect on a changing behavior of the system. Only the dynamics of the modulation is the criterion for controlling the short mute and check times.

Since it is not possible to measure in the future - the actual muting signal is, however, about 8 ms long - the circuit arrangement according to the invention is also based on the fact that after a hearing shade has been detected - not within about 8 ms - the level rises again. Practical tests have shown that about 8% of the 8 ms muting lies in the so-called hearing shadow. This means that only about every twentieth to thirtieth muting could be heard. In the reality of an RDS concept with mute masking, the logic provides the processor with a window of about 3 to 5 ms in length for the start of the AF test. If you miss this window, you have to wait for the next one. If there are time problems with critical reception situations, it is up to the software to allow AF jumps without approval.

Claims (8)

Circuit arrangement for a car radio, in which the playback of the received station program is briefly muted by means of control pulses obtained as a function of the LF signal and alternative stations are checked for their reception within the silent period,
characterized,
that means (1, 2, 3, 4) are provided which obtain a signal (S2) from an LF information taken from the MPX signal path of the car radio, the level of which corresponds to the course of an envelope of the LF signal (S1) that the signal (S2) corresponding to the amplitude profile of the LF information is increased by a predetermined level value, undelayed as reference value level (S3) to a first input (A) of a level comparison stage (8) and secondly as a hearing-related signal (S4) to a second input ( B) the level comparison stage (8) is fed via a first time constant element (6), the time constant of which largely corresponds to the time constant for transient and decay processes of the volume perception of human hearing, and that the level comparison stage (8) is dimensioned such that its output (D. ) which emits a control pulse (S6) initiating a muting and / or a transmitter check if the reference value applied to the first input (A) of the comparison stage (8) rt level (S3) falls below the hearing-related signal level (S4) present at the second input (B). Circuit arrangement according to claim 1,
characterized,
that the signal (S2) corresponding to the amplitude profile of the LF information is fed to a third input (C) of the level comparison stage (8) via a second time constant element (7), the time constant of which is selected such that it forms an average (S5), and that the level comparison stage (8) is dimensioned such that its output (D) emits the control pulse (S6) which initiates a muting and / or a transmitter check when the reference level (S3) present at the first input (A) of the comparison stage (8) falls below the signal level (S4) present at the second input (B) and the mean value signal level (S5) present at the third input (C). Circuit arrangement according to one of claims 1 or 2,
characterized,
that the pulse shaper stage (9) is designed such that it emits a control pulse (S6) for a predetermined duration when it receives an input signal from the comparison stage (8) and is then blocked for further controls for a predetermined duration. Circuit arrangement according to one of claims 1 to 3,
characterized,
that the means for obtaining the signal corresponding to the amplitude profile of the LF information have an LF bandpass (1), a logarithmizer (2), a rectifier (3) and an LF low pass (4). Circuit arrangement according to claim 4,
characterized,
that the LF bandpass filter (1) is followed by a double-path logarithmizer (2), a double-path rectifier (3) and a second-order low-pass filter (4), the order of the logarithmizer (2) and rectifier (3) being arbitrary can. Circuit arrangement according to claim 5,
characterized,
that the low-pass filter (4) has a cut-off frequency of approximately 23 Hz. Circuit arrangement according to one of claims 1 to 6,
characterized,
that the signal (S2) reproducing an envelope of the low-frequency information is fed to the first input (A) of the comparison stage (8) designed as a logic circuit via an adder (5), which is obtained by adding the low-frequency envelope level (S2) and a DC voltage level forms the reference value level (S3), and that the DC voltage level is dimensioned such that blankings occurring in the hearing shadow are imperceptible. Circuit arrangement according to one of claims 1 to 7,
characterized,
that the first and the second time constant elements (6, 7) are designed such that their output levels (S4, S5) change largely linearly as a function of time.

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