EP0963684A1 - Method and corresponding system for influencing the stereo channel separation of an audiosignal - Google Patents

Abstract

The invention relates to a method for influencing the stereo channel separation in a broadcast receiver of an audiosignal that has been obtained from a received broadcast signal and is to be reproduced, as well as to a broadcast receiver for carrying out the method described in the invention. To this end, a field-strength auxiliary signal derived from the received field strength of the received broadcast signal and an interference auxiliary signal derived from signals indicating interference are connected both to each other and to a channel separation auxiliary signal derived from a signal indicating interference frequency, so as to form a factor D which influences stereo channel separation.

Description

Method for influencing the stereo channel separation of an audio signal and arrangement therefor

State of the art

The invention is based on a method for influencing the stereo channel separation of an audio signal to be reproduced and a radio receiver for carrying out the method according to the type of the independent claims.

Modern radio transmitters emit radio signals, the signal format of which enables the transmission of stereophonic audio signals and the surround sound of stereophonic reproduction can be clearly heard on the receiver side.

If a radio signal to be received is only available at the reception location with a low field strength, this advantage is lost, since interference-free channel separation requires a minimum reception field strength of a radio signal received at the reception location. For this reason, radio receivers, in particular car radios, have long been equipped with a switching or sliding transition from stereophonic to monophonic reproduction, which is dependent on the reception field strength of a received radio signal. In such Radio receivers automatically reduce the channel separation if the reception field strength drops.

Frequently, in addition to the fluctuation in the reception field strength of a received broadcast signal, further reception disturbances such as e.g. B. Multipath reception of a set radio station. With such reception conditions, the aforementioned stereo broadcast receivers, in which the sliding mono-stereo transition is set to optimum channel separation, have the disadvantage that the good stereo reproduction when entering a multipath reception area is abrupt and often only disturbed on short journeys. One therefore has stereo-capable radio receivers with a detector for interference such. B. equipped multi-path reception of the set transmitter, the output signal controls a switch that forcibly switches the receiver to monophonic reproduction of the received radio signal.

From EP 0 617 519 A2 a circuit arrangement for such a radio receiver is known, in which a signal indicating the reception field strength is derived from the received field strength of a received radio signal, in which an interference signal indicating interference received is also derived from the received radio signal, and in which the signal indicating the reception field strength and the interference signal are multiplicatively linked to form a factor supplied to a stereo decoder for influencing the stereo channel separation of an audio signal to be reproduced. On routes with short-term multi-path reception, e.g. B. on streets with high-rise buildings or in mountainous areas, changes between one-way reception and multi-way reception often occur within a very short time and lead to correspondingly frequent changes from stereo playback to monophonic playback of a stereo broadcast. This effect has long been perceived as so annoying that motorists in mountainous areas switch off the stereo decoder when receiving modern stereo stations and do without stereo playback altogether.

Finally, radio receivers with the possibility of evaluating information transmitted by means of the radio data system (RDS) are known which, for the purpose of optimizing the reception quality of a received radio program, temporarily from a currently set transmission frequency to an alternative transmission frequency via which the same program is transmitted will be tuned, the reception quality being determined during the dwell time on the alternative transmission frequency and the receiver then being set to the transmission frequency with the best reception conditions. The information about the alternative transmission frequency is taken, for example, from the AF (alternative frequencies) data transmitted via the radio data system.

Tuning the radio receiver to an alternative transmission frequency, the reception field strength of which can deviate greatly from that of the originally set transmission frequency, causes sudden and thus disturbing changes in the

Stereo channel separation of a reproduced audio signal. Advantages of the invention

The inventive method and the radio receiver according to the invention with the features of the independent claims have the advantage that with strongly fluctuating reception conditions or frequently occurring reception interference, such as. B. multipath reception, fast and frequent changes between stereophonic and monophonic

Reproduction and the associated negative auditory impression can be suppressed in favor of a partially or completely monophonic reproduction.

Advantageous embodiments of the invention

The method and the radio receiver according to the invention are specified in the dependent claims.

It is particularly advantageous to carry out the characteristic curves for evaluating the field strength signals indicating the reception field strength of a radio signal in the form of staircase functions, since these can be implemented particularly simply in digital technology if the method according to the invention or the radio receiver according to the invention is implemented.

Especially in the case of digital signal processing, it is also advantageous to use a counter to implement a signal that indicates the frequency of reception disturbances, which is decremented when a disturbance occurs and when there is no disturbance, since the clock required for this counter is simple for example from the System clock z. B. can be derived from the bit clock of the digital signals involved.

Finally, it is of particular advantage in radio receivers for receiving radio data signals, which carry out automatic alternative frequency tests to optimize reception quality, to keep the channel separation auxiliary signal P at its last value for the duration of an alternative frequency test and, if appropriate, only after the alternative frequency test change, as this can avoid strong fluctuations in the stereo channel separation in the course of alternative frequency tests.

drawings

Embodiments of the invention are shown in the drawings and are explained in more detail below.

FIG. 1 shows a block diagram of the part of a radio receiver according to the invention that is essential to the invention, FIG. 2 shows an example of a realization of the second evaluation circuit 6, FIG. 3 shows an implementation possibility for the stereo decoder 11, FIG. 4 shows an example of a first characteristic curve realized in the first evaluation circuit 4, FIG 5 shows a second characteristic curve implemented in the third evaluation circuit and FIG. 6 shows an example of the monotonically falling characteristic curve 62 implemented in the second evaluation circuit 6. Description of an embodiment

An exemplary embodiment of the part of a radio receiver according to the invention essential to the invention for carrying out the method according to the invention is shown in FIG.

At two outputs of a stereo decoder 11, to which a stereo multiplesx signal MPX obtained in a manner known per se by demodulating a received broadcast signal is supplied, audio signals for a left and a right channel (1, r) can be removed.

The formation of the audio signals for the left and right stereo channels 1 and r from the stereo multiplex signal MPX is described with reference to the exemplary embodiment for the stereo decoder 11 shown in FIG. The stereo multiplex signal MPX is processed in two signal paths, the sum signal (L + R) being isolated therefrom by low-pass filtering 113 of the stereo multiplex signal. In a second signal path, a phase difference multiplication 111 with a 38 kHz subcarrier obtained, for example, from a 19 kHz pilot tone contained in the stereo multiplex signal and subsequent elimination of undesired mixed products by means of a low-pass filter 112 results in a difference signal (L-R) which represents the difference of the signals for contains left and right audio channels.

After weighting 114 of the difference signal (L - R) with a

Factor D (0 <D <1) becomes the weighted difference signal to form a signal 1 for the left audio channel Sum signal (L + R) added (116) and subtracted (115) to form a signal r for the right audio channel from the sum signal. Thus 1 = (L + R) + D (LR) and r = (L + R) -D (LR) apply, with maximum stereo channel separation for D = 1 and purely monophonic reproduction for D = 0.

Thus, by changing the factor D, the generation of which is the subject of the following considerations, any stereo channel separation between purely monophonic and purely stereophonic reproduction can be set.

A weighting circuit contained in a first signal path 1 to 3 of the arrangement according to the invention

1, various reception disturbances such as fluctuations in field strength, multi-path reception and interference signals (ST) are supplied, which are individually weighted depending on the value ranges they occupy and their desired influence on the stereo channel separation of an audio signal to be reproduced and linked to form a common interference signal, in the present Case to be added up.

The common interference signal is a threshold value decision

2 supplied, in which it is evaluated with a predetermined threshold value, so that the output of the

Threshold value decider 2 changes from a first to a second state when the predetermined threshold value is exceeded by the common interference signal. In the present case, the values 1 and 0 are selected for the first and the second state. The output of the threshold value decider 2 is fed to an edge controller 3 for controlling the edge steepness of the supplied signal. This is designed such that its output signal, hereinafter referred to as the first interference auxiliary signal s, suddenly assumes a fourth value when the output of the threshold value decider two changes from the first to the second state and as soon as the output of the threshold value decider 2 returns to the first value, after a predetermined time function z. B. within a few 10 ms. goes back to the third value. The predefined time function is implemented in the present case in the form of a linear profile, but it can also be provided that the first auxiliary auxiliary signal s returns to the third value after a non-linear, for example exponential profile and thus in the direction of stereophonic reproduction.

In a second signal path of the arrangement according to the invention, a field strength signal (FST) indicating the reception field strength is fed to a first evaluation circuit 4 to form a first field strength auxiliary signal x, which characterizes the reception field strength of the received broadcast signal. The field strength signal FST is in the present case by rectification and low-pass filtering

Intermediate frequency signal, which is obtained by mixing the received signal down to the intermediate frequency level. In the first evaluation circuit 4, the field strength signal FST is evaluated with a monotonically increasing, in the present case linear characteristic curve, so that higher values for the first field strength auxiliary signal x result for higher reception fields. For high input values the characteristic curve has a saturation range, so that there are no changes in the first field strength auxiliary signal x for very high reception field strengths. The range of values of the first auxiliary field strength signal lies in the present case between the values 0 for a very low reception field strength FST and 1 for high and highest reception field strengths. An example of a non-linear characteristic implemented in the first evaluation circuit 4 is shown in FIG.

A third signal path 5 to 8 comprises a second evaluation circuit 6 for forming a signal which characterizes the frequency of reception interference, ie the number of interference per unit of time, hereinafter referred to as the second auxiliary interference signal P _s tör, to which the first auxiliary auxiliary signal s is supplied .

An embodiment of the second evaluation circuit 6 is shown in Figure 2. This comprises a counter 61, clocked in the present case of digital signal processing, to which the first auxiliary auxiliary signal s is fed. When the first auxiliary auxiliary signal s changes to the fourth state, which indicates the presence of a receiving error, the counter 61 is incremented by a fifth predetermined value, whereas it is decremented by a sixth predetermined value if there is no receiving error. In the present case, the clock T supplied to the counter is derived from the sampling clock for the demodulated received signal, so that the counter 61 operates synchronously with the samples of the stereo multiplex signal MPX.

Alternatively, it is also possible to generate the clock T using a separate clock generator. The counter reading 61 is evaluated by means of a monotonically falling characteristic curve 62, so that for high counter readings Z of the counter 61 at the output of the second evaluation circuit 6 there are low values for the second auxiliary auxiliary signal P _s tör at low counter readings Z. An example of the characteristic curve 62 is shown in FIG. 6, from which the relationship between the counter reading Z of the counter 61 and the second auxiliary fault signal P _s tör can be seen.

In one compared to that shown in Figure 1

The simplified second exemplary embodiment corresponds to the second auxiliary auxiliary signal P _s tör obtained in this way, which indicates the frequency of reception interference, and the second auxiliary signal P _so n, from which a channel separation auxiliary signal P is obtained by means of a tracking circuit 8.

The tracking circuit 8 works in such a way that for values of the second auxiliary signal P _S oll 'which are smaller than a current value of the channel auxiliary signal P, the value of

Channel separation auxiliary signal P quickly decreases to the value of the second auxiliary signal P _so n, while for values of the second auxiliary signal P _so n that are greater than a current value of the channel separation auxiliary signal P, the channel separation auxiliary signal P slowly decreases after a predetermined time function , in the present case after an exponential function, first very quickly, then increasing more slowly, approximating the value of the second auxiliary signal ^p soll.

For a radio receiver that is used for the purpose of optimizing reception of a received radio program Carrying out an alternative frequency test, a suitable further development provides for the channel separation auxiliary signal P to be kept at the value immediately preceding the frequency jump or alternative frequency test during an alternative frequency test or a jump to an alternative frequency. Only after completion of the jump to an alternative frequency (in the case of a frequency change to a transmission frequency that is easier to receive) or after the alternative frequency test is the tracking circuit 8 reactivated for tracking the channel separation auxiliary signal P.

Alternatively, the deactivation of the tracking 8 for the duration of a frequency hopping or alternative frequency test and the second auxiliary signal P may _thus ll ^o f its such an event immediately preceding value are frozen.

In the embodiment of the arrangement according to the invention shown in FIG. 1, the third signal path further comprises a third evaluation circuit 5, in which the field strength signal FST to form a second field strength auxiliary signal psT with a second monotonically increasing characteristic curve, an example of which is shown in FIG. 5, Is evaluated.

The second field strength auxiliary signal PpsT ^and the second interference auxiliary signal P _s tör are fed to form a second auxiliary signal P _so n in a link 7, in which, in the present case, the minimum of the two second auxiliary signals gtör » ^P FST is formed, and the second Auxiliary signal P is _so equated to the smaller of the two auxiliary signals ^p interference ^P FST. In a variant of the present exemplary embodiment, provision is made for the first link 7 to be carried out as a multiplication, so that the second auxiliary signal results as the product ^p disturb ^{x P} FST of the two second auxiliary signals ^p disturb < ^P FST supplied.

The first auxiliary auxiliary signal, the first auxiliary field strength signal x and the auxiliary channel separation signal P are combined with one another in a second link 9, 10 to form the factor influencing the stereo channel separation. For this purpose, in the present case, the first auxiliary auxiliary signal s and the first auxiliary field strength signal x are multiplied with one another in a first multiplier 9 to form a first auxiliary signal. The first auxiliary signal y thus formed is then weighted with the channel separation auxiliary signal P in a second multiplier 10 to form the factor D.

In this way, the following functionality of a radio receiver according to the invention is achieved. The factor D is directly proportional to the first field strength auxiliary signal, so that the reception field strength of the received radio signal has a direct effect on the stereo channel identification. In the case of strong ones, the first interference auxiliary signal s is above a threshold value

Reception interference faded from stereophonic to monophonic playback. Finally, either the interference frequency in the form of the second interference auxiliary signal P _s tör (with a high frequency of interference) or the reception field strength in affects the channel separation auxiliary signal P.

Form of the second field strength auxiliary signal PpsT (with low reception field strength), depending on which of the two quantities signals a poor reception on the stereo channel separation in the sense of a reduction of the same.

The signals ST indicating the disturbances mentioned at the beginning are generated in a manner known per se as follows.

A signal ΔFST which indicates fluctuations in the field strength is obtained, for example, by constant comparison of a signal which indicates the current received field strength. B. generated by rectification of the intermediate frequency signal can be derived with the slowly changing field strength signal FST. In the simplest case, the signal ΔFST indicating field strength fluctuations can be formed by subtracting the current field strength from the field strength signal FST.

A noise indicating signal can e.g. B. by evaluating the high-frequency signal components, for. B. beyond 60 kHz, which are contained in the stereo multiplex signal MPX.

A multipath signal indicating interference is known in a known manner, for. B. derivable by evaluating the symmetry of the sidebands of the 38 kHz subcarrier HT, an asymmetry suggesting multipath reception.

As shown in FIGS. 4 to 6, the characteristic curves realized in the evaluation circuits 4 to 6 are designed in the form of staircase functions, which are shown in broken lines in FIGS. 4 and 5, so that the number of possible output values and thus also the word length of the signals x, s, P _s ör ' ^P FST finite and less Number of steps is low. By executing the characteristic curves as staircase functions with a small number of steps, it is possible to represent them using fewer comparators.

Claims

Expectations

1. A method for influencing the stereo channel separation of an audio signal to be reproduced, obtained from a received broadcast signal, in a broadcast receiver, a sum (L + R) and a difference signal (LR) for forming signals for a left and a right channel (1, r) the audio signal are linked together in a stereo decoder (11), the stereo channel separation between the signals of the audio channels (1, r) being influenced by means of a factor (D) supplied to the stereo decoder (11), whereby from the received field strength of the received radio signal, preferably by means of a monotonically increasing characteristic curve which has a saturation range for high input values, a first field strength characterizing the received field strength of the received radio signal.

Auxiliary signal (x) is formed, and wherein a first interference auxiliary signal (s) indicating interference is formed from at least one signal indicating interference, which is derived from the received broadcast signal, characterized in that the interference auxiliary signal (s), preferably by means of a monotonically falling characteristic curve, a second interference auxiliary signal (PSTÖR) characterizing the number of reception errors per time unit is formed, that a channel separation auxiliary signal (P) is derived from the second auxiliary interference signal (PSTÖR), and that to form the Factor (D) the first field strength auxiliary signal (x), the first interference auxiliary signal (s) and the channel separation auxiliary signal (P) are linked together.

2. The method according to claim 1, characterized in that from the reception field strength of the received radio signal, preferably by means of a monotonically increasing characteristic curve, a reception field strength of the received radio signal indicating the second field strength auxiliary signal (PFST) is formed, and that the second field strength auxiliary signal ( PFST) with the second interference auxiliary signal (PSTÖR), preferably in the sense of forming the minimum of the two second auxiliary signals (PFST, PSTÖR), to form the channel separation auxiliary signal (P).

3. The method according to any one of claims 1 or 2, characterized in that the first field strength auxiliary signal (x) is multiplied by the first interference auxiliary signal (s) to form an auxiliary signal (y), and that the auxiliary signal (y) for Formation of the factor (D) is multiplied by the channel separation auxiliary signal (P).

4. The method according to any one of claims 1 to 3, characterized in that, for the purpose of optimizing reception on the radio receiver, a temporary alternative to a currently received transmission frequency, via which the same program is to be transmitted, is set, during which the duration of the alternative program Transmission frequency whose reception quality is determined, and that for the duration of the transition from the current to the alternative transmission frequency or from the alternative to the current transmission frequency and / or for the duration predetermined by the determination of the reception quality, the second auxiliary signal P _Soll or the channel separation Auxiliary signal P is kept at the value immediately preceding the frequency change.

5. Radio receiver with an arrangement for performing the method according to claim 1, with a stereo decoder (11) for forming audio signals for the left and right channels (1, r) from a sum (L + R) and a difference signal (LR ), whereby the channel separation between left and right audio channels (1, r) can be influenced by means of a supplied factor (D), with a first signal path (1 to 3) in which the signal indicating at least one reception interference is derived from the received radio signal a first interference auxiliary signal (s) is formed, with a second signal path in which a first field strength auxiliary signal (x) characterizing the received field strength of the received broadcast signal is formed from the received field strength of the received broadcast signal by means of a first evaluation circuit (4), characterized in that a third signal path (5 to 8) is provided for generating a channel separation auxiliary signal (P), the one comprises a second evaluation circuit (6), in which a second interference auxiliary signal (PSTÖR), which characterizes the number of reception errors per time unit, is formed from the first auxiliary interference signal (s), and in that a second link (9, 10) is provided, in which the channel separation auxiliary signal (P) derived from the further interference auxiliary signal (PSTÖR) is linked to the first auxiliary auxiliary signal (s) and the first field strength auxiliary signal (s).

6. Radio receiver according to claim 5, characterized in that the second link (9, 10) comprises two multipliers (9) and (10), the first field strength auxiliary signal (x) and the first interference auxiliary signal (s) the first Multiplier (9) for

Formation of an auxiliary signal (y) are fed, and the second Multiplier (10) the auxiliary signal (y) and the second interference auxiliary signal (PSTÖR) are supplied to form the factor (D).

7. Radio receiver according to claim 6, characterized in that the third signal path comprises a third evaluation circuit (5) by means of which a further field strength auxiliary signal (PFST) is derived from the received field strength of the received signal, and that a first link (7) for linking the second field strength auxiliary signal (PFST) is provided with the second auxiliary interference signal (PSTÖR) to form the channel separation auxiliary signal (P), preferably in the sense of determining the minimum of the additional auxiliary signals (PFST, PSTÖR) supplied.

8. Radio receiver according to one of claims 5 to 7, characterized in that the first signal path for evaluating the signal indicating at least one interference comprises a threshold value decider (2), the output of which exceeds a predetermined threshold value by the signal indicating at least one interference from a first changes into a second state, preferably from the value 1 to the value 0.

9. Radio receiver according to claim 8, characterized in that the output of the threshold decision (2) one

Edge control (3) for controlling the edge steepness of the supplied signal is supplied, with the transition of the output signal of the threshold value decision (2) from the first to the second state of the output of the edge control (3) suddenly from a third to a fourth value, preferably from 1 to 0, passes while the output signal of the threshold value decider (2) changes from the second to the first state of the output of the edge control (3) changes from the fourth to the third value after a predetermined time function.

10. Radio receiver according to one of claims 5 to 9, characterized in that the first signal path (1 to 3) comprises a weighting circuit (1) in which, preferably a plurality of signals indicating interference are individually weighted and combined to form a common interference signal.

11. Radio receiver according to one of claims 6 to 10, characterized in that the evaluation of the received field strength of the received radio signal in the first evaluation circuit (4) and the third evaluation circuit (5) each by means of a monotonically increasing, preferably in the form of a

The staircase function is implemented, a characteristic curve takes place, a limitation of the first field strength auxiliary signal (x) or of the second field strength auxiliary signal (PFST) being provided for large values of the received field strength.

12. Radio receiver according to one of claims 5 to 11, characterized in that to form the second interference auxiliary signal (PSTÖR) the interference auxiliary signal (s) is fed to a second evaluation circuit (6), in which the occurrence of a by the interference Auxiliary signal (s) displayed a counter (61) is incremented by a predetermined fifth value, while in the absence of a fault the counter (61) is decremented by a predetermined sixth value, and in which the counter reading of the counter (61) by means of a monotonous falling characteristic curve (62), preferably realized in the form of a staircase function.