DE3414632A1 - Method and circuit for processing signals whose dynamic range has been modified in pre-defined fashion, in particular for audio signals - Google Patents

Abstract

Method and circuit for processing signals whose dynamic range has been modified in pre-defined fashion, in particular audio signals in which automatic identification of the dynamic response is achieved without the use of an additional identification signal by checking the signal for at least two different spectral components in terms of the direction and quantity of an amplification modification and by comparing the result of the check with the amplification modification which was caused by the pre-defined dynamic range modifier.

Description

Method and circuit for processing

signals that are predetermined in their dynamics, especially for Audio signals The invention relates to a method and a circuit according to the preamble of claim 1. If radio stations (e.g. in the VHF-FM range) optionally compressed or to send out uncompressed signals, it is necessary in a broadcast receiver to switch an expander complementary to the compressor used on and off accordingly. This can also be done in a manner known per se by transmitting an additional signal for useful modulation similar to controlling a stereo decoder with the 19 kHz pilot tone happen with the multiplex stereo transmission method.

The transmission of additional signals, however, requires an increased one Effort at the transmitter and the provision of suitable frequencies in the spectrum. Pilot tone signals in addition to the stereo pilot tone and e.g.

to control signals for traffic information transmitters can in addition to Cause disturbances that affect the entire transmission capacity.

The invention is based on the object of a receiver circuit to develop a complementary compressor to a compressor used in the transmitter Expander in the expander switches on and off automatically or varies without a additional information about the status of the compressor (switched on and off) with must be transmitted to the transmitted useful signal.

This task is achieved with a circuit according to the preamble of the claim 1 and solved by the features specified in the label.

Further developments and advantageous embodiments are set out in the subclaims specified.

The invention will now be based on an embodiment that is shown in Drawings is illustrated, explained.

1 shows the block diagram of a transceiver system, where the transmitter has no dynamic compressor and the receiver has a dynamic expander is equipped, Fig. 2 is a block diagram of a transceiver system in which The transmitter and receiver are equipped with a compressor or an expander, FIG. 3 shows the block diagram a receiver with a circuit for recognizing a predetermined change in dynamics of the signal, FIG. 4 the block diagram of a compander circuit, FIG. 5 the in FIG. 4 occurring signal forms, FIG. 6 those occurring in FIG. 1 and FIG. 2, respectively Waveforms.

In Fig. 1 and Fig. 2 the two possible states are shown, which can result for a receiver (1) equipped with an expander (2), if a normal transmitter (4) without a compressor (Fig. 1) and if one with a compressor (3) equipped transmitter (5) is received. In the case of Fig. 1, the output is of the demodulator (6) the desired signal and this is available at the terminal (7) Disposal. The signal at terminal (8) also has the expander (2) run through and is therefore undesirably over-expanded. "On the other hand, it is as in the case of Fig. 2, a transmitter with a compressor received, the demodulated, but the signal is still compressed and then again at the terminal (8) in the desired manner expanded signal available.

The selection of the desired signal can be done, for example, as shown in Fig. 1 and 2 shown by a manually operated switch (9). This switch can also be actuated in a manner known per se by evaluating a control signal will.

In Fig. 3 is a solution according to the invention of the object shown. An evaluation circuit (10) receives the two at two inputs (11, 12) Output signals of the receiver from the terminals (7, 8) either directly or via Filters (26, 27). At a further input (14) the evaluation circuit in the control variable (16) generated by the expander circuit (2) is supplied. At the output (13) of the Evaluation circuit can pick up a control signal for actuating the switch (9) will.

The mode of operation of the evaluation circuit is shown in the following Fig. explained. In Fig. 4 is first a compander system consisting of the transmitter Compressor (3) and receiver-side expander (2) explained in more detail, as e.g. NTG / NTF Hörrundfunk 6, Mannheim 1983, pp. 151-158.

The compressor (3) and expander (15) contain the same control variable generator (15), a control variable (16) with a derive typical course for syllable compander. This control variable is used for control of amplifiers (17, 18), e.g. an increase in the control variable (16) in the Compressor (3) to reduce the gain of the servo amplifier (17) and in the expander (2) to a complementary increase in the gain of the servo amplifier (18) leads.

FIG. 5 shows the waveforms occurring in the arrangement of FIG shown when a signal (20) is applied to the input (19) of the compressor (3), that e.g. from a continuous signal (21) with a low level (-20 dB) and off a short-term signal (22) with a high level (O dB). The signals (21) and (22) should also have different signal frequencies. This signal is in line A of Fig.

5 shown.

Line B of FIG. 5 shows the curve in the control variable generators (15) The characteristic curve of the control variable derived from this and typical for syllable companders 16 shown. This results in the gain curve shown in line C. of the amplifier 17 and the curve of the signal (23) shown in line D am Compressor output.

The same control variable (16) generated in the expander (2) leads to this The course of the gain of the control amplifier (18) shown in line E. If those acts on the signal (23), is obtained again at the output of the expander (2) the input signal (20) corresponding signal (24).

The process described corresponds to that usually used in syllable companders running signal processing. Looking at the output of the compressor in the signal (23) only the part caused by the input signal (21), e.g. by using suitable Filter (26, 27) removes the portion caused by signal (22), so one obtains the signal (25) shown in line F of FIG. 5, which results from the constant Signal (21) and the gain that changes according to line C results.

In the case of a transmission according to FIG. 2, the signal (23) would at the terminal (7) and the signal (24) corresponding to the input signal (20) at the Clamp (8) occur. One in working as desired Evaluation circuit (10) would cause switch 9 to act on terminal (8) To switch signal (24) through to the output.

If, in accordance with FIG. 5, one considers the transmission case shown in FIG. 1, thus the waveforms shown in Fig. 6 are obtained. Line A of Fig. 6 shows first again the input signal (20), which is now applied directly to the input of the expander (2). Since the control variable generator (15) of the expander is now not the compressed signal (23), but evaluates the input signal (20), results in a different in Line B shown control variable (16 ') and a correspondingly different one in line C the course of the gain of the control amplifier (18) shown.

According to the course of the gain of the servo amplifier 18 is obtained the changed output signal shown in line D is obtained from the input signal (20) (24 ') of the expander.

Such a signal is referred to as "over-expanded".

If one also only considers that caused by the input signal (21) Portion of the output signal (24 '), the one shown in line E of FIG. 6 is obtained Course of the signal (25 ').

In the case of a transmission according to FIG. 1, the signal (24 ') would be on the terminal (8) and the changed signal (20) occur at the terminal (7). One evaluation circuit (10) functioning in the desired manner would switch (9) cause the signal appearing at terminal (7) to be switched through to the output.

It is also known from the technology of the compander process (see Sect.

NTG / NTF Hörrundfunk 6, Mannheim 1983, pp. 151-158) that in particular with so-called "compatible" compander methods in the case of a transmission according to FIG. 2 a possible malfunction of the evaluation circuit (10) and consequently a through-connection of compressed signal (23) to the output is tolerable. in the In the case of a transmission according to FIG. 1, on the other hand, there is a malfunction and connection of the "over-expanded" signal (24 ') to the output intolerable.

From the representations in FIGS. 5 and 6 it can be seen that briefly occurring signals with a high level due to the change in gain determined by them in the amplifiers (17) and (18) other additional useful signals in influence the level in a certain way through the properties of the compander. This fact can be used to solve the problem. It is evaluable both the fact that, according to FIG. 5F, a signal (21) at the output of the compressor becomes abruptly smaller at time t = to (25). It is also possible to evaluate that a signal (21), which has only passed through one expander, at time t = to increases abruptly (25 ').

The point in time to at which such an evaluation becomes possible is can be determined by the fact that the control variable (16 or 16 ') of the expander to large jumps is examined in a positive direction. Such a jump indicates an appearance of a signal (22). The amount of the jump of the control variable (16) sets in the case 2 directly determines the amount by which the gain of the servo amplifier (17, 18) changes in compressor (3) and expander (2) at time t = to.

In the case of FIG. 1, the level of the jump of the control variable (16 ') immediately determines the amount by which the reinforcement of the repeater (18) changes in the expander (2) at time t = to.

For the analysis according to the invention in the evaluation circuit (10) in a receiver with expander (2) those occurring at terminals (7) and (8) Signals and the control variable (16, 16 ') generated in the expander (2) are available.

In the case of the transmission according to FIG. 1, these are the signals at the terminals (7, 8) around the input signal (20) and the overexpanded signal (24 '), in the case of the transmission according to FIG. 2 by the compressed signal (23) and the one corresponding to the input signal (20), initially compressed and then complementary again expanded signal (24).

If the signals (21, 22) that form the useful signal (20) are in the frequency can be differentiated from those occurring at the terminals (7, 8) Signals remove the components caused by the signal (22) by filtering. Man then receives a constant from the terminal (7) for evaluation in the case of FIG. 1 Signal (21) and from terminal (8) the signal (25 ') according to FIG. 5F and from the terminal (8) the constant signal (21).

If you now measure the level of the terminals (7, 8) through filters to the Removal of the components supplied by the signal (22), so can one hypothesizes that it is a transfer according to Fig. 1, when the level of the signal from terminal 8 rises at time t = to. if the level of the signal from terminal 7 drops at time t = to, one can use the Make the hypothesis that a transmission according to FIG. 2 is present. Since the measured Change in the control variable (16, 16 ') a certain change in the gain of the servo amplifier (17, 18), the evaluation described can be made even more reliable so that the measured level changes of the signals from the terminals (7, 8) with the gain changes derived from the control variable (16, 16 ') Comparing amplifier (17, 18).

The evaluation process described works perfectly as long as Signals (21, 22) which can be separated by filtering are present as useful signals (20) and for so long the temporal waveform similar to that in Fig.

5A is.

Real music or speech signals can be similar to this form but also have completely different forms, which can be seen in the evaluation described Errors.

This can lead to the switch (9) toggling frequently becomes what is intolerable. This can be eliminated by looking at the evaluation circuit (10) only sends switching information to switch (9) if a series of successive evaluations have come to the same result (the same Hypothesis confirmed). It is also useful if you are looking for a first time Decision for a certain position of the switch (9) the number of for one Changing the switch position requires successive evaluations with the same Result increased.

Due to the relative tolerability of compressed signals, it is advisable to the switch position that connects terminal (7) to the output is a preferred position and every new evaluation, e.g. after a channel change or after a Interrupt the power supply to begin with this switch position.

For evaluation, intermediate storage and counting of the results in succession Measurements (hypothesis counter) for deriving switching information can be a per se Well-known computer module (e.g. type 8080 from Siemens) with associated peripheral modules be used.

- L e r s e i t e -

Claims (9)

Claims I.i Method and circuit for processing signals that are predetermined in terms of their dynamics, especially for audio signals, characterized in that transmitted without using an in addition to the signal Identification signal an automatic detection of the dynamic behavior is achieved by the signal on at least two spectral components (lines or area) on direction and the amount of a gain change is checked and the test result with the Gain change is compared that of the predetermined dynamics changer would be caused. 2. The method and circuit according to Al, characterized in that a) the control variable for a dynamics modifier from the input signal to be examined is formed, b) the control variable is differentiated, c) the differentiated signal is checked for peak values, d) from the input signal for at least two spectral lines Signal values are determined, e) the signal values at time during the duration of the Peak values and / or at times before and after (temporal support points) are checked, f) the signal values at the time support points for change are examined for amount and sign, g) a variable from the control variable is generated which is a measure of the gain change obtained therefrom of the dynamics changer is, h) at a predetermined direction and / or at approximately equal magnitude of the three quantities the hypothesis is used that the signal is in the dynamics is changed in a predetermined manner, i) in the event of a deviation from the predetermined direction and / or if there is a substantial deviation from the predetermined amount, the hypothesis is used it is that the signal in the dynamics is not changed in a predetermined manner, j) a predetermined one Dynamic change is only displayed and / or taken into account when the content a hypothesis counter in a predetermined manner the content of the other hypothesis counter or counters exceeds. 3. Circuit according to Al and 2, characterized in that a known one Dynamics expander (1) an analysis circuit (2) is assigned to the dynamics expander (i) assigned input signal (3) or the output signal (4) of the dynamics expander (1) Analyzed according to criteria related to the dynamic expander (1) and depending on the either the input signal from the result of this analysis to the subsequent circuit part (5) (3) or the output signal (4) of the dynamic expander (1). 4. Circuit according to one of A 1, 2 or 3, characterized in that that a signal (6) is fed to the following circuit part (5) via the output (7) becomes, which in its dynamic properties neither from the expander (1) nor was changed only by a compressor assigned to the expander (1). 5. Circuit according to one of A i, 2, 3 or 4, characterized in that that the input signal (3) assigned to the dynamic expander (1) is analyzed according to such dynamic changes that can be assigned to the dynamic expander (1) Compressor causes. 6. Circuit according to one of A 1 - 5, characterized in that the Output signal (4) of the dynamic expander (1) is analyzed for such dynamic Changes that the dynamics expander (1) generates in an input signal (3), not going through a compressor assigned to the dynamics expander (1) beforehand Has. 7. Circuit according to one of A 1 - 6, characterized in that the The control voltage that determines the dynamic behavior of the compressor or expander () is analyzed for sudden changes, and that before and after the jump or during the jump amplitude changes of spectral components of the the signal causing the control voltage jump can be determined. 8. Circuit according to one of A 1 - 7, characterized in that the changes in amplitude of spectral components determined in the event of a control voltage jump are compared with the gain changes occurring with such a control voltage jump in the expander (1) or in the compressor () and that a hypothesis from this comparison it is deduced whether the determined gain changes affect the action an expander (1) or a compressor () can or neither can be assigned to one or the other. 9. Circuit according to one of A 1 - 8, characterized in that each Hypothesis a counting circuit is assigned, in which a corresponding increment is made and that if there are significant differences in the counter readings Hypothesis with the significantly predominant number of events is accepted and the Dynamic expander (1) or switch (7) is set accordingly.