DE3621513A1 - Audio signal transmission - Google Patents

Abstract

The method transmits an audio signal by converting the analog signal into a digital signal and then sending the digital signal, which is reconverted into analog form on receipt. Thresholds are displaced and/or frequency selective enhancement occurs. The threshold below which the value zero is set within a frequency group is adaptively displaced. The threshold is displaced by between -30 and -50 dB. A signal in the preprocessing stage before the check block passes via a highpass filter. A listen or audible threshold is set over all groups and has a given spacing from the max. and is displaced only as far as a stop which has a spacing of c.-128 dB from an absolute max.

Description

The main application concerns a transfer procedure an audio signal in which the analog signal is converted into a digita les signal converted, digitally transmitted and back into one analog signal is implemented.

The invention according to the main application has the object reasons, a method of transmitting a digital To create audio signal with a lower average Bit rate per sample gets along without having to play back the quality is noticeably affected.

This object is achieved by the invention according to the main application tion solved in that the signal in before converted a signal representing the short-term spectrum and parts of this signal based on psychoacoustic Laws in the coding of the di to be transmitted gital signals in their display accuracy different be weighted.

It is the task of this additional application to weight Am improve plititude values in frequency values, the detec tion of sudden sound events to improve and psy choacoustical aspects in the transmission method esp to take into account.

This task is by the He described in claim 1 finding solved. Advantageous developments of the invention are described in the subclaims.

The threshold below which values in a group Zero is not fixed at -30 dB below the Group maximums set, but must be adaptive up to -50 dB  be moved. This is necessary when in the group there is a pronounced peak in the course of the amount because here at over this large dynamic range the spectral values a have a clear linear dependency. Will these values set to zero results from the dependency after transformation and back transformation a modulating Disturbance in the time signal that is clearly perceptible.

Classification feature for recognizing such a situation tion is the ratio of peak to mean within a group.

To analyze whether there is a jump in the signal curve, is in sub-blocks (e.g. 64 values) the energy of the signal means that is previously passed over a high pass. Thereby a possible jump is healed and can be detected better be animals.

The resulting increase before the jump can be up to forth broadband, but a better effect achieved when the increase starts frequency-selective. they can then turn to the less energetic spectral areas are limited, creating higher raising factors are allowed without changing the course of the short-term spectrum to change significantly.

A hearing threshold is set across all groups, below half of which the spectral values are set to zero. The The threshold is horizontal in the first 23 groups and increases within the last 3 groups by approx. 30 dB. The threshold is shifted as a whole so that in the lower Range a certain distance (type 90 dB) to the maximum Be is held at inertial value. When moving to smaller people a stop is defined for the threshold so that not very small values are taken into account.  

With this threshold, on the one hand, the absolute hearing threshold, on the other hand, cross-group concealment effects be viewed.

For a better understanding of the invention, a Embodiment explained in more detail with reference to drawings.

Show it

Fig. 1 time windows in which a sinusoidal signal oscillates,

Fig. 2 frequency spectra of a windowed sine signal,

Fig. 3 shows the time sequence of the method,

Fig. 4 is a pre-processing of the signal for a specially len signal content,

Fig. 5 is a block diagram and

Fig. 6 shows a frequency spectrum with thresholds.

Fig. 1 shows a curve 4 with a sinusoidal course. Two time windows t 1 and t 2 are placed over this curve 4 . The time window t 1 begins in the zero point 1 of the sine and ends in a second zero point 2 of the sine. The zero points 1 and 2 are the intersection points of the sine and the abscissa, the time t being plotted over the abscissa . The second time window t 2 begins at the zero point of the sine, but ends outside a zero point at point 3 .

When transforming time signals into a signal representing the short-term spectrum, different curves are achieved in the frequency spectrum. Fig. 2 shows the frequency spectrum that belongs to the two windowed sinusoidal signals. Only one frequency line 5 results for the time window t 1 . For the sinusoidal signal, which is windowed over the time window t 2 , there is a frequency spectrum with the curve run 6 , which has a maximum at the frequency line 5 and a falling curve shape with several frequency lines 7 . In a frequency group, the limitation and transmission of values that are only within a dynamic range of 30 dB below the maximum ymax can cause modulating disturbances due to the linear dependence of the spectral values, which are easily perceptible. That is why the dynamic range is adaptively increased to up to 50 dB. The classification feature for recognizing such a situation is the ratio of the peak to the root mean square within a frequency group. The difference from the peak to the mean value is formed in a frequency group and the difference is multiplied by a factor, in this case 3 . The product results in the new dynamic range. If the peak value is 60 dB and the associated mean value is 45 dB, the difference is 15 dB. The difference of 15 dB is multiplied by a factor of 3, which results in a new dynamic range of 45 dB, i.e. an adaptive adjustment between -30 and minus 50 dB. If it is determined in parallel to the determination of the threshold, which defines the group dynamics, that the difference between the maximum and minimum value in a group is less than 30 dB, the dynamic range to be displayed is set equal to this difference.

In Fig. 3, the analog signal a (t) , which represents an audio signal such as voice or music, is converted in the analog / digital converter 11 into a corresponding digital audio signal. In stage 12 , a so-called fensterung of this signal takes place through temporally successive and overlapping time windows. The signal is divided into successive blocks, each with a duration of approximately 20 ms, in particular 23 ms, in such a way that the signal of a block can be processed separately for those who can. In stage 13 , the signal is preprocessed, the meaning of which will be explained later. In stage 14 , the digital signal of a time window or a block is converted into a frequency spectrum by a transformation. At the output of stage 14 there is thus a signal during the successive blocks, which represents the spectral components of the signal over the entire frequency band for the duration of a time window or block. The stage 14 thus effects the conversion of the signal from the time domain into the signal representing the spectrum in the frequency domain.

The signal from stage 14 passes to encoder 15 . Here he is coded according to psychoacoustic criteria. This means that spectral components that are anyway not perceived in the playback, in particular due to masking effects, are weighted less or omitted in the coding. Such processing of the short-term spectrum is possible, for example with the help of a computer.

The signal coded in this way reaches the message channel 17 via the transmitter 16 . Due to the reduction in the average bit rate, this message channel can be dimensioned to be narrow-band. The message channel 17 is followed by the receiver 18 , which essentially performs the functions inverse to the transmitter. The signal first arrives at a decoder 19 which , according to the coder 15, causes the decoding. In stage 20 this is obtained in such a way that the spectrum-representing signal in the frequency domain is converted back into a digital signal in the time domain. In stage 21 , the signal is put together again to form a uniform, continuous digital signal and the preprocessing of stage 13 is taken into account. The signal is then fed to the digital / analog converter 22 . The converter 22 again supplies the analog signal b (t) . This signal is not identical to the signal a (t) because spectral components were differently weighted or suppressed in the encoder 15 during coding. The difference between the analog signals n b (t) and a (t) is such that it is not noticed by the listener during playback. In the signal, therefore, only irrelevance, information inaudible to the listener, is eliminated in order to reduce the necessary bit rate for the transmission via the message channel 17 , in particular the decision content is reduced. On the signal path 23 , the pre-processing stage 13 tells the transmitter 16 whether a preprocessing has taken place. If this is the case, additional information is inserted or multiplexed into the coded signal, which the receiver 18 recognizes and communicates to the adaptation stage 21 via the signal path 24 . Before the analog-Digi tal converter 11 , a low-pass filter is inserted to meet the scanning theory. After the digital-to-analog converter 22 , a second low-pass filter is arranged as a reconstruction low-pass filter.

Fig. 4 shows the preprocessing of a sudden Schaller event 29 that occurs within a time window t 1- t 7 at time t 9 . Such a sound event can be a triangle attack, for example. The preprocessing described takes place in FIG. 3 in stage 13 . The sound event 29 is preceded by a pre-oscillator between t 8 and t 9 , which is however not audible due to a pre-masking. When converting to the frequency spectrum in stage 14 in Fig. 3, a signal is generated in the frequency domain, which indicates the spectral distribution in the window t 1- t 7 . Since the assignment of spectral lines to individual points in time within this time window no longer exists in this signal, event 29 would be averaged over the entire time window t 1 - t 7 , that is to say quasi smeared. This can result in audible falsification.

To avoid this still conceivable error, a time window t 1- t 7 or block is divided into 32 sub-blocks. The amplitudes of the individual sub-blocks are determined. As soon as an amplitude jump between two sub-blocks of more than a predetermined limit occurs, in FIG. 4 due to event 29 , an additional measure is triggered. The specified limit is of the order of 20 dB. The measure consists in that the signal before the amplitude jump is increased in amplitude by a compander method on the transmission side and is correspondingly lowered again on the receiver side. As a result, the errors mentioned are reduced by smearing the short-term event over the entire time window. FIGS. 4D and 4E show the operation of a Kompandersy least. Before a signal jump, a signal with an amplification factor V 1, in this case 5, is amplified in an expander in preprocessing. On the receiver side, this is reversed in a compressor in the adaptation 21 with a second gain V 2, in this case 1/5. The total gain for the signal is "1" for the entire time.

V Ges = V 1 V 2 = 1

After a signal jump, the gain factors are until the next jump both in the expander and in the comm pressor the value 1. In the transitions between the amplifiers Factors 1 and 5 are straight or curved ter course over a period of between half or an entire sub-block, but preferably over time duration of a sub-block. The goal is to use the previous ver covering effect of the ear (less than 1 ms).

The preprocessing 13 is shown in FIG. 5. Block 30 checks whether a signal between two of the 32 subblocks rises by a predetermined limit. As long as the rise between two blocks is below the predetermined limit (20 dB), the signal from input 35 is switched directly via ei ne time delay 36 and switch 33 to output 34 . If there is a signal jump between two sub-blocks of 20 dB, the signal from input 35 is switched to output 34 via an expander 32 and switch 33 . The high pass 31 adjusts a possible jump in the signal so that the jump is better detected by the block 30 . Then the signal is increased in amplitude before the amplitude jump by the expander 32 on the transmitter side and correspondingly lowered again on the receiver side. This reduces errors caused by smearing the short-term event over the entire time window. The test block 30 works continuously, even while the signal from the input 35 is switched directly via the changeover switch 33 to the output 34 . The time delay 36 compensates for time differences that the expander 32 and the test block 30 cause. The test block 30 informs the expan of the 32 of the time of a jump or the exceeding of a limit. This message is information about the number of the sub-block. The expander 32 automatically calculates a suitable gain factor.

Fig. 6 shows a coordinate system, on the abscissa on a frequency f, the curve 41 of a frequency spectrum is plotted. The curve shape 41 has a maximum xmax . An absolute maximum xmax 1 corresponds to a level A of zero decibels. In a computer, these zero decibels correspond to an absolute value of 2 exponent ( exp ) 15, which is additionally amplified with a gain factor of 1024. Then an absolute size of 2 exp 25 is expected. The sizes correspond to an electrical voltage. A hearing threshold 42 is set across the entire frequency curve, below which the spectral values are set to zero, ie are not taken into account. This threshold 42 runs parallel to the abscissa in the first 23 frequency groups and increases by about 30 dB within the last 3 groups, the increase starting from 10 kHz. The threshold 42 is always at a distance of 90 dB from the (changeable) maximum xmax before a first rise point, hereinafter referred to as the break point. This means that this threshold is always set depending on the maximum xmax . However, the threshold 42 cannot drop below a minimum value 43 , hereinafter referred to as the stop. This stop 43 is at -128 dB to the absolute maximum. The first break point is advantageously set at 10 kHz and a second break point at 12 kHz. The threshold 42 initially rises by 10 dB between these two break points. From the second breakpoint, that is in the range between 12 and 22 kHz, the threshold 42 has a slope of 90 dB. The frequency groups and a division of a frequency spectrum is explained, for example, in "Psychoacoustics" by E. Zwicker, published by Springer Verlag, Berlin Heidelberg New York 1982.

Claims (9)

1. A method for transmitting an audio signal in which the analog signal is converted into a digital signal, digitally transmitted and converted back into an analog signal, according to patent application P 35 06 912, characterized in that thresholds are shifted and / or that a frequency selective increase takes place. 2. The method according to claim 1, characterized in that the threshold below which the values are set to zero in a frequency group pe is adaptively shifted ben ( Fig. 2). 3. The method according to claim 2, characterized in that the threshold shifted between -30 and -50 dB is. 4. The method according to claim 1, characterized in that an increase starts frequency-selective.   5. The method according to claim 4, characterized in that a signal in the preprocessing 13 before the test block ( 30 ) is guided via a high-pass filter ( 31 ). 6. The method according to claim 1, characterized in that a hearing threshold ( 2, 3 ) is set across all groups. 7. The method according to claim 6, characterized in that the hearing threshold ( 2 ) takes a predetermined distance to a maximum ( xmax ). 8. The method according to claim 7, characterized in that the hearing threshold ( 2 ) is only moved up to a stop ( 3 ). 9. The method according to claim 8, characterized in that the stop ( 3 ) is at a distance of about -128 dB from an absolute maximum ( xmax 1).