DE1130860B - Method for saving channel capacity when transmitting voice signals - Google Patents

Abstract

969,049. Vocoders. TELEFUNKEN PATENTVERWERTUNGS-.G.m.b.H. Nov. 30, 1961 [Nov. 30, 1960], No. 42827/61. Heading H4R. The pitch signal for a channel vocoder is derived by passing the speech signal from microphone 1, Fig. 2, through a 300 to 600 c.p.s. band-pass filter 27, amplitude limiter 28 and a filter 29 which passes only the fundamental component of the limited signal. At the receiver the pitch signal is added to a noise signal from generator 33 and the combined signal limited in limiter 32 and applied to the inputs of channel filters 10 to 15, the outputs from which are modulated by ring modulators 16 to 21 before being amplified and reproduced by reproducer 22. The channel signals and pitch signals are transmitted by a pulse code modulator.

Description

Method for saving channel capacity when transmitting Speech signals The requirements are directed towards the transmission of speech signals to a transmission system according to criteria of a subjective nature, namely according to comprehensibility and according to the naturalness of the transmitted language. The intelligibility is after judged by the so-called syllable intelligibility, for naturalness there is no generally binding measuring method. Speech transmitted with great naturalness allows for example to recognize the speaker by his speech melody.

In all procedures to save on transmission capacity occurs a loss of comprehensibility and naturalness. In the case of procedures that and the amplitude range of the original speech signal, the speech melody remains received so far that recognition of the speaker is possible. The saving on However, transmission capacity is low with this method.

Procedure derived from the original speech signal by averaging Derive slowly changing parameters, from this a so-called envelope curve information win and transmit and on the receiving side the voice signal with the help of this Simulate parameters in a synthesis device (e.g. with the known vocoder processes), allow far greater savings in transmission capacity, but take a great loss of naturalness. With the vocoder method this becomes Speech signal converted into an equivalent electrical signal in an analyzer through filters in, for example, ten sub-frequency ranges within the limits of 300 divided up to 3200 Hz, the mean amplitude curve in these sub-ranges through Rectifiers and low-pass filters of, for example, 25 Hz cut-off frequency are determined and transmitted as envelope information.

This envelope information is essential for clarity.

At the same time, through a further analysis of the speech signal the mean frequency of the vocal folds oscillation is determined and this size is called Transfer pathogen information. This pathogen information is essential for naturalness.

On the receiving side, the excitation information is used to control a Pulse generator used whose output pulses on the interconnected Inputs of a filter set are given.

This filter set is exactly the same as the analysis filter set on the Sending side. The output amplitudes of these filters are modulators, e.g. B. Ring modulators, controlled by the associated envelope information, and the modulation products given to the output via a summing amplifier. The signal obtained in this way is a rough approximation of the original speech signal, especially the Naturalness through the averaging when determining the mean frequency the vibration of the vocal folds is reduced.

In Fig. 1 an embodiment for the known vocoder system is shown. The sound oscillation converted into an analog electrical oscillation in the microphone 1 is divided into individual frequency ranges, so-called sub-bands, in a number of filters n2 to 7. As a rule, ten ranges will be selected for the frequency range from 300 to 3200 Hz. For the sake of simplicity, only six such areas are shown in FIG. 1. The mean amplitude profile in these partial areas is determined by rectifiers 8 and low-pass filters 9 with a cutoff frequency of 25 Hz, for example, and transmitted as envelope information via the connections 25 shown in dashed lines. This envelope curve information has, for example, the course 34, which is shown in the diagram above FIG. In this diagram shown for one channel, the amplitude A is plotted over time t.

The envelope information is essential for comprehensibility the transmitted language. It contains all those characteristics which the Language can be imposed by the respective posture of the speaker's oral cavity. By means of a further analysis, the speech signal coming from the microphone 1 becomes the mean frequency of the vocal fold vibration in the arrangement 23 is determined and this variable also via a connection 25 as so-called excitation information transfer. This pathogen information has the task of those symbols of the language which are decisive for natural reproduction. It is about in this case, therefore, those characteristics which the language through the larynx of the person concerned has are pressed on and thus produce the characteristic sound image.

On the receiving side, the connection 25 is transmitted Excitation information is used to control a pulse generator 24, the output pulses to the interconnected inputs of the filter set 10 to 15. This filter set 10 to 15, which carries out the synthesis of the transmitted information, is constructed exactly like the analysis filter set 2 to 7.

The voltages at the output of these filters 10 to 15 are connected to a common summing amplifier 26 via ring modulators 16 to 21. The individual ring modulators 16 to 21 are simultaneously from the respective over the connections 25 transmitted envelope curve information controlled. Thus arrived on the summing amplifier 26 in each case the modulation product from the envelope information a partial frequency range and the output voltage of the fed by the generator 24 associated filter. The transmitted signal can then with the help of headphones 22 can be removed from the summing amplifier 26.

An improvement of this known method has been made by the so-called Subband vocoder system achieved. This is a partial frequency range of the speech signal transmitted directly, for example the range from 100 to 800 Hz. The rest of the range from 800 to 3200 Hz is divided into, for example, four partial hands and in equal numbers Way as analyzed in the previously described Vöcodersystem. On the receiving side these four sub-bands are in turn reproduced according to the normal vocoder system; At the same time, a signal is sent to the inputs of the four reception filters that was obtained by distorting the originally transmitted band from 100 to 800 Hz. The signal reproduced in this way has a good naturalness. The expenditure on channel capacity however, it is considerably larger than the normal vocoder system.

In another known method, an excitation signal is transmitted, this by limiting the amplitude twice in a pulse train with constant amplitude and constant duration has been converted. This excitation signal is thereby through Distortion of several harmonics, from which the fundamental frequency is then formed, obtained, followed by filtering by a low-pass filter. So asked the known method a very considerable circuitry effort, äs requires its own rectifier system and a low-pass filter. Besides that, it shows known method still has the disadvantage of being highly susceptible to failure, since it is When obtaining the fundamental frequency by distorting harmonics, never avoid it completely lets that the fundamental frequency is not obtained in pure form.

The invention is based on the object of a vocoder system in such To design in a way that the naturalness of the language is largely preserved, without that the transmission capacity is significantly greater than with the hand of the Fig. 1 explained the original vocoder system.

In the method according to the invention for saving transmission capacity a vocoder system is also assumed for the transmission of speech signals, in which an envelope curve information derived from partial frequency ranges of the speech signal and transmit a frequency segment of the speech signal directly as an excitation signal will. According to the invention, the excitation signal is added before it is transmitted The amplitude is clipped and filtered in such a way that only one excitation signal is more constant Amplitude is transmitted. The amplitude clipping is expedient by doing this a so-called infinite limit is reached, so that the output signal is a Pulse sequence with constant amplitude results, the fundamental wave content of which by a Bandpass is screened out and transferred.

Compared to the known vocoder method, the inventive Method has the advantage that the melody course of the speech oscillation, which for the Recognizability of the speaker is essential, is preserved because part of the natural Speech oscillation used as an excitation signal in the synthesis of speech oscillation will. The natural course of the melody in the speech oscillation to be transmitted is included, in contrast to the original vocoder method transfer.

Compared to the above-mentioned subband vocoder system, the inventive The method has the advantage that a greater saving in transmission capacity is achieved will.

An embodiment of the method according to the invention is shown in Fig. 2 of the drawing reproduced. The upper part of this FIG. 2 corresponds to this upper part of the arrangement according to FIG. 1. Here, too, the microphone 1 in analog electrical vibrations converted speech vibrations through the filter set 2 to 7 resolved into sub-bands and from these sub-bands via the rectifier 8 and the subsequent low-pass filters 9 form the envelope curve information.

For the transmission of the excitation function, however, the microphone 1 coming vibrations passed through a bandpass filter 27 from 300 to 600 Hz and then placed on an amplitude-limiting arrangement 28. At the output of this limiter arrangement 28 one then obtains a pulse sequence with constant amplitude, the fundamental wave content of which sifted out through a further bandpass filter 29 and via the connection 25 as excitation information is transmitted. In Fig. 3 is an example of the amplitude curve 30 in the Part of the speech oscillation reproduced as a function of time, the passes through the bandpass filter 27. Due to the amplitude limitation in part 28 a pulse-shaped oscillation 31 is created, the fundamental wave content of which is constant in amplitude and requires a significantly lower transmission capacity than when the cut out frequency range would be transmitted immediately. The ones in this signal However, the information contained only contains approximately all of the features that are necessary for the Recognizability of a transmitted speech oscillation are necessary.

On the receiving side, the envelope signals transmitted via the connections 25 control the output amplitudes of the filters 10 to 15 via ring modulators 16 to 21, which in turn are constructed in the same way as the corresponding filters 2 to 7 now the excitation signal 31 converted in a second limiter circuit 32 into a pulse sequence of constant amplitude. The modulation products are in turn passed to the headphones 22 via the summing amplifier 26.

Speech components whose energy content is in the above-mentioned, from the band filter 27 screened frequency range of 300 to 600 Hz is so low that the response threshold the limiter device 28 is not reached, are in most cases noisy, where the energy focus is above 2.5 kHz. The synthesis of these parts of speech can be done by an excitation signal with a noise character. This additional excitation signal is obtained according to a development of the invention in that the bandpass filter 27 trimmed in the frequency range and by the limiter device 28 as well the second bandpass filter 29 brought to a constant amplitude excitation signal the transmission and before the second amplitude clipping with a noise generator 33 generated noise signal is added, the rms value of which is slightly larger than the response wave of the limiter device 32. In this way is at the output the limiter device 32 constantly receives a signal with a constant amplitude as the excitation signal.

When dividing the information between the two shown in FIG Paths it has proven to be beneficial for the recovery of the speech signals The total amount of information to be transmitted is roughly equal to the envelope information the individual subbands and on the other hand to distribute the excitation signal.

Finally, to carry out the method according to the invention still proposed, the envelope information and the excitation information by pulse code modulation transferred to. To transmit both information on a common connection path it is also advisable to use the various envelope information and the excitation information serving pulse code modulation signals according to the time division multiplex method transferred to.

In this case, you naturally need the appropriate ones on the receiving side Facilities to on the one hand the impulses of the individual areas as well as the excitation signal to separate from each other and on the other hand facilities to get from these impulses Reassemble the amplitude curve of the transmitted information.

Claims (6)

PATENT CLAIMS: 1. A method for saving channel capacity when transmitting voice signals based on a vocoder system, in which envelope information derived from partial frequency ranges of the voice signal and a frequency segment of the voice signal as the excitation signal are transmitted directly, characterized in that the excitation signal is additionally transmitted before it is transmitted is clipped and filtered in amplitude in such a way that only an excitation signal of constant amplitude is transmitted. 2. The method according to claim 1, characterized in that that on the receiving side the transmitted excitation signal before its renewed amplitude clipping a noise signal is added. 3. The method according to claim 1 and 2, characterized in that that the noise signal is added with such an amplitude that its effective value the response wave which causes the renewed amplitude limitation of the excitation signal Establishment just tops. 4 .. The method according to claim 1 to 3, characterized in that that the division of the transmission into envelope information and the excitation signal takes place in such a way that the 'amounts of information in the sum of the subbands for the Envelope information on the one hand and in the excitation channel on the other hand are roughly the same size are. 5. The method according to claim 1 to 4, characterized in that the envelope curve information and the excitation information is transmitted by pulse code modulation. 6. Procedure according to claims 1 to 5, characterized in that the different envelope curve information and the excitation information serving pulse code modulation signals on the same connection path are transmitted according to the time division multiplex method. Considered publications: U.S. Patent No. 2,928,902.