DE4040107C1 - Analysing human singing and speech voice strength - forms relation of preset formant level and total voice sound level in real time - Google Patents

Abstract

Voice signals from the microphone (1) are amplified by a preamplifier (2) with the same transfer characteristics as the human ear and passed to a dynamic compressor (3) which compresses the dynamic range of the voice signal from 80 to 40 dB. The compressed signal is then rectified by a precision rectifier (4) and passed to an A=D converter (5) with a sample and hold facility. The resultant sampled digital signal is then passed to a single chip computer (6) that calculates the RMS sound pressure and inertia valves for both the entire voice signal and the Formant (2-4kHz) range voice signal. These two valves are then digitally expanded and their relative sound energies displayed as a percentage value on either a LED (7) or LCD display (8). USE/ADVANTAGE - For voice training, rehabilitation etc., with detecting and display of voice parameters.

Description

The invention relates to a method according to the preamble of claim 1. It is used to analyze the singing and speaking voice during training, rehabilitation and control of people with high voice and speech stress like singers, actors, Teachers and patients in voice therapy.

A method is known in which the simultaneous display two spectral ranges of the human voice, which are in the others are referred to as high or low singer formants, should be used in the sense of a biofeedback effect (DD 2 21 866, A. Pobbig).

Voice field measuring devices are used to analyze the human voice known, the total sound level or the total sound level and the high singer formants in their dynamic and Record and register frequency-related limits. A voice analyzer is known in which a voice is used Variety of formants determined and after a frequency-voltage conversion is visually displayed. The input sound level is also displayed. Based on the display there is a Interpretation possible (US 46 41 343).

It is known to use amplitudes for speech signal analysis to divide neighboring formants (US 39 19 481).

A method is also known in which, by measuring Overall sound level and high singer formants and after Dividing both values a quality value of the voice is calculated and is displayed (F. Winckel, Folia phoniat., 23, 1971, pp. 228-233).

The latter methods do indeed refer to the calculated one Quotients as quality value of the voice, but do not meet any Statements on the course of this quotient, so that a Exploitation of the biofeedback effect is not possible.

The solution described in DD 2 21 866 uses two Spectral ranges (420-880 Hz and 2200-3600 Hz) as deep or high singer formants without taking into account that the spectral range of the deep singer formant is identical to  the position of the vowel formants in the voice spectrum, so that a Use of this method regardless of the type of voice and vowel not possible. Furthermore, there is no physically exact Measurement of the real energy content of the spectral ranges mentioned.

The invention has for its object a measurement to determine and present recordable voice parameters with which the rehabilitation, training and Control of the singing and speaking voice can be improved.

According to the invention this is in a method in which the level of the spectral energy component between 2 and 4 kHz (formant level) in relation to the overall sound level of the human voice is achieved in that the ratio is in real time is formed by first a frequency evaluation of the Microphone signal to simulate the ear characteristics ("A") of the People performed that after implementing the analog voltage into a binary coded data word for both the overall sound level as well as the square mean for the formant level is formed that both are related and the Quotient is displayed optically.

It is appropriate that dynamic compression of the Microphone voltage is made in the analog level and that the dynamics of the overall sound level and the formant level on the digital level.

It is also expedient that the detection of the formant level using digital filtering.

The basis of this solution was the discovery that the relationship the level of the spectral energy component between 2 and 4 kHz and of the total sound level of the human voice with increasing vocal qualification both vowel and frequency related loses variability and strives for a constant value. This increasing constancy of the quotient takes place in the Vocal pedagogy under the name vowel or layer compensation an adequate meaning, with which a unification of the individual voice timbres throughout the Tessitur or  Vowel area is meant.

The basis for this discovery was two independent ones Series of measurements. The first series of measurements is based on studies by 30 non-singers, 30 singing students and 30 each Professional singers. The second series of measurements recorded a total of 50 Music teacher students once after 60 hours and the other after 90 hours of vocal training. The vowels / a /, / u / and / i / on basic genre-specific frequencies (6 measuring points each within the physiological vocal range). The statistical evaluation of the series of measurements showed that the specified measuring points the arithmetic mean of the above. Quotients both vowel and frequency related with increasing vocal qualification a diminishing Standard deviation had what was clearly called Compensatory tendency can be assessed. It is therefore possible to growing within a vocal training intra-individual constancy of this quotient as a biofeedback parameter to use.

According to the knowledge of learning physiology, a motor Learning process is decisively supported when this process can be visually monitored and if the optical information synchronized with motor activity (Biofeedback effect). This will make the conventional Auditory and voice training available kinesthetic control mechanisms when practicing visual Component expanded. When processing all on the The incoming signals of the human organism are confirmed by the visual Channel a capacity of approximately 40%. Accordingly, the addition represents visual feedback in vocal training significant expansion of the control and control options regarding the effectiveness of the motor processes.

A device for applying the method has a measuring microphone Conversion of the voice signal from a sound pressure proportional Signal into an electrical signal. The measuring microphone is a Subsequent frequency evaluator, the frequency evaluation of the of the human ear is simulated (A-rating). The Frequency evaluator is a sound level meter for two channels  effective voice sound level and the second channel for the Detection of the selective effective voice sound level in the area of 2-4 kHz is used. The sound level meter closes one Measured value processing unit to calculate the quotient from spectral energy in the range of 2-4 kHz and complex effective voice sound level in real time and preferably on a light-emitting diode display.

In one embodiment, the invention is intended to be based on Drawings are explained. It shows

Fig. 1, the measurement principle schematically,

Fig. 2 is a block diagram.

In FIG. 1, the already further presented above measuring principle is shown by the successive process steps.

In the block diagram, the measuring microphone 1 is followed by a preamplifier 2 with frequency evaluation for emulating the ear characteristic ("A") of the person. A dynamic compressor 3 , which compresses the dynamic range 2: 1 to 40 dB, is required for processing an input level dynamic of 80 dB (40-120 dB). A multi-range switchover can thus be dispensed with. A precision rectifier 4 delivers the amount of the input AC voltage to the following analog-digital converter 5 . This converts the amount of the AC input voltage into a binary coded data word. The AD converter is equipped with a sample & hold input stage and implements an error-free transfer of analog values to the AD converter. All further functional units necessary for measuring the sound pressure and formant level are implemented and calculated in the single-chip microcomputer 6 . These are the following calculations:

• - Effective value formation (root mean square) of the Sound pressure channel (Ps channel) including inertia assessment
• - digital filtering (formant filter as 6th order bandpass)
• - Effective value formation and inertia evaluation of the formant channel (2-4 kHz)
• - Calculation of the sound pressure level and the formant level
• - digital dynamic expansion of both measuring channels  
• - Quotient formation and percentage calculation

A light-emitting diode display 7 enables the quotient to be displayed in percent or the sound pressure or formant level in real time. For the registration of measured values, the device can be switched over to manual triggering of the measurement, in which a digital display 8 is helpful.

Claims (3)

1. A method of analyzing the singing and speaking voice, in which the level of the spectral energy component between 2 and 4 kHz (formant level) is related to the overall sound level of the human voice, characterized in that the relationship is formed in real time by first a frequency evaluation of the microphone signal to simulate the ear characteristics ("A") of humans is carried out, that after converting the analog voltage into a binary coded data word, the quadratic mean is formed for both the overall sound level and for the formant level, that both are related and the quotient is displayed optically. 2. The method according to claim 1, characterized in that a Dynamic compression of the microphone voltage in the analog level is made and that the dynamics of the overall sound level and of the formant level can be expanded on the digital level. 3. The method according to claim 1 and 2, characterized in that the detection of the formant level using the digital Filtering takes place.