DE19526333A1 - Music generation method - Google Patents

Abstract

The method involves picking up an acoustic signal with a microphone. The frequency or wavelength of the signal is determined. The result is used to control an electronic musical instrument. The acoustic signal may be digitised by an analog to digital convertor. The wavelength or frequency may be determined using a program. The distances between signal maxima or minima, or the null crossing point, or wave shapes of the same phase, may be determined. The signal may be smoothed before analysis, or may be differentiated. Alternatively, the wavelength or frequency may be determined using pattern recognition. The results of the frequency determination may be sent to a MIDI system via a MIDI driver of a sound card or a MIDI interface of a sound card. Alternatively, the frequency results may be rounded to a standard note value.

Description

The present invention describes a method for producing music, characterized in that an acoustic signal recorded with a microphone, its frequency or wavelength determined and this result is used to control a synthesizer or a MIDI device.

Background of the Invention

All previous musical instruments are essentially played with hands, what skill and requires years of practice. However, hardly any practice requires singing or whistling a melody. The most people can do this more or less well without the need for long training would. It was therefore the object of the present invention to provide a method for using a z. B. whistled melody, preferably electronic, to control musical instrument.

A whistled melody (the same applies to a sung melody) contains all the information about it are necessary:

• - time of sound.
• - Frequency of the tone (pitch).
• - If necessary, the volume.
• - End of the tone.

The signals, or derivable data, are sufficient for a synthesizer or a sound card or a to control electronic, preferably MIDI musical instrument. If MIDI is mentioned in the following The examples refer to the conventions of the Musical Instrument Digital Interface (MIDI) standard.

Description of the procedure

An acoustic signal (= e.g. a whistled melody) is recorded via a microphone and particularly preferred, via the analog / digital converter of a sound card (e.g. SOUND BLASTER (R)) digitized.

A data block with this digitized acoustic signal is then subjected to a signal analysis as a result, the fundamental frequency of the whistled sound delivers.

This signal analysis can be done by an FFT analysis or by the method of speech pattern recognition or particularly preferably by determining the wavelength by identifying the Signal maxima and signal minima occur. It is also possible to determine the wavelength by determining the Zero crossing (crossing the zero line from bottom to top or from top to bottom) or one to determine another phase in phase.

For this signal analysis, you can use both the raw data and a mathematically smoothed (filtered) Use signal. It may also be useful to test the signal one or more times before analysis differentiate (formation of the derivative) or the difference signal (difference of two consecutive Values).

In a particularly preferred embodiment, for. B. a 10-50 ms long block of data is captured. Since the typical pitch of a whistle is around 1-2 kHz, this block contains around 20-100 wave trains. You search this data block sequentially until you find the first relative maximum (see following example) and then alternately searches for the next signal minimum or Signal maximum.

The duration of the average wavelength is then the time of the last maximum found minus the time of the first maximum found divided by the number of identified wave trains. On  Wave train is the distance between two signal maxima or two signal minima or two in-phase zero crossings.

The reciprocal of the wavelength (in seconds) corresponds to the tone frequency in heart. That is already it Result with which you can control an electronic musical instrument.

To increase the precision, the outliers can be eliminated from the detected wave trains, i. H. the Remove wave trains with a wavelength that clearly deviates from the mean.

In a particularly preferred method, the distances of all signal maxima are first searched for then the distance that occurs most frequently and determines the wavelength by taking the weighted Distances in the vicinity of the most frequent distance added, e.g. B. according to the formula:

MI = most frequent distance;
AZ = number of wave trains with this distance;

With this method, outliers (= severely disturbed wave trains) fall out.

To increase the reliability of the sound recognition, criteria can also be added, which only apply to a clearly pronounced signal are satisfied, such as e.g. B .:

• - The number of detected wave trains in a data block should be in a certain range.
• - The maximum distance should be clearly pronounced.
• - The amplitude should be above a certain value.
• - The specific frequency should be in a specific range (e.g. 800-3000 Hz).

As long as these criteria are not met, it is good to repeat the measurement before a tone is played becomes.

To suppress interference, it can also be beneficial to set a sensitivity threshold introduce so that only signals that exceed a certain amplitude are detected.

It is also very cheap if you normalize the determined frequencies to the standardized grading scale, d. H. as a result, the frequency of a normalized tone that the determined frequency is closest to comes (see example).

Since many musical instruments are played on a lower pitch than the whistled melody, it can also make sense to transpose the pitch, especially by n-octaves (n = whole number) belittling. It is also possible to use a transposed melody instead of the original melody, in particular Chords to let play. Chords can preferably be played in parallel (= simultaneously). The Transposition is a simple arithmetic operation. To decrease the tone by one octave the frequency to be played is simply halved (or n times halved for n octaves) or by the MIDI Tone number subtracted the value 12 (or n times 12 subtracted for n octaves). A transposition to Playing chords is done analogously by multiplying the frequency by the xth power of the root 12 (x - is the chord tone higher by x semitone steps, especially 4, 7 and 12) or by Addition of x to the MIDI tone numbers (x = 4, 7 or 12 etc.).

In addition to the frequency, the amplitude of the signal (the whistled melody) can also be determined. With This information can be used to control the start, end and velocity of the sound.

The start and end of sound can also be determined by the number of identified wave trains per data block be identified.

A possible embodiment for determining the amplitude is that in the above described data block the mean of the difference between the determined maxima and minima certainly. Of course, you can also make a single difference between a maximum and a minimum use as a measure of the amplitude.  

Also the integral (or the series of sums) over the absolute value (based on the zero line) of the signal (possibly divided by the signal duration) can be a measure of the amplitude or the sum of all positive (or negative) amplitude values.

To suppress the feedback (superposition of the whistle and that played by the MIDI device Tones) it can be useful to use a microphone with a pronounced directional pattern. It is also possible to prevent the whistling sound during the pause between two to detect playing tones, d. H. after the end of the last tone and immediately before the start of the new tones.

If you at least the frequency (possibly also the amplitude and the time of the Sound insert and possibly the end of the sound), you can use a suitable sound z. B. thereby cause a note-on command with the specification of the note number to be played to a MIDI Instrument or particularly preferably sends an equivalent command to a sound card. To the sound can be stopped again after a certain time or after the amplitude of the acoustic signal or after a certain time after the amplitude of the acoustic signal or after recognizing a new story, a note-off or equivalent Send command. In addition, there is also the possibility to let the sound fade away or to overwrite. The choice of "sound's" d. H. of the instrument to be played, for example with a MIDI command "program change".

These commands (note-on, note-off, program change etc.) can of course also be different other sound cards or various electronic musical instruments via a MIDI interface, especially keyboards and synthesizers, to be sent to the corresponding melody to play.

With these two steps:

• 1. detection of the sound signal and determination of the pitch,
• 2. Send a note-on command with the pitch specification

you are now able, preferably a multimedia computer with a sound card, one in a microphone to let whistled melody play synchronously in the sound of the selected instrument.

example

The following example was in Visual C ++ (Microsoft) using the MMSYSTEM library (Windows) written and on a 486 computer (Packard Bell) with one SOUND-BLASTER compatible sound card (with Voyetra Super Sapi FM Driver) tested.

Claims (26)

1. A method for generating music, characterized in that an acoustic signal is recorded via a microphone, its frequency or wavelength is determined and the result is controlled by an electronic musical instrument. 2. The method according to claim 1, characterized in that the acoustic signal via a Analog / digital converter digitizes and the wavelength or frequency of the acoustic signal is determined. 3. The method according to claim 1-2, characterized in that the wavelength or frequency thereby it is determined that the distances of the signal maxima or signal minima or zero crossings or in-phase shaft sections can be determined. 4. The method according to claim 1-3, characterized in that the average value of the distances two in-phase shaft sections is used as a measure of the wavelength. 5. The method according to claim 1-3, characterized in that the maximum frequency of the distances determined two in-phase shaft sections and this distance, possibly under weighted Taking into account the obvious distances, is used as a measure of the wavelength. 6. The method according to claim 1-3, characterized in that the number of wave trains in one Signal section is used as a measure of the wavelength. 7. The method according to claim 1-3, characterized in that the adjusted for outliers Average value of the distances between two in-phase wave sections as a measure of the wavelength is used. 8. The method according to claim 1-3, characterized in that the signal computationally before the analysis is smoothed. 9. The method according to claim 1-3, characterized in that the signal differentiates before the analysis or a difference signal is used. 10. The method according to claim 1-2, characterized in that the wavelength or frequency thereby it is determined that a Fourier transform is performed. 11. The method according to claim 1-2, characterized in that the wavelength or frequency above pattern recognition is determined. 12. The method according to claim 1, characterized in that the result of the frequency determination sent to a MIDI device. 13. The method according to claim 1, characterized in that the result of the frequency determination sent to a MIDI driver on a sound card. 14. The method according to claim 1, characterized in that the result of the frequency determination is sent to a MIDI interface on a sound card. 15. The method according to claim 1, characterized in that the result of the frequency determination a frequency standardized according to the grading scale is rounded. 16. The method according to claim 1, characterized in that the result of the frequency determination a different tone, especially a tone higher or lower by an octave, or a tone by 4 or transpose sound offset by 7 semitones. 17. The method according to claim 1, characterized in that the start of sound by exceeding a certain signal amplitude is recognized.   18. The method according to claim 1, characterized in that the tone end by falling below a certain signal amplitude is recognized. 19. The method according to claim 1, characterized in that the sound start by identifying at least more than 2 similarly long wave trains are recognized. 20. The method according to claim 1, characterized in that the tone end by the identification of less than an arbitrarily definable number of similarly long wave trains is recognized. 21. The method according to claim 1, characterized in that the volume by determining the Distance from at least one signal maximum and one signal minimum is determined. 22. The method according to claim 1, characterized in that the volume by determining the Sum of the absolute signal distances from the zero line in a signal section is determined. 23. The method according to claim 1, characterized in that the acoustic signal in the pause is measured between two tones. 24. The method according to claim 1, characterized in that a 1-500 millisecond segment of the acoustic signal is detected and used for frequency or wavelength determination. 25. The method according to claim 1, characterized in that determining the frequency or Wavelength limited to a 1-100 millisecond segment of the acoustic signal. 26. The method according to claim 1, characterized in that the acoustic signal with a microphone is recorded with a pronounced directional characteristic.