DE1213210B - Musical tone generator in which the tones are obtained by frequency division - Google Patents

Description

Musical tone generator in which the tones are obtained by frequency division The invention relates to a musical tone generator, in which the tones through Frequency division can be obtained.

As with these instruments for construction and playing reasons only a limited supply of notes stored and with one of the requirements of the musical Match practice can be equipped to agree access time becomes a requirement required, according to which individual tones are to be selected. There are several such selection rules known. They are reflected in the different tone systems or moods, essentially the Pythagorean tuning, the naturally harmonious tuning, the mid-tone mood and the equally tempered mood.

The equally tempered tone system, also known as “well tempered”, has now been introduced in practically all keyboard instruments. It shows a circular closure with twelve equal tempered fifths. The tempering consists in the even distribution of the ratio called the Pythagorean comma (531 441: 524 288), which represents the excess of twelve pure fifths over the octave, over these twelve fifths. This means that the equally tempered fifth is only a twelfth Pythagorean comma (- 1.001) too small compared to the perfect fifth. The advantage of circular reasoning (unlimited continuous modulation possibilities) is bought by fairly sharp major and correspondingly too soft minor thirds.

The tuning (tuning) of the oscillators (strings, whistles, reeds, electronic generators) of the instruments with stored tones that are known from Reasons must be repeated from time to time, happens when the mood is well-tempered mostly in fifths. It is the art of the respective stoner, the right one To find the temperature control, in which the circle closes after twelve steps. In addition to the fifth, the fourth, the major seventh and the small second (semitone) is suitable for tuning. When tuning in semitone steps the otherwise always necessary setting back to the starting octave would even be omitted. Tempering a dissonance is almost impossible aurally, so that the consonant Intervals fifth and fourth preferred.

Correct tuning by ear also requires concentration, Time and a trained musical ear. It is getting less and less of one today running number of specialists. The invention wants this the voting process simplify. According to the invention, a single RF oscillation can be switched through digital frequency dividers with predetermined whole division ratios all audible Frequencies obtained with musically usable intervals.

It is known that the known Baldwin organ has a low-frequency oscillator for each tone of the octave, from which octave tones are derived by frequency division. This has the disadvantage that at least eleven separate oscillators must be kept frequency-stable. In contrast to this, in the invention, the musically interesting tone intervals are obtained from a single high-frequency oscillation by digital frequency counting in predetermined sub-ratios. There is therefore only one single frequency to be stabilized and, so to speak, only switches to be operated in order to obtain every musically useful interval. The dividing ratios of digital frequency dividers are particularly easy to handle, so that even a deaf person can use simple switch settings for. B. with the tone sequence of the musical tone generator according to the well-known education law with n as a whole number could set exactly.

With the help of the new music tone generator, z. B. build a tuner that enables an exact equal-part tempered tuning in the shortest possible time. The adjustment to the correct pitch takes place. optically - e.g. B. with a pointer instrument - and does not require any hearing training for the vocalist - The operation is so simple that certain keyboard instruments are given such an electronic tuner from the outset and the occasional tuning can be left to the user. -A tuner with the new music tone generator can also find an important application in church organs that are due to. The seasonal temperature fluctuations require frequent retuning. Especially with larger works this has always been time-consuming and time-consuming because of the large number of different registers and pipes .. ,,. ,, - "With the new music tone generator" you can also produce monophonic or polyphonic instruments. The structure of both types is similar to that of the tuner. The most important difference is in the unanimous version, a switchable frequency divider, 'aii'"aem -twelve -different divisors can be set'-while in the polyphonic version a maximum of twelve dividers are provided, which are j6 dividers on different, set a minimum number of divisors.

All instruments have in common that they are fundamentally not can detune, since all tones by numerical 'division from a common Mother frequency f, and that all tones can be derived from `simple Change f, let it transpose as desired. -For the selection of the divisor numbers is the type of tuning desired and, if applicable, the accuracy with which individual intervals are to be realized, decisive.

The drawing represents exemplary embodiments of the invention; it shows = -F i g .-. 1 an arrangement for the tuner, - - -F i g. 2 a circuit option for octave divider, F i g. 3 one of the possible circuits for the frequency range, F i g. 4a and 4b diagrams and FIG. 5 an arrangement for a monophonic musical instrument, F i g. 6 a - arrangement for a polyphonic musical instrument.

As is well known, it can be done with means. In digital technology, divide a given frequency f by any integer z. If z is larger, f ,: is usually counted into a counter that recognizes the preselected number z, emits a reset pulse and then starts counting again. The repetition frequency of the reset pulses is It is easy to preselect such plate numbers z that the associated frequencies form musically usable intervals.

Are z. B. selected z1 = 2 and z2 = 3, then applies and the result is a perfect fifth. All other intervals can be implemented in a similar way. The main advantage of this digital method is the independence of the interval from f .. By varying fo, the absolute position is changed, which can be used with advantage for trans = position. With these means, music-aesthetic examinations could be carried out and pure chords with different temperaments could be compared quickly and easily with one another and depending on the absolute height.

In the equally tempered mood, the intervals are determined by the education law given. The positive integer v exception -v = 12 (octave) - is irrational numerical values that cannot be precisely produced in digital interval generation. However, it has been found that the equally tempered semitone is approximated by the quotient -196: 185 with an error of only 5--10-B. This fact and the possibility of arbitrarily shifting intervals generated by frequency division in the absolute height allow the construction of the one shown in FIG. 1 tuner shown schematically.

The output signal of a frequency generator 1 with the frequency fa, z. B. continuously variable between 40 and 90 kHz in a range slightly larger than an octave, is fed to a divider stage 2, which can optionally divide by z = 196 or z2 = 185. At the output A of the divider 2 are therefore with one after the other two frequencies are available which, at constant fo, are practically exactly an equally tempered semitone apart from one another.

. The frequency of, e.g. B. Tones to be tuned, depending on the device via a corresponding transducer 3 - after amplification and pulse shaping as f "eß - compared with fi or f2 as fvergl. In an indicating frequency comparison circuit 5.

The display 6 is phase sensitive; it is preferably done optically. During the adjustment one observes an ever slower beat (fluctuating deflection of an instrument, slowly flickering light bulb, etc.), which disappears when the frequency is exactly the same (constant deflection, constant brightness). . The tuning process proceeds as follows: a) Setting the frequency generator 1 to the internal - if necessary quartz-controlled - normal frequency of 81.4000 kHz: In position z2 = 185, fverel. = 440 Hz; with this the note a 'of the instrument concerned is to be tuned. Of course, a 'can also be set to any other desired level, e.g. 435 Hz.

b) Switch to z ,, = 196. The comparison frequency is now one Semitone decreased; according to her as' is voted.

c) Switching back to z2 = 185 and reducing fo until fvergi. corresponds to the previously tuned as'.

d) switch to z, = 196; Tuning the tone g '. e) Downshift to z2 = 185 and decrease f., until f "cf. corresponds to the previously tuned g '.

f) Switching to z ,. = 196; Voices of the tone f sharp, etc. By layering or superimposing semitones twelve times, all necessary intervals are found and finally the octave is reached again. This octave can be found with an accuracy of about 6-10-Ii, taking into account the systematic error of a semitone step of 5-10-B. For comparison, it should be stated that the smallest deviation from the prime, which the ear can just detect in the most sensitive pitch range around 1 kHz, is 4 -10-3 - i.e. two orders of magnitude higher. If there is a need to tune the parallel octaves in the bass or treble in addition to the twelve tones in the middle register, a chain of octave dividers 7 can be added to the comparison branch at A (bass) or in the measuring branch at B (treble). be switched. The octave dividers are simple bistable multivibrators that divide the frequency by two.

One of the possible frequency comparison circuits is shown in FIG. 3 shown; the mode of operation is shown in FIGS. 4 a and 4 b explained.

It is assumed that the measurement and reference voltage U.eß or Uverei, can only assume two values, namely zero and the negative maximum value. aside from that let the ratio of pulse duration to pulse pause be constant.

The circuit is dimensioned as a NOR component with a transistor 8: the presence of one of the two is sufficient for the transistor 8 to be completely switched on Input voltages. Both must have zero potential for blocking.

If the measurement and comparison frequency are different from each other (Fig. 4a), so at the collector of the transistor 8 there is a series of pulses U, with periodically fluctuating Pulse width. This corresponds to a fluctuating DC mean value Ue, which the instrument 9 displays.

If f "" ß and fv "ga. Are equal, then Ue shows one - of the accidental Phase position dependent - constant pulse width. The instrument remains accordingly 9 in a row.

The described optical method can also be used very slowly Beats of z. B. 0.01 Hz, which can no longer be perceived by the ear, demonstrate well.

The transducers used depend on the type of instrument. With organs it is advantageous to use a microphone, while with the piano one special magnetic pick-up is proposed, which you can use for. B. with permanent magnet pole pieces staples on the strings adjacent to the string to be tuned and thus these adjacent strings at the same time dampens. The pick-up also contains a small transistor amplifier, which closes a feedback loop that causes the string to be tuned to vibrate continuously is stimulated.

Continuous vibrations of the test object are necessary in order to enable the exact frequency comparison to enable.

Tuning an electronic one requires the least amount of effort Musical instrument. No electroacoustic transducer is required here, as it is already AC voltages of the required frequencies are available in the instrument.

It succeeded with the help of the digital tuner described, starting out from an arbitrarily out of tune initial state, in the case of an electronic musical instrument Establish perfect, equal temperature control within a few minutes.

The schematic structure of a monophonic or polyphonic musical instrument show F i g. 5 or 6. The oscillation generator 10 supplies the oscillator frequency fo, which is connected to the individual dividers in the dividing device 11 by means of the Keys z1 to z12 z. B. is obtained as a tone sequence within an octave. By the octave divider 0T and switches S to S "'can change the individual tones according to the desired Octave position are fed to the playback device 12.

For polyphonic musical instruments, according to FIG. 6 an octave divider chain OTl ... 0T3 etc. connected to each of the parallel dividers 1: Z1, 1: Z2 etc., while switch groups Sl to S12, S1 'to S12 etc. are provided so that any sound combinations can be fed to the playback device 12 .

Claims (5)

Claims: 1. Musical tone generator in which the tones are divided by frequency can be obtained, d a -characterized in that from a single RF oscillation through switchable digital frequency dividers with predetermined whole division ratios all audible frequencies can be obtained with musically useful intervals. 2. musical tone generator according to claim 1, characterized in that for tuning of Musical instruments have a frequency divider for an adjustable frequency HF oscillation with two different predetermined sub-ratios that can be switched on alternately and a preferably optically indicating comparison device for these frequencies provided with the electrically converted vibrations of the instrument to be tuned are. 3. musical tone generator according to claim 2, characterized in that in the frequency divider channel and / or further frequency dividers as octave dividers in the channel receiving the measurement frequency can be switched on. 4. music tone generator according to claim 2, characterized in that that for absorbing vibrations of a strummable string instrument a preferably magnetic pick-up is provided, which is used to excite continuous vibrations Includes feedback circuit with electronic amplifier and its permanent magnet pole pieces can be attached to the adjacent strings for damping. . 5. Musical tone generator according to Claim 1, characterized in that it can be used for polyphonic musical instruments is, in which one or more frequency dividers are generally several alternately switchable different division ratios with subsequent octave dividers provided and all outputs of the dividers of a sound reproduction point that can be switched on and off at will are supplied. Documents considered: Dr. M e y e r - E p p 1 e r, Electr. Sound generation, Ferd. Dümmlers Verlag, Bonn, 1949, p. 101, F i g. 89