DE2044462B2 - ELECTRONIC MUSICAL INSTRUMENT WITH A KEYBOARD - Google Patents

Description

2.Electronic musical instrument with a keyboard and the key switches assigned to the loads, with a plurality of I on sig na! Generators that generate sound frequency signals, and with a coupling system, the selected audio signal voltages of different frequencies in an amplitude envelope that can be adjusted with the help of controllable gate circuits do a mixture signal coupled to an electroacoustic! Converter is fed, characterized in that

a) the gate soundings {la. . . 7c) (27. 27 ') are each fed via a resistor coupling network and a collecting line from a plurality of control voltage sources (28. 28'. 12k. 12 / '), each with a single-pole key switch (13ii, 13 / ) .... 24, 24 '. 32) are connected and each time a key is pressed, they emit a low voltage signal (Fig. 111 that

b) between at least some of the control panel sources assigned to each of the gate circuits and the resistance coupling system, one / hacking / wide gate circuit (KI t /) 1. 9, /. 9h ... Kl /.

10 /) ..., II «, Hh .... 25, 25 ') is switched on that

c) the chopping second gate circuit by means of rectangular genera assigned to them gates (Fig. 16; Ί5, <6, 17, 29, 29 '), the ji a rectangular pulse chain (Fig. 3) of fü all generators have a constant repeat frequency, but each can be selected individually Generate duty cycle, be controlled that

d | the thus chopped up DC voltage signals (Fig. 12) either passed through the resistor coupling network to the bus and then smoothed by a KC smoothing element, with ...
or are smoothed by a KC smoothing element (K 2 + -Cl) assigned to each of the second gate circuits and then fed to the bus line via the resistor coupling network, and that

ei the first controllable gate circuits (7 (... 7f. 27, 27 ') output with a all the first gate circuits associated busbar (Fig. 10 above; 30, 30 ') connected which leads to the electroacoustic transducer (Fig. 10. 14. 15).

3. Musical instrument according to claim i, characterized in that the amplitude of the right-hand pulse chain (Fig. 3) is higher than the maximum amplitude of the audio signal voltage to be chopped (Fig. 2).

4. Musical instrument according to claim 2, characterized in that the keyboard is divided into at least two keyboards (23, 23 '), each of which has a part of the tone signal generators (26, 26') and the controllable first gate circuits (27, 27 ', 30 . 30 ') is assigned. in that each of the control voltage sources (28, 28 ') of one of the keyboards is connected to the busbar of a given one of the first gate circuits (27, 27') of this one keyboard via a resistor (K8. RH ') of the resistor coupling network. and in that the smoothed output signal of each of the chopping second gate circuits (25. 25 ') of one of the keyboards is connected (F "i g. \ 4).

5. Musical instrument according to claim 2 or 4, characterized in that the amplitude of the rectangular pulse pulse (Fig. 3) is higher than the maximum amplitude of the chopping DC voltage unit (F ie. II) of the control voltage sources (12 «... 12 /) λ . 28. 28 ').

6. Musical instrument according to one of claims 2. 4 and 5, characterized in that the level of the DC voltage signal (11) of the control voltage source (14, C5, K9) as a function is variable from the keystroke speed.

The invention relates to an electronic one Musical instrument with a "keyboard and tasi-shells associated with the keys, with a plurality

s \

of tone signal generators generating audio frequency signal voltages and with a coupling system, the selected audio signal voltages of different frequencies with the help of controllable tone circuits adjustable amplitude ratio to a Mixtursigral couples that an electroacoustic! Converter is fed.

In the case of electronic musical instruments, it is mostly necessary to have mostly pure tones coming from different tone sine generators in a selectable amplitude ratio to each other / and tables. The mixture of tones is important for achieving musical sound effects and timbres in a wide variety of electronic musical instruments. For example, it is performed on an electronic organ in the form of octave couplings or is used on electronic pianos in order to produce a magnificent timbre m . Constant higher frequencies can be added to generate the timbre, for example, as is the case, for example: o is carried out in a Mixtur-Trautonium with the help of l-'orniants (! '. Winding. Sound structure of music. Verlag für Radio-Foto-Kinotcchnik GmbH. Beriin-Borsigwalde 1955. pp. 92 to 10, p). Ls is possible. Mixture components of given: -s given amplitude ratio, which is determined by the amplitudes of the output signals of the tone signal generators (LiS-PS 32 97 S12. DT-AS II Sl 030). Fs is also known (U.S. Patent 3,440,324). to adjust the amplitude ratio of the tonal sigmoid voltages to be mixed as desired. For this purpose, a large number of key switches are connected to each of the keys, for example six, of which one is located in each of the circuits for the transmission of the audio signal voltages coupling / u. When the keyboard is struck, all assigned switches are operated simultaneously. This results in considerable difficulties because the construction of the keyboard is very complicated and insofar (yours and must be worked with particularly high precision because the contacts of the key switches of each key must be opened and closed at the same time, which on the one hand leads to a considerable labor-intensive adjustment and on the other hand leads to high susceptibility to failure 4 ^

On the other hand, the task is the Friindiing based on, with moderate construction effort. namely with just a single switch per button The amplitudes of the audio signal voltages to be mixed can be selected in an adjustable ratio without interference and thereby having a wide variety of changeable timbres available.

This object is achieved by the alternative embodiments of the specified in claims 1 and 2 Electronic musical instrument achieved, according to which the Tonsignalspaniiungen to be mixed itself or Tax relief. the passage of the audio signal voltages through a controllable gate circuit control continuously, with the help of a chopping with adjustable duty cycle and subsequent smoothing (10 Uing can be caught individually in exact linearity in their height are. There are lowering signals for the individual in the predetermined ratio / 11 no problems of an individual linearity or passage characteristic of the individual that each- <\ s assemblies determining sacred amplitude ratio, because the hacking controllable gate switches always either fully or completely are locked. So they serve as a push button switch and are characterized by precise proportionality of the input signal to the final smoothed output signal. In particular, will be also the signal components of low amplitude are not simply suppressed, but in the specified Ratio exceeded. So the finest peculiarities of the control signal can be found in the generated sound can be implemented. It is important here that the structure of the specified circuit is purely electronic and can therefore be created using integrated technology, the only one being Verslellglieder the duty cycle adjusting members must be available on the square wave generators.

Further advantages, details and developments of the invention emerge from the following description and from the subclaims. The invention is illustrated in the drawing, for example, namely shows

Fig. I shows a circuit of an embodiment of a chopping gate circuit used according to the invention.

F i g. 2 to 5 graphical representations of the signal voltage curve at various points in the circuit of Fig. 1.

FIGS. 6 to 9 partly in perspective view circuits of parts of some of the invention Embodiments.

Fig. Figure 10 is a block diagram of parts of an alternative according to the embodiment.

Tig. 11. 12 and 13 graphical representations of the signal voltage curves to explain the operation the embodiment of FIG. 10.

14 is a block diagram of parts of a further embodiment of the invention.

Fig. 15 a circuit for generating a pressing speed-dependent DC voltage signal.

T '1 g. 16 shows an embodiment of a circuit for a Square pulse generator for generating square pulse with variable duty cycle and

FIGS. 17a to 17d are graphical representations of FIG Pulse shapes at various points on the square wave generator of FIG. 16.

The following follow I land from FIG. 1 to 5 describe a description of those used in the present invention chopping controllable gate circuits and then the description of the application of a coupling system on an electronic musical instrument, its key switches connected to the keys directly Lead sound signals.

In a chopping controllable gate circuit according to T i g. I resistors R 1 and Rl are connected in series between an input terminal 1 and an output terminal 4. A diode D \ is connected between a control terminal 2 and the connection point 3 of the resistors Rl and Rl and a capacitor Π between the output terminal 4 and earth. A sound signal <· 1 with the voltage curve according to FIG. 2 is applied to input terminal 1 and a control signal e2 in the form of a square pulse chain as shown in FIG. 3 applied to control terminal 2 of the gate circuit. The repetition frequency of the control signal el is high compared to the frequency of the audio signal ti. and the maximum value Vl of the drive signal el is greater than the maximum value V 1 of the tone signal <■ ' I- The following is a description of the signal occurring at the connection point 3 between the diode Dl and the resistors Kl and Rl.

If the maximum voltage 12 is applied to the control terminal 2, the diode D 1 is charged in the direction Voi and is not conductive because Vl < 12. so that the tone signal applied to input terminal 1 passes resistor R 1 and occurs at connection point 3. By reducing the voltage at control terminal 2 to zero, the diode I) 1 is forward-biased and becomes conductive and the voltage at connection point 3 becomes zero. In this way, the diode /) 1 is switched on and off at exactly the same frequency as the repetition frequency of the control signal e 2 at the sleucrklcmme 2. and at the connection point 3 there is a chopped audio signal voltage e3 of the curve according to FIG. 4 on. This signal c3 is smoothed by the resistor φ2 and the capacitor Cl, so that a signal e4 occurs at the output terminal 4, the signal of which is shown in FIG. The course shown in FIG. 5 corresponds to that of the audio signal c I at the input terminal 1. F i g. 5 shows that the amplitude of the output signal ί'4 can be changed by changing the duty cycle L of the drive signal el.

F i g. 6 shows an embodiment of the invention, there are several circuits for a 4-FuM-. an 8-foot or a 16-foot sound signal is provided. The output terminals of these circuits are connected to a resistor coupling network made up of resistors R 3 and R 4 and grounded via a capacitor C2, which blocks the direct voltage, and a charging resistor R5. The connection point of the capacitor C 2 and the charging resistor R5 is connected to a movable contact 6 of a key switch 5 and the control terminals 2a, Ib and 2c are connected to the respective sources of the 4-foot. 8-foot or 16-foot control signals connected. By changing the duty cycle of the control signals applied to the control terminals 2υ, 2fr and 2c , ie by changing the blanking time for these Tonsignalc isl the relative level of the components of a key switch 6, which is connected to a key 5. occurring mixed sound signals can be set completely independently on the basis of the principle described above.

F i g. 7 shows a further embodiment of the invention, in which the relative position of the contradiction R 1 and the diode D 1 with respect to the example of FIG. 6 is reversed; the diode D 1 is thus connected in the conduction path of each of the 4-foot, 8-foot and 16-foot audio signals. The embodiment according to FIG. 7 is based on the same principles as that according to FIG. 6. In this case too, the on the basis of FIG. 1 maintained relationship between the audio signal and the control signal. Is connected to each control terminal 2a. Ib and 2c a voltage V2 (V2> 11) is applied, the diode DI is forward-biased and conductive, so that the tone signal applied to the input terminal occurs at the connection point 3 between the diode Dl and the resistors R 1 and R 2 When the voltage applied to control terminal 2 is reduced to zero, diode D 1 is reverse-biased and switched off so that no sound signal appears at prevention point 3. In this way, diode Z) 1 is switched on and off at a frequency that corresponds to the repetition frequencies / the square pulse pulse of the control signal at the Stcucrklemmc 2 corresponds. As a result, at connection points 3, as in the case of FIG. 6 signals of the courses according to FIG. 4th

While in the Alis guide forms according to FIG. (and 7 the 4-foot, 8-foot, and 16-foot tones are blanked in relation to the time axis and then smoothed and mixed, it is also possible to use them in terms of: on the timeline and then blending and then smoothing as shown in FIG. 8 and 9 shown is. The same results are obtained

ίο as in Fig. 6 and 7. The latter case is relevant advantageous that the number of switching elements can be reduced compared to the first case can.

The above description refers to an elastic

is a tronic musical instrument, its key switch direct and switch the mixed audio signal. So with the system you can have a powerful and generate variable sound coloration over a large area, because they are at a relative height mixed the 4 foot. 8-foot and 16-foot beeps through a single button switch to one Electronic converters can be switched without requiring a plurality of key switches per key is. The audio signals are not on one

2 <i sine wave limited but can be any you want Have waveform, e.g. B. that of a rectangle, a triangle or a sawtooth.

F i g. 10 shows a further embodiment of the invention which is applied to an electronic music instru-

w ment is applicable, in which the key switches lead and switch the audio signals directly, but DC voltage signals that cause the audio signals to be switched through at another point.
Referring to Fig. 10, tone signal generators generate Ha

is Hb. 8c, Hd and He Tone signals corresponding to the emergency tones C 1, C2, C3, C4 and C5, respectively. Gate switch Ία. Tb. 7c. Id and 7c are each connected to the tone signal generators 8 ″, Hh, Hc. Hd or 8c connected. Fin the respective gates 7 «. lh. 7c. Id and 7 (are control voltage sources 12 ". \ 2b. 12c. 12.7 by 12c, which are each connected to key switches YSu, YSb,! 3c. 13 {/ or ISe . A DC voltage source 14 is connected to the control voltage Voltage sources 12 ", 12 / ?. 12c, I2d and 12c via the respective key switches 13a, 13fr, 13c, 13d or 13c DC voltage applied. Chopping 8-foot gate circuits 10", U) b, 10c. 10J and 10c, the gate circuit according to FIG. 1 are between the control voltage sources 12 ″. 12b. 12c 12J and 12c and the corresponding continuous gate circuits Ία, Tb, Tc, Te. Ίά or 7e switched. The control terminals 2 of these chopping gate circuits 10 ″, 10b, 10c, 10i / and 10c are connected together to the output terminals of an 8-foot square pulse generator 16. Hacking Ifi-foot gate circuits II «. Wb. Lic. Hi / and Hc correspond to those of FIG. 1 and are / are the control voltage sources I2u. 12fr. 12c. 12i / unc 12c on the one hand and a gate circuit arranged to the left of the continuous gate circuit Ία and the gate circuits Ta. Tb. Tc and Td on the other hand switched. The control terminals 2 of these chopping gate circuits 11a, 11fr. lic. lld and lic are connected together to the output terminal of a 16-foot pulse generator 17. 4-foot chopping door circuits 9u. 9fr. 9c. 9d and 9c. that of the paintings F i g. 1 are between a left control signal source 12 ″ arranged control signal

source and the control signal source \ 2a. 12 /). 12c and I2i / on the one hand and the gates Ta, 7 />, Tc. Id or Tc on the other hand switched. The control terminals 2 of these chopping gate circuits 9 ', 9h, 9c.9il and 9t' are connected together to the output terminal of a 4-foot square-wave generator 15. The bypass and output terminals of all of these chopping gates are labeled 1 and 4, respectively.

If a certain key is struck during operation, current is supplied to the control signal source corresponding to the key pressed, and it generates a DC voltage signal e5 of a forward run as shown in FIG. 11. This signal is applied to the chopping gate connected to the wrapper. If, for example, the key switch 13ί is closed, the control signal source 12c emits the signal c5 which is applied to the output terminals 1 of the chopping gate circuits 9d, 10c and lic. Square-wave pulses e2 emitted by the respective square-wave pulse generators 15, 16 and 17 as shown in FIG. 3 are applied to the control terminals 2 of the chopping gate circuits 9d, 10e and lic. The relationship V5 <Vl is maintained between the maximum value V 5 of the signal eS responsive to the indentation and the maximum value Vl of the rectangular pulse c 2. In this way, when the voltage Vl (Vl > VS) is applied to the control terminal 2 of each chopping gate circuit 9 (/. 10c and lic, the diole D I is biased in the reverse direction and switched off, so that the signal that occurred when the key was pressed crosses the resistor R 1 and, as described with reference to Fig. 1, appears at connection point 3. If the voltage at control terminal 2 then drops to zero, diode D 1 is forward-biased and conductive, so that at the connection point 3. As a result, a signal <? 6 of the voltage curve according to Fig. 12. A signal eT of the voltage curve according to Fig. 13, which corresponds to that of the signal e5 , appears at the output terminal 4 if the signal voltage t'6 is integrated by the resistor Rl and the capacitor Cl. The amplitude of the signal eT can be changed by changing the duty cycle I. der

Square-wave pulse chain of control signal c2 at control terminal 2 can be changed. In this way, according to the diagram of FIG. 10. in which the 4-FuD. 8-foot and 16-foot square-wave signal generators 15, 16 and 17 are provided separately from one another, so that the pulse duty factors of the square-wave pulses can be changed independently of one another, the direct voltage signal resulting from the keystroke, supplied by the control signal source 12c and into the chopping gate circuits 9d. 10c and lic is fed, transformed according to the duty cycles of the square-wave signals supplied by the square-wave signal generators 15, 16 and 17, and the transformed signals are fed into the associated continuous controllable gate circuits to achieve the audio signals. It is assumed, for example, that the pulse duty factors of the square-wave signals output by the 4-foot, 8-foot, and 16-foot square-wave signal generators 15, 16, and 17 are 1. 0 and 12, respectively. By depressing the key switch 13c, the control signal source 12c assigned to the key switch 13c is supplied with energy and the resulting DC voltage signal is fed into the three chopping gate circuits 9d, 10c and 11c. After it has gone through the 4-foot gate circuit 9 </, the signal has a

Amplitude corresponding to the value '= I, and

appears on the door terminal of the gate circuit 7 </ for the tone C4; consequently the gate circuit opens

ίο Td and the signal corresponding to the tone C4 is output from the output terminal of the gate circuit Td . The signal which occurs in response to the depression and which is applied to the 8-foot gate sounder 10c cannot pass through, the gate circuit 7c does not open and no sound signal corresponding to tone C3 appears. The amplitude of the signal which occurs in response to the depression and which has passed through the 16-foot gate circuit lic corresponds to

the value ', = 12, namely half the amplitude

7th

of the signal that passed the 4-foot gate 9i /. As a result, the gate circuit 7b is half opened for the tone C 2 and emits the tone signal corresponding to this tone C1 , the amplitude of which, however, only has half the value of the amplitude of the tone signal corresponding to the tone C4.

The desired coupling of the audio signals is not achieved by several pushbuttons, but by one reached a single switch, and the number of controllable continuous gate circuits only needs the Number of tone signal generators to match. Furthermore, the respective foot volume can through Changing the duty cycle of the square-wave pulses can be changed continuously. This eliminates all problems which result from the presence of a large number of contacts per key switch. When switching according to FIG. 10 is the smoothing capacitor C1 (FIG. 1) in each one of the chopping gate circuits switched on and therefore carries out a smoothing in each of these gates. The condenser Cl in the circuit according to FIG. 1 can be omitted there and with the output of several such chopping gate circuits, which then fewer parts are necessary.

14 shows a keyboard coupling system according to the invention. Rigid contacts of a key switch 24 of an upper keyboard 23 and a key switch 24 'of a lower keyboard 23' are connected to the positive terminal of a DC voltage source 14 connected whose negative terminal is grounded. The moving contacts of key switches 24 and 24 ' are connected to a control signal source 28 assigned to the upper keyboard 23 or to one of the lower ones Keyboard 23 'associated control signal source 28' connected.

The control signal source 28 is connected to a resistor R 8 and to the input terminal I of a chopping gate circuit 25 which connects the circuit of the upper keyboard 23 with that of the lower keyboard 23 '. The control signal source 28 'is connected to a resistor Λ 8' and to the input terminal Γ of a chopping gate circuit 25 ', which connects the circuit of the lower keyboard 23' with that of the upper keyboard 23. Square pulse generators 29 and 29 ', which generate a square pulse pulse generator (FIG. 3). are connected to the Stcucrklcmmcn 2 and T of the chopping gate circuit 25 and 25 ', respectively. The other terminals of the

509 584/58

Right-hand pulse generators 29 and 29 'are grounded. The gate circuits 25 and 25 'have the .Aulhau of FIG. 1. The output terminals of the chopping gate circuit 25 is connected to the resistor RH and the control terminal of one of the lower keyboard 23 '/ uge-'. arranged digit gate circuit 27, while the output terminal 4 'of the chopping 1 or circuit 25' is connected to the contradiction RH and the control terminal of a continuous gate circuit 27 assigned to the upper keyboard 23. A tone signal is fed into the input terminal of the continuous gate circuit 27 assigned to the upper keyboard 23 and a tone signal from a tone generator 26 'is fed into the output terminal of the continuous gate circuit 27' assigned to the lower keyboard 23 '. After the required voltage has occurred at the control terminals of the continuous Torsehalumgen 27 and 27 '. these open according to the control voltage level and emit the audio signals to their output terminals 30 or 30 '.

If a desired key is struck in the upper keyboard 23 and the key switch 24 corresponding to this 'key' is closed, the voltage E of the DC voltage qucHc 14 is sent to : <. the control voltage source 28 assigned to the upper keyboard 23 is applied. If the button is then released after a certain period of time, a signal according to T'i g is sent from the control voltage source 28 to the control terminal of the continuous gate circuit 27 via the resistor R 8 ui. 11 is applied, the I or circuit 27 opens, and the tone signal emitted by the tone signal generator 26 appears at the output terminal 30 of the gate circuit 27. The direct voltage signal which appears when the key is pressed and which is emitted by the control signal source 28 assigned to the upper keyboard 23 is identical at the output terminal 1 of the chopping gate circuit 25. This signal has the course according to Tig. 11. The square-wave pulses emitted by the square-wave pulse generator 29 in accordance with ri g. 3 lies on the, control gill 2 of the chopping gate circuit 25 according to FIG. 1 and at the connection point 3 between the diode 1 and the resistors R 1 and R 2, pulses according to FIG. 12 occur around the passage and blocking of the diode D 1. which are smoothed by the resistor R 2 and the capacitor C I, so that a signal according to Tig at the output terminal 4 of the chopping gate circuit 25. 13 appears. This signal is fed into the control terminal of the continuous gate circuit 27 'assigned to the lower keyboard 23' to open it, so that the tone signal emitted by the Tonsmnal'jenerator 26 occurs at the external terminal 30 'of the continuous gate circuit 27 \ s. The amplitude of the Si occurring at output terminal 4 of the chopping I orxchaltum: 25

Unals can by changing the identity,

des \ om square pulse generator "29 emitted · * ■ Square pulse can be changed. Ts is therefore wrong. the amplitude of the at the output terminal Wdcr the gate circuit assigned to the lower keyboard 23 27 'to change the signal occurring and thereby the degree of coupling of the lower f> s Keyboard 23 'generated tones to the I on generated by the upper keyboard 23 to set.

If a load of the lower lastatui 23 is depressed in order to close the 'key switch 24' corresponding to this key, then the voltage / ·. ' of the direct voltage source 14 is applied to the power voltage source 28 'assigned to the lower keyboard 23'. If the button is then released after a certain time has elapsed, the signal according to T 'ig is sent from the control voltage source 28' via the resistor R 8 'to the control terminal of the continuous gate circuit 27'. 11 created. The digit gate circuit 27 'opens, and the tone signal emitted by the tone signal generator 26' appears at the output terminal 30 'of the gate circuit 27'. At the same time, the low voltage signal emitted by the slewing signal source 28 assigned to the linear keyboard 23 'is applied to the input terminal Γ of the chopping gate circuit In the control terminal 2 'of the chopping gate circuit 25 according to FIG. 1, the signal according to FIG. 13 appears at the output terminal 4' of the gate circuit 25 '"Gate circuit 27 is applied and this is opened so that the ion signal emitted by the THrsignalgenerator 26 occurs at the output terminal 30 of the gate circuit 27. In this case too, the amplitude of the signal occurring at the output terminal 4 'can be changed by changing the duty cycle.

nisses - ■ delivered by the rectangular pulse vulture 29 Rectangular impulses are therefore changed the amplitude of the audio signal can be changed at the output terminal 30 of the keyboard associated gate circuit 27 occurs, and thereby the degree of coupling of the upper keyboard 23 'tones generated' can be set to the 'tone generated' by the lower keyboard 23. In this way is an adjustable 1 keypad coupling system with a single key switch per key.

Tin essential feature of the I laupibestandleil of the coupling system according to Fi g. ! forming circuit is in the fact that the voltage appearing at the output terminal 4 is proportional to the voltage. which is applied to the finger clamp 1 in the range of 0 S V 1 <L 12 (F 1 g. 2

and 31st and also proportional to the! ast relation ..

the square-wave pulse chain applied to control terminal 2. The following is the description, a Systems that derive additional benefit from this proportional relationship between the output and input voltage.

The uegenwiirtit! used musical instrument !: include, among other things, an instrument such as eir Harpsichord in which the ion volume is constant mi.it-> häiiüis: of the strength is. mn who depressed the load as well as an instrument like a piano in which the tone volume depends on the Force is changeable. with which the load is depressed will. The former musical instrument produces a, • It has a rather delicate and shimmering tone color, however Disadvantage that the volume is not dependent wedge of the force changes with which the 'key is depressed is pressed. That’s why there was certainly also: a piano developed to replace the harpsichord: kicked. From a historical perspective (.lieser music Instruments it becomes clear that the electronic!

Musical instruments will also be aimed for in the future, depending on the force or the speed at which branches are loaded, the onlauistiirke and a changeable one To achieve timbre.

This is due to the use of a control signal source according to! - 'i g. 15 possible in an electronic musical instrument, the key switches of which switch a control DC voltage, the volume of the generated 1 one being variable depending on the keystroke. II and 15 show a key switch with a normally closed fixed contact piece 31. a movable contact piece 32 and a normally open fixed contact piece 33. In this branch switch, the log-called contact transition line is used. the (Jas movable contact piece 32 needs to be in contact mn tiem normally open fixed contact piece 33 tu reach, after it has been with au 1.Wr K (Mitakt. the normally closed fixed contact piece 3 brought!. with increasing lastenlvauffcehlagungsgeschwindigkcit shorter, while the The normally closed fixed contact piece 31 is connected to the tiegativcn terminal of a DC voltage source 14 and the normally open (first contact piece 33! Milder positive terminal and is at the same time connected to the ground) 32 is connected via a parallel cable of a capacitor C'5 and a resistor R 9 to an output terminal 34 which is connected to the cathode of a diode 3, the anode of which is grounded, in the position in which the key is not pressed The capacitor C5 is supplied by the DC voltage source 14 via the diode 03 the movable contact piece 32 and the normally closed fixed contact piece 31 are charged to E volts with the capacitor terminal connected to the output terminal 34 being positive with respect to the other terminal connected to the movable contact piece 32. If the load is then struck and the movable contact piece 32 is lifted from the normally closed fixed contact piece 31, the charge stored in the capacitor C'5 is discharged via the opposing Rf. At the output terminal 34, however, no voltage occurs.

After a corresponding period of time, the movable contact piece 32 is brought into contact with the normally open fixed contact piece 33, and the voltage across the capacitor Γ5 appears at the output terminal 34. '5 stored charge is not discharged i ¹ ^ largely via the resistor R9, and to de; -Nusg-ingsklemme 34 enters a relatively hol.:. · voltage on the moving contact piece 32 ui.un in contact with the normally open fixed contact piece If, on the other hand, the line is long, the charge stored in the capacitor ( 5 is largely discharged through the resistor R9 , and a very low voltage occurs at the output terminal 34 when the movable contact piece 32 comes into contact with the normally open fixed contact piece 33 is brought. This means that with a high keystroke speed and consequently short l ' career time at the Aussianiisklcmme

34 sets a high voltage, while a low voltage appears at the output terminal 34 at a low strike speed and consequently a long transition time. The circuit shown in FIG </ and 13c and the control voltage source 12 (/. 12 /). 12c, 12el and 12c in the system of FIG. 10 can be used. It should be noted that between the output from the control voltage sources 12 (, 12 /), 12c, 12i / and 12c and the output to the continuous I oischaliungen Ta. Th. Tc. Td and 7c applied signal is given a proportional relationship, that is, a proportional relationship between the component; and the exit of the chopping gate circuits 9a. 9b. 9t \ 9tL 9c; lOi /. 10 /). 10c. Kh /. 10c and 11 </, Mh, lic, Md. Me. For this reason, every change in the control voltage sources 12ii. 12 /). 12c. 12i / and 12c as a function of the wedge of the speed at which the object is hit . Tc and 7c applied signal, so that at the output terminals of these gate circuits with high keystroke vision windigkeil sound signals of large amplitude occur, while sound signals of small amplitude occur at low load impact speed. In this coupling system for use in an electronic musical instrument, in which the amplitude of the signal appearing in response to the load depression is variable depending on the speed of the keystroke. the amplitude of the input signal and that of the output signal are linear to one another.

The square pulse generator for generating square pulse with variable 'load ratio ' ... can have different designs. One possible embodiment is shown in FIG. Id shown. This Rechteekimpulsgenerator is such (.laß the key ratio in Depending wedge by the height of the DC voltage is changed. In FIG. 16 of the Rechteekimpulsgenerator comprises a differential amplifier composed of two transistors / Vl and Tr 2. If a Sägezahnimpulsfolge according F i g. 17a is applied to the base of one of the transistors Tr 1 and a DC voltage Va is applied to the base of the other transistor 7> 2 , the output signal appearing at the collector of the transistor Tr2 has the form according to FIG. 17b, in which only the section of the sawtooth wave above the level F u is substantially increased. This pulse shape is then shaped by a Schmitt circuit, which consists of two transistors Tr3 and TV4 to give the pulse shape shown in Fig. 17c. the SE pulse obtained is to AVIF the desired amplitude amplified by a 1 ransistor 7 i5. The resulting signal is then passed through an emitter-folsier circuit with an Iran · Mstor 7 V6, and the signal is obtained as follows:

I .miller of the transistor 7Vh output pulse shape by changing the DC voltage Va constantly variable in the range from 0 to 1.

While the above description refers to a system in which a diode is used as a switching element is used in the chopping gate circuit. the switching element is by no means on the diodes

limited, and in their place a transistor, an electron tube, can be used to achieve the same operation or the like weraen used. Furthermore, exactly the same operation as described above is possible, if the polarity of all circuit components including the diode and the voltage qucüe

O 14

is reversed. Likewise, the above description refers to a coupling system with 16-foot. 8-foot and 4-foot audio couplers, however, work just as well on a 32-foot coupling system. 2 -., - FuIK l ' _5- foot, I ² , -1-foot couplers and other tonsisznak' applicable.

See S sheet drawings

Claims (1)

Patent claims: ). Electronic musical instrument with a keyboard and key switches assigned to the keys, with a plurality of audio signal generators generating audio frequency signal voltages and with a coupling system, the selected audio signal voltages of different frequencies in an adjustable amplitude ratio with the help of controllable gate circuits couples to a mixture signal that is fed to an electroacoustic transducer, thereby marked that 15th a) the gate circuits (K 1 and D 1) by means of square-wave generators assigned to them (FIG. 16). each of which generates a rectangular pulse chain (FIG. 3) of a constant repetition frequency for all generators, but each individually selectable pulse duty factor, are controlled that b) the thus chopped up audio signal voltages (F i g. 4) are either conducted via a resistor coupling network (K2 + R4) to a collecting line and then smoothed by means of a KC smoothing element (K2 f CI), the resistances of the resistor coupling network / works can partly also be part of the (ilüttuniisuliedes (Fig. 8. 9) or smoothed by a KC smoothing element (K 2 f CI) assigned to each gate circuit and then via a resistor coupling network (Λ3 -I- K 4) to a collecting line pasture and that c) this bus line via a single-pole key switch (6) with all key switches assigned, single busbar is connected. the / um eiekiroakustisehen Converter leads (F i g. 6 to 9).