DE1188920B - Circuit arrangement for the generation of drum-like sounds in electronic musical instruments - Google Patents

Description

Circuitry for generating drum-like sounds Electronic Musical Instruments The invention relates to means for generating Drum-like sounds in an electronic musical instrument with tone generators and sound amplifier and having a plurality of keys and key switches for control of these generators.

As is known, there are electronic musical instruments that use electrical oscillators, e.g. B. tube oscillators, use. It is not particularly difficult to get drum-like effects, i. H. so-called percussion effects, to be achieved with such electronic oscillators. This requires JE but for each oscillator a separate circuit, so that the appropriate instruments are disproportionately costly. When deriving these drum-like sounds from the amplifier or from a transmission circuit, this multitude of switching elements is no longer necessary, but difficulties arise here. In the case of types of electronic musical instruments provided with a keyboard, e.g. B. in electronic organs, a drum-like effect can be produced without too much difficulty by pressing a key. However, the amplifier soon tries to remain in a steady state, and a drum-like effect cannot readily be achieved on a second note if the first key is kept depressed and a second key is depressed. Accordingly, the object of the invention is to provide in an amplifier of an electronic instrument provided with a keyboard means for generating percussion-like sounds in which these can be achieved even with successive notes regardless of whether previous notes are held or not.

To this end, the invention is characterized in that the Amplifier means for controlling the gain in accordance with one of the gain controlling means has potential supplied, and that by the keys for the generation of electrical impulses actuated means for generating drum-like Noise with the amplifier or with the means through a normally open, electronic switch are connected, which is generated when a pulse is supplied drum-like noises close automatically for a short time and become independent immediately opens again from the position of the key switch triggering this pulse.

An exemplary embodiment of the subject matter of the invention is shown in the drawing, FIG. 1 is a perspective view of an organ constructed according to the invention, F i g. 2 shows a perspective view of a section of the keyboard and the associated switching means, FIG . 3 is an electronic circuit diagram showing the essential electronic parts of the invention, FIG. 4 shows an additional circuit for generating a plucking effect, FIG . 5 is a block diagram of the organ, FIG. 6 is a schematic diagram showing change in a waste of part of the circuit of F i g. 3 represents, FIG. 7 shows another schematic circuit diagram, roughly according to FIG. 4, which illustrates another embodiment, FIG. 8 shows another electronic circuit diagram showing a further embodiment in detail. In the drawings, FIG. 1 shows an organ 10 which is designed according to the invention and has a console 12. The console has two manuals or keyboards 14 and 16 and is provided with stop keyboards 18 and 20 connected to them. The organ has various control means indicated at 24 and also has a chord register 22 for playing chords. The console is provided with a loudspeaker 26 and an expression pedal 28 .

Each of the manuals, e.g. B. the manual 14 (see also F 1 g. 2), has a large number of white keys 30 and a large number of black keys 32 . These keys are mounted on key sticks 34 which are mounted on suitable rotatable means, e.g. B. flexible springs are attached to a fixed plate or flange 36 . The key bars are arranged so that they move actuating members 38 in the vertical direction, whereby a movement of a plurality of contact wires 40 is caused. The contact wires are arranged in such a way that they touch conductive inserts 42 in insulating cross members 44, whereby the oscillators are connected to the amplifier or the oscillators are put into operation for exact sound generation. The conductive inserts 42 correspond to the organ's stop buttons controlled by the stop button panels. In addition, an additional insulating cross member 46 is provided which has a conductive insert 48 at its upper end. The adjacent contact wire 40 is normally connected to the conductive insert 48 above, and all contact wires 40 are normally separated from the conductive insert 42. When a key is depressed, the corresponding contact wires 40 are moved downwardly by the actuating member 38 into connection with the conductive inserts 42 underneath, while the upper contact wires are separated from the conductive insert 40 at the same time. The insulating cross members 44, with the exception of the upper one, are rotatable about their own axis in order to selectively bring the conductive inserts into a position connecting or not connecting to the contact wires 40, depending on whether a given "stop" is effective or not.

In Fig. 3 shows the amplifier for generating the drum-like sounds in detail. A jack 50 is provided for the audio input to this amplifier, which is generally designated 52 in the following description. The sound input is connected to a preamplifier and is connected via filters to the key switches, which usually have various organ stop switches. The input at the jack 50 is conventionally connected to a phase reversing triode which has the usual equally large anode and cathode resistances 56 and 58, respectively. The anode resistor is connected via the usual RC smoothing filter 60 to a branching point 62 and from there via a resistor 64 to an anode voltage supply line labeled 66. This is supplied by a power amplifier of conventional design. The anode output of the phase inversion tube 54 is conventionally connected to the grid 68 of a triode 70 via an RC coupling. The cathode output is connected to the grid 72 of a triode 74 via an RC coupling. The tubes 70 and 74 are push-pull, the corresponding anodes 76 and 78 of these tubes are connected to the opposite ends of the input turn 80 of a transformer 82 . The input turn is provided with a center tap 84 which is connected to the branching point 62 leading to the B + feed line. The cathode 86 of the tube 70 is connected to the branching point 90 via a cathode resistor 88 . The cathode 92 of the tube 74 is connected in a similar manner via a resistor 96 to the center tap of the transformer and at the same time to the electrode-resistor combination 98 , which consists of a grounded resistor 100 and a capacitor 102 connected in parallel therewith. Resistance 100 is small in relation to resistance 96. The upper end of the cathode-resistor combination is connected to a series-connected potentiometer 106 and a fixed resistor 108 via a line 104. The potentiometer is somewhat smaller than the fixed resistor 108. The fixed resistor is connected to terminal 6 of a base 110 . The meaning of this connection will be emphasized in the following description.

A triode 112 has its anode 114 connected directly to the anode 76 of the tube 70 . Furthermore, the cathode 116 of the tube 112 is directly connected to the cathode 86 of the tube 70 .

Similarly, the cathode 118 of a triode 120 is directly connected to the anode 78 , while the cathode 122 of the same tube is connected directly to the cathode 92 . Grids 124 and 126 of respective tubes 112 and 120 are connected in parallel to conductor 128 .

Phase inverting tube 54, tubes 70 and 74, tubes 112 and 120, and associated circuitry are evidently a "variable resistor" of the type sometimes used for volume enhancement. Tubes 70 and 74 are controlled by tubes 112 and 120. If the grids of the tubes 112 and 120 are biased so that the internal resistance of the tubes 112 and 120 becomes high, the tubes 70 and 74 will only transmit a very low reverse voltage and accordingly a maximum will be at the output thereof. However, if the tubes 112 and 120 are oppositely biased, their internal resistance will drop and the tubes 70 and 74 will be energized, thereby reducing the output of the tubes applied to the transformer 82. The grid bias of tubes 112 and 120 causes the drum-like sound to be generated across conductor 128.

The secondary winding 130 of the transformer 82 is grounded at 132. The opposite end of the transformer is connected to a conductor 134 which, through a resistor 136 of relatively high resistance, e.g. B. 2.2 megohms, leads to an output plug or jack 138 . The secondary winding of the transformer is bridged by a combination of a resistor 140 connected in series with a capacitor 142 with an additional resistor 144, which is also switched into the transformer secondary winding.

The wire or conductor 134 is also through a resistor 146 relatively low resistance value of, for. B. 22,000 ohms connected to socket no. 2 of the base 110 .

In the lower right part of FIG. 3 shows a B auxiliary feed line 148 which is connected via a resistor 150 to the branching point 62 leading to the B + line in 66 . A voltage divider is connected to the conductor 148 and consists of a resistor 152 in series with a resistor 154 which is grounded. The two resistors 152 and 154 have the same resistance value. The junction between these two resistors is connected to socket no. 3 of the base 110 .

The B + feed line 148 is also connected to the anode of a triode 160 via an anode resistor 156 . The grating 162 of this tube is shunted with a Gitterwiderstand164 and connected to the socket no. 5 of the socket 110. The labeled cathode 166 of the tube 160 is grounded via a resistor 168. The resistor 168 is connected in parallel with a capacitor 170. The cathode is also connected through a resistor 172 to the B + - feed line connected 148th Resistor 172 is much larger than resistor 168. Resistor 172 has, for example, 100,000 ohms, resistor 168, for example, 2700 ohms.

The anode 158 is also connected to one of the electrodes of a neon tube 176 via a capacitor 174. The size of the capacitor 174 is significant and is e.g. B. 0.47 mF. The opposite electrode of the neon tube is connected at junction 178 to a resistor 180 which leads to socket # 4 of socket 110 . The branch point 178 is grounded via a capacitor 182 of greater capacitance than the capacitor 174. The capacitor has z. B. 1.00 mF. The branch point is also connected to the grid 184 of a triode 186 . The anode 188 of this tube is connected to the B + feed line 148. A smoothing capacitor 189 with e.g. B. 20 mF is connected to the anode on the one hand, and grounded on the other.

The cathode 190 of the tube 186 is grounded through a cathode resistor 192. The resistor is connected in parallel to a capacitor 194, the size of which is from e.g. B. 0.1 mF is significant. The cathode is also connected to conductor 128 which leads to grids 124 and 126 of charge tubes 112 and 120.

A connection is established between the grid 184 of the triode 186 via a conductor 196 with one cathode 198 of a double diode 200. The corresponding anode 202 is connected to the anode 204 of the other diode, and both anodes are connected to a circuit comprising a resistor 206 and a capacitor in parallel therewith, which in turn is grounded. 13. 10,000 ohms, the capacitor e.g. B. 25 mF. The remaining cathode 210 is connected to a 12 volt secondary winding 212 of a transformer 214 that has a 110 volt primary winding 216 . The main power transformer of an electronic organ to be installed - if it is desired, the secondary winding can 212th

Some of the triodes shown can be triode parts of double tubes. As previously stated, the tube 200 consists of a double diode. The filaments of all of these tubes, commonly shown in FIG. 218 , are connected between the .6.3 volt AC power lines labeled 220.

Between the lines is also a small resistor 222 of z. B. 27 Ohm incandescent bulb, a 220 turned on. The light bulb is arranged spatially close to the neon tube 176 - and - suitably housed with it in a small housing. The reason for this measure is that certain neon tubes are somewhat sensitive to light and operate much more reliably when they are exposed to light.

In the upper part of FIG. 3 shows the plug 226 which cooperates with the socket 110 . The plug pin no. 3, which is connected to the B + feed line from the contact no. 2 is referenced. This rail normally is with all the floating contacts for - generating -the connected percussion sounds, all contacts are connected to a capacitor 228 which is connected in series with a grounded resistance 230th The capacitor has z. B. 0.047 mF and the resistance was 2200 ohms. It will be understood that there is a floating contact 40, a corresponding capacitor 228 and a resistor 230 for each key of the organ. When the key corresponding to any intended floating contact 40 is depressed, the contact 40 is detached from the fixed rail 48 and connected to the immediately adjacent rail 40. It will also be understood that there is only one rail 42, which is associated with all of the Floating contacts 40 cooperate for the pereussion, and similarly there is only one rail 48. The rail 42 is connected to a fixed contact 232 of a pereussion switch shown in an "off" position.

The circuit is made to work by closing the switch, which is designated 234 in the following description, whereby the movable contact 236 is connected to the fixed contact ZU and thus the B + feed line of the capacitor 228 is connected to the pin 5 of the plug 226 and from there connected to the grid 162 of the triode 160 .

The movable switch arm 236 , as indicated by 238, is synchronized with a movable switch arm 240. This movable switching arm is connected to the wrapping or shielding 24Z of an electrical cable or wire. The shield is connected to pin 1 of connector 226 and is grounded from there. The movable contact 240 is normally connected to the upper fixed contact 244, which is connected to the pin 2 of the connector 226 via the shielded wire 246. As a result, when the switch is in the normal "off" position, pin Z is grounded and resistor 146 shunts the output of the circuit. If the switch is brought into the "on" position, the movable contact 240 is connected to the fixed contact 248 below. This contact is connected to connector pin # 6 of connector 226 .

The operation of the circuit is as follows. With the percussion switch 234 in the down or "on" position, each time the floating contact 40 of any key switch is lowered from the B + rail to the busbar, the charge on the associated capacitor 228 has a positive potential across the switch contacts 232 and 236 and over the pin 5 and contact 5 of the plug 226 and the socket 110 to the grid 162 of triode 160, respectively. the tube 160 is, however, the capacitor is charged up to typically 100 volts 228 normally closed (cut off). Once, is the tube 160 is suddenly biased for conduction , but the capacitor 228 discharges through the resistors 230 and 164, causing the conduction of the tube 160 to break off quickly.

The neon tube 176 is normally non-conductive and the side of the capacitor 174 facing the tube has essentially the potential of ground. Resistor 177 of the same order of magnitude as resistor 156, approximately 100,000 ohms, pivots the just mentioned electrode of neon tube 176 to ground. The opposite side of capacitor 174 is approximately 200 volts above ground. The neon tube 176 becomes conductive at about a 90 volt potential between the electrodes and becomes non-conductive when the voltage between them drops to about 60 volts. Usually, as mentioned above, it is non-conductive. However, when tube 160 is energized, its anode potential drops quite appreciably and the potential of the plate of capacitor 174 connected to neon tube 176 sends a negative pulse of about 140 volts to the neon tube. This makes this tube conductive. The capacitor 182 is negatively charged and the conduction of the neon tube 176 stops when this charge is built up to a sufficient potential. Thus, the neon tube operates like any electronic switch, and the tube 160 can be viewed as a switch tube for triggering the neon tube.

The charge of the capacitor 182 dissipates via the resistor 180 and via a potentiometer 250 connected in series with it, and when the switch 234 is connected, the connection is made via the pins 4 and 1 of the connector 226 and the associated contacts of the socket 110. A negative pulse is thus fed to the grid 184 of the triode 186 , whereby this tube is either blocked or substantially reduced in its conduction. This significantly lowers the bias in conductor 128 and, consequently, the grid bias of charging triodes 112 and 120. - Triodes 112 and 120 are normally conductive. In this case they feed the tubes 70 and 74 to a greater or lesser extent. If the negative potential is suddenly applied to the grids, the tubes 112 and 120 are suddenly blocked and the tubes 70 and 74 are not fed. As a result, the audio frequencies fed to input 50 simply pass through unattenuated with a certain amount of amplification up to output 138. However, as soon as the neon tube 176 goes out, the charge on the capacitor 182 is dissipated through the resistors 180 and potentiometer 250 , and the conductive tube 186 becomes progressively more conductive as a result. The potential of the cathode 190 as well as the potential in the conductor 128 increases accordingly. As a result, grids 124 and 126 become progressively more positive and tubes 112 and 120 progressively more conductive, placing an ever increasing charge on tubes 70 and 74 and thereby reducing output 138 . The tones so generated are produced very quickly and break off at a level controlled by the setting of potentiometer 250. This creates a variable percussion.

The double diode 200 serves as a clamp tube and limiter to prevent the capacitor 182 from being charged to anything other than a predetermined value. This is important when successive notes are played percussively, since the succession of charges on capacitor 174 transferred through switching neon tube 176 would charge capacitor 182 to a sufficiently high potential that tube 186 could operate for a considerable amount of time Would remain locked in time, whereby the output of the circuit would remain at a constant level for a certain time before it is aborted, whereas the abortion should , desirably, be essentially instantaneous. The barrier tube limiter 200 shuts off any voltage above the desired value across the power supply to ground. The rectifier part of the diode drives a predetermined DC bias voltage from the power supply to the blocking part of the diode, so that the blocking is controlled with regard to its mode of operation.

The grids of charge or control tubes 112 and 120 receive a normal positive potential of 12 volts from the cathode of tube 186. This requires that the cathode circuit of control tubes 112 and 120 and output tubes 70 and 74 be raised to 12.8 volts in order to establish the proper operating bias for those tubes. As a result of the tube changes and component changes, this operating point is difficult to maintain. Therefore the 1000 ohm potentiometer 106 is provided to give a certain setting for this operating point. For precise setting, the switch for the drum-like sounds is switched on, the stops on the organ are pulled and a chord is played and held. If the signal is decreasing, some amount of signal will still pass through the amplifier. The potentiometer 106 is not adjusted until the signal is essentially blocked.

Resistor 146 shunts the output when the permanent switch is in the "off" position. It does not shunt the output when the switch is in the "on" position. This is done to prevent a noticeable drop in output from occurring when using the percussion, especially when the drum-like sound is short, as set by potentiometer 250 .

In addition to powering tubes 70 and 74, tubes 112 and 120, when conducting, reduce the resistance of conduction of tubes 70 and 74 to the common cathode resistors, which raise the cathode bias when tubes 112 and 120 are conducting.

In this connection, reference is made to the arrangement of the amplifier 52 in the organ, which can be seen more clearly from the block diagram in FIGS . 5 can be found. The tone generators are denoted by 52 therein. These tone generators can be of any type desired for generating electrical oscillations corresponding to musical tones. The tone generators are connected to key switches 254, which include the various floating contacts 40 and the collectors or rails 42. The output from the key switches, with the exception of the one floating contact 40 which controls the percussion, is connected to the preamplifier unit 256 which is provided with the waveform filters. The tones, which are precisely pre-amplified and shaped in 256, are then fed to the percussion amplifier 52 by means of the input jack. The output from the jack 138 of the percussion amplifier is fed to a power amplifier 258 and the output from the power amplifier is connected to the speaker 26 .

In Fig. 4 shows a circuit which can be used in cooperation with the circuit for generating drum-like effects in order to produce a pulling effect, such as, for. B. in a guitar. The circuit according to FIG. 4 essentially comprises a free-running multivibrator 260 of generally conventional design that includes a double triode 262. An anode of this tube is coupled to a terminal labeled X through a capacitor 264, a high resistance shunt resistor 266, and a high value resistor 268. Terminal X is connected via a capacitor coupling 270 to a branch point 272 , which is grounded via a resistor 272. The branch point 272 is connected via a conductor 276 to a fixed “on” contact 278 of a foot switch, generally designated 280. The footswitch also includes a grounded movable contact 282 which can be connected to the fixed contact 278 and to the fixed "off" contact 284, which in turn has no further connection.

The corresponding grid of the double triode 262 is connected directly to a pole no. 1 of a base 288 via a conductor 286 . Pole no. 2 of the base is grounded, while pole no. 3 is connected to another pole or to a branch point marked with Y.

A plug 290 cooperates with the socket 288. Plug pin no. 2 of the plug is connected to a second movable contact 292 of the foot switch 280, which is coupled in its movement to the movable contacts 282. In the "off" position shown, the movable contact 292 is connected to a fixed contact 294 which is directly connected to terminal no. 1 of the plug 290. Pole no. 3 of the plug is directly connected to a fixed contact 296 , to which the movable contact 292 can be connected when the latter is brought into the "on" position.

If the repeater or pluck circuit according to FIG . 4 is built into the organ, point X of the circle is with point X of the circuit in FIG. 3 , which leads to the grid 162 of the trigger tube 160 . Similarly, point Y is similar to point Y in FIG. 3 connected, which is located in the discharge path for the capacitor 182 and in particular between the individual resistor 180 and the potentiometer 250 .

If, as in FIG. 4, when the movable switch contact 292 is engaged with the "off" contact: 294, it grounds a grid of the multivibrator tube 262 via the conductor 286, whereby the multivibrator is put out of operation. When the switch contact 292 is moved down onto the fixed contact 296 , the bottom of the resistor 180 is grounded. This removes the grounding of the multivibrator grid, which now continues to work freely. This also switches off the potentiometer 250 , as a result of which the time constant for the capacitor 182 and its discharge path is set. The switch arm 282 is moved toward the fixed contact 278 at the same time. Pulses for the trigger tube 160 are thereby grounded, thereby preventing the normal operation of the percussion. The percussion is repeated at a predetermined amount by a multivibrator 260. In this way, a plucking sound is produced, and particularly, a banjo can be easily imitated.

In the F i g. 6 to 8 different embodiments of the key circuit of the amplifier are shown. The original training used in conjunction with FIG. 3 and includes a capacitor 228 works unusually well. However, it requires a capacitor for each individual note, and capacitors are relatively expensive. That is with regard to FIG. 6 particularly easy to recognize. Certain parts previously described are shown therein which form the common rail 48 for cooperation with all of the floating contacts, five of which are shown in FIG. 6 and referenced 40-1 to 40-5. All of these floating contacts 40-1 etc. can optionally be connected to the collector 42 which, as previously described, is connected to the trigger tube 160 and the subsequent parts associated therewith.

Although only five floating contacts are shown, it will be understood that the actual number in an organ is much larger and the number of keys is the same. With each of these floating contacts, one of the in FIG. 6 , capacitors 228 labeled 228-1 to 228-5 and to the corresponding resistors 230-1 to 230-5 . The cost of the resistors 230-1 , etc. is not great, the cost of the various capacitors 128-1 , etc. is quite significant.

In Fig. 7, there is shown a circuit in which the capacitors 228-1 , etc. are removed, thereby reducing the cost of materials. In this embodiment of the invention, the same reference numbers are used for similar parts, but with the additional index a. In this version there are still a large number of floating contacts, which are designated here with 40 a-1 to 40 a-8. It will be understood, however, that the actual organ will have many more of these floating contacts. A common B + rail48a is provided for the connection with all floating contacts40a-1 etc. and is charged with 300 volts, for example. The floating contacts are normally no longer connected to the rail 48a. Each of these floating contacts has a resistor connected to it, here designated 298-1 through 298-8 . Each of these resistors is connected to a common conductor 300 . This conductor is shunted to ground via a resistor 302 and connected via a capacitor 304 to the branching point 306 , which is arranged between a grounded resistor 308 and a resistor 310 , which leads to the grid 162 a of the trigger tube 160 a.

The relative values of the components in the circuit shown in FIG. 7 are important. So have z. B. the key switch resistors 298-1 , etc. each have a size of 1 megohm. The common resistor 302 has 150,000 ohni. The capacitor 304 has a capacitance of 0.0082 mF, while the grid resistor 308 has a resistance of 1 megohm. The size of the resistor 310 is less critical; B. be chosen with 100,000 ohms.

When the first key is depressed, the corresponding floating contact 40a draws a 300 volt DC voltage from rail 48a. This voltage is in the ratio of approximately 10: 1 and divided feeding the capacitor 304 through the resistor grid 308, the a trigger tube 160a issued to the grid 162 a positive pulse. From here on, the circuit is the same as the previous one in connection with FIG. 3 and works in the same way.

Each time an additional key is depressed, the 1 megohm resistor 298 connected to the corresponding floating contact is connected in parallel with the preceding resistor 298 , assuming the first key remains depressed. This decreases the resistance of the top of the voltage divider, thereby increasing the voltage at the top of common resistor 302 . This causes capacitor 304 to charge to the new voltage at the top of resistor 302 , thereby giving another pulse to the grid of trigger tube 160a. Each time a different key is pressed, a different pulse is given in the same way. However, the successive pulses become smaller and smaller due to the parallel connection of the resistors 298 until the charging circuits no longer work. With 300Volt on the rail48a, it is possible to hold down six keys and still achieve percussion when the seventh is depressed. However, that requires 300 volts on the B + rail as opposed to the 100 volts on the circuit described above.

In Fig. 8 is a further embodiment of the key switches according to FIG . 7 , the operation of which is generally the same and in which similar parts are designated with similar numbers with the addition of the subscript b . In this case, a common, grounded rail 312 is provided. This rail is usually with some floating contacts connected to others not. The grounded rail is z. B. connected at RuhesteHung the buttons with alternating contacts 40b-1, 40b-3, etc., while the floating contacts 40 b-2 40 b-4, etc., are not connected. When any key is depressed, its corresponding floating contact 40 b is moved and thus connected to the 300 volt leading B + rail 48 b .

It can be seen that when successive keys are pressed, resistors are connected in parallel to the B + side of the voltage divider, while resistors are also removed from the parallel connection on the grounded side of the voltage divider. By these means, the voltage steps used to charge the capacitor 304 are controlled so that the generated pulses are almost the same. Accordingly, the range in which the percussion can be generated, i. H. the number of keys that can be held down, and on which one more key can produce percussion, is significantly increased.

Claims (2)

Claims: 1. Means for generating drum-like sounds in an electronic musical instrument with tone generators and tone amplifiers and with a plurality of keys and key switches for controlling these generators, characterized in that the amplifier (256, 52) means (112, 120) for controlling the Amplification corresponding to a potential applied to the amplification controlling means, and that means (40, 42) actuated by the buttons for generating electrical pulses for generating drum-like noises with the amplifier or with the means (112, 120) through a normally open , electronic switch (176) are connected which, when a pulse is supplied to generate drum-like noises, automatically closes for a short time and opens again immediately regardless of the position of the button switch triggering this pulse. 2. Means according to claim 1, characterized in that the electronic switch is designed as a gas diode (176) . 3. Means according to claim 1 or 2, characterized in that a normally blocked electronic tube (160) is provided which connects the pulse generating means (40, 42) and the electronic switch (176) to one another and is momentarily conductive by the pulses is made. 4. Means according to one of the preceding claims, characterized in that the switching means (40, 42) capacitors (228 or 304, 174) are connected and that the potential at these capacitors by actuating the switch (40, 42) for generating Pulses is changed. 5. Means according to claim 4, characterized in that the capacitors (228 or 304) are discharged via the electronic switch (176). 6. Means according to one of claims 3, 4 and 5, characterized in that the capacitors have a first capacitor (228 or 304) connected to the input of the electronic tube (160) and that a second between the output of the electronic tube (160 ) and the electronic switch (176) interposed capacitor (174) is provided. 7. Means according to one of the preceding claims, characterized in that a via the electronic switch (176) charged and with the gain controlling means (112, 120) connected capacitor (182) is provided to the gain of the amplifier in accordance with to change the charge of the capacitor (182). 8. Means according to claim 7, characterized in that means (200) are provided for limiting the charge supplied to the capacitor (182) controlling the gain to a predetermined value. 9. Means according to claim 8, characterized in that this is done by a variable load (112, 120) at the output of the amplifier (52). 10. Means according to claim 9, characterized in that the variable load has a variable impedance (112, 120) with the applied rail, the electrical circuit means supplying this impedance with a variable bias voltage (128) with the pulses. 11. Means according spoke 9 or 10, characterized in that the load includes the output impedance of an electronic tube (112, 120). 12. Means according spoke 11, characterized in that the load is the anode resistance of an electronic discharge tube (112 or 120). 13. Means according to one of the preceding claims 9 to 12, characterized in that the amplifier means has a push-pull electronic tube output (70, 74) and the variable load has a pair of electron tubes (112, 120), each tube having an anode ( 114, 118), a grid (124, 126) u! 1 d a cathode (116, provided 122) and the anodes (114, 118) of the charging tubes (112, 120) to the anodes (76, 78) of the Push-pull output tubes (70, 74) are connected in parallel, while the cathodes (116, 122) of the charging tubes (112, 120) are connected in common with the cathodes (86, 92) of the push-pull output tubes (70, 74), and that the grids (124 , 126) of the charging tubes are connected in parallel with each other and independently of the grids (68, 72) of the push-pull output tubes (70, 74) to the circuit means, the circuit means being connected to the pulse generating means (40, 42). 14. Means according to one of the preceding claims, characterized in that further means (260) are provided for switching on a sequence of pulses independently of the actuation of the buttons (30, 32) . 15. Means according to claim 14, characterized in that manually operable means (224) for locking the key-operated pulse generator means (40, 42) are provided. 16. Means according to one of the preceding claims, characterized in that each key switch (40, 42, 48) has a movable contact (40) that further capacitors (228 or 304) are provided which are connected to the movable contacts of the key switches, and that a common DC voltage rail (48) is provided with which the movable key switch contacts can alternately be connected and disconnected in order to change the charge on the capacitors (228 or 304) for generating pulses. 17. Means according to claim 16, characterized in that all movable switch contacts for generating the drum-like noises are normally connected to the common DC voltage rail (48), that the capacitors (228) are connected to the corresponding movable switch contacts (40), and that further a common busbar (42) which can be selectively connected to the movable switch contacts and a common discharge resistor (164) connected to this busbar is provided, the common discharge resistor comprising part of the means connecting the capacitor means (228) to the means (112, 120) to change the gain. 18. Means according spoke 16, characterized in that a plurality of resistors (298) is provided, which are each connected to each movable switch contact for drum-like noises, that further means (302) are provided, which with these switch contact resistors (298) a voltage divider with an output branching point (300) , and that the potential at this output branching point is changed when the connection conditions of the movable switch contacts with the common DC voltage rail (48) change, the output branching point (300) being connected to the voltage divider with the capacitors (304) is. 19. Means for an electronic musical instrument according to claim 16, characterized in that a plurality of resistors (298) are provided which are each connected to the movable switch contacts, that all resistors (298) are connected at a common point (300) , that a common resistor (302) is grounded from this common point and forms a voltage regulator with the plurality of resistors (298) , that a capacitor (304) is connected to this common branch point (300) , and that all movable switch contacts are normally connected to the common DC voltage rail (48) are disengaged and optionally connected to it, whereby the resistance in a part of the voltage divider is changed and so the potential in the common junction point (300) is changed. 20. Means according to claim 16, characterized in that a common ground line (312) is provided to which at least some of the movable contacts are normally connected, that a plurality of resistors (298) are also provided which are each connected to the movable switch contacts , and that a common rail (300) is provided to which all resistors (298) are connected, and a single capacitor (304 b) which is connected in series between the last-mentioned rail and the means which connect the capacitors to the Means (112, 120) for changing the gain of the amplifier connects. References considered: Alan Douglas, The Electronic Musical Instrument Manual, 3rd Edition 1957, p. 134, published by Liv Isaac Pitman and Sons, Ltd., London.