DE1204505B - Control oscillator for an electronic musical instrument - Google Patents

Description

Control oscillator for an electronic musical instrument The invention relates to a control oscillator for an electronic musical instrument having a Transistor as well as with a number of connected to the control oscillator and from this controlled frequency divider.

The control oscillator is intended in particular to generate vibrato and serve glissando or sliding effects.

Various types of electronic musical instruments are known, particularly those with keys commonly referred to as electronic organs. Different types of tone generators are used, e.g. B. unanimous, in which only a single tone is generated, and z. B. polyphonic, in which several notes sound at the same time. The most successful and most useful design of such a keyboard instrument has a full octave of control oscillators (frequency stabilizers) with various chains of controlled or dependent partial oscillators (frequency dividers) for generating subharmonics or the respective sub-octaves. It has been found that the musical tones generated by such instruments overall mature or sonorous, if one means for generating a vibrato effect, providing, with which the respective sound is frequency modulated. In other words, the nominal frequency is initially distorted or blurred at a rate of change below the audible limit, preferably in the order of magnitude of 7 periods per second, and then made sharp again. It has also been found that various types of sound, such as that of a Hawaiian guitar, are best reproduced by adding devices that can produce a glissando or portamento effect (holding the tone).

The aim of the invention is thus to create a control oscillator for an electronic musical instrument with additional facilities for generating a vibrato or glissando effect, the oscillator preferably consisting of transistors should be built.

It is known that the change in the base bias causes a frequency change in the oscillator. The invention uses this otherwise undesirable property of the generator for the purpose of generating vibrato and glissando or sliding effects. The new control oscillator is therefore characterized in that the base voltage of the control oscillator (24) equipped with the transistor (62) is controlled to increase or oscillate slowly. The invention is described in more detail below with reference to the exemplary embodiments shown in the drawing. In the drawings, F i g. 1 is a block diagram of an electronic musical instrument according to the invention, FIG. 2 shows a combination of a block diagram with a normal circuit diagram to illustrate the tone generators and FIG. 3 is a partial diagram of the invention employed in accordance with oscillators.

The general structure of an electronic musical instrument according to the invention is shown in FIG . 1. Therein a number of tone generators are denoted by 10 , each of which is connected to a device 12 for generating vibrato effects and to a device 14 for generating glissando effects. The tone generators are guided via a number of key switches 16 which are controlled by the keys of one or more keyboards and, if desired, also by a pedal keyboard. The electronic oscillations which are transmitted or controlled by the key switches, which correspond to the respective tones, are fed to suitable registers and filters 18; the filtered vibrations then reach an amplifier 20, which is connected to a loudspeaker 22 or the like, in order to convert the amplified electronic vibrations into audible musical tones.

In Fig. 2, a number of control oscillators 24 are shown. Twelve such control oscillators are expediently provided which - comprise the top octave including the semitones. Each oscillator 24 is connected via the connection 26 to a first frequency divider 28 , which is led via the connection 30 to a second frequency divider 32. In each frequency divider, the frequency of the supplied vibrations is halved, so that the same note is created an octave lower. In the embodiment according to FIG. 2, a control oscillator, a first and a second frequency divider are provided for each note, so that the tone is generated in three octaves. It can be seen that the number of frequency dividers can be expanded infinitely, depending on the number of octaves desired, by coupling subsequent frequency dividers, for example at point 34.

All control oscillators and frequency dividers form the tone generators 10 according to FIG. 1. Each control oscillator is connected at 36 to the key switches, while the first dividers at 38 and the second dividers at 40 are connected to the key switches.

A vibrato oscillator is shown schematically at 42 a-die opposite and is with its side of the one vibrato oscillator side to earth. ' is led to a branch point 44 at which there is also a normally closed vibrato switch 46, the other side of which is grounded at 48, so that the vibrato oscillator can be connected in parallel or bypassed. The branch point 44 is also connected to a vibrato distribution line 50 in which the vibrato oscillations occur when the switch 46 is opened. The vibrato oscillator operates in the range of 5 to 7 periods per second, which is common in these cases. The speed can be varied over a limited range and the amplitude of the vibrato oscillations can also be varied in a manner known per se. Connections go from the distribution line 50 via insulating resistors 52 to each control oscillator and then, in sequence, also through the frequency dividers in order to impress the vibrato oscillations on all oscillators.

A glissando switch 54 has a grounded stationary contact 56 and is connected to a distribution line 58 . This line is routed to the control oscillators via insulating resistors 60. The way in which the glissando unit works is described below, although it should only be pointed out that this unit produces glissando or portamento effects.

The control oscillator includes a pnp transistor 62 ( FIG. 3). The emitter 64 is grounded via a resistor 66. The base 68 is led to a branch point 70 which is connected to earth via a resistor 72. The branch point 70 is also connected to the insulating resistors 52 and 60 .

The collector 74 is connected to a junction point 76 , which in turn is connected via a resistor 78 to a feed line 80 for a bias voltage, which comes from a current source shown at 82 of -20 volts direct current. The branch point 76 is also connected to a branch point 86 via a capacitor 84. This branch point is connected to one end of a tuning coil 88 , the other end of which is grounded. The coil 88 is provided with a tap 90 located near its center, which is led to a branch point 92 . A capacitor 94 between point 92 and point 86 is thus essentially parallel to half of coil 88. A capacitor 96 is between points 92 and 70. This structure is a transistorized Hartley oscillator.

The connection point 76 is led to a further connection point 98 , which is connected to a main outlet, for example with the line 36 leading to the key switches. It can be seen in this context that the special type of circuit construction for the oscillators and the devices for generating the Vibrato and glissando effects are not of particular concern. The coupling 26 , which comprises a line 100, a capacitor 102 connected to a branch point 104, a grounded resistor 106 connected to this point, and a diode 108 , which is also connected to the branch point 104, is also routed to the branch point 98.

The first partial oscillator 28 consists of a transistorized flip-flop or Eccles-Jordan circuit. The capacitor 102 and the resistor 106 cause a more or less square wave input to the oscillator 28, so that this is triggered or triggered at every second period in order to generate a frequency with half the value of that of the control oscillator. The diode 108 serves for supplying a synchronization pulse from the Steue - roszülator zirrn prsten frequency dividers, without thereby any signal appears from the first divider to the main take-off point.

The first divider oscillator comprises two pnp transistors 110 and 112, which are connected in the usual cross-over manner. Since the person skilled in the art is familiar with this type of circuit structure and this is evident from the drawing, it is not necessary to go into more detail about it and the individual values of the circuit elements. It should be noted, however, that the collector of transistor 110 is connected to a keyboard output line for the first partial oscillator, which connection may consist of line 38 . The collector is also fed to a pedal output line 116 via a resistor 114. Further frequency dividers are used to generate the pedal tones in accordance with normal practice. Diode 108 is connected to the top of a grounded resistor 118 and to the base of transistors 110 and 112 through similar resistors. The emitters of the transistors are connected via a common grounded resistor 120.

There is a connection between the first and second frequency divider through the line 30. This leads from the collector of the transistor 112 via a capacitor 122 to the top of a grounded resistor 124, while the structure of the second frequency divider 32 corresponds to the first and consists of a flip-flop Circuit with two pnp, transistors 126 and 128 . Since the output of the first frequency divider 28 has a square wave shape from the outset, no wave shaping circuit needs to be provided in the connection between the first and second frequency dividers. The output at the second frequency divider is also a square waveform, which is taken from the collector of transistor 128 via a line 40 which leads to the key switches or other suitable keys or actuating devices. An additional pedal output is provided at the collector of transistor 128 and leads via a resistor 130.

The control oscillator 24 generates an approximately sinusoidal oscillation; For this reason, the differentiating circuit, consisting of the capacitor 102 and the resistor 106 - must be used to generate a rectangular oscillation in order to trigger the first partial oscillator 28 .

It can be seen that the structure of the transistorized oscillators is sensitive to voltage. This property is exploited in that the vibrato oscillator 42 causes the bias voltage on the base 68 of the transistor 62 to be raised above its normal value and alternately decreased below its normal value. As a result, the oscillator is periodically detuned sharply and out of focus and creates a real frequency vibrato effect. This in turn causes the dividing oscillators or frequency dividers to be cyclically focused and distorted so that a true frequency shift vibrato effect is produced. The value of the frequency shift depends on the value of the voltage deviation and it can be seen that the frequency shift is proportional to the frequency due to the dividing effect of the partial oscillators.

The detuning due to the change in tension is also used in connection with the glissando or portamento effect. When the glissando switch 54, 56 is closed, the bias of the base is changed in the direction that the voltage is decreased. As a result, all of the instrument's oscillators are detuned, preferably in such a way that all of the oscillators vibrate half a tone lower. As soon as the switch 54, 56 is opened, the voltage returns to its normal value and the generators return to their nominal frequencies, so that a portamento or glissando effect occurs on the transition from the lowered tone to its nominal frequency. This is particularly effective in producing a Hawaiian guitar style tone. Although the location of the vibrato and glissando switches is not shown in detail , the vibrato switch can expediently be arranged next to an organ keyboard along the register panels or slides. The glissando switch is normally in the open position and is conveniently placed on the usual expression pedal for operation by moving the foot sideways.

Claims (2)

Claims: 1. Control oscillator for an electronic musical instrument with a transistor and with a number of frequency dividers connected to the control oscillator and controlled by it, characterized in that the base voltage of the control oscillator (24) equipped with the transistor (62) is controlled to increase or oscillate slowly will. 2. Control oscillator according spoke 1, characterized in that the device (42) for changing the voltage on the transistor base (68) in only one direction comprises a resistor and a device with which the resistor is optionally connected to the bias of the transistor base to control. 3. Control oscillator according to claims 1 and 2, geken n ei hn et by a switch (54) with a grounded, fixed contact (56) which is connected to a distribution line (58) , for changing the voltage of the control oscillator in only one direction, to create a glissando effect. 4. Control oscillator according to claims 1 to 3, characterized in that the control oscillator (24) has a sinusoidal output oscillation and all frequency dividers (28,32) each have a square wave output and that a differentiating circuit (102, 106) is provided which the control oscillator and connect the first frequency divider (28) to one another in order to generate a synchronization pulse from the control oscillator for the first divider (28) . 5. Control oscillator according to claim 4, characterized in that a diode (108) is connected between the differentiating circuit (102, 106) and the first partial oscillator (28) . Publications considered: BW Meyer-Eppler, "Elektro Klangerzeugung", Ferd. Dümmlers Verlag Bonn, 1949, p. 101.