DE2252653C3 - Signal selection system for an electronic keyboard musical instrument - Google Patents

Description

The invention relates to a signal selection system for an electronic keyboard musical instrument which, when several keys are pressed simultaneously, selects the highest or lowest of the tone signals assigned to the keys - with a power supply; with 12 corresponding to the notes of the highest octave. ongenerators; πί a number of key switches which are defined by a number of keys comprising at least 2 octaves, that is to say forming at least 2 octave groups, ie. T. »Nc? 4 are operated; with 12 bistable Z old rents X "The keys can be switched to the notes of an octave, whereby keys Ii n" TonbeleTchnung can switch the same bistable switch; with 12 sound circuits. forward the de audio signals when activated by the bistable switching elements; with a multi-stage F enzTeHer, which halves the frequency per stage and which is connected to the outputs of the audio circuitry with a set of key selection circuits corresponding to the number of octaves, which select the outermost of the simultaneously closed key switches in each octave group, thereby selecting the let the corresponding bistable switching elements tip over.

In a known signal selection system of this type for an electronic musical instrument (DT-AS 14 72 451) a number of circuits containing bistable switching elements is required which corresponds to the number of key switches corresponds, whereby the signal selection system is relatively complex and thus expensive.

The invention is based on the object of a dialing system for an electronic keyboard musical instrument to create according to the type mentioned in such a way that in a cost-saving manner d.e required Number of bistable switching elements for the entire range forming several octave groups Buttons is minimized.

According to the invention, this object is achieved by that an octave selection device is also provided which selects the outermost of the octave groups, namely by the fact that it can tip over more bistable switching elements that power the Switch off the remaining octave groups when the other bistable switching elements of at least one, with the key switches and the 12 bistable switching elements coupled detector that determines which octave groups have been activated, receives a signal, in addition, the further bistable switching elements the number of active divider stages of the frequency divider determine and wherein the detector delivers a further signal when the buttons are released, all of which are bistable Resets switching elements.

The octave selection device advantageously has at least two detectors, which are associated with the corresponding Octave groups are connected in order to then determine the closure of any key switch and then to block the operation of the less distant octave groups.

The twelve bistable switching elements and the others bistable switching elements can consist of flip-flop circuits and the at least one stage comprehensive frequency divider can consist of a flip-flop circuit.

The advantage of the invention is thus in particular in reducing the number of bistable switching elements required and the associated ones Reduction of susceptibility to interference in the signal selection system. The invention is now on hand the description of the drawing explained in detail. In the latter are

F i g. 1 is a block diagram of a signal selection system according to the invention for an electronic keyboard musical instrument and

FIG. 2 shows a circuit arrangement of an embodiment of the signal selection system according to the invention.

Fie ί shows a block diagram of the signal selection system according to the invention that the signal selection system Uir is suitable for an instrument which has a number of three keys forming 5 octave groups.

The keys can operate a number of key switches K] to K , which are divided into three groups 31 ('/ Ci to K] ₂ ), 32 IK to / Cj ₄ ) and 33 CZC ₂₅ to K _{) b} ) according to each octave group. In the case of the key switches assigned to each octave group io, the rest contact of the latter is connected to a movable contact of the subsequent key switch in order to enable the signal to be selected when a number of keys are actuated at the same time. On the other hand, the 15 working contacts of each of the key switches / Ci to K ₁₂ assigned to an octave group are each connected to the working contacts of the key switches Km to K ₂₄ , K ₂₅ to / C ₃₆ assigned to the same To. Designation in the other octave groups, i.e. the ₂₀ key switches Ki. K _n and / C ₂₅ as well as K ₇ , K, ₄ and / C ₂₆ etc. are connected to one another.

A circuit 1 has twelve bistable switching elements which are assigned by the tones of an octave Buttons are switchable and each z. B. consist of the usual 25 flip-flop circuit. The tone generators 2 supply the tone signals assigned to an octave, each tone generator 2 is associated with the corresponding one of the twelve Flip-flop circuits are connected and the switching on and off of the sound signal is carried out according to the 30th State of the flip-flop circuits controlled. "The to a terminal 20 via the circuit of the bistable switching elements 1 of the circuit I placed frequency of the sound signals is through a multi-stage Frequency divider 3, 4 halved per stage. In accordance with an octave selection device 5 the audio signal is passed either directly via a gate 13 or via the divider stage 3 to the divider stage 4.

The octave selection device 5 has three detectors 6 7 and 8, which are arranged so that the detector 6 or 7 or 8 responds when any key switch / C. until Kn of the first group 31 or any key switch K, ₃ to / C _{24 of} the second group 32 or any key switch / C ₂₅ to / C _{36 of} the third group 33 is closed.

The Oktavenwählinnchtung 5 also has two bistable switching elements 11 and 12, the so are arranged that the bistable switching element 11 overturned by a pulse from the detector 7 and is switched back by a pulse from the detector 6 and that the bistable switching element 12 by a Pulse from detector 8 is tipped over and switched back by pulses from detectors 6 and 7. If the bistable switching element 1! is upset, is the gate 13 is conductive and that at the terminal 20

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The audio signal lying on the ground is skipped directly to the divider stage 4 of the frequency divider 3, 4 passed, so that at terminal 23 as a result of the frequency halving by the divider stage 4, a tone signal half the frequency compared to the audio signal at terminal 20.

A further gate 14 is provided which is conductive when the bistable switching element is overturned, and the audio signal on terminal 20 goes directly to terminal 23 without passing through the frequency divider 3, 4 so that the frequency of the audio signal at terminal 23 is the same as that of the audio signal at terminal 20 will. When the two gates 13 and 14 are blocked.

If the tone signal at terminal 20 is passed through divider stage 3 and then through divider stage 4, see above that the sound signal aaftretene at the terminal 23 has a frequency which is equal to a quarter of the frequency of the audio signal at terminal 20.

The octave selection device 5 also has two circuits 9 and 10, which are normally conductive. The circuit 9 is connected to the detector 6 via a diode D12 and is switched off by the operation of the detector. The circuit 10 is connected to the detectors 6 and 7 via diodes Dn and D _{) 4} and is switched off by the operation of the detectors 6 and 7.

If a detector 22, which is connected to a terminal 21, detects the closing of the buttons, then it sets all flip-flop circuits in the circuit back, thereby only sending one selected audio signal to the Terminal 20 is supplied.

F i g. 2 shows a circuit arrangement of an embodiment of the signal selection system according to the invention, with elements of FIG. 1 matching Elements have the same reference numerals and the circuit 1 and the tone generators 2 are shown as a block are. The mode of operation of the signal selection system is shown in the following description. The number of bistable switching elements and the tone generator is equal to twelve, corresponding to the number of tones one Octave, and a flip-flop circuit is provided for the divider stages 3 and 4 of the frequency divider 3, 4. The divider 3 halves the frequency of the audio signal, and the divider 4 in turn halves the frequency of the from the divider 3 coming sound signal.

The detectors 6, 7 and 8 consist of the transistors Ti ₅ , Ti ₆ and Ti _7, respectively. When the key switches (Ku K ₂ to K _n ) or 32, (7C _n , K ₁₄ to / C ₂₄ ) or and (K ₂₅ , K _2b to / C ₃₆ ) of group 31 or 32 or 33 are closed are, the transistors T15, Ti ₆ and Tw are saturated. Saturation indicates that the key switches in each group are closed.

The other bistable switching elements 11 and 12 also consist of flip-flop circuits with transistors T ₂ ] and T ₂₂ as well as T ₂₃ and T ₂₄ . The bistable switching element 11 is switched over via a diode Di ₆ when a positive voltage is applied to the collector of the transistor T _{16 of} the detector 7, and it is _{reset via the diode D 15} when a positive voltage is applied to the collector of the transistor Ti ₅ of the detector 6 is placed. The bistable switching element 12 is switched over via a diode D19 when a positive voltage is applied to the collector of the transistor Ti _{7 of} the detector 8, and it is reset via the diodes Di ₇ or Di ₈ when a positive voltage is applied to the collectors of the transistors Ti ₅ or T _{) 6 of} the detectors 6 or 7 is placed.

The anode of a diode D _{22 of} the gate 13 is connected to the collector of the transistor T ₂ ] of the bistable Schaltete Mentes 11 via a resistor R ₂₆ , and the cathode of the diode D ₂₂ is connected to the terminal 20. When the transistor T ₂ ] des bistable switching element 11 is blocked, the diode D _{22 is} conductive and the divider stage 3 is bypassed, so that the audio signal from the terminal 20 to the divider stage 4 passes. When the transistor T _{2 of} the circuit 11 is saturated, the diode D _{22 is} blocked.

Similarly, diode D21 is the gate conductive when the transistor T23 of the bistable switching element 12 is blocked, and thus a bypass of the divider stage 3 and 4 is given, so that the terminal

20 lying sound signal is fed directly to terminal 23. If the transistor 723 of the bistable switching element 12 is saturated, then the diode D ₂ I is blocked.

A capacitance G differentiates the fall of the tone signal and delivers a negative pulse to the Triggering the divider stages 3 and 4 of the frequency divider, with a negative pulse at terminal 23 with the Frequency of the audio signal is obtained.

If the frequency of the audio signal at terminal 20 is not changed, the audio signal at terminal 23, if both gates 13 and 14 are blocked, has a frequency which is equal to that of the audio signal two octaves lower and if gate 13 is conductive , a frequency which is equal to that of the tone signal, which is one octave lower, and the same frequency as the i _S tone signal at terminal 20 when gate 14 is conductive.

The circuits 9 and 10 consist of transistors Tig and Tig and resistors R \ g and R ^, respectively. Normally, both circuits are conducting 9 and 10 due to the J ₀ by the resistors /? Ie or R \ g flowing base current. In this time, the currents of the transistors Tie and 71g to base currents of the transistors 7ib or Tu of the detectors 7 and 8. The values of resistors /? Ie and Rw are yet large enough j ₂ and resistors R \ t and R \ ₇ are shunted to the base currents, so that the transistors Tie and Tu of detectors 7 and 8 are not saturated.

When the transistor Γ15 of the detector 6 is saturated, the current flowing through the resistor R \ s flows from the collector of the transistor T ^ via the diode D \ ₂ , and the transistor Tjg is blocked. Accordingly, the key switches / Cn, Kn to K24 of the second group 32 are not supplied with electrical power. Similarly, the circuit 10 is blocked when the detector 6 or 7 responds, so that the key switches K ₂ s, Κχ, to K ^ of the third group 33 no electrical power is supplied.

If the detector 22 detects the moment the key switches close, then it switches all of them Flip-flop circuits of circuit 1 back, so that only one audio signal can be selected to terminal 20 got.

The octave selection device, which consists of the detectors 6, 7 and 8, the circuits 9 and 10, the further ₄ bistable switching elements 11 and 12 and the gates 13 and 14, determines the groups of key switches that contain the closed key switches and selects them Button switches of the outermost octave group that correspond to the lowest or highest note in those octave groups, and then interrupts the power supply to all button switches of the octave group which is in the opposite direction from the selected outermost octave group. Furthermore, the octave selection device simultaneously actuates the divider stages of the frequency divider to generate a tone signal with a frequency which corresponds to the lowest or highest tone signal assigned to the frequency de; = the outermost key of the keyboard that is pressed simultaneously.

Since the key switches in each group of key switches are in series, the signal selection for each Group of key switches made.

As an example, the signal selection for the first group 31 of the key switches K 1, K ₂ to K ₂ and between the other groups is described below with reference to FIG. 1 described.

If z. B. the key switch K _{25 is} closed, a voltage present at the terminal 21 is applied to a flip-flop circuit of the circuit 1, which is assigned to the key switches K ₁ , K] ₃ and K ₂₅ , via the detector 22, the detector 8, the circuit 10 and the key switch K _{2i are} set, and this flip-flop circuit is switched. In this way, the sound signal corresponding to key switch K _{25 reaches terminal 20.}

On the other hand, when the detector 8 responds, the bistable storage element 12 is overturned and the gate 14 thus becomes conductive. For this reason, the acoustic signal is sent to terminal 20 unchanged to terminal 23.

If the key switches Kn and K ₂₅ are closed at the same time , the flip-flop circuit assigned to the key switches K \, K \ 3 and / C25 is switched again by the detector 7, the circuit 9 and the key switch K _t3 . On the other hand, the circuit 10 is blocked by the detector 7, so that the detector 8 does not respond. The bistable switching element 12 is also reset by the detector 7, and the bistable switching element 11 is overturned, whereby the gate 14 is blocked and the gate 13 becomes conductive. Accordingly, the frequency of the audio signal at terminal 20 is halved by the divider 4, so that the frequency of the audio signal at terminal 23 is half the frequency of the audio signal at terminal 20.

If the key switches K \, Ku and AT ₂ S are closed at the same time, the flip-flop circuit assigned to these key switches is switched by the detector 6 and the key switch Ki and the corresponding sound signal is switched on. On the other hand, the circuits 9 and 10 are blocked by the detector 6 so that no current flows to the detectors 7 and 8. As a result of this, the bistable switching elements 11 and 12 are reset and the gates 13 and 14 blocked is on terminal 20, reaches terminal 23.

The preferred constant generation of the lowest tone signal when a number of key switches are closed at the same time can preferably be ^{reversed to generate de 1} highest tone signal by the Ar of the triggering of the circuits 9 and 10 and the gate 13 and 14 of the signal selection system described is changed little eil.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims 1. Signal selection system for an electronic keyboard musical instrument, when several keys are pressed simultaneously from the keys ζ Selects the highest or lowest sound signals; with a power supply; with 12, the 12 tones of the tone generators corresponding to the highest octave; with a number of key switches, which are represented by a Number of keys comprising at least 2 octaves, i.e. at least 2 octave groups, d. H. at least 24 are operated; with 12 bistable Switching elements that can be switched by the keys assigned to the tones of an octave, with Keys with the same tone designation can switch the same bistable switching element; with 12 sound circuits, which forward the audio signals when activated by the bistable switching elements; With a multi-stage frequency divider that halves the frequency per stage and the one with the outputs the sound circuitry is connected; with a set of corresponding to the number of octaves Key selector circuits, which in each octave group the outermost of the simultaneously closed key switches select and let the corresponding bistable switching elements tip over, characterized in that an octave selection device (5) is additionally provided which selects the outermost of the octave groups by virtue of the fact that it has further bistable switching elements (11, 12) can tip over, which switch off the power supply of the remaining octave groups, if the other bistable switching elements of at least one, with the key switches and the 12 bistable switching elements coupled, detector (6, 7, 8), which determines which octave groups are actuated were received, a signal, the other bistable switching elements also the number of Determine active divider stages of the frequency divider (3, 4) and the detector when released the keys e: n supplies another signal that resets all bistable switching elements. 2. Signal selection system according to claim 1, characterized in that the octave selection device (5) comprises at least two detectors (6,7,8) which are connected to the corresponding octave groups in order to close any key switch (K \ to K \ 2, Ku to K ₂ A, Kx to Kx) and then to block the operation of the octave groups that are less far out. 3. Signal selection system according to claim 1, characterized in that the twelve bistable switching elements (1) consist of flip-flop circuits. 4. Signal selection system according to claim 1, characterized in that the further bistable switching elements (11,12) consist of flip-flop circuits. 5. Signal selection system according to claim 1, characterized in that the at least one stage comprehensive frequency divider (3, 4) consists of a flip-flop circuit.