DE2328851A1 - ELECTRONIC MUSICAL INSTRUMENT - Google Patents

Description

L 5280

DERLhM 33
Dissolved-Viktor! " Punish «« ■

Matsushita üilectric Industrial Go. , Ltd., 1000 Kadoina, Osaka

(Japan)

electronic musical instrument

The subject of the invention is an electronic Idusikinstruiuent with a high-frequency generator that generates a high-frequency pulse signal, with a jinkoder that generates a series of logical Generates encodings corresponding to a tone of a musical scale, depending on a scale control signal, the is fed to an input contact, with an adjustable divider, which the high frequency generated by the high frequency generator divides by an integer, which is determined by the logical coding that is fed to the program contacts, and with a memory for storing the scale control signal or of a signal that is essentially equivalent to the logical Coding is the program contacts of the adjustable divider is to be supplied, the signal stored in the memory is maintained even if the 'i'onleiter control signal persists stops until a new legal control signal is generated.

309851/0473

The invention relates to an electronic musical instrument and in particular an instrument with which a sound signal by determining the division factor of an adjustable divider as a function can be generated from a number of stored logical codes.

According to the invention, an adjustable divider, for example a shift register counter, is provided in an integrated circuit (Linear shift register, maximum length generator, kaxiuial sequence generator, programmable divider or a kodul-ü-divider), which is extremely small and cheap to obtain is.

A conventional musical electronic instrument uses a frequency divider in form: an integrated circuit that uses an input signal with a very high frequency of, for example, several megahertz through twelve different divides whole number divisors, with twelve tone signals of a scale with equal tempered tuning within of a frequency range of a main oscillator can be generated · The divisors of such an integrated circuit are fixed and cannot be changed.

In a known such musical instrument is together uses a tone generator with a shift register counter, the divisor of which is changeable and programmable. With an Italian instrument in which such a conventional tone generator is used, hears a weighed and generated tone signal after the release to insist on the key so that the sound no longer lingers and a memory effect is created.

However, an electronic so-called synthesis musical instrument can maintain a selected sound signal for some time. Such a synthesis instrument basically consists of a voltage-controlled oscillator and a gray voltage memory. The output signal of the DC voltage store controls the spamiungsge controls an oscillator in such a way that it generates a sound signal and will continue to be sustained.

However, such Syixtheseschaltun _o /. has the disadvantage that the AUs ^ CiIi ₀ ^- sequence is unstable and in a short time

: * 0 9 8 B 1 / (K 7 3

The period cannot be corrected.

The aim of the Arfindun _o is therefore to create a new electronic music instrument with which a sound signal of a stable frequency can be generated.

The invention sees a new and better electronic one i «, musical instrument with which a sound signal is generated, whose Frequency is corrected in a very short start-up time.

In the musical instrument according to the invention, a storage device used to store a signal that controls an adjustable divider even after a control signal has ceased, until the next control signal is generated.

The electronic musical instrument according to the invention has a high-frequency generator for generating a high-frequency pulse signal, a JSncoder for generating a series of logical codings depending on a scale _{control input signal that is fed to a Mn 0} contact, which codings are a tone of a scale an adjustable divider for dividing the frequency of the high-frequency pulse signal generated by the high-frequency generator by an integer divisor which is determined by the logic codes supplied to the program contacts, and a memory device for storing said scale control signal or a signal that corresponds to the program contacts of the adjustable divider applied logical codings is essentially equivalent, said signal remaining stored in the memory device, even if said musical scale; control signal has ceased to exist until the next musical scale steering signal is generated.

The invention will now be described in detail. In the accompanying drawings is the

1 shows a block diagram of a basic version of an electronic musical instrument according to the invention,

Fig. 2-4 each a block diagram for various other designs Shapes of an electronic and musical instrument according to the invention,

309851/0473

5 shows a circuit diagram for an embodiment of a control device and a storage device used in the electronic musical instrument according to the invention will,

Fig. 6 shows a circuit diagram for another embodiment of a Control and storage device used in the electronic läusikinstrument according to the invention,

7 shows an overview of an encoder that is used in an electronic musical instrument according to the invention is used,

8, 9 each have a circuit diagram for a frequency divider and a Control device for the envelope curve,

10, 11 each have a circuit diagram for a control device and a Audio filter circuit in an electronic musical instrument according to the invention.

1 shows a block diagram of a keyboard 1 with a number of keys, each key actuating a control device 2, a scale control signal 14 being generated which corresponds to a key and / or a tone of the scale. An encoder 4 generates, as a function of the scale control signal 14, a series of logical codings which correspond to a tone of the scale. A memory device 3 is connected to the cited encoder and stores a signal which is essentially equivalent to the cited series of logical codings. Eim adjustable divider 5> e.g. a shift register counter, a linear shift register, a laximal length counter, a programmable counter or a Lodul-li divider divides a high-frequency pulse signal generated by a high-frequency generator 6 by the integer divisor N. This divisor N can be changed and is determined of the series of logical codings mentioned, which the program contacts P ^. to P ^ ₂ aes adjustable divider 5 are supplied.

An output tone signal f / N from the adjustable divider 5 is passed through a gate 9> a sound filter 10 and through an amplifier 11 and converted into a sound by a loudspeaker.

309851/0473

The memory device 3 can, as shown in FIG. 2, be connected between the control device 2 and the encoder 4, so that the scale control signal 14 is stored and then passed to the encoder 4. The memory device 3 can also, as in FIG shown, are connected between the encoder 4 and the adjustable divider 5, so that the coded scale control signal 14 is stored and then _{fed to the program contacts P. - P ^ 2 of} the divider 5.

4 shows an embodiment as a block diagram an electronic musical instrument according to the invention a memory device according to Figure 2, which is between the control device 2 and the Jänkoder 4 is switched. The keyboard consists of a number of keys, each key of which is one Sound corresponds to a musical scale and the control device 2 is actuated. The control device 2 generates scale control signals 14, which correspond to the keys pressed. The storage device stores the output signals from the control device 2. The The signal stored in the memory device 3 is passed to the encoder 4 and encrypted. The encoder 4 generates a series of logical coding outputs corresponding to said scale control signal 14. The logical coding outputs become adjustable to the program contacts Pm (m »1, 2, 3 ···) Divider 5, e.g. a shift register counter.

In the embodiment described below, a shift register counter is used as the adjustable divider 5, the frequency divisor N (N 1, 2, 3 ···) of which can be changed as a function of an input signal of a series of logic codes which are fed to the program contacts. The shift register counter 5 divides a high-frequency pulse signal f from the high-frequency generator 6 by the divisor N, a sound signal having the frequency f _Q / N being generated as the output. This audio signal is divided by a dividing device 7 by a further suitable divisog, for example by 2, 3 or 5 etc., and then fed to a gate 9. The output signal from the gate 9 is converted by a tone filter 10 into a wave-shaped signal which has the appropriate tone characteristics, which signal is then from an amplifier 11 and

■ 30985 1/04 73

a loudspeaker 12 is converted into a sound

An envelope control device 8 detects the actuation of a key and generates an envelope signal which the gate 9 controls so that the envelope of the output tone signal from the gate 9 is influenced. The high frequency generator 6 is of modulates a vibrato signal from the vibrato oscillator 13

5 shows the circuit diagram for the control device 2 and the memory device 3 · The control device 2 can consist of a priority circuit, for example. The key switches 101 - 120 are operated by the keys of the keyboard 1. The key switches 101-112 of the first octave consist of a priority circuit, in which a normally closed key switch with a common contact of the next Key switch is connected, as can be seen from Fig. 5. The key switches 113-116 of the second octave and the key switches 117-120 of the third octave also consist of Priority switching. The normally open contacts of the key switches 101-112 of the first octave are in connection with the S-contacts of the flip-flop circuits 121-132. The normally open contacts of key switches 117 - 12 ^ are on furthermore via the diodes 137-140 with the S-contacts of the flip-flop circuits 121-132 in connection. The common contact of the Key switch 101 is via a current detector 154 with the positive pole of a voltage source 360 in connection. Furthermore, the common contact of the key switch 113 is via a normally closed control switch 157 and via a further current detector 155 connected to the positive pole of voltage source 360 · The common contact of key switch 117 is via a further control switch 153, which is normally closed, and via a further current detector 156 bits connected to the positive pole of the voltage source 360. The negative pole of the voltage source 360 is grounded.

The normally closed control switch 157 is opened every time the current detector 154- tines the flow Current determined, and then interrupts the connection between the key switch 113 and the voltage source 360.

309851/0473

The normally closed control switch 158 is controlled by a OR circuit 159 controlled and opened every time one of the current detectors 154 or 155 detects the flow of a current, wherein the connection between the key switch 117 and the voltage source 360 is interrupted. The key switches 101 - 112 of the first octave therefore have priority over key switches 11 ^ - 116 of the second octave and this Key switches have priority over key switches 117 - 120 of the third octave. Of the key switches 101 of the The first octave therefore has priority over the other key switches 102-112 when actuated, and doe The order of the priorities is the order of the key switches 101 - 112 · Of the key switches 113 - 116 of the second octave the key switch 113 has the priority over the other key switches 114-116 when actuated, and the The order of priority is the order of the key switches 113-116. Of the key switches 117-120 of the third octave, the key switch 117 has the priority when actuated the other key switches 118-120, the order of priority being the order of the key switches 117-120. From all Key switches 101-120 are therefore given priority by key switch 101 over the other key switches 102-120 on, and the order of priority is the order of the key switches 101 - 120 when actuated.

In the memory device 3, the output signals of the flip-flop circuits 121-132 for sound storage are fed to the input contacts 161-172 of the encoder M- and also via the resistors 141-152 ^. The conversion circuit 153 determines the supplied current or voltage and then generates a conversion voltage if ^{two or more flip-flop circuits of the flip-flop circuits 121-132 are in the operating state H} 1 ". The conversion voltage is applied to the conversion contacts of the flip-flop circuits 121-132, so that all flip-flop circuits 121-132 can be reset to the operating state ^{11 O ".} Thereafter, only one flip-flop circuit is put into the operating state "1" by the corresponding key switch, which is preferably through

309851/0473

2 3 Ί 8 KS 1 - β -

Actuation of the control device 2, i.e. the priority circuit 2 is selected. The output signals from the current detectors 154, 155 and 156 become the switching contacts (state "1") of the Flip-flop circuits 181, 182 and 185 for storing the octave information are supplied. Those stored in the flip-flop circuits 181 Signals for the octave information are passed to an input contact of a further switch back circuit 184 the respective resistors 186, 187 and 188 conducted. The feedback circuit 184 determines a supplied or a applied voltage, a switch-back voltage being generated when two of the flip-flop circuits 181, 182 and 183 or three circuits have been switched (state "1") · The switchback voltage is applied to the switchback contacts of the flip-flop circuits 181-183, so that all flip-flop circuits 181-183 are switched back immediately (state "0") · After this, only one flip-flop circuit is switched (State "1") by means of a corresponding current detector 154 »155 or 156, through which the current preferably flows. the Flip-flop circuits 181-183 therefore store octave information, which has been selected from the first, second and third octave after the selected key switch is in the initial position has returned.

The feedback circuits 163 and 184 consist, for example, of a direct current amplifier that operates on a current or a Voltage responds that exceeds a certain threshold value, with a voltage suitable for all reset contacts is produced. FIG. 10 shows an exemplary embodiment for the downshift circuit 153 with two transistors 281, 282 and with three resistors 283, 284 and 285. The base electrode of transistor 281 is connected through resistor 283 to the negative bias voltage source -V-g and via the resistors 141-152 with the output contacts of the flip-flop circuits 121-132. The collector electrode of the transistor 281 is connected to the base electrode of the transistor 282 and also via the resistor 284 with the source of a positive voltage + V "" in connection. the

CC

Emitter electrode of transistor 282 is grounded. The collector electrode of transistor 282 is connected to the reset contacts

3 09851/0473

ORIGINAL INSPECTED

2 ') ' - ¹ R i) ^ 1

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the flip-flop circuits 121-132 and esistance through the VI / 285 illite the positive pole of the voltage source V in compound vie -emitterelektrode of the transistor 281 is grounded, ivird one or none of the flip-flop circuits 121 to 132 in the storage state offset so located on the base electrode of the transistor 281 has a lower potential than at the central electrode of the transistor 281. The transistor 281 is therefore blocked, while the transistor 282 is conductive. Accordingly, no switch-back voltage appears at the collector electrode of transistor 282. If, on the other hand, two or more flip-flop circuits 121-132 are set to the memory state, a higher potential is present at the base electrode of transistor 281 than at the emitter electrode of transistor 281. Transistor 281 therefore becomes conductive while transistor 282 is blocked. Accordingly, a positive switch-back voltage is generated at the collector electrode of the transistor 282, so that the switched flip-flop circuits 121-132 are switched back immediately (state "0").

The downshift circuit 184 has the same structure and operation as the downshift circuit 153 »so that a more detailed description is not necessary.

FIG. 6 shows the circuit diagram for another embodiment of the control device 2 and the memory device 3, the same circuit elements being provided with the same reference symbols as in FIG. 5. The control device 2 is composed of a priority circuit, similar to the circuit of FIG. 5 Since the memory device 3 according to FIG. 6 is similar to the memory device according to FIG. 5, it will not be described further.

The operation of the priority circuit of the controller 2 will be described below. The key switches 201 are normally open and operated by keys in accordance with the musical scale. The normally open key switches 201-212 of the first octave are connected to a common conductor 174- which is connected to the a ^ negative pole of the voltage source 160 is connected. Usually open key switches 213-216 of the second octave

3098 5 1/0473

INSPECTED

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connected to a common conductor 175 passing through the current detector 155 with the negative pole of the voltage source 260 in Connection.

The normally open key switches 217-220 of the third octave are connected to a common conductor 176, the is connected to ground via current detector 156. The two voltage and current sources 160 and 260 are mutually exclusive connected downstream in such a way that the positive pole of the voltage source is connected to the negative pole of the voltage source 260, whose positive pole is connected to earth.

The normally closed control switch 157 is turned off every time opened when the current detector 154 detects a current flow and the connection between common conductor 175 and the negative pole of the voltage source 260 interrupts. The normally closed control switch 158 is operated through an OR circuit 158 opened every time either the current detector or the current detector 155 detects a current flow and the connection between the common conductor 176 and ground interrupts. The key switches 201-212 of the first octave therefore have priority over the key switches 213-216 of the second octave whose key switches have priority over key switches 217-220 of the third octave.

The movable contacts of the key switches 201-212 of the first octave are connected to the respective emitter electrodes of the transistors 221-232. The collector electrodes of the transistors 221-232 are connected to the changeover contacts S of the flip-flop circuits 121-132. The resistors 241-252 are connected between the base and collector electrodes of the transistors 221-232. All resistors 241-252 have the same resistance value - r -. The resistors are connected in series between the base electrode of the transistor 232 and the positive pole of a voltage and current source 360. The eegettive pole of the voltage source is connected to the ground. The connection points between the resistors 261-272 are connected to the respective base electrodes of the transistors 221-231. All resistors 261-272 show

3 0 9 8 5 1/0 U 7 ?>

ORIGINAL INSPECTED

? 3? R R S 1

have the same resistance value R, which is equal to or slightly higher is than the resistance value r. The movable contacts of the key switches 215-216 of the second octave are above the diodes 136 in connection with the emitter electrodes of the associated transistors 221-232. The movable contacts of the key switches 217-220 of the third octave are connected via the diodes 157 to the emitter electrodes of the associated transistors 221 in Connection The transistors 221 - 232 are all blocked when all key switches 201 - 220 are opened, since then ' no current flows between the base and emitter electrodes of transistors 221-232.

If one of the key switches 201 - 220 is closed, the relevant transistor is switched to the conductive state, whereby the relevant flip-flop circuit is switched. If two or more switches of the key switches 201-212 of the first octave are closed, a current only flows through them that transistor which is the key located closest to the key switches of the current source 360 which are closed at the same time switch corresponds, so that only one transistor is switched to the conductive state, after which the corresponding flip-flop circuit is placed in the memory state. The operation described above is the same as that of the key switches 213 of FIG second octave and with the key switches 217-220 the third octave. From the key switches 201 - 212 of the first octave the key switch 201 is actuated first before all other key switches 202-212, the order of priority being the The order of the key switches 201 - 212 corresponds. Of the key switches 213 - 216 of the second octave, the key switch 213 pressed before all other key switches 214 - 216, the order of priority corresponding to the order of the key switches 213-216. Of the key switches 217 - 220 of the In the third octave, key switch 217 is actuated before all other key switches 218-220, with the order of priority corresponds to the order of the key switches 217-220. As already stated, the order of priority corresponds when operating the three octaves in the order of the first, second and third octaves. As a result, the key switch

3 0 9 8 5 1/0 Ll 3

- ¹² - changed according to input • received on

ter 201 the priority over the other key switches 202 to 220, the order of priority corresponding to the order of the key switches 201-220.

The current detectors 154 »155 or 156 and the normally closed control switches 157 or 158 consist of transistor circuits » as shown in Fig.11. The current detector 154 · »155 or 156 consists of a transistor 191» one Base resistor 192 and a collector resistor 193 · The emitter electrode of transistor 191 is connected to an output contact 196 in connection. The base electrode of the transistor 191 is connected to a bias contact via a base resistor 192 198 in connection. The collector electrode of the transistor 191 is connected to the bias contact via the collector resistor 193 198 and with a control output contact 199 in connection.

The normally closed control switch 157 or 158 consists of a transistor 194 and a base resistor 195 » which is connected between the base electrode and the collector electrode of the transistor 194-. The collector electrode of the transistor 19 ^ is connected to an input contact 197. the Emitter electrode of transistor 194- is connected to an output contact 190 connected. The base electrode of transistor 194 is connected to a control input contact 189.

The bias contacts 198 of the current detector 155 and 156 are connected to the positive pole of the voltage source 360 according to FIG. 5 or with the negative pole / of the voltage source / 16G ee 260 / HTi t of the grounding / according to FIG. 6y

The transmitter output contact 199 of the current detector 154 is on with the conductor 100 in connection as well as with the control input contact 189 of the next control switch 157 and via the OR gate 159 with the control input contact 189 of the further next Control switch 158. The transmitter output contact 199 des Current detector 155 is connected to conductor 200 and via the OR gate 159 with the control input contact 189 of the control switch 158 in connection. The control output contact 199 of the current detector 156 is connected to the conductor 300. The output contact 196 of the current detector 155 or 156 is connected to the input

309851/0473

- 13 - changed according to input

at JUJLi

contact 197 of the relevant control switch 157 or 158 connected. The output contact 196 of the current detector 154- is at the The embodiment according to FIG. 5 with the common contact of the key switch 101 and in the embodiment according to FIG. 6 connected to the common conductors 174-. The output contact 190 des Control switch 157 or 158 is in the execution according to the Fig. 5 with the common contact of the key switches 113 or 117 and connected to the common conductor 175 or 176 in the embodiment according to FIG.

The operation of the current detector 154 and the control switch 157 (Fig.iisO, which elements can be used in the embodiment according to FIG. If one of the key switches 213 - 216 is closed, the output contact 190 a high negative voltage is applied from the voltage source 360 so that a flows from the input contact 198 to output contact 190 through transistors 191 and 194, and when transistors I91 and 194 are turned on the output voltage at the control output contact 199 negative and roughly equal to the negative voltage on Output contact 190. The negative output voltage at the control output contact 199 becomes the control input contact through OR gate 159 189 of the next control switch 158, which here is opened. As the current detector 154 or 155 and the control switch 158 works in the same way as the current detector 155 and the control switch 157j so can be detailed Description can be omitted.

The current detectors 154, 155 and 156 and the control switches 157 and 158 may consist of electromechanical relays. There a corresponding circuit can be implemented without difficulty, a detailed description can also be found in this case be waived.

7 shows an embodiment of an Ekoder 4 in With respect to the shift register counter 5 »the high frequency generator 6 and the vibrato oscillator 13. The output signals from the Storage devices are fed to the input contacts 161 - 172 of the encoder 4 and with the aid of the diode network 14

3 098 5 1/0473

encrypted. The encrypted output signals of the diode network 14 are the programm contacts P ^. - P ^ ₂ ° ^ es shift register counter 5 supplied. An output pulse signal from the high-frequency generator 6 is fed to the input contact of the shift register counter 5. The signal from the high-frequency generator 6 is frequency-modulated by the vibrato oscillator 13, a vibrato frequency in the sub-tone range being generated.

The case will now be considered when the frequency f of the output pulse signal s from the high-frequency generator 6 is 7.74 MHz, and when the program contacts P _x . _ P ^ _{2 of} the shift register counter 5 are supplied with the logical input codes, as can be seen from the following table 1, after which the division factor N of the shift register counter 5 is determined with, for example, 1850, 1960, 2077 »2200, 2331, 2470, 2616, 2772 , 2937, 3111, 3296 or 3492, as listed in Table 1. The shift register counter 5 therefore divides the input frequency f 7,733 l & b-z by the divisor N and generates an output _{tone signal f Q} / N with the frequency 4185.946 - 3951.020 3728.455 - 3520.000 - 3322, 179 - 3136.223 - 2960.245 - 2793.651 2636.704 - 2489.232 - 2349.515 or 2217.640 Hz for the above divisors. These output tone signals correspond to the tones C, B, A sharp, A, G sharp, F, F sharp, F, E, D flat, D and C sharp of the scale with equal tempered tuning. Since the memory device 3, this program contacts P ^ - P ^ ₂ stores the supplied logical encodings, including der.Divisor N is stored, until the state of the memory device 3 changed by a different choice of the key switches · The input level f _Q / N is therefore is still generated at the output of the shift register counter, even if the corresponding key switch is opened until the next key switch is closed. The output tone signal f _Q / n is continuously supplied to the dividers 7 in the next stage until the state of the memory device is changed. The storage device 3 can be switched on between the encoder 4 and the shift register 5, so that the device operates in the same way as described with reference to FIG.

Table 1 309851/0473

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309851 / 0A73

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8 shows an embodiment of the dividing device 7, the envelope control device 8, the gate device 9 and the tone filter device 10. The output tone signal f _Q / N from the shift register counter 5 is fed to the dividing device 7, in which the frequency of the tone signal f _Q / N der Is divided in sequence in the frequency dividers 17 »18 and 19 by the divisor 2. The output signals from the frequency dividers 17, 18 and 19 are fed to the gates 20, 21 and 22 of the gate device 9, which is controlled by an output signal from the envelope control device 8 fed via a conductor 500. The outputs from the gate circuits 20, 21 and 22 are fed to the tone filters 23, 24 and 25 of the tone filter device 10, which converts the waveform of the fed tone signals. The initial

11 signals from the audio filter device are used to amplify the next stage.

The normally open switches 26 and 27 are switched on between the input and output contacts of the frequency dividers 15 and 16. If the switches 26 and 27 are closed, the input tone signals are passed past the frequency dividers 15 and 16 directly to the output contacts. If one of the key switches 117-120 or 217-220 of the third octave is closed as wali, a stored control signal for the third octave is sent via the conductor 300 to the switch 26 from the flip-flop 183 for the third octave and via the conductor 300 * and on OR gate 28 passed to switch 27. Here, the normally open switches 26 and 27 closed, is terminated so that the operation of the frequency dividers 15 and 16 · As a result, f at the output contacts of the frequency dividers 17, 18 and the Ausgangstonsignale / 2N f, _Q / ^ N BEZW. f / 8N generated.

If one of the key switches 113-116 or 213-216 of the second octave is closed, a stored control signal for the second octave is passed via the conductor 200 * and via the ODÜR gate 28 to the switch 27, this switch being closed when it is closed , the work of the frequency divider 1o is finished. As a result, at the -kus ^ ungskontakten the frequency dividers 17, 10 and 19, the Auslangstonsi ^ nale f _Q / 4-N, ^ / 8Im ¹ and f _Q

generated.

λ 0 9 RS 1 / Π U 7 Γ;

If one of the key switches 101-112 or 201-212 of the first octave is closed, the frequency dividers ^ and 1b work in the normal way, since the switches 26 and 27 are kept open. _{As a result, the output tone signals f / 8N, f Q} / 16N and f _o / 32K are generated at the output contacts of the frequency dividers 17 »18 and 19.

The envelope control device 8 consists, for example, of an ODüK gate 321 and a diode 29 'from the resistors 30, 31 and 34 · »from a capacitor 32 and a transistor 33» as shown in Fig.8. If one of the key switches of the first, second and third octave is closed, the capacitor 32 with a (not stored) octave control voltage via the resistor 31, the diode 29 »the OR gate 321 and a charged via conductors 100, 200 or 3OO. In this case transistor 33 is blocked because no switch-back pulse is supplied from switch-back circuit 153 and / or 184 to the base electrode via the OR gate 35 and via the conductors 400 'and / or 400. After opening the closed key switch the octave control voltage disappears, and the charge on the capacitor 32 gradually flows away through resistors 30 and 31.

Whenever the memory state of the memory device 3 changes, the switch-back circuits 153 and / or 184 generate Switch-back pulses applied to the base electrode of transistor 33 via the conductors 400 and / or 400 'and via an ODüR gate circuit 35 are supplied, the transistor 33 in the conductive State is shifted. At the time the switch-back pulse is supplied, the capacitor 32 is immediately discharged via the The collector-jamitter circuit of the transistor 33 Capacitor 32 charged with another octave control voltage will.

The envelope control signal generated at the capacitor 32 is sent to the gate circuits 20, 21 and 22 of the gate device 9 fed via the .Leiter 500, the envelope curve of the output signals is influenced from these gate circuits 20, 21 and 22. If the resistors 30 and 31 consist of real resistors,

309851/0473

ORlQtMAL INSPECTED

2 3? 8 8 5 1

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so it can be the cooldown time (or the hold time) and / or the swelling time can be changed according to the wishes of the player of the instrument this one infinitely large resistance value on that will a charging voltage is stored on capacitor 32 even if The octev control voltage that is not stored disappears until the base electrode of transistor 33 is supplied with a switch-back pulse will. In this case, an output sound signal is stored or maintained in a sounding state after the selected key switch has been opened until the next key switch is closed. 2

The octave control voltages stored in the memory device £ are respectively via the conductors 100 ', 200 * and 30O ^{1 to} the tone filters 23, 24 and 25. via the conductors 501, 502 and 503, the frequency response characteristics of the tone filters 23, 24 and 25 then being influenced in such a way that they match the selected octave.

9 shows a further different embodiment of the dividing device 7> the gate device 9 and the audio filter device 10. The output audio signal f / N from the shift register counter 5 is passed to the dividing device 7, in which the frequency of the audio signal f_ / N from the frequency dividers 15 - 19 is divided by the divisor 2, the output _{signals f Q} / 2N, f _Q / 4N, f _Q / 8N, f _Q / 16N and f _Q / 32N are generated. These output signals are passed to the gate circuits 45 - 49 of the gate device 9. The output signals from the aforementioned gate circuits are fed to the tone filters 60-64. The output signals from these tone filters are passed to an amplifier 11. The envelope control voltage is passed to the switches 54, 55 and 56, which are normally opened by the envelope control device 8 via the conductor 500.

If one of the key switches 101-112 or 217-212 of the first octave is selected, a stored control signal for the first octave from the flip-flop circuit 1B1 is ^{fed to the switch 56 via the conductors 10O 1} and 501 for the first octave memory Switch 56 is closed. Thereafter, the envelope control signal is sent to the gate circuits 49, 4b and 47

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ORIGINAL INSPECXfD

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fed from the envelope control device 8 via the normally open switch 56 and / or via the diodes 69 and 68, the envelope of the output signals from the gate circuits ^V , 4 $ ^ and 47 being influenced.

If one of the key switches 113-116 or 213-216 of the second octave is selected, a stored signal for the the second octave is fed to the switch 55 from the flip-flop circuit 182 via the conductors 200 'and 502 for the second octave memory, the switch 55 being closed. Thereafter, the envelope control signal from the envelope control device 8 becomes the gate circuits 48, 47 and 46 fed via the normally open Switch 55 and continue through diodes 53 »67 and 68, where the envelopes of the output signals from the gate circuits 48, 47 and 46 are influenced.

If one of the key switches 117-120 or 217-220 of the third octave is selected, the switch 54 becomes a stored one Control signal for the third octave supplied from the flip-flop circuit 183 via the conductors 300 and 503 for the third octave memory, so that the switch 5 ^ · is closed. After that Envelope control signal from the envelope control device 8 is supplied to the gate circuits 47, 46 and 45 via the switch 54 and continue through diodes 52 and 51, the envelope the output signals from the gate circuits 47, 48 and 46 is influenced.

In the electronic musical instrument according to the invention a tone holding effect and a memory effect can be achieved since the program contacts of the shift register counter 5 are supplied Logical codes are stored by the memory device 2 even after you stop operating a Key on the keyboard, or in other words, even after opening a key switch until the next key is pressed, i.e. until the next key switch is closed.

The Järfindung also has the advantage that the envelope the Aus ^ anystonsignale be designed in various ways can by adapting the envelope control device 8 to the electronic musical instrument according to the invention.

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It is also advantageous that the frequencies of the output audio signals can be fairly accurate and stable, for which purpose only an accurate and stable high-frequency generator 6 needs to be used.

The musical instrument of the present invention can do no without difficulty be equipped with integrated circuits, since the digital system is used in all systems according to the invention can·

The described embodiments of the invention can Of course, changes, modifications and replacements are made by experts within the scope of the inventive concept The invention itself is therefore only defined by the accompanying claims delimited.

Claims

309851/0673

Claims (5)

.2378851 claims 1.) Electronic musical instrument, characterized by a high-frequency generator for generating a high-frequency pulse signal, by an encoder for generating a series of logical codes corresponding to a tone of a musical scale
correspond, depending on a scale control input signal that is fed to an input contact, by an adjustable dividing device that divides the frequency of the high-frequency pulse signal generated by the high-frequency generator by an integer divisor, which is determined by the logic code supplied to the program contacts, and by a Storage means for storing the scale control signal or a signal which is substantially
is equivalent to the logical coding that is fed to the program contacts of the adjustable dividing device
is to be, wherein said signal stored in the storage device remains stored, even after
The scale control signal fades until the next scale control signal is generated. 2. Electronic musical instrument according to claim 1, characterized in that said storage device is in front
the named encoder is switched on. 3 · Electronic musical instrument according to claim 1, characterized characterized in that said memory device is switched on between aen said encoder and the adjustable dividing device. 4- · Electronic music instrument according to claim 1, characterized characterized in that the scale control signals are generated by control means operated by keys on a keyboard will. 309851 / (U73 Blank page - 22 - 23? B 851 5. Electronic musical instrument according to claim 4 ·, characterized characterized in that said control means consists of a priority selector providing a scale control signal that corresponds to the highest or lowest key of the keys pressed at the same time 6 · Electronic musical instrument according to claim 1, characterized characterized in that the musical instrument is equipped with a filter device, a gate device and an envelope control device is equipped that an output contact the adjustable dividing device via said Gate device connected to the tone filter device is that the gate device is controlled by the envelope control device, and that the envelope control device is actuated in dependence on the scale control signals and on the output from the memory device. 7 · Electronic musical instrument according to claim 6, characterized in that the properties of the tone filter as a function from the output signal from said control device to be influenced. 3 0 9 R 5 1 / D U "3