DE3504382A1 - Electronic musical instrument - Google Patents

Abstract

The electronic musical instrument contains a microcomputer (8) and a single sound memory (6, 7, 9) which is connected to the microcomputer and which is designed as a common memory for all voices. The sounds are generated by sequential read-out of the sound-memory data. The sound memory can be sub-divided into random-access memory areas (9) and preferably erasable, programmable memory areas (6, 7). The programmable memory areas (6, 7) are constructed as plug-in modules which are arranged on the front panel of the musical instrument and can be easily interchanged by the user. <IMAGE>

Description

Electronic musical instrument

Description The invention relates to an electronic musical instrument according to the preamble of claim 1.

Such a musical instrument is called a so-called synthesizer the DE-OS 28 26 429 known. There are several tone generators as a tone generator are used, which are activated depending on the pressing of the respective buttons. The individual keys are continuously queried there, whereupon each is pressed A tone generator is activated. Required unlike older devices this well-known synthesizer no longer has one tone generator per key, but instead only one tone generator per key pressed. Since in four-handed play a maximum of 20 keys can be pressed, this synthesizer only needs a maximum of 20 Tone generators.

As a result, the cost of components is already considerably reduced, but still relatively large.

The object of the invention is to provide the electronic musical instrument of To improve the type mentioned at the outset in such a way that the structural effort is reduced and at the same time a higher flexibility in the sound generation is achieved, in particular, diverse types of tones can be generated.

This object is achieved by the characterizing part of the claim 1 specified features solved. Advantageous refinements and developments the invention can be found in the subclaims.

Sound generators are no longer used in the conventional to generate sounds Senses used. Rather, the sound is generated through the interaction of Keyboard, microcomputer and a single common sound memory for everyone playable voices. The sound is generated by reading out data sequentially from the sound memory, the microcomputer after pressing one or more Keys the required addresses of the signals stored in the sound memory, which after digital / analog conversion to tones, contains. Other features and advantages of the invention emerge from the following description.

In the following the invention is based on an exemplary embodiment explained in detail in connection with the drawing. It shows: Figure 1 a schematic front view of the electronic musical instrument according to the invention; and FIG. 2 is a block diagram of the electronic musical instrument according to the invention.

In the figure, a keyboard 1 and one above it are offset to the rear arranged front panel 2 to recognize. The front panel 2 has an input keypad 3, different regulators 4 and 5 as well as recesses for pluggable, programmable ones Blocks 6 and 7, which can be PROMs, EPROMs, etc., for example. These building blocks 6, 7 can be pulled out from the front or inserted from the front. You can so be exchanged at your discretion. Although in Figure 1 only two such modules are shown, it should be noted that any number of such Building blocks can be provided, including the possibility of just a single one pluggable, programmable module.

These modules are also given the same reference numbers in the block diagram of Figure 2, to which reference is made below.

The musical instrument contains a microcomputer as a central component 8, the usual assemblies such as central processing unit (CPU), memory (RAM, ROM), clock generator and input / output modules (I / O modules). Its connections are with denotes the letters D, A, S or I, whereby these symbols mean the following: D: Data lines A: address lines S: control lines I: input lines.

A "sound memory" is assigned to the microcomputer A, here is divided into two parts, namely in a sound memory designed as a RAM memory 9 and a sound memory designed as PROM 6, 7. Both together form the real one Sound memory. Both sound memory areas are accessible via address lines (address inputs Ao * s * An) connected to the address outputs of the microcomputer. They are still over Control lines connected to control outputs of the microcomputer. The microcomputer 8 can call up any "addresses" in the sound memory, both for writing as well as reading processes.

If tones or sounds are to be read into the sound memory, so they are, for example, from a microphone, a tape, etc. to a Sampling input 11 applied and an amplitude controller (potentiometer 12), a Low-pass filter 13, an analog / digital converter 14 and a bus coupling unit 15 given a data bus 16, from where they via bus coupling units 17 and 18 the sound memory 6, 7, 9 are fed. Furthermore, these can be digitized Sounds via the data bus 16 and a bus coupling unit 19 also have a data input of the microcomputer 8 are supplied. During this "writing process", the microcomputer 8 successively determined memory areas via the address lines addressed, in which the signals are stored. Work appropriately the analog / digital converter 14, the data bus 16 etc. in parallel to achieve a high signal processing speed to achieve.

The low-pass filter 13 is a so-called one "Aliasing low-pass filter", of signals whose frequency is above half the sampling frequency is suppressed.

In addition to the sound memory 6, 7, 9, another, larger one can be used Memory 10 be connected to the microcomputer. This memory can for example be a floppy disk, hard disk, etc. Under the control of the microcomputer 8, data can be exchanged between the sound memory and the mass memory 10 will.

When producing music, i.e. when "playing" the electronic musical instrument the digital signals stored in the sound memory are processed in a certain way read out and made audible again. This readout is carried out by pressing one of the or several keys of the keyboard 1 triggered. The microcomputer 8 asks for this in the Operating mode "play" continuously the keys (switches) of the keyboard from whether they are depressed or not. If a key is now pressed, the microcomputer calculates 8 the addresses of memory areas based on the programs stored in it of the sound memory that are to be "read out". Before that, the bus coupling units 15, 17, 18 and possibly 19 are switched over via control signals in such a way that the bus coupling unit 15 is blocked and the bus coupling units 17 and 18 are opened in the outlet direction are.

By addressing the sound memory areas and the clock frequency on the control lines from the microcomputer to the sound memory Signals read out on the data bus 16. From there they arrive via a digital / analog converter 20, where they are converted back into analog signals, to an analog switch 21. This is, for example, a high-speed MOS-FET switch. The analog switchover, more precisely its switch position, is controlled by control signals (Control line 22) controlled by the microcomputer 8.

At the outputs of the analog switch 21 are several sampling and Holding circuits (sample and hold) 23-25 connected. Depending on the position of the analog switch 21 is the analog sound signal in one of the sample and hold circuits 23 to 25 stored and operated by a microcomputer 8, not shown Control line activated. The output signals of all sample and hold circuits 23 to 25 are added up in a summer 26 and smoothed in a low-pass filter 27 and fed to a loudspeaker 29 via an amplifier 28. The cutoff frequency of the low pass 27 can correspond to that of the low pass 13.

Each individual instrumental part or optionally each of several Simultaneously pressed keys on the keyboard is a separate sample and hold circuit 23-25 assigned. This greatly simplifies the organization of the sound memory and also the program of the microcomputer.

It is of particular importance for the invention that all votes only one common sound memory is provided. The sound is generated by sequential readout of sound memory data. The sound memory is arbitrary Can be divided between the respective voices, i.e. certain memory areas of the sound memory are assigned to certain voices. This makes it possible to use certain voices to be called up by programmable address counters in the microcomputer. The sound memory can be divided into different subgroups, for example.

a memory area with random access (RAM memory area) and one or more programmable read only memories (PROM). These PROM's are pluggable according to the invention and can therefore be easily exchanged.

Erasable memories are preferably used for this purpose, for example those that can be erased with ultraviolet light.

With such a storage subdivision, any electrical Analog signals in the low frequency range (sound range) after analog / digital conversion (Converter 14) initially stored in the RAM sound memory 9 and then under control of the microcomputer 8 loaded into the programmable memory.

In general, arbitrary digital signals are from all sound storage areas (RAM or ROM) can also be transferred to the mass storage device 10 and vice versa.

The respective sound memory address ranges for recording and / or Playback can be set during the game by means of the regulators 4, 5 (Figure 1) will. This enables a simple choice of the during sound recording with sound data to be loaded and a real-time sound influencing during the game.

Different or the same sound colors can be used for each voice can be generated in the sound reproduction by appropriately assigning a Memory area for the respective voice.

The sound memory can also contain signals other than tones, for example Signals for the order of triggering the waveform or signals for the automatic pitch to be played (so-called sequencer). It is also possible while recording as well as changing the sampling frequency during playback. Corresponding signals for this can either be in the sound memory or in the microcomputer.

All in the claims, the description and the drawing The technical details shown can be used both on their own and in any Combination with one another be essential to the invention.

Claims (8)

Electronic musical instrument Claims 1. Electronic Musical instrument with a keyboard (manual), one that is connected to the keyboard, digital control device and a sound generating device connected to it, characterized in that the control device is a microcomputer (8) and that the tone generation device has a single digital one that is common to all voices Has sound memory (6, 7, 9). 2. Musical instrument according to claim 1, characterized in that the Sound memory at least one pluggable programmable memory (PROM 6, 7) having. 3. Musical instrument according to claim 2, characterized in that the programmable memory (6, 7) can be erased, preferably by irradiation with ultraviolet light. 4. Musical instrument according to one or more of claims 1 to 3, characterized in that memory areas of the sound memory (6, 7, 9) are arbitrary can be divided between the respective voices of the musical instrument. 5. Musical instrument according to one or more of claims 1 to 4, characterized by an additional Massenspeic.h.er (10), which is so connected to the microcomputer (8) is connected to the fact that it can send any digital signals to the sound memory (6, 7, 9) can exchange. 6. Musical instrument according to one or more of claims 1 to 5, characterized in that the memory areas addressable by the microcomputer (8) of the sound memory (6, 7, 9) during recording and playback using the control knob (4, 5) are preselectable. 7. Musical instrument according to one or more of claims 1 to 6, characterized in that certain storage areas of the sound memory (6, 7, 9) any voices of the musical instrument can be assigned to produce different ones or the same timbre in the sound reproduction of the respective voice. 8. Musical instrument according to one or more of claims 1 to 7, characterized in that the sound memory (6, 7, 9) in addition to the tones representing, digital signals contains further signals stored, e.g. for the sequence the triggering of waveforms or the pitch to be played automatically (sequencer).