DE19905232A1 - Electronic musical instrument for creation of musical sounds, has playing section and sound generation section with volume control, to produce sounds according to actuation of playing section. - Google Patents

Abstract

The volume adjuster (3) influences the sound volume in dependence on its position and characteristics. The adjuster is coupled to an equalizer (17) which continuously determines a maximum of its energizing, using the maximum as preset value of the characteristic. The equalizer comprises a comparator, a memory, and a characteristic generator. It determines also the minimum of energizing, using it as a second value of the characteristic. The volume generator may be designed as a beat generator. Independent claims are included for the volume adjuster.

Description

The invention relates to an electronic musical instru ment with at least one game unit, a sound generating device depending on a loading operation of the game unit produces sounds, and one volume control adjustable during operation, who depending on his position and a Kenn line affects the volume of the sounds. Furthermore be the invention meets a volume control for electronic musical instrument that depends on its position and a characteristic curve an output signal generated.

The invention is based on an electronic organ as an example of electronic music instrument described. With an electronic organ the game unit is given by the manuals and in case the pedal is formed. But the invention is also applicable to musical instruments that are otherwise  be played, like a guitar or one Wind instrument. Here is just on the way from the game unit to the sound generator further signal processing required for the present invention does not matter.

When a button is pressed on an electronic organ the sound generating device receives an ent speaking signal and in the simplest case generates egg sound corresponding to this key. Usually leaves this tone also corresponds to the selection change the corresponding register. This change can go so far that you can basically no longer speak of can speak a tone that is based on, for example ner pitch is identifiable, but generally from must speak a sound, d. H. a sound with a certain characteristic.

The musician or artist who is the musical instrument plays, i.e. the game unit operated, used as essential design feature of his lecture too the volume. The volume should be during the lecture can be changed dynamically. For this, the Volume control used.

The volume control is easy to start with as a potentiometer, d. H. as changeable electrical Imagine resistance, the resistance value of which Position of the volume control is dependent. Since that Hearing sensation is not linear, but essentially log is arithmic, the volume control is usually a characteristic curve assigned to the individual positions a generally non-linear relationship to one Assigned output signal. Of course you can instead a potentiometer other possibilities to set  use averaging, for example an inductor ve, capacitive, optical or magnetic detection.

In all cases there is a problem with treatment of the output signal in that when detecting the Potentiometer values (or the values of the corresponding on directions) due to mechanical and electrical Manufacturing tolerances and thermal ver changes a spread of the individual parameters occurs, which is significant without additional measures Has an impact on the acoustically relevant volume, which leads to considerable losses in the controllability of the Musical instrument can lead.

So far this problem has been solved by the fact that everyone Reconnect the volume control the maximum full control can be carried out manually got to. For stationary volume controls the problem is not that serious, but it does exist yet. The deed is critical above all thing that one usually forgets the comparison here.

The comparison assumes that every user does this has speaking knowledge and, if necessary, this comparison can perform quickly. Experience has shown that but musicians are not constantly aware of these problems, so that often a not optimally adapted characteristic is used, resulting in unsatisfactory acoustic Behavior of the electronic musical instrument.

The invention has for its object the volume to improve the influence of c  

This task is done with an electronic music instrument of the type mentioned solved in that the volume control with a balancing device connected, which is continuously a maximum of its off control determined and this maximum as predetermined th value of the characteristic curve is used.

After switching on the device, a Characteristic curve used, for example, in the factory is given and the lower predetermined tolerance limits corresponds to zen. A trigger value is on this lower Limit set.

After assembling the musical instrument and fol switching on or just after switching on The adjustment device now continuously determines whether the current output value of the volume control, at for example the potentiometer value mentioned above, lies above the trigger value. If this happens, the trigger value is to be set to the current value and a new characteristic curve is calculated for this case net. Through the constant application of this step ensures that with a single full off control, d. H. Setting the volume control to maximum volume that for this musical instrument with Maxi available in its corresponding configuration painting level is always reached and thus an optimal Controllability of the instrument is ensured regardless of the individual mechanical and elec tolerances. This procedure naturally sets Lich ahead that the musician sets the volume control times fully activated, for example in a foot swell all through. However, it can be observed that most musicians start this behavior at the beginning show - usually unconsciously. Should  if this is not the case, the musician will unsatisfactory volume of sound the volume control just put it "as far as it will go", so that the ge desired condition is reached again.

Preferably, the adjustment device continuously determines fend the minimum of the modulation and uses this Minimum as the second value of the characteristic. So that too the lower limit of controllability reliably de finishes.

The adjustment device preferably has at least one a comparator, at least one memory and one Characteristic curve generator on. The memory stores the maximum triggerability. The comparator now compares whether the saved one Trigger value is greater or less than the current one Trigger value. The larger of the two values is saved saves and at the same time continues to the curve generator given, which forms the characteristic and if necessary also used to evaluate the control signal.

The adjustment device preferably has a clock give up. One can then determine the maximum or the minimum at predetermined time intervals perform, for example with a frequency of 100 Hz. The sampling rate is large enough to cover all digits changes in the volume control reliably to be able to average.

The volume control is an advantage as a foot sill educated. This is one in particular at elektroni preferred musical instruments type of volume stellers, where the problems described above have shown to a special degree.  

In a particularly preferred embodiment, it is provided see that the sound generator on the Motherboard of a personal computer is arranged and the adjustment device by one on the main place ne arranged processor is formed. Such a thing The musical instrument is thus formed by the Kombinati on from a conventional musical instrument with his Game equipment and, if necessary, other controls directions and the main components of a normal per personal computers. Its processor, for example a Pentium I from Intel or a comparable processor with a frequency of 166 MHz provides enough computing or processing power available to not only calculate the data necessary for sound generation to be able, but also the adjustment of the volume to be able to make.

It is particularly preferred that the volume with its own MIDI interface with the Mu Sikinstrument is connected, the processor at least least when starting an identification routine running. The communicates with the identification routine Processor on the motherboard with the MIDI cut usually place a processor points, which is preferably an inexpensive single chip can be trained by. So the volume shares at least present the musical instrument with the is so that the processor at the next Bear processing of signals take this fact into account can. In most cases, the volume control but also transmit certain key data can, so that the musical instrument also "knows" to wel Chen volume control.  

The task is also carried out by a volume control solved the type mentioned, in which an Ab the same device is provided, which continuously Maximum of its modulation determined and this maxi mum used as the predetermined value of the characteristic. Man can such a volume control also "autonomously" design so that at the output of the volume control always a signal can be taken that is on the maximum controllability is related.

The features and advantages that the volume control in the In connection with the musical instrument of course, even if the volume control as an egg gene device is considered.

The invention is preferred below on the basis of one th embodiment in connection with the drawing described in more detail. Show here:

Fig. 1 is a schematic block diagram of an elec tronic musical instrument,

Fig. 2 is a schematic representation of a characteristic and

Fig. 3 is a block diagram for explaining a comparison.

Fig. 1 shows a schematic block diagram of a musical instrument 1 with a keyboard 2 , a volume switch 3 designed as a foot sill, a sound generator 4 and an amplifier / speaker unit 5th The sound generating device 4 is connected to a sound selection device 6 , with which, for example, different registers can be selected.

Depending on the type of register, the musical instrument 1 generates a tone with a specific sound characteristic when a key on the keyboard 2 is pressed. For this purpose, the musical instrument 1 has a processor 7 , which communicates with the connected parts 2 , 3 , 5 , 6 via a communication card 8 . The actual sound generation takes place under the control of the processor 7 on two sound cards (sound generation cards) 9 , 10 . Here, the first sound card 9 is responsible for the sound generation and the second sound card 10 is configured for mixing all the existing sound information.

An essential design feature of a musician's lecture is the dynamic, ie the change in sound strength. The foot sill 3 is used for this .

In order to simplify the following explanation, the output behavior of the foot sill 3 is referred to as "from control". The higher the level of the foot sill 3 is, the greater the volume emitted by the musical instrument 1 . Conversely, the volume is low with a low modulation. Whether the physical signal actually reaches its greatest value at a high level depends on how the foot sill is constructed. If its actuator is designed, for example, as a potentiometer or a sliding resistor, then it may well be that the output voltage output has its smallest value as the output signal at the greatest modulation. The specific type of signal generation does not play a role for further consideration. The modulation can also be generated optically, capacitively or inductively, for example.

With a foot sill, the greatest control is usually reached when the foot sill is fully depressed, similar to a motor vehicle, where the greatest speed is reached when the accelerator pedal is depressed. The relationship between the setting angle 11 of the foot rocker pedal 12 and the modulation A is shown schematically in FIG. 2.

At maximum displacement 11 of the foot plate 12 also gives the maximum modulation A. The difference between the largest and the smallest modulation modulation based on the angle 11 of the foot plate 12 is the dynamic range.

The problem now is that the solid characteristic curve shown in FIG. 2 represents a certain ideal run, but this is not achieved at least without previous adjustment work. Mechanical and electrical tolerances during production, thermal influences during operation or mechanical stress during transport result in a noticeable spread of the individual parameters. If one were to specify a conversion characteristic, this would lead to considerable losses in the controllability of the acoustically relevant volume. So far, you had to readjust the foot sill with every new connection, ie set it to maximum full level. This comparison requires that each user has the appropriate knowledge and can carry out this comparison quickly if required. Experience has shown that musicians are not always aware of these problems. In many cases, the corresponding training or instructions are also missing, so that a characteristic curve that is not optimally adapted is often used. This leads to unsatisfactory overall acoustic behavior of the musical instrument 1 .

The solution to this problem is now in the following procedure. After switching on the musical instrument 1 , a characteristic curve is used which corresponds to the lower tolerance limit set at the factory. A corresponding trigger value is set in a memory 14 , which corresponds to a lower tolerance limit. The memory 14 is connected to a comparator 15 . The memory 15 is in turn connected to a characteristic curve ner 16 . As shown in FIG. 3, these parts can be arranged in a balancing device 17 , which is accommodated in the housing of the foot sill 3 ( FIG. 1). But it is also possible that the equalization device 17 is arranged in a manner not shown on the sound generating device 4 or is even formed by the processor 7, which is accordingly program-controlled.

The modulation A is now fed to the comparator 15 . This now continuously determines whether the current value of the modulation A is above the trigger value stored in the memory 14 . If this occurs, the trigger value is set in the memory 14 to the value of the modulation aktuel len A and passed on this current value to the characteristic curve generator 16 which calculates with the aid of this value, a new characteristic curve. This is shown in FIG. 2 by the transition from the dashed line to the solid line.

At the same time, the modulation is fed to another input of the characteristic curve generator 16 , which uses the newly determined characteristic curve to pass a modulation A 'to the musical instrument 1 .

The constant application of this procedure ensures that with a one-time full actuation of the rocker pedal 12, the maximum level of modulation available for this hardware configuration is always achieved and thus optimal modulation availability of the musical instrument 1 is ensured, regardless of the individual tolerances of the Foot sill 3 .

In the same way you can of course also the minimal Determine the value of the controllability, so that two Has points available for the characteristic curve. The Kennli is never linear, as a rule. She obeys but in most cases prescribed by law liquids, so that one with a maximum value and one "Zero point" or with a maximum value and a mini calculate the necessary characteristic curve can.

Claims (11)

1. Electronic musical instrument with at least one game unit, a sound generating device that generates sounds as a function of an actuation of the play unit, and an adjustable volume control during actuation, which in dependence on its position and a characteristic curve influences the volume of the sounds, thereby characterized marked that the volume control ( 3 ) is connected to a balancing device ( 17 ) which continuously determines a maximum of its modulation (A) and uses this maximum as a predetermined value of the characteristic. 2. Musical instrument according to claim 1, characterized in that the matching device ( 17 ) continuously determines the minimum of the modulation (A) and uses this minimum as the second value of the characteristic curve ver. 3. Musical instrument according to claim 1 or 2, characterized in that the adjustment device ( 17 ) at least one comparator ( 15 ), at least one memory ( 14 ) and a characteristic curve generator ( 16 ). 4. Musical instrument according to one of claims 1 to 3, characterized in that the matching device ( 17 ) has a clock. 5. Musical instrument according to one of claims 1 to 4, characterized in that the volume control ( 3 ) is designed as a foot sill. 6. Musical instrument according to one of claims 1 to 5, characterized in that the sound generator device ( 4 ) is arranged on the main board of a personal computer and the alignment device is formed by a processor arranged on the main board ( 7 ). 7. Musical instrument according to one of claims 1 to 6, characterized in that the volume control ( 3 ) is connected via a dedicated MIDI interface to the musical instrument, the processor ( 7 ) passing through at least at the start of an identification routine. 8. Volume control for an electronic music instrument that generates an output signal as a function of its position and a characteristic curve, characterized by a matching device ( 17 ) that continuously determines a maximum of its modulation (A) and uses this maximum as a predetermined value of the characteristic curve . 9. Volume control according to claim 8, characterized in that the adjustment device ( 17 ) continuously determines the minimum of the modulation (A) and uses this minimum as the second value of the characteristic curve ver. 10. Volume control according to claim 8 or 9, characterized in that the adjustment device ( 17 ) has at least one comparator ( 15 ), at least one memory ( 14 ) and a characteristic curve generator ( 16 ). 11. Volume control according to one of claims 8 to 10, characterized in that it is a foot sill is trained.