ITPD20090009A1 - FILTER DEVICE FOR ELECTRICAL MUSICAL INSTRUMENTS - Google Patents

Description

DESCRIPTION

Technical field

The present invention relates to an improved filter device for electric musical instruments, having the characteristics set out in the preamble of the main claim.

Technological background

Filters for electric musical instruments are known, which are called wah or wah-wah in the jargon, and which allow the sound produced by the instrument to which they are connected to be modified, obtaining particular and desired acoustic effects.

The wahs allow you to cut and gradually re-insert the high frequencies of the sound emitted by the instrument to which they are connected, modifying that sound through a gradual change in tone between treble and bass.

In this way, acoustic effects are generated in the final sound emitted which can be assimilated to a m iagolio or a cry.

The wahs usually used are pedal-operated, that is, they are operated by pushing the foot on a special mobile platform which is operationally connected to a potentiometer provided inside the wah.

By varying the thrust exerted and varying the area in which this thrust is exerted, toe or heel of the foot, a certain signal is given to the potentiometer and the tone is varied between treble and bass, consequently varying the effect generated by the instrument.

The use of pedal wahs, especially for long times, is particularly uncomfortable for musicians due to the prolonged and high effort to which the ankle is subjected.

In addition, the presence of mechanical parts makes these wahs inaccurate in modifying the sound of the instrument, and the precision of the effect produced decreases significantly after prolonged use, due to the weariness of the musician.

Therefore, digital wahs have been proposed which apply a predetermined effect to each sound produced by the instrument and which do not require a command from the musician.

However, with these wahs the effect of customizing the sound is lost which can, on the other hand, be obtained with traditional wahs, with which, at the total discretion of the user, a different effect can be potentially obtained at each performance of the same passage.

Therefore, these wahs are used above all by novice m usicians but not by experienced m usicians who prefer to customize the sound produced from time to time by their instrument.

Furthermore, wahs have recently been proposed activated by a proximity sensor that detects the position of the foot and, consequently, activates a filter provided inside the wah.

In these wahs the mechanical elements foreseen in the pedal wahs are eliminated.

However, some drawbacks remain in the use of these wahs which are particularly evident in prolonged use, for example during live performances.

In fact, these wahs remain uncomfortable to use and, therefore, following prolonged use and due to fatigue, there are worsening in the sound emitted, and loss of precision.

Furthermore, these wahs are optimized on the first octave, or lower octave, resulting, on the contrary, ineffective on the upper octave, or second octave. In other words, these wahs allow you to effectively modify a sound produced only on the lower octave, identified by the first eleven frets of the electric guitar fretboard, that is, the frets facing the headstock of the guitar, for which they are optimized.

Therefore, the sound produced by a note played on the second octave, or upper octave, identified by the frets facing the body of the guitar, is not significantly modified by these wahs.

Description of the invention

One purpose of the invention is to provide a filter device for electrical m usical instruments that has a high comfort of use.

Another object is to provide a filter device for electric musical instruments having good accuracy and which can be used in more than one mode of use while maintaining a considerable modification of the sound.

Another object is to provide a filter device for electric musical instruments which can be used on both octaves of extension of the sound produced with an electric instrument.

Another object is to provide a filter device for electric musical instruments which can be easily used with the usual electric power supply networks.

These objects are achieved by the present invention by means of a filter device for musical instruments made in accordance with the following claims.

Brief description of the drawings

The features and advantages of the invention will better emerge from the detailed description of one of its preferred embodiments, illustrated by way of non-limiting example with reference to the accompanying drawings in which:

Figure 1 is a top view of a filter device for electrical m usical instruments according to the invention;

Figure 2 is a front view of the filter device of Figure 1;

Figure 3 is a side view of the filter device of Figure 1;

Figure 4 is a perspective view of the filter device of Figure 1, in an assembled configuration;

- Figure 5 is an exploded view of the filter device of Figure 4, Figure 6 is a block diagram illustrating the operation of a signal transformation circuit of the filter device according to the invention;

Figures 7a-7b are diagrams illustrating the operation of a filter device according to the invention as the distance of the foot from a proximity sensor varies, respectively at the maximum and minimum resonance value, in a first operating mode of the device same;

Figures 7c-7d are diagrams that illustrate the operation of a filter device according to the invention as the resonance varies respectively at the maximum and minimum distance of the foot from the proximity sensor, in a first operating mode of the device itself;

Figures 8a-8d are diagrams respectively like those of Figures 7a-7d, but related to a second operating mode of the filter device according to the invention.

Preferred way of carrying out the invention

With reference to the attached Figures 1 -6, a filter device 1 for electric musical instruments made according to the invention is shown.

The filter device 1 is adapted to be connected to an electric musical instrument to be operated by a musician in order to create particular effects in the sound produced by the instrument.

The filter device 1 is particularly suitable for being operated by a musician's foot, however it can be operated in any other desired way.

The filter device 1 comprises a body 2 on which control means 101 are provided, better described below, which can be operated by a user of said device to generate a command for modifying the sound generated by the instrument, and a signal transformation circuit. 100 adapted to modify the sound of the instrument and output a modified sound to the amplifier.

The control means 101 are operatively connected to the transformation circuit 100, so that the command generated by the control means 101 constitutes an input to the transformation circuit 100.

The device 1 also comprises feet 3, or other support means, associated with the body 2 and arranged to rest the device 1 on a desired support surface, for example on the ground, or on the floor of a stage.

The body 2 is preferably made of metal and has the shape of a parallelepiped, in which an upper surface 4 can be identified which is able to be turned, in use, towards the user of the device 1, an opposite lower surface 5 to which the feet are associated 3, two opposite lateral surfaces 6, 7, a front surface 8 and an opposite rear surface 9.

The device 1 also comprises an input plug 10 by means of which the device 1 is connected, in use, by means of suitable connectors, to a musical instrument, for example an electric guitar whose sound is to be modified, creating desired effects. in the aforementioned sound produced. The connectors and the m usical tool are not shown in the Figures,

The device 1 also comprises an output plug 11 through which the device 1 is connected, in use, by means of suitable connectors, to an amplifier to amplify the modified sound produced by the device 1. The connectors and the amplifier are not shown in the Figures. The inlet 10 and outlet 11 plugs are preferably positioned respectively on the opposite side surfaces 6, 7 of the body 2 of the device 1.

The control means 101 comprise a selection portion 12 suitable for selecting the particular operating mode of the device 1, as better explained below, a control portion 15 by means of which the musician gives operating commands to the transformation circuit 100 of the device 1, in the way better explained below.

The selection portion 12, the control portion 15 being defined on the body 2, and in particular on its upper surface 4.

On the body 2 there is also identified a support portion 13, also made preferably of metal material, and suitable to receive in use a part of the heel of the foot of the musician during the use of the device 1.

In this way, the musician rests the heel part of the foot on the support portion 13, moving the foot so that it interacts with the control zone and / or with the selection zone, as better explained below.

In the embodiment shown, the control portion 15 is interposed between the selection portion 12 and the support portion 13, the latter being preferably contiguous to the control portion 15. In particular, the support portion 13 is provided by the part of the rear surface 9 of the body 2, while on the contrary the selection portion 12 is provided on the part of the front surface 8 of the body 2. As can be seen in particular from Figures 3 and 4, the control portion 15 and the resting portion 13 of the device 1 are shaped so that their respective upper surfaces 15a, 13a, or those facing in use towards the user, are positioned at almost the same height, or are almost coplanar.

This greatly improves the comfort of use of the device 1, greatly increasing it with respect to conventional known wahs.

In fact, this conformation minimizes the tension exerted on the joints of the musician's foot, in particular on the ankle if the device is operated with the foot, as usually happens.

This greatly reduces the fatigue associated with the use of the device according to the invention compared to known filter devices for musical instruments.

The selection portion 12 comprises a first and a second selection button 14, 16 operatively connected to a selection circuit 30 provided inside the body 2 to generate a selection command respectively of a first and a second operating mode of the device 1.

The first and second operating modes of the device 1 are respectively related to the lower and upper octave of the notes generated by the instrument to which the device 1 is connected.

When, for example, the first operating mode is selected, device 1 is suitable for modifying the notes emitted in one of the two octaves, for example in the lower octave, while when the second operating mode is selected, device 1 is adapted to modify the notes emitted in the other octave, for example in the upper octave.

This allows you to use device 1 to modify notes belonging to both the first and second octave of the electric guitar. The first and second selection buttons 14, 16 are movable between an inserted position, not shown in the Figures, in which the selection buttons 14, 16 are partially inserted in a respective seat 14a, 16a inside the body 2, and a position extracted, shown in Figures 2 - 4, in which the selection buttons 14, 16 protrude from their respective seat 14a, 16a.

In the inserted position, an edge portion 14b, 16b of each selection button 14, 16 abuts with a respective abutment element 14c, 16c provided on the upper surface 4 of the body 2.

Bringing the first selection button 14 and, respectively, the second selection button 16 to the respective inserted position, an operating mode selection command is generated, suitable for alternately activating / deactivating the operating mode of the device 1 corresponding to the selection button 14 , 16 which was eventful.

After having given the above operating mode selection command, the selection button 14, 16 automatically returns to the extracted position.

The first and second selection selection buttons 14, 16 deactivate each other, or by activating one operating mode, the other previously active is automatically deactivated,

Therefore the device 1 can operate alternatively in the first or second operating mode, or be effective in modifying a sound belonging alternatively to the first or second octave. It is also possible, by suitably moving the first and / or second selection button 14, 16, to deactivate both operating modes of the device 1, or to deactivate the device 1. In this configuration, device 1 does not affect the sound produced by the instrument to which device 1 is connected.

Therefore, the sound emitted by the instrument comes out of the device 1 and reaches the amplifier to which the device 1 is connected, as it was generated by the instrument, without having suffered any influence from the device 1.

The conformation of the device 1 according to the invention allows to generate, in the aforementioned deactivation configuration, a mechanical contact between the input pin 10 and the output pin 11 which isolates the transformation circuit 100 of the signal provided inside the body 2 of the device and predisposed to process the sound in its path through the device 1.

In this way, the sound emitted by the instrument is only transported from the instrument to the amplifier through the device 1 without suffering any signal loss.

The device 1 acts, in this case, solely as a by-pass of the sound between the instrument and the amplifier.

By varying the operating modes of the device 1, by means of the selection buttons 14, 16, the octave on which the device 1 acts is varied, as mentioned, and the operating parameters of the device 1 are varied, and, therefore, the sound is changed. obtained with device 1.

As can be seen from the comparison between the graphs presented respectively in Figures 7a-7d and 8a-8d, in the two operating modes the minimum and maximum frequency range of the sound produced by the instrument between which the device 1 operates, i.e. resonant frequency of the device and, consequently, the frequency of the sound emitted by the device 1.

The graphs of Figures 7a-7d and 8a-8d are semi-logarithmic, the frequency in Hz is shown on the abscissa axis, while the gain expressed in dB is shown on the ordinate axis, i.e. y = 10 <*> Log10 (Vout / Vin ). In the first operating mode, Figures 7a-7d, the device 1 operates in the first octave, ie between a minimum frequency n1 equal to about 270 Flz and a maximum frequency n2 equal to about 1600 Flz. ; In the second operating mode, Figures 8a-8d, the device 1 operates in the second octave, i.e. between a minimum frequency n3 equal to about 420 Hz and a maximum frequency n4 equal to about 2300 k. ; Therefore, it is as if two distinct filters were present inside the device 1, each suitable for modifying sounds with notes belonging to one of the two different octaves which can be selected alternatively by means of the selection buttons 14, 16.; This allows to optimize the operation of the device 1 in the two distinct modes of operation, and thus obtain an effective modification of the notes emitted by the instrument both in the first and in the second octave. The optimization of each of the two operating modes can be performed independently of each other, further improving the operation of the device 1 in both operating modes. ; A respective selection LED 17, 18 is operatively connected to each of the first and second selection buttons 14, 16, as indicated by the arrow F1 in Figure 6. Each of the two selection LEDs 17, 18 lights up when the corresponding selection button selection 14, 16 has been activated, i.e. when the device 1 operates in the corresponding operating mode, so as to signal the current operating mode of the device 1. ; If none of the operating modes are activated, i.e. when the device 1 acts as a by-pass for the sound of the instrument, both LEDs 17, 18 are off. ; The first and second selection buttons 14, 16 are also operationally connected to a selection microcontroller 19 which receives the selection signal 19a, effected through the first and second selection buttons 14, 16 respectively and correspondingly emits a command designed to select one, or none, of the two operating modes of device 1.; The selection microcontroller 19 emits, according to the operating mode set for device 1 by means of the first or second selection button 14, 16, an operating mode management signal 19b, which is fed to the processing circuit 30 provided inside the body 2 of the device 1 and arranged to process, as is said in the jargon, the sound produced by the instrument; the operating parameters of each of the two operating modes can be set by the user by means of adjustment means 41 which are preferably provided s on the body 2 of the device 1 so as to be accessible from the outside, for greater ease of use, in order to optimize, as mentioned, the operation of the device 1 in both modes of operation provided. In the embodiment shown, four distinct adjustment means 41 a-41 d are provided which are adapted to regulate respectively the resonance and the volume of the first and second operating modes. ; The adjustment means 41 a-41 d comprise a respective screw which is rotated from the outside by the user to adjust the resonance and the volume of the operating modes of the device 1, as better explained below. ; In this way it is possible to separately adjust the resonance and the input for both operating modes of the device 1. This allows, as mentioned, to optimize the operation of the device 1 in both modes of operation, that is, for a sound belonging to both the first and second octave. ; By acting on the adjustment means 41 a-41 d, an adjustment signal 41 is generated and depends on the resonance and linearity set for each of the two operating modes of the device 1, which is fed to the processing circuit 30, as better explained in following. The control zone 15 of the device 1 comprises a plate 26 positioned on an upper portion of the body 2, shaped, as mentioned, so that its upper surface 15a is positioned at almost the same height as the supporting surface 13a. ; The plate 26 is operatively connected to the signal transformation circuit 100, so as to modify the sound emitted by the instrument connected to the device 1.; The plate 26, made of metallic material, possibly AISI 304 steel, acts as an antenna of a signal command given by the musician to the device 1. The plate 26 is a proximity sensor which is activated by the musician according to the distance of a part of the body, preferably the foot, of the player himself from the plate 26. In the embodiment shown, between the plate 26 and the body 2 of the device 1 there is interposed a plate made of dielectric material 35 suitable for improving the operation of the plate 26 as a proximity sensor. By varying the distance of the musician's foot from the plate 26, a different command signal 23 is generated, produced by the plate 26 and imparted to microcontroller means 20 of the transformation circuit 100, provided inside the body 2, to which the plate 26 is operatively connected . With the other operating conditions of the device 1 being equal, the command imparted to the plate 26 varies between a maximum value, when the foot is resting on the plate 26, to a minimum value when the foot is at the maximum distance from the plate 26. by maximum distance means that beyond which the foot is not capable of generating any command on the plate 26, ie by further moving the foot away from the plate 26 after the maximum distance, no command is generated on the plate 26 itself. By varying the distance of the foot from the plate 26, the command signal 23 emitted and, therefore, the modification of the sound obtained by the device 1 varies. As indicated by the arrow F2 in Figure 6, LED devices 21 or other lighting means are operatively associated with the plate 26, shaped in such a way as to vary the intensity of the lighting generated as the distance of the musician's foot from the plate 26 varies. , and, therefore, of the signal generated by the plate 26 and fed to the microcontroller means 22.; The LED devices 21 can be shaped, for example, to increase the intensity of the illumination as the distance of the foot from the plate decreases 26, or vice versa. ; In both cases, through the LED devices 21 an indication of the level of use and modification of the sound by the device 1 is provided. ; The LED devices 21 also make it possible to improve the use of device 1, as in low-light environments such as concerts, they facilitate the identification of device 1 by the musician who must use it. This also makes it possible to improve the positioning of the foot with respect to the plate 26 and, therefore, the precision of actuation of the device 1 itself by the musician. ; The microcontroller means 20 comprise a plurality of microcontrollers 22, in the embodiment shown four microcontrollers 22 are provided.; The microcontroller means 20 receive the command signal 23 coming from the plate 26, which, as said, depends on the distance of the musician's foot from the plate 26 and decode this command signal 23, taking into account other operating parameters of the device 1, as better explained below, by emitting an electronic signal 27 for managing the sound. ; The electronic signal 27 generated by the microcontroller means 20 also depends on other operating parameters of the device 1 which can be set by the user through the control means 101, for example on the sensitivity and / or linearity of the plate 26.; A for this purpose, the control means 101 comprise a sensitivity regulator 42 provided on the body 2 of the device 1, and arranged to set the sensitivity of the plate 26, generating a consequent sensitivity signal 25 which is fed to the microprocessor means 20.; control devices 101 also comprise a linearity regulator 43, provided on the body 2 of the device 1, and arranged to set the linearity of the plate 26, generating a consequent linearity signal 24 which is fed to the microprocessor means 20. The linearity serves to correctly move the peak of the device 1 according to the movements of the foot with respect to the plate 26.; Varying the sensitivity and the linearity of the device 1 changes the final effect in the sound produced with the device 1 itself, other quantities being equal. Therefore, the microcontroller means 20, as shown in Figure 5, are processed: the command signal 23 coming from the plate 26, the sensitivity signal 25 and the linearity signal 24 of the plate 26. Inside the box-shaped body 2, the device 1 comprises, as mentioned, the transformation circuit 100 suitable for suitably transforming the signal generated by the instrument connected to the device 1, the operation of which is explained below with particular reference to Figure 6.; The transformation circuit 100 comprises the means the microcontroller 20, the processing circuit 30 and the selection circuit 36. The microcontroller means 20 processes the command signal 23 coming from the plate 26, the sensitivity signal 25 and the linearity signal 24 of the plate 26 respectively coming from the sensitivity regulator 42 and linearity regulator 43. The signals 23-25 are processed by the controller means 20 which produce an electronic sound management signal 27 which is sent to an optical module 28.; The optical module 28 receives the management signal 27 coming from the microcontroller means 22 and transforms it into a command signal 29 of the device 1 which is sent to the processing circuit 30. The processing circuit 30 comprises a valve device provided with a valve 31 of the analog type, preferably a thermionic valve, and a selection circuit 36 suitable for selecting the two operating modes of the device 1.; processing circuit 30 is a valve device which allows to modify the sound signal coming from the instrument connected to the device 1 through the input pin 10.; The presence of the thermionic valve allows to considerably increase the performance of the device 1 compared to known filter devices . ; The thermionic valve allows you to improve the timbre of the sound transformed by the device 1. The thermionic valve also allows to increase the dynamics of the response of the filter 1, considerably improving it with respect to known filter devices. ; The control signal 29 emitted by the optical module 28, the sound signal 30a emitted by the musical instrument through the input pin 10, signals for regulating the operating modes 41 and, entered by means of the control means, are supplied to the processing circuit 30. 41 a-41 d and the operating mode selection signal 19b emitted by means of the microcontroller 19.; On the basis of the aforementioned input signals 29, 30a, 41 and, 19b, the processing circuit 30 emits a modified sound signal 32 adapted to suitably modify the sound emitted by the instrument which is brought in output, through the output pin 1 1, to an amplifier that emits the sound modified by the device 1.; We see how the input signals 29, 30a, 41 and , 19b to the processing circuit 30 are independently variable from each other. ; By varying one or more of the aforementioned signals, the response of the device 1 varies and, therefore, the sound brought to the amplifier. ; The sound effects that can therefore be generated using the device 1 are many and can change from time to time in the various performances even of the same piece of music. ; The graphs of Figures 7a-7d and 8a-8d show the frequency response of the device 1 in the first (Fig.7a-7d) and, respectively, in the second (Fig.8a-8d) operating mode as the settings vary of the device. ; The aforementioned graphs are semi-logarithmic, the frequency in Hz is shown in the abscissa axis, while the gain expressed in dB is shown in the ordinate axis, i.e. y = 10 * Log10 (Vout / Vin).

With particular reference to Figures 7a-7b, the variation of the response of the device 1 is shown as the distance of the musician's foot from the plate 26 varies, with a resonance value set by means of the screw 41 a, respectively minimum (Fig. 7a) and maximum. (Fig.7b).

When the foot rests on the plate 26, the response of the device 1 is represented by the curve 50 (Fig. 7a) and 51 (Fig. 7b).

By moving the foot away from the plate 26, the curve representing the response of the device 1 varies, and when the foot is at the maximum distance from the plate 26, beyond which the foot does not generate any command signal on the plate 26, the response of the device 1 it is represented by the curve 52 (Fig. 7a) and 53 (Fig. 7b), instead.

Similarly, with regard to the second operating mode, when the resonance value, set by means of the screw 41 c, is at a minimum, with the foot resting on the plate 26 the response of the device 1 is represented by the curve 50 '(Fig. 8a), while with the foot at the maximum distance from the plate 26, the response of the device 1 is represented by the curve 52 '.

When, on the other hand, the resonance value is set to maximum, with the foot resting on the plate 26, the response of the device 1 is represented by the curve 51 '(Fig.8b), while with the foot at the maximum distance from the plate 26, the response of device 1 is represented by curve 53 '.

The graphs of Figures 7c-7d show the variation of the frequency response of the device 1 in the first operating mode of the device 1 as the resonance of the device 1 varies, which is modified by acting on the adjustment means 41 a, respectively with the foot resting on the plate 26 and with the foot at the maximum distance from plate 26.

When the resonance is set to the minimum, for example the screw 41 a is turned completely to the left, the response curve of the device 1 is represented by the curve 60 and 61, respectively in Figure 7c and 7d, increasing the resonance, i.e. by rotating the screw 41 a to the right, the response curve of the device moves until it reaches when the resonance is maximum, i.e. the screw 41 a is turned completely to the right, respectively the curve 62 and 63.

Similarly, in the second operating mode of the device 1, by varying the resonance of the device 1 and keeping the foot on the plate 26, the response curves of Figure 8c are obtained, while keeping the foot at the maximum distance from the plate and varying the resonance of the device 1 , the response curves of Figure 8d are obtained.

Keeping the foot on the plate 26, when the screw 41 c is turned completely to the left, i.e. resonance set to minimum, the response curve of the device 1 is represented by the curve 60 ', increasing the resonance, i.e. turning the screw 41 c to the right , the response curve of the device moves until it reaches the curve 62 'when the resonance is maximum, that is, the screw 41 c is turned completely to the right.

By keeping the foot at the maximum distance from the plate 26, beyond which the foot does not generate any command signal on the plate 26, with resonance set to the minimum, the response curve of the device 1 is represented by the curve 61 ', increasing the resonance, that is, by turning the screw 41 c to the right, the response curve of the device moves until it reaches the curve 63 'when the resonance is maximum, that is, the screw 41 c is turned completely to the right.

The control of the resonance of the device 1 both in the first and in the second operating mode is linear, and not jerky, ie there is a fine and precise adjustment throughout the resonance range.

The valve 31 of the processing circuit 30 is housed inside a seat 33 provided in the body 2, almost in correspondence with the support portion 13.

The seat 33 is externally delimited by the support portion 13 and by the rear surface 9 of the body 2.

Corresponding to the rear surface 9 there is a closure element 9a fixed in a removable manner, by means of screws 9b, to the rear surface 9.

In this way the seat 33 and, therefore, the valve 31, are immediately and easily accessible from the outside.

Therefore to change or replace the valve 31 it is not necessary to disassemble the whole body 2, but only to unscrew the two screws 9b and access the seat 33.

The device 1 also comprises a power supply plug 34 adapted to be connected to a power supply voltage 12/24 Volts, both in DC and in AC to allow the device 1 to be powered and recharged. The power plug 34 is preferably provided on the front surface 8 of the device 1.

This allows the device 1 to be used with a common power supply for low consumption appliances such as those widely available on the market.

The pin 34 is operatively connected to a power supply system 37 provided inside the body 2 of the device 1 which receives a 12/24 V direct or alternating power supply voltage and which produces a 12 V stabilized direct power supply voltage for the filaments of the valve 31 220 V for the anode voltage of valve 31, as indicated by arrow F3 in Figure 6.

In operation, the musician connects the device 1 to the chosen musical instrument and to an amplifier, respectively through the input plug 10 and the output plug 1 1.

Subsequently it sets the operating parameters of the device 1, for example linearity and / or sensitivity of the plate, by acting on the respective control means 101, for example, therefore, respectively on the linearity 43 and sensitivity 42 regulator.

The dealer also adjusts the adjustment parameters of the two operating modes of the device 1 by acting on the adjustment means 41.

The musician can also select, through the first or second selection button 14, 16, the type of operating mode desired for the device 1, this selection can be easily varied even while using the instrument.

Subsequently, by playing the instrument connected to the device 1 and, by suitably moving the foot in proximity to the plate 26, a command is generated to the transformation circuit which is suitably processed as seen above and which allows the sound generated by the device 1 to be transformed. instrument.

A certain desired effect is therefore generated in the sound produced by the instrument which is transported from the device 1 to the amplifier and reproduced in the air.

In this way, the instrument emits a different sound from the “classic” one produced by the instrument. In addition, the musician can vary the sound emitted with the instrument at his discretion, either by moving the foot at his discretion or by varying the operating parameters of the device 1.

As mentioned, the effect generated by the device 1 on the sound produced by the instrument varies both by moving the foot with respect to the plate, and by varying the linearity and / or sensitivity of the plate 26, and also by varying the adjustment parameters of the operating modes.

In addition, the operating mode can also be changed during execution.

In addition, the device 1 can also be positioned in the bypass mode, avoiding any effect on the sound generated by the instrument, which is reproduced by the amplifier as generated by the instrument.

The possibilities for customizing the use of an instrument and / or the performance of a piece are therefore numerous.

To operate the device 1, i.e. to interact with the plate 26, the m usicist places the rear part of the foot, the heel, on the support portion 13 and moves the front part of the foot, the toe, with respect to the plate 26, so that to generate a certain command to device 1.

By resting the heel on the upper surface 13a of the support portion 13, this being almost at the same level as the plate 26, the fatigue generated on the joints of the mechanic for the use of the device 1 is particularly reduced.

Therefore, a high precision of movement of the foot is maintained, and, consequently, a high sensitivity for controlling the device 1 and modifying the sound.

In addition, the presence and position of the selection buttons 14, 16 on the selection area 12, allows you to vary the operating mode of the device 1 even during use. In fact, these buttons can be pressed 14, 16 with the front part of the foot, thus varying the operating mode of the device 1 and / or deactivating it.

Therefore, with the device of the invention, the different effects that the musician can generate during the sound of the instrument are considerably increased.

Although the device object of the invention has been described with particular reference to its use for electric guitars, it can be used to modify the sound of other electric musical instruments, for example keyboards, clavinets, trumpets, brass instruments in particular for use in jazz music. , DJ plates, electric violins, etc ...

Claims (10)

RESELL CAZI ONI 1. Filter device (1) for electric musical instruments able to be operatively interposed between a musical instrument and an amplifier of said instrument by means of respective connection means (10, 1 1) provided on a box-like body (2) of said device for modify a sound generated by said instrument, comprising a box-like body (2) on which a control portion (15, 15a, 26) is defined, provided with a proximity sensor (26) which can be operated by a user of said device to generate a command (23) for modifying the sound generated by said instrument, and a signal transformation circuit (100) for modifying said sound and emitting a modified sound signal (32) to said amplifier, said proximity sensor (26) being operatively connected to said transformation circuit (100) so that said command (23) constitutes an input to said transformation circuit (100), said box-like body (2) further comprising a support portion (13, 13a) suitable for receiving a portion of the body of said user, in which said support portion (13, 13a) and said control portion (15, 15a, 26) being shaped so that respective surfaces external (13a, 15a) suitable to be turned towards a user are practically coplanar with each other. 2. Device according to the preceding claim, and further comprising selection means (14, 16) provided on said box-like body (2), operatively connected to a selection circuit (30) to select an operating mode of said device in which said device is suitable for modifying a sound produced by said instrument belonging to a desired frequency range. 3. Device according to the preceding claim, wherein said selection means (14, 16) are shaped so as to make a contact between an input pin (10) and an output pin (11) of said sound to isolate said sound transformation circuit (100) to bypass said device so as not to modify said emitted sound. Device according to one of the preceding claims, wherein said transformation circuit (100) comprises a processing circuit (30) for modifying said sound on the basis of input commands to said circuit provided with thermionic valve means (31) for processing said sound. 5. Device according to one of the preceding claims and comprising adjustment means (101) for adjusting the operating parameters of said device. 6. Device according to the preceding claim, wherein said adjustment means comprise resonance adjustment means for said device, linearity adjustment means (41) for said sensor (26), sensitivity adjustment means (41) for said sensor (26), to adjust the sound emitted by said device. 7. Device according to one of the preceding claims and comprising a plug (34) for connecting said device to an electrical power supply network shaped so as to be able to be connected to a 12/24 Volts network both in DC and in AC. 8. Device according to the preceding claim, and further comprising a power supply circuit (37) provided inside said box-like body (2), interposed between said pin (34) and said processing circuit (30), and arranged to stabilize said supply voltage suitably for said valve (31). Musical instrument comprising a filter device according to one of the preceding claims. 10. An instrument according to the preceding claim, wherein said instrument is selected from a group comprising electric guitars, keyboards, clavinets, trumpets, brass instruments in particular for use in jazz music, DJ plates, electric violins, etc.