JPH05224673A - Electronic stringed musical instrument - Google Patents

Abstract

PURPOSE:To delicately vary timbre corresponding to the position of pizzicato operation of a string by pressing a pizzicato operation position detection part at the time of the pizzicato operation and setting musical sound characteristics according to a detected pizzicato operation position. CONSTITUTION:The pizzicato operation position detection part provided on the body part of the electronic musical instrument constitutes a pizzicato position detecting circuit 110, and a specific resistance value detected by this circuit 110 is picked up as an analog value indicating the pizzicato operation position and converted into a digital value, which is outputted to a CPU 20. A foot switch group GSW an a panel switch group PSW are connected to a switch status detecting circuit 30 respectively, and a string trigger switch group TSW is connected to a latch circuit 95 connected to the CPU 20. Then, when the string trigger switch TSW is put in the pizzicato operation, the musical sound corresponding to the depressed foot switch FSW is generated. At this time, the pizzicato operation position detection part is depressed and musical sound characteristics are set according to the pizzicato operation position detected from the depression position.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic stringed instrument, and more particularly to a stringed instrument having a fret, such as a guitar, even if the strings are picked at the same fret operating position during playing, the string is picked up according to the picked position. ,
The present invention relates to an electronic stringed instrument capable of subtly changing the characteristics of a generated musical sound.

[0002]

2. Description of the Related Art In recent years, with the rapid development of electronic technology,
Electronic string instruments capable of producing a wide variety of tones by picking operations similar to those of traditional natural string instruments (acoustic guitar, etc.) have been developed. As an electronic stringed instrument of this kind, the pitch designation operation state sensing unit provided on the fingerboard side senses the fret position of the string currently being pressed and designates the musical tone of the corresponding pitch, while The string trigger detection unit provided in the unit detects the picking operation state for the string, and the string trigger detection unit provides a musical sound of a predetermined tone with the pitch specified by the pitch specified operation state detection unit. There is a string trigger type electronic string instrument that produces the pronunciation of. The advantage of this string trigger type electronic stringed instrument is that its simplified structure, that is, the string trigger sensing unit senses the start of string vibration, sounds a musical tone in response to this, and generates a pitch-specified operation state sensing means. It has a simple structure in which the pitch of the musical tone to be generated is determined by the pitch designation signal from.

By the way, in a so-called raw guitar (acoustic guitar) or the like having a resonance plate in the instrument body, when strings are pressed at the same fret (fingerboard) position, the strings are bridged even if the picking strength is the same. (Fixed part of the string)
Picking near the side produces a hard tone, and conversely picking near the fret produces a soft tone. In this way, when the strings are picked up, the tones with a hard tone that are emitted when the strings are picked up are picked up by the pickup, and when picked up on the bridge side, as shown in Fig. 8 (a). This is because the peak value a ₀ at the first pitch period has a waveform characteristic that is more prominent than the next peak value a ₁ . In addition, the soft tone generated when picking a string has a peak sound as shown in Fig. 8 (b) when picking up the string vibration when picking the string with a pickup. Value a
_{This is because 0} and the next peak value a ₁ become almost the same value.

In a conventional guitar or the like, the signal strength at the time of picking a string is detected, and the musical tone generating circuit generates a musical tone whose volume and tone color are changed corresponding to the signal intensity. As described above, since the conventional guitar or the like changes the tone volume and tone color with only one parameter, for example, when the input waveform signal changes and the tone volume increases, the tone color becomes hard at the same time. It was always changing with correlation.

[0005]

However, a finger having at least one string stretched on the fingerboard of the conventional musical instrument body and having a plurality of frets below the string in the direction of the upper string of the musical instrument body. There is an electronic string instrument of a type in which a fret state detecting means for detecting a fret state is arranged between the frets on the board, and a musical tone is generated at a pitch corresponding to a fret operation position detected by the fret state detecting means. For example, even if the picking operation is performed while shifting the string playing position, it is not possible to control the volume and timbre separately, and there is the problem that a rich playing effect cannot be obtained. Was there.

The present invention has been made in view of the above problems of the prior art. An object of the present invention is to pick a string in a stringed instrument such as a guitar at the same fret position during playing. if you did this,
An object of the present invention is to provide an electronic stringed instrument capable of subtly changing the characteristics of a generated musical sound according to the picking operation position.

[0007]

In order to achieve the above object, an electronic stringed instrument according to the present invention has a string operation detecting means for detecting a string operation and a fret state detecting means for detecting a fret operation state. Pitch setting means for setting the pitch of a musical tone based on the fret state, and a string operation position detecting means for detecting a position at which the string operation is performed,
Musical sound characteristic setting means for setting a musical sound characteristic based on the string operation position detected by the string operation position detecting means, a pitch set by the pitch setting means, and a musical sound set by the musical sound characteristic setting means. It is characterized in that it has a musical tone generating means for generating a musical tone having a characteristic in response to a string operation detected by the string operation detecting means.

The string position detecting means may detect the string operation position by sensing a pressing operation position corresponding to the string operation position.

Further, the musical tone generating means sets the wave height of the musical tone generated in response to the string operation detected by the string operation detecting means at the pitch set by the pitch setting means to the tone characteristic setting means. It is also possible to generate a musical tone that is modulated based on the musical tone characteristic set by.

[0010]

In the electronic stringed instrument constructed as described above, when a finger presses the string between the frets, the fret state sensing means detects the fret operation position corresponding to the pressed part.

On the other hand, a hand for picking the string operation position detecting means of the tone operation control device capable of changing the tone of the tone signal generated by the string operation of the tone operation control device provided on the body of the musical instrument body. Press the finger to determine the musical sound operation position.

In this state, when an operation such as plucking a string or plucking a finger is performed, a musical tone corresponding to the pressed portion of the string operation position detecting means starts to sound. When the position where the strings are picked is slid in the stringing direction from this state, the pressing portion of the string operation position detecting means of the musical tone operation control device which is pressed by the finger changes. Corresponding to the change in the pressed part, the part of the string operation position detecting means sensitive to the pressing of the finger changes. This change state is detected by the string pressing position change detecting means. The change in the sensitive state of the string-pressing position change detecting means is, for example, a peak value change. That is, the peak value is modulated in the (+) or (-) direction from the musical sound wave peak value of the basic string-pitch position change detecting means. In this way, when the chopping position of a string is changed along the stringing direction during a performance, the subtle pitch changes caused by the change along the stringing direction of the string are more subtly similar to those of a traditional stringed instrument. Can be held by Of course, changes in the sensitive state of the fret state sensing means may be reflected in parameters other than the pitch. That is,
By reflecting the tone color, the volume, the effect, and other parameters, it is possible to take a performance form different from that of the natural musical instrument.

[0013]

EXAMPLES Examples of the present invention will be described below. FIG. 1 shows the entire appearance of an electronic stringed instrument according to the present invention. In the figure, an electronic stringed instrument 1 has the shape of a guitar composed of a body 2, a neck 3, and a head 4. A plurality of strings 5 for playing a stringed instrument are stretched in the same direction as the neck 3. In addition, the body 2 has a parameter switch 6 for setting various parameters.
And a speaker 90 for emitting a musical sound. One end of the string 5 is supported by a peg 8 provided on the head 4 so that the tension can be adjusted, and the other end of the string 5 extends on a fingerboard 9 formed with the upper surface of the neck 3 to extend to the body 2. It is fixed in a certain string trigger switch section 7. Further, the fingerboard 9 is provided with a fret switch FSW, which is a fret state sensing means, at a position between the frets corresponding to one string. The fret switch FSW forms a string-press position switch array. This fret switch FS
W is arranged along the stringing direction of the strings 5, and the frets 10 provided on the upper surface of the fingerboard 9 in the stringing direction.
By pressing the string 5 between and pressing the string 5 against the upper surface of the fingerboard 9, the corresponding fret switch F
It is configured so that the SW is turned on. In addition, inside the string trigger switch unit 7, the string trigger switch TSW
The string trigger switch TSW is turned on by performing an operation such as striking the string 5 connected to the string trigger switch TSW, and plucking the claw 5 with the string trigger switch TSW. There is. Also,
On the surface where the string 5 of the body 2 of the electronic stringed instrument 1 is stretched,
A pick guard 11 is attached. The pick guard 11 protects the body portion 2 of the electronic string instrument 1 from being damaged by a nail or the like during picking. A string 5 is stretched above the pick guard 11. A groove 12 is provided in the vicinity of the string 5 along the string 5 on which the pickguard 11 is stretched, and the string 12 is provided with a string operation position detector 13 of the musical tone operation control device. The position where the string operation position detecting section 13 of this musical sound operation control device is provided is usually attached to the pickup guard for the player to fix his right hand during picking, and the little finger or ring finger to support is naturally located. It is a place.

The string operation position detecting section 13 of the musical tone operation control device is provided in the body section 2 of the electronic string instrument 1 as shown in FIG. That is, the body 2 of the electronic stringed instrument 1 is provided with a casing 14 for accommodating the string operation position detection unit 13 of the musical tone operation control device. This casing 14
Is formed in a box shape, and the string operation position detecting portion 13 is housed and fixed in the casing 14. A flange portion is formed on the casing 14, and a pick guard 11 is attached to the flange portion so as to fix the casing 14 to the body portion 2 from above. The pickguard 11 is provided with a groove 12 through which the string operation position detecting section 13 can be operated.

The string operation position detecting section 13 of the musical sound operation control device has a structure as shown in FIGS. That is, as shown in FIG. 2, a resistance plate 134 is fixed to the inner bottom surface of the casing 14, and the resistance plate 134 is fixed to the bottom surface.
A conductive rubber 133 is fixed on the top of the. A metal plate 132, which is a flexible conductive plate, is provided on the conductive rubber 133.
Is fixed, and a flexible makeup sheet 131 is coated on the metal plate 132. The conductive rubber 133 has a structure as shown in FIG. That is, in the conductive rubber 133, the insulating portions 1332 are provided in a grid shape, and the insulating portions 133 provided in the grid shape are provided.
Between the two, the conductive portion 13 made of conductive rubber
It is configured such that 31 does not come into contact with the metal plate 132 and the resistance plate 134, that is, the gaps 1333 and 1334 are provided and fixed to the insulating portions 1332. Therefore, the conductive rubber 133 has the conductive portions 1331 and the insulating portions 1332 alternately as shown in FIG. 3, and the surface of the conductive portion 1331 is slightly recessed, and the recess normally insulates the metal plate 132 and the resistance plate 134. There is. 2 and 3, when the finger 16 presses a part of the metal plate 132 from above via the sheet 131 with the finger 16, a part of the pressed metal plate 132 bends. Board 13
Part of 2 touches the lower resistance plate 134 and the conductive rubber 133,
Further, the metal plate 13 is inserted by the fingers 16 via the sheet 131.
When a pressure is applied to a part of 2, the conductive rubber 133 is pushed, the conductive rubber 133 contacts the resistance plate 134, and the metal plate 132
And the resistance plate 134 are electrically connected to each other via the conductive rubber 133.
Due to this conduction, the string operation position detection unit 13 constitutes a string operation position detection circuit 110 as shown in FIG. 4, and the predetermined resistance value detected by the detection circuit 110 is set to the string operation position. The analog value shown is taken out, and this analog value is converted into a digital value by the A / D converter 15 and output to the microcomputer.

In FIG. 5, the fret switch FSW,
The circuit configuration of an electronic stringed instrument having a panel switch PSW and the like is shown. In the figure, a CPU 20 is connected to a string operation position detection circuit 110 via an address bus 100. The string operation position detection circuit 110 has a configuration as shown in FIG. 4 and has a function of detecting the position where the player picks the string 5. Further, the CPU 20 is provided with a switch status detection circuit 30, a ROM 35, and an R via an address bus 25.
AM 40, LCD driver 45, tone generation circuit 50
Are connected. This switch status detection circuit 3
0, the ROM 35, the RAM 40, the LCD driver 45, and the musical tone generating circuit 50, the data bus 55
It is configured to be sent to the CPU 20 via the.
To the switch status detection circuit 30, a fret switch group FSW is connected via a bus line 60 and a panel switch group PSW is connected via a bus line 65. Further, an LCD display unit 75 is connected to the LCD driver 45 via a bus line 70. Further, the musical tone signal generated in the musical tone generating circuit 50 is emitted as a sound from the speaker 90 via the amplifier 80. A latch circuit 95 is connected to the CPU 20 via a bus line 85, and a string trigger switch group TSW is connected to the latch circuit 95 via a bus line 86.

Therefore, the ON input signal output from the string trigger switch TSW which is turned ON by striking the string or by striking the claw is first output by the latch circuit 95.
It is latched, and the CPU 20 detects the trigger of the string 5 through the latch circuit 95. Also, each switch state of the fret switch group FSW and the panel switch group PS
The input state of each switch of W (parameter setting switch 6 shown in FIG. 1) is input to the switch status detection circuit 30, and C is input via the switch status detection circuit 30.
It is taken into PU20. Further, the tone generation circuit 50
It is controlled by the CPU 20 and generates a tone signal corresponding to the tone specified by the CPU 20,
The generated tone signal is amplified by the amplifier 80 and is emitted to the outside through the speaker 90.

Next, the arithmetic processing of the CPU 20 shown in FIG. 5 will be described with reference to the processing flow chart shown in FIG. First, when the power is turned on, initialization processing is performed in step 200. This step 2
When the initialization processing is performed at 00, the information latched in the latch circuit 95 shown in FIG. 5 is read out at step 201, and the presence or absence of a trigger for all the strings 5 shown in FIG. It is determined whether or not the picking operation state is sensed as to whether or not there is a picking operation. When the triggered string of the strings 5 shown in FIG. 1 is detected in this step 201, the musical tone generating circuit 50 shown in FIG. 5 is controlled to generate a musical tone. Then, in step 202, fret state detection processing is performed. In the fret state detection processing in step 202, the CPU 20 reads the state of the switch group per string for each switch of the fret switch group FSW via the switch status detection circuit 30 shown in FIG. It is something that is processed. Next, in step 203, with respect to the so-called fret operation state indicating that the fret switch group FSW is ON, it is determined whether or not the current fret operation state has changed from the previous fret operation state, and in this step 203 If it is determined that the fret operation state has not changed from the previous fret operation state, the process proceeds to step 205. When it is determined in step 203 that the fret operation state has changed from the previous fret operation state, in step 204, the tone information change process, that is, the frequency is changed to a frequency corresponding to the change destination fret operation position. Is performed to the tone generation circuit 50, and the process proceeds to step 105. In addition,
When any of the fret switches FSW belonging to the string being sounded changes to the separated state, that is, the operation state of the so-called open string, the sound is muted. Further, nothing is done with respect to the change to the fret operation state for the fret switch FSW belonging to the string which is not currently sounded.

Next, at step 205, the state of each parameter setting switch of the panel switch group PSW shown in FIG.
The PU 20 reads it. Then, in step 206,
Panel switch group PS detected in step 205
It is determined whether or not the state of each W parameter setting switch has changed. If it is determined in step 206 that the state of each parameter setting switch of the panel switch group PSW has not changed, the process proceeds to step 208. Further, in this step 206, the panel switch group PS
When it is determined that the state of each W parameter setting switch has changed, in step 207, the panel switch state changing process is performed. The panel switch state change processing in step 207 is, for example, processing of tone color, modulation data, bend range, and LCD display. When the panel switch state change process is performed in step 207, a string operation position detection process is performed in step 208. This string operation position detection processing is performed by the finger 16 shown in FIG.
A part of the metal plate 132 is pressed from above via 31. The bending of the metal plate 132 causes the metal plate 132 and the resistance plate 1 to move.
34 detects the position where 34 is electrically connected through the conductive rubber 133. When the string operation position is detected in step 208, tone color control processing is performed in step 209.

This tone color control processing is performed, for example, as shown in FIG. That is, the scale data based on the pressed string position detected by the fret switch FSW provided between the frets is input to the address signal generation circuit 300, the input scale data is converted into a predetermined address value, and the waveform memory 310 is input. It This waveform memory 3
The waveform information 10 corresponding to each scale data is stored in advance and outputs a waveform corresponding to the input address signal. The waveform memory 310 includes a D / A converter 3
20 is connected to the D / A converter 320.
Converts the digital waveform signal output from the waveform memory 310 into an analog signal to convert the voltage-controlled filter VCF.
Output to 330. On the other hand, a part of the metal plate 132 is pressed from above by the finger 16 shown in FIG.
The string operation position data corresponding to the string operation position detected by electrically connecting the resistance plate 134 with the resistance plate 134 via the conductive rubber 133 is input to the D / A converter 340. This D / A
The converter 340 converts the string operation position data input as a digital signal into an analog signal and outputs it to the electronically controlled filter VCF 330. The analog signal of the string operation position data input to the voltage control type filter VCF 330 serves as an element for changing the musical sound. Therefore, this voltage control type filter VCF33
At 0, a filter is applied to change the tone to a desired tone color, and the tone of the corresponding tone color is generated from the speaker 90. In this embodiment, for example,
The degree of modulation inside the tone generation circuit 50 shown in FIG. 5 is controlled so that a hard sound is generated when the string operation position is close to the bridge and a soft sound is generated when the string operation position is close to the fret. However, in addition to this, the shape of the envelope waveform signal added to the output signal of the waveform memory (particularly the shape of the attack waveform portion) may be changed according to the string operation position to change the timbre content. Good.

In the above-described embodiment, the string 5 is stretched on the finger board 9, but it is not always necessary to dispose the string 5 on the finger board 9, and The strings 5 may be arranged only on the part 2 side. Further, in the above-described embodiment, the case where the plurality of frets 10 are formed on the fingerboard 9 at predetermined intervals along the longitudinal direction thereof has been described. ,
It is not necessary to form frets. Further, in the above-described embodiment, the musical tone of the pitch designated by each fret switch FSW is once sounded corresponding to the ON state of the string trigger switch TSW, and then the fret is generated. When the operation position is subtly changed, the frequency of the musical tone being currently sounded is changed according to the changed state. However, the frequency may not be after the string trigger switch TSW is turned on. Even if the string trigger switch TSW is not turned on, if you perform fret operation, you can only perform that fret operation and apply it to an electronic stringed instrument that produces a pitched tone corresponding to the operated fret position. If so, the pitch of the musical tone being sounded by the fret operation is subtly changed according to the subtle change in the fret operation position. Unishi may be. Furthermore, in the above-described embodiment, the case where the present invention is applied to an electronic stringed instrument of the type that produces a musical tone of a pitch designated by the fret switch FSW in response to the ON state of the string trigger switch TSW will be described. However, an electronic stringed instrument of various types other than an electronic stringed instrument of a type using the fret switch FSW and the string trigger switch TSW, for example, a fret that propagates ultrasonic waves to a string and makes contact with the string by fret operation. The present invention may also be applied to an ultrasonic type electronic stringed instrument (for example, the one described in Japanese Patent Laid-Open No. 62-99790) that measures the reflection time of ultrasonic waves from a position to specify the pitch.

[0022]

Since the present invention is configured as described above, when a string is picked at the same fret position during a performance, which is not possible with a conventional electronic stringed instrument, when the string is picked, the picking operation position is set. The musical tone characteristics can be subtly changed in response to this, and as a result, it is possible to perform a deep and detailed performance similar to an ordinary stringed instrument with subtle characteristic changes, further enhancing the use of electronic stringed instruments. It has the effect of being able to do so, and has the effects described below for each claim. The electronic stringed instrument according to claim 1 or 2, wherein the electronic stringed instrument comprises a plurality of pressed position detection switches which are arranged along the strings in the body of the musical instrument body and which are pressed by the fingers of the picking side of the strings. The string operation position detecting means detects the string operation position corresponding to the position at which the string is operated, and the tone generating means generates the characteristic of the tone according to the tone characteristic control signal corresponding to the string operation position. Therefore, the musical tone characteristics (for example, tone color) can be delicately changed according to the position of the string picking operation. In the electronic stringed instrument according to claim 3, the musical tone generating means modulates the wave height of the musical tone generated according to the string operating position detected by the string operating position detecting means. For example, it is possible to perform control so that a hard sound is produced when the string operation position changes toward the bridge, and a soft sound is produced when the string operation position changes toward the fret.

[Brief description of drawings]

FIG. 1 is an overall perspective view of an electronic stringed instrument according to an embodiment of the present invention.

FIG. 2 is an AA shown in FIG. 1 showing a string operation position detection device.
Sectional view.

3 is a partially enlarged view of the string operation position detecting device shown in FIG.

FIG. 4 is a diagram for explaining a detection method of the string operation position detection device shown in FIG.

5 is a drive block diagram of the electronic string instrument body shown in FIG. 1. FIG.

6 is an operation flowchart of the block diagram shown in FIG.

7 is a circuit diagram showing an embodiment of a string operation position detection circuit shown in FIG.

FIG. 8 is a diagram showing a difference in tone color depending on a picking operation position as a waveform signal.

[Explanation of symbols]

 1 Electronic String Instrument 2 Body 3 Neck 4 Head 5 String 6 Parameter Switch 7 String Trigger Switch 8 Peg 9 Fingerboard 10 Frets 11 Pickguard 12 Groove 13 String Operation Position Detector FSW Fret Switch

Claims (3)

[Claims] 1. A pitch operation detecting means for detecting a string operation, and a pitch setting means for setting a pitch of a musical tone based on the detected fret state by a fret state detecting means for detecting a fret operation state. A string operation position detecting means for detecting a position where the string operation is performed; a tone characteristic setting means for setting a tone characteristic based on the string operation position detected by the string operation position detecting means; Musical tone generating means for generating a musical tone having the pitch set by the high setting means and the musical tone characteristic set by the musical tone characteristic setting means in response to a string operation detected by the string operation detecting means. An electronic stringed instrument characterized by. 2. The electronic string according to claim 1, wherein the string position detecting means detects the string operation position by sensing a pressing operation position corresponding to the string operation position. Stringed instrument. 3. The musical tone generating means sets the pitch of a musical tone generated in response to a string operation detected by the string operation detecting means at the pitch set by the pitch setting means, to the musical tone characteristic setting means. 3. The electronic stringed instrument according to claim 1, wherein a musical tone modulated based on the musical tone characteristic set by is generated.