JP7006729B2 - An electronic musical instrument having a musical tone generation instruction device, a musical tone generation instruction method, a program for the musical tone generation instruction device, and a musical tone generation instruction device. - Google Patents

Description

The present invention relates to an electronic musical instrument having a musical sound generation instruction device, a musical sound generation instruction method, a program for the musical sound generation instruction device, and a musical sound generation instruction device.

Conventionally, an electronic musical instrument is provided with a plurality of pads, and based on the output of a sensor that detects a pad operation in which a performer presses each pad, a sound corresponding to the type of pad on which the pad operation is performed is generated. There is something configured. Various methods have been proposed as a method for realizing velocity detection of a drum pad in an electronic musical instrument.

Further, in this type of electronic musical instrument, a technique is disclosed in which a striking mode of a striking applied to a striking surface of a pad is detected and the presence or absence of a roll playing method is determined according to the detected striking mode (for example, Patent Document). 1 and Patent Document 2).

Japanese Unexamined Patent Publication No. 2006-30476 Japanese Unexamined Patent Publication No. 6-118946

However, there is a problem that no conventional electronic musical instrument realizes the aftertouch function of the pad. Here, the aftertouch means an operation of pressing the pad once and then pushing it further, and the aftertouch function means a function of outputting a sound corresponding to the aftertouch operation.

The present invention has been made in view of the above problems, and is a musical sound generation instruction device capable of realizing an after-touch function in a pad or the like, a musical sound generation instruction method, a program for a musical sound generation instruction device, and a musical sound generation. It is an object of the present invention to provide an electronic musical instrument having an instruction device.

In order to solve the above problems, the musical tone generation instruction device of the present invention is generated in response to a storage unit that stores waveform data for generating a musical tone corresponding to the operation unit and a pressing operation on the operation unit. With the first process of producing a musical tone having a volume corresponding to the maximum value detected between the time when the level of the pressing signal exceeds the first threshold value and the time when the first time elapses, based on the waveform data. After instructing the sounding of the musical tone by the first processing, when the state where the level of the pressing signal is higher than the second threshold value continues for the second time or more, the pressing signal with respect to the musical sound being pronounced. It has a second process for imparting an after-touch effect according to a change in the level of the above, and a processing unit for executing the second process.

According to the present invention, it is possible to provide an electronic musical instrument having a musical sound generation instruction device, a musical sound generation instruction method, a program for the musical sound generation instruction device, and a musical sound generation instruction device capable of realizing an after-touch function in a pad or the like. ..

It is a front view of the keyboard instrument provided with the electronic musical instrument of embodiment which concerns on this invention. It is a block diagram which shows the structure of the electronic musical instrument of this embodiment. It is sectional drawing which shows the structure of the pad in this embodiment. It is an exploded view which shows the structure of the pad in this embodiment. It is a flowchart which shows the operation of the electronic musical instrument in this embodiment. It is a flowchart which shows the flow when changing the setting contents of an effect time. It is a figure explaining the operation of the electronic musical instrument in this embodiment.

Hereinafter, embodiments for carrying out the present invention (hereinafter referred to as embodiments) will be described in detail with reference to the accompanying drawings. In the drawings, the same elements are numbered or coded the same throughout the description of the embodiments.

<Composition of electronic musical instruments>
The configuration of the electronic musical instrument of the embodiment according to the present invention will be described with reference to FIGS. 1 to 4. FIG. 1 is a front view of a keyboard instrument including the electronic musical instrument according to the embodiment of the present invention. FIG. 2 is a block diagram showing the configuration of the electronic musical instrument of the present embodiment. FIG. 3 is a cross-sectional view showing the structure of the pad in the present embodiment. FIG. 4 is an exploded view showing the structure of the pad in this embodiment.

As shown in FIG. 1, the electronic musical instrument MI of the embodiment according to the present invention is provided in a part of the keyboard instrument, and by pressing (pressing) the pad 11 of the operation unit 1 (see FIG. 2), the electronic musical instrument MI is provided. This is an electronic musical instrument MI that produces a sound corresponding to the pad 11. However, it does not have to be integrally provided with the keyboard instrument, and may be an electronic musical instrument consisting only of the electronic musical instrument MI.

As shown in FIG. 2, the electronic musical instrument MI according to the present embodiment includes an operation unit 1, a sound control unit 2, and a sound output unit 3, and each of these units is connected to each other via a bus 4. ..
Hereinafter, each of these parts will be described in order.

(Operation unit)
The operation unit 1 includes a pad 11 pressed by a performer to output sound from a sound source (sound output unit 3) and an A / D conversion unit 12, and the pad 11 is provided with a pressure sensor. The pad 11 is connected to the bus 4 via the A / D conversion unit 12, and when pressed by the performer, outputs a digital signal corresponding to the pressing pressure. As shown in FIGS. 3 and 4, in the electronic musical instrument MI in the present embodiment, the operation unit 1 has a plurality of pads 11. The electronic musical instrument MI may have an operation unit 1 having one pad 11.

As shown in FIGS. 3 and 4, the pad 11 is a rubber key 51 in which a substrate 53 having a pad-shaped carbon printing 55, a conductive sheet 52 having carbon printing 54, and a plurality of key buttons are continuously provided. Are stacked from bottom to top in this order. Although not shown in FIGS. 3 and 4, for example, in the pad 11, the performer puts the rubber key 51 in the housing of a keyboard instrument (see FIG. 1) having an opening for leading the rubber key 51 to the outside. It is housed in a state where it is derived to the outside for operation. As shown in FIGS. 3 and 4, the carbon printing 55 is applied at a position corresponding to each pad 11 on the substrate 53, and has, for example, two spiral shapes so as to form a pair of electrodes. Further, in the carbon printing 54, for example, carbon is solidly printed in a range corresponding to the two spiral-shaped portions constituting the pair of electrodes formed by the carbon printing 55, and the carbon printing 54 is the carbon printing 55. When in contact with, the pair of electrodes formed by the carbon printing 55 can be made conductive.

When the pad 11 is pressed by the performer, the pair of electrodes formed by the carbon printing 55 of the substrate 53 is connected by the carbon printing 54 of the conductive sheet 52, and the pair of electrodes of the carbon printing 55 are electrically connected to each other. do. In the pad 11, the contact area of the carbon printing 54 with respect to the carbon printing 55 changes according to the change of the pressing force, and the contact area increases (the resistance value decreases) as the pressing force increases, so that the voltage value increases. , Outputs the voltage value according to the pressing force. This voltage value is A / D converted by the A / D conversion unit 12, output as a digital signal corresponding to the pressing force, and detected as velocity by the sound control unit 2.

In the electronic musical instrument MI of the present embodiment, a pressure sensor is used in which the resistance value changes depending on the change in the contact state of the carbon printing 54 with respect to the carbon printing 55 and the change in the pressing force of the pad 11 can be detected. By adopting the conductive sheet method, it is possible to detect the velocity in multiple stages, and it is possible to detect the velocity at the same time even when a plurality of pads 11 are pressed at the same time. The pressure sensor is not limited to the configuration of the present embodiment.

(Sound control unit)
The sound control unit 2 includes a CPU 21, a ROM 22, and a RAM 23, is connected to each other via a bus 4, and is connected to an operation unit 1 and a sound output unit 3, and the sound control unit 2 serves as a musical sound generation instruction device. Function. Further, the CPU 21 functions as a processing unit of the musical sound generation instruction device, and executes various processes such as control of the entire electronic musical instrument MI, processing according to the operation of the pad 11, and control of sounding to the sound source (sound output unit 3). do.

The ROM 22 causes the sound source (sound output unit 3) to produce sounds corresponding to various processes to be executed by the CPU 21, for example, processing of a signal output from the pad 11 of the operation unit 1 and operation of the pad 11 of the operation unit 1. Stores programs such as control. Further, the ROM 22 stores waveform data for generating various musical tones corresponding to the plurality of pads 11. The RAM 23 stores data and the like necessary for the CPU 21 to execute various processes. Further, the RAM 23 stores the program read from the ROM 22 and the data generated in the process of the processing in the CPU 21.

In the present embodiment, the storage units of the ROM 22 and the RAM 23 include a tone color selection table assigned to each pad 11 of the operation unit 1, an effect mode selection table, an effect sensitivity value curve (V_EfeSenc) as effect variable items, and a fourth setting. The time (fourth time EfecTime) is stored. Tones such as "Piano", "E. Piano", "Organ", "Guitar", "Bass", and "Synth" are stored in the storage as a tone selection table, and "Delay", "Reverb", and "Roll" are stored as an effect mode selection table. Effect modes such as "LPF" are stored.

The sound control unit 2 presses the pad 11 of the operation unit 1 based on the pressing signal (voltage value) output according to the pressing force of the operation unit 1 for outputting sound from the sound source (sound output unit 3). A function to detect the start, a function to control the sound source (sound output unit 3) to emit a sound corresponding to the pad 11 of the operation unit 1, and a predetermined first set time from the start of pressing based on the signal. (First time) The function of detecting that the pad 11 of the operation unit 1 is pressed and detecting the after-touch of the pad 11 of the operation unit 1 and the transition of the signal after the after-touch detection are performed. It has a function of controlling the sound source (sound output unit 3) to produce a sound having a change.

More specifically, with reference to FIG. 7, the sound control unit 2 functioning as a music sound generation instruction device has a first unit for detecting the start of pressing the pad 11 of the operation unit 1, as shown in FIG. The reference voltage value (V_OnThr) is set in advance as the threshold value of, and the sound control unit 2 monitors the voltage value (V_in) output from the pad 11 of the operation unit 1, and this voltage value (V_in) is the reference voltage. When the value (V_OnThr) is exceeded, the start of pressing the pad 11 of the operation unit 1 is detected. Therefore, the CPU 21 functioning as the processing unit of the musical tone generation instruction device determines whether or not the level of the voltage value (pressing signal) generated in response to the pressing operation of the pad 11 of the operating unit 1 exceeds the first threshold value. The first determination process to be performed will be executed. By setting this reference voltage value (V_OnThr), the electronic musical instrument MI in the present embodiment prevents false detection of the start of pressing of the pad 11 due to noise.

In the present embodiment, the sound control unit 2 functioning as the music sound generation instruction device has a time measurement function, and the CPU 21 functioning as the processing unit of the music sound generation instruction device detects the start of pressing the pad 11 of the operation unit 1. Then, based on the voltage value (V_in) output from the pad 11 of the operation unit 1, the pressing signal (voltage value) is obtained between the start of pressing and the elapse of the second set time (second time ScanTime). The maximum value detection process for detecting the maximum value (voltage value (Vmax)) of the level of (V_in)) is executed, and the maximum value (voltage value (Vmax)) of the level of the pressing signal (voltage value (V_in)) is executed. ) Is performed to instruct the sound source (sound output unit 3) to produce a musical sound at a volume corresponding to). In response to this instruction, the sound source (sound output unit 3) starts to pronounce a musical tone. Specifically, the sensitivity value (V_VelSenc) of the velocity is set in the sound control unit 2, and the difference between the highest voltage value (Vmax) and the reference voltage value (V_OnThr) within the second set time. A velocity corresponding to (= Vmax-V_OnThr) is generated, and the sound source (sound output unit 3) starts sound generation at a volume corresponding to the velocity.

Further, the sound control unit 2 functioning as a musical sound generation instruction device is the most after the lapse of the second set time from the lapse of the second set time to the lapse of the third set time (third time MaskTime). The sound output unit 3 has a function of sustaining the sound output corresponding to the sound produced at a volume corresponding to a high voltage value (Vmax).

Further, the sound control unit 2 that functions as a music sound generation instruction device is preset with a reference voltage value (V_OffThr) as a second threshold value for detecting the end of pressing of the pad 11 of the operation unit 1, and music sound is generated. The CPU 21 functioning as a processing unit of the instruction device determines whether or not the level of the pressing signal (voltage value (V_in)) has fallen below the reference voltage value (V_OffThr), which is the second threshold value, after the sound of the music is instructed. The second discrimination process for discrimination and the state in which the level of the pressing signal (voltage value (V_in)) did not fall below the second threshold value (reference voltage value (V_OffThr)) continued for the first set time (first time). A third determination process for determining whether or not to perform is executed.
The first set time (first time) is the second set time (second time ScanTime), the third set time (third time MaskTime), and the fourth set time (fourth time) shown in FIG. Time EfecTime) is the combined time.
However, as will be described later, the fourth set time (fourth time EfecTime) is a user-settable item and can be set to zero, so in this case, the first set time (first set time). (1 time) is the total time of the second set time (second time ScanTime) and the third set time (third time MaskTime).

Then, after it is determined that the CPU 21 has continued for the first set time, the CPU 21 imparts an after-touch effect according to the transition of the level of the pressing signal (voltage value (V_in)) to the sound being sounded. Execute the process.
On the other hand, when the CPU 21 determines by the second discrimination process that the level of the pressing signal (voltage value (V_in)) is lower than the second threshold value (reference voltage value (V_OffThr)), the sound source (sound output unit 3) The mute instruction process for instructing the mute of the musical sound being sounded is executed.

The reference voltage value (V_OnThr) for detecting the start of pressing of the pad 11 of the operation unit 1 and the reference voltage value (V_OffThr) for detecting the end of pressing of the pad 11 of the operation unit 1 are set to the same voltage value. However, since the influence of noise is small at the end of pressing, it is preferable to set the reference voltage value (V_OffThr) to a voltage value lower than the reference voltage value (V_OnThr). In the electronic musical instrument MI in the present embodiment, as shown in FIG. 7, the reference voltage value (V_OffThr) is set to a voltage value lower than the reference voltage value (V_OnThr).

In the present embodiment, the sound control unit 2 functioning as a musical sound generation instruction device has a first set time (that is, a second set time, a third set time, and a fourth set time) from the start of pressing the pad 11 of the operation unit 1. When it is detected that the pad 11 of the operation unit 1 is pressed (the state in which the EfecTime has elapsed in FIG. 7), it is determined that the operation unit 1 is "after-touch", and the after-touch is detected. Move to phase. As will be described later, in the present embodiment, the fourth set time is a variable item that can be set by the user.

In the after-touch detection phase, the CPU 21, which is the processing unit of the sound control unit 2 that functions as a musical sound generation instruction device, has an effect mode assigned to the pad 11 of the corresponding operation unit 1 and an effect sensitivity corresponding to this effect mode. The value curve (V_EfeSenc) is read from the storage unit, and an effect corresponding to the read effect sensitivity value curve (V_EfeSenc) is generated based on the voltage value (V_in).
Specifically, in the after-touch processing, an effect that controls at least one of the volume, timbre, and pitch of the musical tone that is being produced according to the transition of the level of the pressing signal (voltage value (V_in)) is produced. Added to the sound.

The electronic musical instrument MI according to the present invention has a configuration in which an after-touch function is added by detecting that the pad 11 of the operation unit 1 is pressed for a predetermined time or longer, so that the pad 11 has an after-touch with a simple configuration. The function can be realized.

(Sound output section)
As shown in FIG. 2, the sound output unit 3 includes a speaker 31 that outputs sound, a digital signal processor 32, a D / A conversion unit 33, and a power amplifier 34. The speaker 31 is connected to the digital signal processor 32 via the power amplifier 34 and the D / A conversion unit 33, and the digital signal processor 32 is connected to the sound control unit 2 via the bus 4. The sound output unit 3 D / A-converts the sound generation data generated by the sound control unit 2 into an analog waveform signal, and outputs it from the speaker 31 via the power amplifier 34.

The electronic musical instrument MI according to the present invention outputs the sound assigned to each pad 11 from the speaker 31 of the sound output unit 3 in response to the pad operation by pressing the pad 11 of the operation unit 1. The electronic musical instrument MI has an after-touch function that cannot be realized by a conventional pad, and can output a sound with an effect added according to a change in pressing pressure after detecting after-touch from the speaker 31. In the present embodiment, as shown in FIG. 1, the case where the electronic musical instrument MI is incorporated in a keyboard instrument such as a synthesizer is shown, but the electronic musical instrument MI according to the present invention comprises only a part of the electronic musical instrument MI. It may be a musical instrument.

<Operation of electronic musical instruments>
Hereinafter, the operation of the electronic musical instrument MI in the present embodiment will be described with reference to FIGS. 5 and 6. FIG. 5 is a flowchart showing the operation of the electronic musical instrument MI in the present embodiment, and more specifically, is a flowchart showing the processing of the CPU 21 functioning as the processing unit of the musical instrument generation instruction device of the electronic musical instrument MI. FIG. 6 is a flowchart showing a flow when changing the setting contents of the effect time (“EfecTime” in FIG. 7).

(Velocity detection phase)
In step S1, the CPU 21 acquires the voltage value from the pressure sensor of the pad 11 which is A / D converted and output by the A / D conversion unit 12, and sets it as the input voltage value “V_in”. Then, the CPU 21 compares the input voltage value (V_in) with the reference voltage value (V_OnThr) for detecting the start of pressing the pad 11. When the input voltage value (V_in) is equal to or less than the reference voltage value (V_OnThr), the CPU 21 repeatedly executes the process of step S1. This state is a stationary state in which the pad 11 is not pressed.

On the other hand, when the input voltage value (V_in) is larger than the reference voltage value (V_OnThr), the CPU 21 detects the start of pressing the pad 11 and substitutes the input voltage value (V_in) for the maximum voltage value "V_max" to obtain this. The value is stored in the RAM 23 (step S2).

When the CPU 21 detects the start of pressing the pad 11, the CPU 21 starts measuring the elapsed time. Then, the CPU 21 compares the elapsed time with the second set time (second time ScanTime), and when the second set time elapses, proceeds to step S5 to generate velocity, and the second set time elapses. If not, the process proceeds to step S4 (step S3).

In step S4, the CPU 21 acquires an input voltage value (V_in) and compares it with the maximum voltage value (V_max) stored in the RAM 23. When the input voltage value (V_in) is larger than the maximum voltage value (V_max), the process returns to step S2, and the CPU 21 substitutes the input voltage value (V_in) for the maximum voltage value “V_max” to obtain the maximum voltage value “V_max”. Is updated and this value is stored in the RAM 23. On the other hand, when the input voltage value (V_in) is equal to or less than the maximum voltage value (V_max), the process returns to step S3, and the loop for updating the maximum voltage value “V_max” is continued until the first set time elapses. As a result, when the second set time elapses and the process proceeds to step S5, the voltage value of Vmax shown in FIG. 7 is stored in the maximum voltage value “V_max”.

Then, when the second set time elapses and the process proceeds to step S5, the CPU 21 reads out the function "V_VelSenc" set as the sensitivity value of the velocity, and the maximum voltage from the start of pressing to the elapse of the second set time. Velocity is generated by substituting the difference (= Vmax-V_OnThr) between the value (V_max) and the reference voltage value (V_OnThr) into the function "V_VelSenc". Then, the CPU 21 selects a tone color assigned to the pad 11 that has detected the pressing, and causes the sound output unit 3 to start producing a sound at a volume corresponding to the generated velocity.

After the second set time has elapsed from the start of pressing, the state transitions to the input ignoring state for preventing double ringing (step S6). The CPU 21 compares the elapsed time with the third set time (third time MaskTime), shifts to step S7 when the third set time has elapsed, and proceeds to step S6 when the third set time has not elapsed. Repeat the process and continue measuring the elapsed time.

When the process proceeds to step S7 after the third set time elapses, the CPU 21 acquires the input voltage value (V_in) and compares it with the reference voltage value (V_OffThr) for detecting the end of pressing of the pad 11. When the input voltage value (V_in) is larger than the reference voltage value (V_OffThr), the process proceeds to step S8. When the input voltage value (V_in) is equal to or less than the reference voltage value (V_OffThr), the process proceeds to step S11. Instruct the sound output unit 3) to mute the sound. Then, the sound source (sound output unit 3) mute the sound according to the muffling instruction.

When shifting to step S8, the CPU 21 compares the elapsed time with the fourth set time (fourth time EfecTime), and when the fourth set time has elapsed, the CPU 21 shifts to the aftertouch detection phase (step S9), and the fourth If the set time has not elapsed, the process returns to step S7, and the CPU 21 compares the input voltage value (V_in) with the reference voltage value (V_OffThr).

In this way, after the CPU 21 detects the start of pressing the pad 11, the first set time (that is, a predetermined time including the second set time, the third set time, and the fourth set time) or more is When the pad 11 is pressed, control is performed to shift to step S9, which is the after-touch detection phase.

When the process proceeds to step S9, the CPU 21 reads out the effect mode assigned to the corresponding pad 11 and the effect sensitivity value curve (V_EfeSenc) corresponding to this effect mode, and inputs the input voltage value (V_in) to the effect sensitivity value curve (V_EfeSenc). ) Is substituted to generate an effect, the generated effect is added to the sound output from the sound output unit 3, and then the process proceeds to step S10.

When the process proceeds to step S10, the CPU 21 acquires an input voltage value (V_in) and compares it with a reference voltage value (V_OffThr) for detecting the end of pressing of the pad 11. Then, when the input voltage value (V_in) is larger than the reference voltage value (V_OffThr), the process of step S9 is executed again. That is, the CPU 21 generates an effect according to a change in the input voltage value (pressing pressure) while the input voltage value (V_in) is larger than the reference voltage value (V_OffThr), and generates the sound output from the sound output unit 3. Controls to repeat adding the applied effect.

On the other hand, when the input voltage value (V_in) is equal to or less than the reference voltage value (V_OffThr), the process proceeds to step S11, and the CPU 21 ends the sound output unit 3.

In the electronic musical instrument MI according to the present invention, when the pad 11 is pressed for a time equal to or longer than the first set time (that is, a predetermined time including the second set time, the third set time, and the fourth set time). After shifting to the after-touch detection phase and shifting to this after-touch detection phase, it is possible to add an effect corresponding to the pressing state of the pad 11 to the sound. As described above, the electronic musical instrument MI according to the present invention can add an after-touch effect that changes the volume, etc., even though it has a simple configuration, and can perform more diverse and unique performances. can.

(Effect time setting)
Next, the procedure for changing the parameter of the fourth set time, which is a variable item that can be set by the user, will be described with reference to FIG.

In the electronic musical instrument MI according to the present invention, when the user selects an operation for changing the setting contents of variable items that can be set by the user (for example, pressing the setting change start button), the process according to the flowchart shown in FIG. 6 starts. Will be done.
In step S21, the CPU 21 causes the operator to select the pad 11 whose effect time is to be changed. As shown in FIG. 4, the electronic musical instrument MI in the present embodiment includes 16 pads 11, for example, each pad 11 is designated by a reference numeral 1 to 16, and the user can use the reference numeral to indicate the pad. You can choose. The pad 11 may be selected by pressing the pad 11.

In step S22, the CPU 21 causes the operator to select a tone color that can be assigned to the pad 11 selected in step S21. When there is only one tone that can be assigned to the pad 11, the CPU 21 displays the tone assigned to the pad 11 and asks the operator to confirm it.

In step S23, the CPU 21 causes the operator to select an effect mode that can be added to the tone color selected in step S22. When there is only one effect mode that can be added to the tone color, the CPU 21 displays the effect mode added to the tone color and asks the operator to confirm it.

In step S24, the CPU 21 causes the operator to select an item whose parameters can be changed in the effect mode selected in step S23. In the present embodiment, the operator selects the effect time (fourth set time) as a variable item.

In step S25, the CPU 21 causes the operator to change the parameter of the effect time. Then, the CPU 21 stores the changed effect time parameter in the RAM 23. As described above, since the electronic musical instrument MI in the present embodiment can change the parameter of the effect time, the sensitivity of the effect can be freely set.

Although the present invention has been described above based on the specific embodiments, it goes without saying that the technical scope of the present invention is not limited to the above embodiments. It will be apparent to those skilled in the art that various changes or improvements can be made to the specific embodiments described above, and such modifications or improvements are also included in the technical scope of the present invention. It is clear from the description of the scope of claims.
In the present embodiment, when the level of the pressing signal exceeds the first threshold value, the sound of the musical tone is instructed, and when the level of the pressing signal falls below the second threshold value, the sound of the musical tone is instructed to be muted. When the level reaches the first threshold value, the musical tone may be instructed to be pronounced, and when the level reaches the second threshold value, the musical tone may be instructed to be muted.

The inventions described in the claims originally attached to the application of this application are described below. The claims described in the appendix are the scope of the claims originally attached to the application for this application.

[Additional Notes]
[Claim 1]
The first determination process for determining whether or not the level of the pressing signal generated in response to the pressing operation on the operation unit exceeds the first threshold value, and
After it is determined by the first discrimination process that the level of the pressing signal exceeds the first threshold value, a pronunciation instruction process for instructing the sound source to pronounce a musical tone, and a pronunciation instruction process.
After being instructed to pronounce the musical tone, a second discrimination process for determining whether or not the level of the pressing signal has fallen below the second threshold value, and
A third discrimination process for determining whether or not the state in which the level of the pressing signal does not fall below the second threshold value continues for the first time by the second discrimination process.
After being determined to have continued for the first time by the third discrimination process, the after-touch process for imparting an after-touch effect according to the transition of the level of the pressing signal to the sounded musical sound. ,
A musical tone generation instruction device having a processing unit for executing.
[Claim 2]
Further, when it is determined by the second discrimination process that the level of the pressing signal is below the second threshold value, the processing unit further instructs the sound source to mute the sound being pronounced. The musical tone generation instruction device according to claim 1, wherein the processing is executed.
[Claim 3]
In the pronunciation instruction processing, the processing unit further
From the time when it is determined that the level of the pressing signal exceeds the first threshold value to the lapse of the second time, the maximum value detection process for detecting the maximum value of the level of the pressing signal is executed.
The musical tone generation instruction device according to claim 1 or 2, which executes a process of instructing the pronunciation of a musical tone having a volume corresponding to the maximum value of the level of the pressing signal.
[Claim 4]
According to any one of claims 1 to 3, the processing unit controls at least one of the volume, timbre, and pitch of the musical tone being pronounced according to the transition of the level of the pressing signal in the after-touch processing. The described musical tone generation instruction device.
[Claim 5]
A musical tone generation instruction method used in a musical tone generation instruction device, wherein the musical tone generation instruction device is used.
It is determined whether or not the level of the pressing signal generated in response to the pressing operation on the operation unit exceeds the first threshold value.
After it is determined that the level of the pressing signal exceeds the first threshold value, the sound source is instructed to pronounce a musical tone.
After the sound of the musical tone is instructed, it is determined whether or not the level of the pressing signal is below the second threshold value.
It is determined whether or not the state in which the level of the pressing signal does not fall below the second threshold value continues for the first time.
A method for instructing a musical sound to generate a musical sound, which imparts an after-touch effect according to a transition of the level of the pressing signal to the sound being pronounced after it is determined that the musical sound has continued for the first time.
[Claim 6]
For computers used as musical tone generation instruction devices,
A step of determining whether or not the level of the pressing signal generated in response to the pressing operation on the operation unit exceeds the first threshold value, and
After it is determined that the level of the pressing signal exceeds the first threshold value, a step of instructing the sound source to pronounce a musical tone, and
After being instructed to pronounce the musical tone, a step of determining whether or not the level of the pressing signal has fallen below the second threshold value, and
A step of determining whether or not the state in which the level of the pressing signal does not fall below the second threshold value continues for the first time, and
A step of imparting an after-touch effect according to the transition of the level of the pressing signal to the sound being pronounced after it is determined that the first time has continued.
A program to execute.
[Claim 7]
The musical sound generation instruction device according to claim 1 and
An operation unit that outputs a pressing signal at the level corresponding to the pressing operation,
A sound source that generates a musical tone in response to an instruction to generate a musical tone from the musical tone generation instruction device,
Electronic musical instrument with.
[Claim 8]
In the operation unit, a carbon-printed substrate having a pair of electrodes, a conductive sheet printed with solid carbon, and a rubber key in which a plurality of key buttons are connected are laminated from bottom to top. The electronic musical instrument according to claim 7.
[Claim 9]
The operation unit is in a state where the pair of electrodes on the substrate are conducted by the solid printing carbon of the conductive sheet by the pressing operation on the operation unit, and in response to the change in the pressing force of the pressing operation. The electronic musical instrument according to claim 8, wherein a pressing signal whose level changes according to the pressing force is output by changing the contact area between the pair of electrodes and the solid printing carbon.

1 Operation unit 2 Sound control unit 3 Sound output unit 4 Bus 11 Pad 12 A / D conversion unit 21 CPU
22 ROM
23 RAM
31 Speaker 32 Digital signal processor 33 D / A converter 34 Power amplifier 51 Rubber key 52 Conductive sheet 53 Board 54,55 Carbon printing MI electronic musical instrument

Claims (11)

A storage unit that stores waveform data for generating musical tones corresponding to the operation unit,
A musical tone with a volume corresponding to the maximum value detected between the time when the level of the pressing signal generated in response to the pressing operation on the operation unit exceeds the first threshold value and the time when the first time elapses. The first process of making a sound based on the waveform data and
After instructing the pronunciation of the musical tone by the first processing, when the state in which the level of the pressing signal is higher than the second threshold value continues for the second time or more, the pressing signal is transmitted with respect to the musical sound being pronounced. The second process that gives an after-touch effect according to the transition of the level, and
And the processing unit that executes
Musical tone generation instruction device. The storage unit stores waveform data for generating various musical tones corresponding to each of the plurality of operation units.
In the first process, the processing unit generates a pressing signal corresponding to a pressing operation on the operating unit when producing a musical sound corresponding to the operated operating unit among the plurality of operating units. The musical tone generation instruction device according to claim 1, wherein the sound is produced at a volume corresponding to the maximum value detected between the time when the level of is exceeded the first threshold value and the time when the first time elapses. The storage unit stores the tones corresponding to each of the plurality of operation units.
The musical tone generation instruction device according to claim 2, wherein the processing unit produces a musical tone having a tone corresponding to the operated operation unit among the plurality of operation units in the first processing. The musical tone generation instruction device according to claim 3, wherein the processing unit sets a tone color corresponding to each of the plurality of operation units based on a user operation. The processing unit further performs any one of claims 1 to 3 to execute a third process for instructing the mute of the musical tone being pronounced when the level of the pressing signal falls below the second threshold value. The musical tone generation instruction device described in 1. Any one of claims 1 to 5 , wherein the processing unit controls at least one of the volume, timbre, and pitch of the musical tone being pronounced in the second process according to the transition of the level of the pressing signal. The musical tone generation instruction device described in the section. A device having a storage unit that stores waveform data for generating a musical tone corresponding to the operation unit
A musical tone with a volume corresponding to the maximum value detected between the time when the level of the pressing signal generated in response to the pressing operation on the operation unit exceeds the first threshold value and the time when the first time elapses. The first process of making a sound based on the waveform data and
After instructing the pronunciation of the musical tone by the first processing, when the state in which the level of the pressing signal is higher than the second threshold value continues for the second time or more, the pressing signal is transmitted with respect to the musical sound being pronounced. The second process that gives an after-touch effect according to the transition of the level, and
How to instruct to generate a musical tone. In a computer of a device having a storage unit that stores waveform data for generating a musical sound corresponding to the operation unit ,
A musical tone with a volume corresponding to the maximum value detected between the time when the level of the pressing signal generated in response to the pressing operation on the operation unit exceeds the first threshold value and the time when the first time elapses. The first process of making a sound based on the waveform data and
After instructing the pronunciation of the musical tone by the first processing, when the state in which the level of the pressing signal is higher than the second threshold value continues for the second time or more, the pressing signal is transmitted with respect to the musical sound being pronounced. The second process that gives an after-touch effect according to the transition of the level, and
A program to execute. An operation unit that outputs a pressing signal at the level corresponding to the pressing operation,
A storage unit that stores waveform data for generating a musical tone corresponding to the operation unit, and a storage unit.
A sound source that generates musical tones based on the waveform data ,
Generation of a musical tone with a volume corresponding to the maximum value detected between the time when the level of the pressing signal generated in response to the pressing operation on the operation unit exceeds the first threshold value and the elapse of the first time. Is instructed to the sound source, and after instructing the sound source to generate the musical sound, when the state in which the level of the pressing signal is higher than the second threshold value continues for the second time or more, the sounded musical sound is selected. On the other hand, a processing unit that executes a process of imparting an after-touch effect according to the transition of the level of the pressing signal, and a processing unit.
Electronic musical instrument with. In the operation unit, a carbon-printed substrate having a pair of electrodes, a conductive sheet printed with solid carbon, and a rubber key in which a plurality of key buttons are connected are laminated from bottom to top. The electronic musical instrument according to claim 9 . The operation unit is in a state where the pair of electrodes on the substrate are conducted by the solid printing carbon of the conductive sheet by the pressing operation on the operation unit, and in response to the change in the pressing force of the pressing operation. The electronic musical instrument according to claim 10 , wherein a pressing signal whose level changes according to the pressing force is output by changing the contact area between the pair of electrodes and the solid printing carbon.

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