JP4735662B2 - Electronic keyboard instrument - Google Patents

Electronic keyboard instrument Download PDF

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JP4735662B2
JP4735662B2 JP2008122141A JP2008122141A JP4735662B2 JP 4735662 B2 JP4735662 B2 JP 4735662B2 JP 2008122141 A JP2008122141 A JP 2008122141A JP 2008122141 A JP2008122141 A JP 2008122141A JP 4735662 B2 JP4735662 B2 JP 4735662B2
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signal
performance
sound
soundboard
generating
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JP2008225498A (en
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康剛 鈴木
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ヤマハ株式会社
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  The present invention relates to an electronic keyboard instrument that generates a musical sound by vibrating a soundboard.

  Conventionally, electronic keyboard instruments have been improved so that the generated musical sounds are closer to natural musical sounds with a sense of expanse like acoustic musical instruments, but there are still differences in acoustics from acoustic musical instruments. .

  In natural musical instruments, this can be heard not only by the sound produced by vibrating members such as strings, but also by resonating with the abutment sounds of the parts in the musical instrument and by the respective parts and soundboards when the operating elements such as keys are driven. This is because there are many sounds generated by the complex action of sounds and the like, and existing electronic keyboard instruments cannot fully express such complicated sounds.

  For example, some sounds are generated in response to a performance operation, and each sound is generated from a speaker as a performance sound. However, it may be complicated depending on the situation (keyboard or pedal operation status, operation timing, etc.). There are limits to the reproduction of pronunciation in the working environment, and there are cases where expressions are insufficient.

On the other hand, there is also known an electronic keyboard instrument that has a speaker and is equipped with a vibrator on a soundboard so as to generate a musical sound due to vibration of the soundboard in addition to sound generation by the speaker (Patent Document 1 below).
Japanese Unexamined Patent Publication No. 7-92967

  However, in the electronic keyboard instrument disclosed in Patent Document 1, both the sound generation of the speaker and the drive of the vibrator are performed based on the same performance information generated according to the key pressing information. Therefore, for example, it is possible to faithfully reproduce a performance sound caused by pressing a key, such as an acoustic piano, and a damper sound having a sense of spread due to resonance of strings other than the string that is struck when the damper pedal is turned on. Then there was room for improvement.

  The present invention has been made to solve the above-described problems of the prior art, and an object thereof is to provide an electronic keyboard instrument that can realize natural sound with good sound quality such as an acoustic piano. .

In order to achieve the above object, an electronic keyboard instrument according to claim 1 of the present invention has a keyboard performance operator operated by a performer to perform, and a length over the entire range of the keyboard performance operator. A sound board composed of a single plate-like member that generates a musical sound by vibration, and a position and a high-frequency area on the lower-frequency side than the center of the whole sound range of the keyboard performance operator, separately from the sound board. a speaker which is respectively disposed at the position of the side than said center of the total pitch of the keyboard performance operator is at least one attachment to the soundboard in only the low frequency range side, pressurized to vibrate the sound board oscillator And a first signal generating means for generating a first performance signal based on an operation state of the keyboard performance operator, and a pitch based on the first performance signal generated by the first signal generating means. The speaker is pronounced for localization. Having an output signal to the order of the speakers, and the first based on the performance signal output means for performing in parallel with the output of the drive signal to the pressurized exciters for driving the vibrator It is characterized by that.

  According to the present invention, natural sound can be realized with good sound quality such as an acoustic piano.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a block diagram showing the overall configuration of an electronic keyboard instrument according to an embodiment of the present invention. FIG. 2 is a plan view of the electronic keyboard instrument. FIG. 3A is a front view of the electronic keyboard instrument, and FIG. 3B is a cross-sectional view of one attachment portion with respect to the frame of the soundboard.

  As shown in FIG. 1, the electronic keyboard instrument 1 includes a detection circuit 3, a detection circuit 4, a ROM 6, a RAM 7, a timer 8, a display device 9, a storage device 10, an external interface (external I / F) 11, and a sound source circuit 13. And the effect circuit 14 are connected to the CPU 5 via the bus 16.

  Further, a performance operator 15 is connected to the detection circuit 3, and the performance operator 15 includes a keyboard 17 composed of a plurality of keys for inputting pitch information, and a damper pedal (hereinafter referred to as a performance pedal) operated with feet. 18) (referred to as "pedal"). A panel operator 2 including a plurality of switches for inputting various information is connected to the detection circuit 4. The display device 9 is composed of a liquid crystal display (LCD) or the like, and displays various information such as musical scores and characters. A timer 8 is connected to the CPU 5, and an external performance device 100 is connected to the external I / F 11. A sound generator 20 is connected to the effect circuit 14 via a sound system 19. The sound system 19 includes a DAC (Digital-to-Analog Converter), an amplifier, and the like.

  The detection circuit 3 detects the operation state of the performance operator 15, and the detection circuit 4 detects the operation state of the panel operator 2. The CPU 5 controls the entire electronic keyboard instrument 1. The ROM 6 stores a control program executed by the CPU 5, various table data, and the like. The RAM 7 temporarily stores various input information such as performance data and text data, various flags, buffer data, calculation results, and the like. The timer 8 measures the interrupt time and various times in the timer interrupt process. The storage device 10 stores various application programs including the control program, various music data (performance data such as MIDI and audio data), various data, and the like.

  The external I / F 11 has MIDII / F and various communication I / Fs. For example, a MIDI (Musical Instrument Digital Interface) signal from an external device such as the external performance device 100 is input, or a MIDI signal is input to the external device. Or output to The tone generator circuit 13 converts the performance data input from the performance operator 15 or preset performance data into a musical sound signal. The effect circuit 14 gives various effects to the musical tone signal input from the sound source circuit 13.

  The storage device 10 includes, for example, a hard disk drive (HDD). In addition, the storage device 10 can read and write data from and to an external storage medium 12. Examples of the storage medium 12 include a flexible disk drive (FDD), a CD-ROM drive, a magneto-optical disk (MO) drive, and the like.

  The sound generation unit 20 includes a plurality of (for example, four) speakers 41 (41A, 41B, 41C, and 41D) and a plurality of (for example, three) transducers 21 (transducers 21A, 21B, and 21C). The speaker 41 generates a musical sound based on each operation of the performance operator 15 or performance data. The transducer 21 generates sound by exciting (exciting) the soundboard 33 shown in FIG. 2 based on each operation of the pedal 18 and the performance operator 15 or performance data. In other words, in this electronic keyboard instrument 1, sound is generated not only by the speaker 41 but also by the vibration of the soundboard 33.

  As shown in FIG. 3A, the pedal 18 is provided at the lower front part of the leg body 30, and a frame 31 is fixed to the upper part of the leg body 30. As shown in FIG. 2, a keyboard 17 is arranged on the player side (front side) in the same manner as a grand piano. The soundboard 33 is disposed behind the keyboard 17. As shown in FIG. 2, the soundboard 33 has a plan view shape similar to that of a soundboard disposed under a string in a grand piano. The soundboard 33 is a wooden board having a thickness of about 1 cm and is formed to have a uniform thickness. The depth of the soundboard 33 is shorter on the high sound side (right side in FIG. 2) than on the low sound side (left side in FIG. 2). Note that the soundboard 33 can be appropriately changed in the design as long as it is suitable for vibrating and sounding, regardless of the material.

  Although the plan view shape of the frame 31 is not illustrated, the frame 31 has a frame shape that substantially follows the peripheral portion of the soundboard 33. Specifically, the outline of the frame 31 is slightly smaller than the peripheral portion of the soundboard 33 and has a similar shape to the soundboard 33. As shown in FIG. 3 (b), the soundboard 33 is fixedly held on the upper end of the frame 31 via a rubber plate member 32 by a plurality of screws 34 with appropriate intervals. As the rubber plate member 32, it is desirable to employ a member having a high buffering function so as not to transmit the vibration of the soundboard 33 to the leg body 30.

  An openable / closable lid 42 similar to an acoustic grand piano is provided above the soundboard 33. 2 and 3A show the open state of the open / close lid 42. FIG. At the time of performance, the sound of the speaker 41 and the soundboard 33 is efficiently emitted by opening the opening / closing lid 42.

  The speakers 41 </ b> A and 41 </ b> D are arranged at both left and right ends immediately behind the keyboard 17. The speakers 41 </ b> B and 41 </ b> C are fixed to a stay (not shown) fixed to the frame 31 and are arranged below the soundboard 33. As shown in FIG. 2, the speaker 41 </ b> B is arranged in the middle to low sound region side and at the position of the second half of the soundboard 33 in plan view, and the speaker 41 </ b> C is on the high sound region side and in front of the soundboard 33. It is arranged at the position of the part.

  The transducers 21A, 21B, and 21C are disposed on the upper surface of the soundboard 33 so as to be separated from each other. The transducer 21A is disposed on the low sound side of the soundboard 33, the transducer 21B is disposed on the midrange of the soundboard 33, and the transducer 21C is disposed on the high sound side of the soundboard 33 in a region having a short depth. With respect to the position in the front-rear direction, the transducer 21C is located at the foremost position, and the transducer 21B is located at the rearmost position. Each transducer 21A, 21B, 21C is arranged at a position where the soundboard 33 can be vibrated efficiently with a relatively large number of natural frequencies in a frequency band that can be generated by a keyboard instrument. That is, each transducer 21 not only avoids the position of the screw 34 and the position of the frame 31, but the density of the nodal line group at each natural frequency generated when the soundboard 33 freely vibrates while gradually changing the frequency is “rough. Is disposed at such a position.

  Each transducer 21 is directly attached to the soundboard 33. As for the attachment to the soundboard 33, any means such as screwing or adhesion may be used. The structure of the transducer 21 is a known structure as described in FIG. 1 or FIG. 2 on page 266 of the March 1971 issue of radio technology, and vibrates itself by an electric signal (performance signal or drive signal). Then, the soundboard 33 is vibrated by a reaction due to its own weight. The transducer 21 may have any structure as long as the sound board 33 can be vibrated and sounded by an electric signal.

  In the present embodiment, transducers 21A and 21B have the same configuration. The transducers 21A and 21B are large in size, have a low frequency band that can be handled, and have particularly good vibration efficiency in the vicinity of a frequency of 250 Hz. For higher frequencies, the generated vibration is minute. In addition, the intensity of vibration that can be generated is strong, and it is mainly responsible for low-frequency sound generation.

  On the other hand, the transducer 21C is different from the transducers 21A and 21B in characteristics (capability), that is, vibration efficiency with respect to an input signal. The transducer 21C is smaller than the transducers 21A and 21B, has a high frequency band that can be handled, and can efficiently excite a frequency of 1000 Hz or more. Further, the intensity of vibration that can be generated is not as strong as that of the transducers 21A and 21B, and is mainly responsible for high-frequency sound generation.

  FIG. 4 is a block diagram showing functions of the electronic keyboard instrument 1. The signal processing unit 40 shown in the figure includes, as function units, first and second performance signal generations 22 and 23, first and second performance data 24 and 25, adders 36 and 37, effect processing 26, and delay processing 27. , SP output distribution 28, TR output distribution 29, and the like. The functions of these functional units of the signal processing unit 40 are components such as the CPU 5, the ROM 6, the RAM 7, the timer 8, the storage device 10, the external interface 11, the sound source circuit 13, the effect circuit 14, and the sound system 19 shown in FIG. This is realized through collaboration.

  The first performance data 24 is waveform data obtained by sampling musical tones that are generated when each key is operated without pressing the damper pedal in an acoustic grand piano. On the other hand, the second performance data 25 is waveform data obtained by subtracting the data corresponding to the first performance data 24 from the sampled musical sounds produced by operating each key while depressing the damper pedal. . That is, the first performance data 24 is data for reproducing a normal performance sound. The second performance data 25 is data for reproducing a damper sound having a sense of spaciousness due to resonance of strings other than the string being struck when a damper pedal is operated in an acoustic piano. These are stored in the ROM 6, for example.

  The first performance signal generator 22 generates a first performance signal using the first performance data 24 in response to the key release operation of each key on the keyboard 17, and sends it to the effect processing 26 via the adder 36. On the other hand, the second performance signal generator 23 generates a second performance signal using the second performance data 25 according to the operation of the pedal 18 and the keyboard 17 and sends the second performance signal to the delay processing 27 via the buffer and the adder 37. . The first performance signal is for sounding the speaker 41, and the second performance signal is for driving the transducer 21, both of which have different characteristics.

  When the first and second audio signals 43 and 44 are input, the first audio signal 43 is sent to the effect processing 26 via the buffer and adder 36, and the second audio signal 44 is buffered and added. It is sent to the delay processing 27 via the device 37.

  Here, the first and second audio signals 43 and 44 are signals stored in the storage device 10 or input from the external performance device 100, and a plurality of (for example, two) tracks of audio data are used as sources. Signal. The first audio signal 43 is a signal for reproducing the normal performance sound, and corresponds to the first performance signal in the real-time performance. The second audio signal 44 is a signal for reproducing a damper sound, and corresponds to a second performance signal in real-time performance. The audio data is created in advance as data for reproducing the normal performance sound and the damper sound.

The first performance signal and the first audio signal 43 sent to the effect processing 26 are subjected to the effect set in the effect processing 26 and supplied to the SP output distribution 28, and the buffer and adder 37 are also supplied. To the delay processing 27. On the other hand, the second performance signal, the second audio signal 44, and the signal sent from the effect process 26 sent to the delay process 27 are subjected to a predetermined delay process by the delay process 27, and are sent to the TR output distribution 29. Supplied.

  The SP output distribution 28 distributes the output to the speakers 41 based on the signal (first performance signal, first audio signal 43) supplied from the effect processing 26. That is, the signal is distributed and amplified to each of the speakers 41A to 41D and output. At that time, an output corresponding to the pitch and velocity specified by the signal is made. However, the sound field localization matches the pitch of the operated key or the pitch specified by the first audio signal 43. Thus, the output distribution to each speaker 41 is set.

  The TR output distribution 29 distributes the output to the transducer 21 based on the supplied signals (second performance signal, second audio signal 44, etc.). That is, an analog drive signal is generated, amplified and output for each of the transducers 21A, 21B, and 21C. Specifically, a drive signal that vibrates with a frequency according to the pitch specified by the signal and a strength according to the velocity is generated and output.

  FIG. 5 is a flowchart of the main process. This process is started when the power is turned on.

  First, initialization is executed, that is, execution of a predetermined program is started, and initial values are set in various registers such as the RAM 7 to perform initial setting (step S101). Next, input from the panel operator 2 is confirmed (step S102), and device settings (volume, timbre, effect setting, automatic performance execution availability, etc.) corresponding to the input are executed (step S103). Then, it is determined whether or not there is an input from the performance operator 15 (step S104). If there is no input, the process proceeds to step S105. If there is an input, it is instructed to press the key (the key of the keyboard 17). It is determined whether or not (pressed) (step S106).

  As a result of the determination, if it is not a key pressing instruction, it is determined whether or not it is a key release instruction (step S110), and if it is not a key release instruction, it is determined whether or not the pedal 18 is turned on ( If the pedal 18 is not turned on in step S113), the pedal 18 is turned off, and the process proceeds to step S115. Accordingly, if the input of the performance operator 15 is a key depression instruction, steps S107 to S109 are executed. If the key release instruction is a key release instruction, steps S111 and S112 are executed, and the pedal 18 is turned on. Step S114 is executed. If the pedal 18 is turned off, step S115 is executed and the process proceeds to Step S105.

  First, in step S107, it is determined whether or not the pedal 18 is currently on. If the pedal 18 is not in the on state, the process proceeds to step S 109, where the first performance data 24 corresponding to the pitch of the key press (key pressed) is read from the ROM 6 and based on the first performance data 24. Then, a first performance signal having an envelope corresponding to the key depression velocity is generated. On the other hand, if the pedal 18 is on, the process proceeds to step S108, where the second performance data 25 corresponding to the pitch of the key depression key is read, and a second performance signal having an envelope corresponding to the key depression velocity is generated. Then, the step S109 is executed.

  In step S111, it is determined whether or not the pedal 18 is currently on. If the pedal 18 is not in the on state, the process proceeds to step S112, and the performance signal of the key released (key released) is stopped. That is, a mute signal is generated in order to mute the corresponding musical tone being generated. In this process, the first performance data 24 is read, and a first performance signal for muting having an envelope corresponding to the key release operation is generated. On the other hand, if the pedal 18 is on, the process proceeds to step S105 without stopping the performance signal.

  In step S114, if there is a key being pressed and a sound is being generated, a second performance signal corresponding to the key being pressed is generated in response to an on operation of the pedal 18. That is, the second performance data 25 corresponding to the pitch of the key in the depressed state is read, and a second performance signal having an envelope that matches the sound attenuation state during the sound generation process is generated.

  In step S115, if there is a sound being generated at a pitch corresponding to a key other than the key being pressed, the performance signal corresponding to the tone is stopped. That is, a mute signal is generated in order to mute the corresponding musical tone being generated. In this process, the first performance data 24 and the second performance data 25 corresponding to the pitches other than the key being pressed and corresponding to the pitch being sounded are read out and the pedal 18 is turned off according to the off operation. A mute first performance signal and a second performance signal having an envelope are generated.

  In step S105, a signal is output to each speaker 41 and each transducer 21 based on the generated first performance signal and second performance signal. Furthermore, when execution of automatic performance is permitted and the first and second audio signals 43 and 44 are input, output based on these signals is performed. In some cases, outputs based on the first and second performance signals and the first and second audio signals 43 and 44 are performed in parallel.

  That is, in step S105, first, based on the generated first performance signal, the signal is distributed to each speaker 41 so that the localization is in accordance with the pitch at the output level corresponding to the first performance signal. Output. The same processing is performed when the first audio signal 43 is input. As a result, a normal performance sound corresponding to the key depression and / or audio data is generated from the speaker 41.

  In step S105, based on the generated second performance signal, a drive signal is generated individually in consideration of the characteristics and arrangement of each transducer 21 so as to be localized according to the pitch. ,Output. The same processing is performed when the second audio signal 44 is input. As a result, the tone of the damper sound corresponding to the key depression and / or audio data is generated. Thereafter, the process returns to step S102.

  Compared to the musical sound from the speaker 41, the musical sound due to the vibration of the soundboard 33 is close to the reproduction of the sound in a complicated working environment depending on the operation state of the keyboard 17 and the pedal 18 and the operation timing thereof, and the sound quality is good. , Natural sound. In particular, since the soundboard 33 has the same shape as the soundboard of a grand piano, its sound is similar to that of a live piano. In particular, since the shape of the frame 31 in plan view is a frame shape that substantially follows the periphery of the soundboard 33, the soundboard 33 vibrates greatly (at a sufficiently low frequency) in the inner region of the frame 31. Therefore, the damper sound in the low sound range can be reproduced well. In addition, since the transducer 21 is disposed at a position where the soundboard 33 can be vibrated efficiently, a sufficient sound output can be obtained.

  Here, it is assumed that the balance between the output level (volume) of the performance sound based on the first performance signal and the output level of the damper sound based on the second performance signal is fixed in advance. However, the present invention is not limited to this, and the balance between the two may be varied according to the set output level. For example, as the output level setting increases, the degree to which the output level of the performance sound increases as compared to the damper sound may be increased.

  According to the present embodiment, the speaker 41 produces a performance sound by the first performance signal generated according to the operation of the keyboard 17, and the second performance signal generated according to the operation of the pedal 18 and the keyboard 17. Since the transducer 21 is driven and the soundboard 33 produces a damper sound, a natural sound can be realized with a good sound quality like an acoustic piano.

  Moreover, since the sound board 33 has the same shape as the sound board of a grand piano, a natural sound close to that of a grand piano can be realized. In particular, when a bass is vibrated by vibrating the board, a larger area is required compared to the treble sound, so the shape of the soundboard 33 is ideal for reproducing piano sounds.

  Note that the distribution to the speakers 41 </ b> A to 41 </ b> D may be determined when the first performance signal is generated by the first performance signal generation 22. For example, in the first performance signal, the waveform for the left / right channel is read from the first performance data 24 and is generated as a stereo signal for the left / right channel. Then, the left channel signal may be generated by the speakers 41A and 41B, and the right channel signal may be generated by the speakers 41C and 41D. In this case, the speaker 41A and the speaker 41B, the speaker 41C and the speaker 41D have different characteristics from each other, and the left channel (or right channel) signal is generated as an appropriate signal through a filter. Also good. The speaker 41 may have two specifications instead of four (for example, only the speaker 41A and the speaker 41D).

  Similarly, the distribution to the transducers 21 </ b> A to 21 </ b> C may be determined when the second performance data 25 is generated by the second performance signal generation 23. The number of transducers 21 may be two instead of three, for example, only transducers 21A and 21B. In that case, contrary to the example of FIG. 2, the left transducer 21A is arranged on the back side, and the right transducer 21B is arranged on the near side. Similarly to the above, in the second performance signal, the left / right channel waveform is read from the second performance data 25 and is generated as a left / right channel stereo signal, and the left channel signal is used as the transducer 21A. And the transducer 21B may be driven by a signal for the right channel.

  In this embodiment, in order to reproduce the piano sound more appropriately, the soundboard 33 has a piano soundboard shape. However, the soundboard 33 may have any shape for simple sound generation. In order to produce a more appropriate sound, it may be appropriately selected according to the type of sound to be produced. For example, when playing a violin sound, an ideal pronunciation can be expected if it is configured in the shape of a violin.

  In the present embodiment, the second performance signal generated by the second performance signal generation 23 (see FIG. 4) is a signal for generating a damper sound, but the present invention is not limited to this. It may be generated for various sound effects that can be realized by sound generation by vibration of the soundboard 33. In that case, in response to the operation of a pedal other than the damper pedal 18, a signal for controlling those effects may be generated.

  The second performance signal is generated using the second performance data 25, but the present invention is not limited to this, and the first performance data 24 may be used. In this case, for example, by reading the first performance data 24 and processing the waveform, a pseudo damper sound waveform different from the first performance signal is generated, and this may be used as the second performance signal. .

  When the second performance signal generator 23 generates the second performance signal in response to the operation of the pedal 18, not only the pedal 18 is turned on / off, but also the operation of the pedal 18 is changed (the damper is completely in contact with the string). The second performance signal may be generated in consideration of sound generation in a half-contact state between the current state and the complete separation.

  In the present embodiment, the transducer 21 is attached to the upper surface of the soundboard 33, but may be attached to the lower surface. The transducers 21A and 21B may have different characteristics. Further, the number of transducers 21 may be at least one as long as the damper sound is simply generated, but from the viewpoint of obtaining good sound quality, it is preferable to provide at least two or more. May be.

It is a block diagram which shows the whole structure of the electronic keyboard musical instrument which concerns on one embodiment of this invention. It is a top view of this electronic keyboard instrument. It is a front view (figure (a)) of an electronic keyboard musical instrument, and sectional drawing (figure (b)) of one attachment part with respect to the flame | frame of a sound board. It is a block diagram which shows the function of an electronic keyboard instrument. It is a flowchart of a main process.

Explanation of symbols

1 electronic keyboard musical instrument, 17 keyboard (keyboard performance operator), 21A, 21B transducer (vibrator), 23 second performance signal producing formation, 27 delay processing, 29 TR output content distribution, 33 soundboard, 41 speaker

Claims (6)

  1. A keyboard performance operator operated by the performer to perform,
    A sound board made of a single plate-like member having a length over the entire sound range of the keyboard performance operator , and generating a musical sound by vibrating;
    Separately from the soundboard, speakers disposed respectively at a position on the low-frequency region side and a position on the high-frequency region side from the center among the entire sound region of the keyboard performance operator,
    Wherein at least one is attached to the soundboard in only the low range side from the center of the total pitch of the keyboard performance operator, the shaker for vibrating the sound board,
    First signal generating means for generating a first performance signal based on an operation state of the keyboard performance operator;
    Based on the first performance signal generated by the first signal generation means, an output of a signal to the speaker for sounding the speaker so as to be localized according to a pitch, and the first performance signal An electronic keyboard instrument comprising: output means for performing output of a drive signal to the vibrator for driving the vibrator in parallel .
  2. A damper pedal; second signal generating means for generating a second performance signal in accordance with an operation state of the keyboard performance operator and an operation state of the damper pedal; and the driver based on the first performance signal and the second performance signal. 2. The electronic keyboard instrument according to claim 1, further comprising drive signal generating means for generating a motion signal.
  3. Storage means storing first waveform data and second waveform data, wherein the first signal generation means generates the first performance signal using the first waveform data read from the storage means; and 3. The electronic keyboard instrument according to claim 2, wherein the second signal generating means generates the second performance signal using the second waveform data read from the storage means.
  4. 4. The electronic keyboard instrument according to claim 2 , wherein the drive signal generating means generates the drive signal by performing at least a delay process on the first performance signal and the second performance signal.
  5. It said drive signal generating means according to any one of claims 2-4, characterized in that to generate the drive signal by performing at least amplification process on the first performance signal and the second performance signal Electronic keyboard instrument.
  6. 6. The apparatus according to claim 2 , wherein there are a plurality of the vibrators, and the drive signal generation unit individually generates the drive signals for the plurality of vibrators. Electronic keyboard instrument as described.
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EP2757552A1 (en) 2013-01-22 2014-07-23 Yamaha Corporation Soundboard acoustic transducer
EP2757554A1 (en) 2013-01-22 2014-07-23 Yamaha Corporation Keyboard musical instrument

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JP5526535B2 (en) * 2008-12-17 2014-06-18 ヤマハ株式会社 Electronic keyboard instrument
JP5428333B2 (en) * 2008-12-26 2014-02-26 ヤマハ株式会社 Electronic keyboard instrument
JP5262731B2 (en) * 2009-01-09 2013-08-14 ヤマハ株式会社 Electronic keyboard instrument

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JPH0573039A (en) * 1991-02-21 1993-03-26 Yamaha Corp Acoustic effect controller of musical instrument
JPH0573038A (en) * 1991-09-12 1993-03-26 Yamaha Corp Keyboard musical instrument
JPH0580748A (en) * 1991-09-18 1993-04-02 Yamaha Corp Keyboard musical instrument
JPH0580750A (en) * 1991-09-18 1993-04-02 Yamaha Corp Keyboard musical instrument
JP2003208182A (en) * 2002-01-15 2003-07-25 Yamaha Corp Musical sound generator

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP2757552A1 (en) 2013-01-22 2014-07-23 Yamaha Corporation Soundboard acoustic transducer
EP2757554A1 (en) 2013-01-22 2014-07-23 Yamaha Corporation Keyboard musical instrument
US9035164B2 (en) 2013-01-22 2015-05-19 Yamaha Corporation Keyboard musical instrument
US9508324B2 (en) 2013-01-22 2016-11-29 Yamaha Corporation Soundboard acoustic transducer

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