The present invention relates to tone generating style notification control for wind instruments having a mouthpiece section.
Japanese Patent Application Laid-open Publication No. HEI-6-43867 (hereinafter referred to as “patent literature 1”) discloses an electronic wind instrument which simulates performance operation and tone color (timbre) of a wind instrument. The electronic wind instrument disclosed in patent literature 1 includes a mouthpiece section, and, in response to a human player performing, with a finger, operation for designating a tone color and pitch within an octave pitch range, the electronic wind instrument generates a tone corresponding to the designated tone color and pitch. Further, Japanese Patent Application Laid-open Publication No. 2010-48909 discloses an audio processing apparatus which outputs a tone of a wind instrument based on an octave corresponding to an angle at which a body device has been inclined by a human player and a note name corresponding to depressing operation performed by the human player.
With a real, acoustic or natural wind instrument, harmonics responsive to human player's piston operation are sounded while resonating in accordance with a state of human player's lips applied to the mouthpiece. However, with the conventionally-known electronic wind instruments, where a human player designates a desired tone pitch using a finger of its (i.e., his or her) hand, a performance feeling felt by the human player is completely different from an actual performance feeling (i.e., performance feeling felt by a human player when performing an acoustic or natural wind instrument).
In view of the foregoing prior art problems, it is an object of the present invention to provide an improved technique which allows a tone, desired by a human player, to be generated with a performance feeling approximate to that of an acoustic or natural wind instrument.
In order to accomplish the above-mentioned object, the present invention provides an improved tone generating style notification control apparatus for a musical instrument having a mouthpiece section, the mouthpiece section being operable with a mouth of a human player, which comprises: a detector which detects a physical amount caused by operation performed on the mouthpiece section with the mouth of the human player; a storage section which stores therein information defining relationship between various values or ranges of the physical amount and tone pitches; an identification section which, by referencing the storage section, identifies a tone pitch corresponding to the physical amount detected via the detector; and a notification section which notifies the human player of an expected tone generating style on the basis of the tone pitch identified by the identification section, the expected tone generating style being a style of a tone expected to be generated by the musical instrument in response to the operation performed on the mouthpiece section with the mouth of the human player.
According to the present invention constructed in the aforementioned manner, the human player can ascertain, on the basis of the expected tone generating style notified by the notification section, what tone pitch the operation performed on the mouthpiece section with the mouth of the human player corresponds to, and thus, feedback to the human player can be made effectively to thereby allow the human player to appropriately operate the mouthpiece section for achieving a desired tone pitch.
According to another aspect of the present invention, there is provided an improved tone generating style notification control apparatus for a musical instrument having a mouthpiece section, the mouthpiece section being operable with a mouth of a human player, which comprises: a detector which detects a physical amount caused by operation performed on the mouthpiece section with the mouth of the human player; a first storage section which stores therein a tone pitch table defining relationship between various ranges of the physical amount and tone pitches; a second storage section which stores therein a gain table defining, as gain information, values corresponding to deviations of the physical amount from a predetermined reference point, for each tone pitch and within the range of the physical amount corresponding to the tone pitch; an identification section which, with regard to the physical amount detected by the detector, identifies a tone pitch by referencing the tone pitch table and identifies gain information by referencing the gain table; and a notification section which notifies the human player of the tone pitch and the gain information identified by the identification section.
According to the present invention thus constructed, the human player can ascertain, on the basis of the notification by the notification section, what tone pitch and gain the operation performed on the mouthpiece section with the mouth of the human player corresponds to, and thus, feedback to the human player can be made effectively to thereby allow the human player to appropriately operate the mouthpiece section for achieving a desired tone pitch and gain. Thus, the human player can, for example, cause a desired tone to be generated by operating the mouthpiece section with its (his or her) mouth as if he were playing a natural wind instrument. Further, by associating the reference points of the individual tone pitches with resonance points of the wind instrument, the present invention allows the human player to ascertain, on the basis of the notified gain information, a degree of resonance corresponding to the operation performed on the mouthpiece section.
According to still another aspect of the present invention, there is provided an improved musical instrument, which comprises: the aforementioned tone generating style notification control apparatus; the mouthpiece section; an operation section operable with a finger of a human player; a tone generation mechanism which generates a tone on the basis of a combination of operation performed on the mouthpiece section with a mouth of the human player and operation performed on said operation section with the finger of the human player.
The present invention may be constructed and implemented not only as the apparatus invention as discussed above but also as a method invention. Also, the present invention may be arranged and implemented as a software program for execution by a processor such as a computer or DSP, as well as a storage medium storing such a software program.
The following will describe embodiments of the present invention, but it should be appreciated that the present invention is not limited to the described embodiments and various modifications of the invention are possible without departing from the basic principles. The scope of the present invention is therefore to be determined solely by the appended claims.
Certain preferred embodiments of the present invention will hereinafter be described in detail, by way of example only, with reference to the accompanying drawings, in which:
A tone generating style notification control of the present invention is suited for application to musical instruments and particularly suited for use in electronic wind instruments, and embodiments of the tone generating style notification control apparatus of the present invention will hereinafter be described as used in a trumpet-type electronic wind instrument.
<Outer Appearance>
The piston operation section 4 includes three pistons, i.e. first piston 4a, second piston 4b and third piston 4c. Each of the pistons 4a to 4c is constructed to be depressed by a human player's finger into the body casing 2, and each of the pistons 4a to 4c is provided with a switch (detector or detection section) for detecting whether or not the piston in question has been depressed into the body casing 2 by the human player. The following describe details of the mouthpiece unit 3.
<Mouthpiece Unit>
The mouthpiece section 31 includes a small-diameter portion 310 to be held in the human player's mouth (or between the lips of the human player), and a large-diameter portion 311 greater in diameter than the small-diameter portion 310. The large-diameter portion 311 of the mouthpiece section 31 has an annular recessed portion 31b formed in the outer periphery thereof. An end surface 311b of the annular recessed portion 31b closer to the small-diameter portion 310 supports one end of a coil-shaped compression spring 33 wound around the outer periphery of the annular recessed portion 31b. An annular portion of the large-diameter portion 311 defining the other end surface 311a of the recessed portion 31b is provided as a stopper portion (flange) 31a. Further, the mouthpiece section 31 has a central hole H1 formed therein to extend axially through the mouthpiece section 31 from the small-diameter portion 310 to the stopper portion 31a of the large-diameter portion 311.
The large-diameter portion 311 has a hole H2 formed in the recessed portion 31b and radially extending through an upper region (i.e., upper region in
The pressure sensor 35 moves along the center axis A as the mouthpiece section 31 is moved or displaced along the axis A, to detect pressure variation in the hole H1 formed in the mouthpiece section 31 and thereby detect pressure of breath blown by the human player via the small-diameter portion 310 of the mouthpiece section 31. Such pressure of breath blown by the human player via the small-diameter portion 310 of the mouthpiece section 31 will hereinafter be referred to also as “breath pressure”.
The mouthpiece casing 32 includes two ring-shaped or annular projecting members 32a and 32b that project inwardly from an inner wall portion of the mouthpiece casing 32 toward and short of the center axis A and that are spaced from each other by a predetermined distance along the center axis A. The annular projecting member 32b supports the other end of the compression spring 33; namely, the compression spring 33 is provided between, and fixed at its opposite ends to, the end surface 311b of the annular recessed portion 31b and the annular projecting member 32b. The mouthpiece section 31 is axially movably supported at its outer peripheral surface by the inner peripheral surfaces of the annular projecting members 32a and 32b; namely, the mouthpiece section 31 is movable or displaceable in parallel to the center axis A while being supported by the annular projecting members 32a and 32b.
Further, a sliding volume control 34, which is a detector or detection section for detecting a physical amount caused by human player's operation on the mouthpiece section 31, is provided on a lower portion (i.e., lower portion in
When no force is being applied to the mouthpiece section 31 in a direction toward the rear end of the mouthpiece casing 32 opposite from the front end of the mouthpiece casing 32 that is closer to the human player, the mouthpiece section 31 is held stationary by the compression spring 33 at a position where the stopper 31a and the projecting member 32a of the mouthpiece casing 32 abuttingly contact each other, as shown in
A limit of the movement of the mouthpiece section 31 toward the rear end of the mouthpiece casing 32 is at a position where the compression spring 33 is compressed to the greatest extent as shown in
Whereas the foregoing has described the construction of the mouthpiece unit 3 in the first embodiment, it should be appreciated that the interior construction of the mouthpiece unit 3 is not necessarily limited to the foregoing as long as the mouthpiece casing 32 and the mouthpiece section 31 are slidable relative to each other and arrangements are made for detecting, at least in a multistep fashion, an operational position of the mouthpiece section 31 and pressure of breath blown into the mouthpiece section 31. The following describe a construction for the embodiment of the electronic wind instrument 1 to perform tone generation processing.
<Construction of Electronic Circuitry>
The control section 10 includes a CPU (Central Processing Unit), and a memory comprising a ROM (Read-Only Memory) and a RAM (Random Access Memory). By executing control programs stored in the ROM, the control section 10 controls various components connected to the control section 10. More specifically, the control section 10 not only identifies, as notification information, a tone pitch soundable at a moved-to position (i.e., current operating position) of the mouthpiece section 31 and causes the display section 5 to visually display a tone generating style based on the identified notification information, but also identifies tone generation instructing information indicative of a tone pitch corresponding to an operational state of the piston operation section 4 and an operational position of the mouthpiece section 31 and performs control to audibly generate a tone based on the tone generation instructing information and with a tone volume level corresponding to an intensity of breath blown by the human player into the mouthpiece section 31.
The operation section 11 includes a switch for turning on or off (i.e., switching between ON and OFF states of) a power supply (not shown) to the electronic wind instrument 1, and a first piston switch (SW), second piston switch and third piston switch corresponding to the first piston 4a, second piston 4b and third piston 4c, respectively, of the piston control section 4. In the instant embodiment, each of the piston switches outputs an ON/OFF signal indicative of whether or not the corresponding piston is currently in a depressed position. Note that an operation detection section for detecting an operational state of the piston operation section 4 may be in the form of a multistep switch or a continuous amount sensor.
The display section 5 is a display device in the form of LEDs, LCD and/or the like, which displays a tone generating style under control of the control section 10. The sliding volume control 34 is an example of a detection section for detecting a physical amount caused by operation performed on the mouthpiece section 31 with the human player's mouth. In the instant embodiment, the sliding volume control 34 detects an operational position of the mouthpiece section 31 having been moved by the human player (i.e., moved-to position of the mouthpiece section 31) and sends a result of the mouthpiece section position detection to the control section 10. The pressure sensor 35 is an example of a breath pressure detection section for detecting pressure of breath blown by the human player into the mouthpiece section 31, which detects pressure variation within the mouthpiece section 31 and sends a result of the pressure detection to the control section 10.
The storage section 12, which is in the form of a non-volatile storage medium, stores therein various data, such as a tone pitch determination table 110 and tone pitch conversion information 120 that are examples of tone pitch information shown in
<Data>
The following describe the data stored in the storage section 12.
More specifically, fingering “1” indicates depressing operation on the first piston 4a, fingering “2” indicates depressing operation on the second piston 4b, and fingering “3” indicates depressing operation on the third piston 4c. Further, fingering “0” indicates a state where all of the pistons are in the non-depressed, open position, fingering “1·2” indicates operation in which the first and second pistons 4a and 4b are depressed simultaneously, fingering “2·3” indicates operation in which the second and third pistons 4b and 4c are depressed simultaneously, fingering “1·3” indicates operation in which the first and third pistons 4a and 4c are depressed simultaneously, and fingering “1·2·3” indicates operation in which all of the pistons 4a, 4b and 4c are depressed simultaneously.
Each of the harmonics predetermined per fingering indicates what integer multiple of a fundamental vibrational mode of air column resonance corresponding to the fingering a vibration mode in question is. Threshold values of positions of the mouthpiece section 31 are preset in relation to each harmonics row where the order of harmonic sequentially increases like “2, 3, 4, 5, . . . ” from the left end of the row corresponding to the fingering. In the illustrated example, threshold values of the harmonics row when the fingering is “1” are identified as smaller than V13 for the second-order harmonic, as equal to or greater than V13 but smaller than V23 for the third-order harmonic, as equal to or greater than V23 but smaller than V33 for the fourth-order harmonic, and so on. In the instant embodiment, the threshold values of the harmonics row corresponding to the current fingering operation are identified, and a tone pitch to be sounded is identified in accordance with the threshold values and current operational position of the mouthpiece section 31. Thus, if the operational position of the mouthpiece section 31 is equal to or greater than V13 but smaller than V23 when the fingering is “1”, then tone pitch “F3” is identified as the tone pitch to be sounded.
<Behavior>
The following describe behavior of the electronic wind instrument 1.
The control section 10 then identifies, as notification information, a tone pitch corresponding to the operational position of the mouthpiece section 31, detected at step S11, by referencing the tone pitch conversion information 120 stored in the storage section 12, and displays an expected tone generating style corresponding to the identified tone pitch, at step S12. The expected tone generating style is a style of a tone expected to be generated by the electronic wind instrument 1 in response to human player's operation on the mouthpiece section 31 with its (his or her) mouth, e.g., a tone pitch expected to be sounded in response to the human player's operation on the mouthpiece section 31. For example, if the detected current operational position of the mouthpiece section 31, having been depressed by the human player, corresponds to tone pitch “C3”, then an indicator indicating tone pitch “C3”, corresponding to the current operational position of the mouthpiece section 31, in such a manner that tone pitch “C3” is distinguishable from the other tone pitches is displayed on the display section 5 as the tone generating style.
With the display of such an indicator, the human player can confirm that the current operational position of the mouthpiece section 31 having been depressed thereby is in a harmonics state corresponding to tone pitch “C3”. Then, the human player determines whether the tone corresponding to the current operational position of the mouthpiece section 31 coincides with its (his or her) desired tone, and, if not, the human player moves or adjusts the operational position of the mouthpiece section 31 so as to approach the desired tone.
Once the operational position of the mouthpiece section 31 varies by more than a predetermined amount (Δ V), i.e. once the mouthpiece section 31 is moved by the human player to an operational position corresponding to a tone pitch different from the tone pitch identified at step S12 above (YES determination at step S13), the control section 10 reverts to step S12, where it identifies a tone pitch corresponding to the moved-to position on the basis of the tone pitch conversion information 120 and displays, on the display section 5, a tone generating style indicative of the identified tone pitch.
With the mouthpiece section 31 having been placed at the operational position corresponding to the desired tone as above, the human player operates the piston operation section 4. If, on the other hand, the operational position of the mouthpiece section 31 has not varied by more than the predetermined amount (Δ V) (NO determination at step S13), the control section 10 detects human player's operation on the piston operation section 4 at step S14, identifies threshold values of a harmonics row corresponding to the fingering represented by the human player's operation on the piston operation section 4, and identifies, as tone generation instructing information, a pitch corresponding to the operational position of the mouthpiece section 31 detected at step S11, at step S15. If, in the illustrated example of
When the piston operation section 4 has been operated by the human player so as to execute fingering “0” (where all of the pistons are “OFF”) while the mouthpiece section 31 is at the operational position corresponding to tone pitch “F3”, tone pitch “G3” is identified as a tone pitch to be sounded, because, in this case, the mouthpiece section 31 is located within the threshold value range of the third-order harmonic corresponding to fingering “0” in the tone pitch determination table 110.
The human player blows breath into the hole H1 with the mouthpiece section 31 moved to the operational position corresponding to the desired tone and with the piston operation section 4 operated in the aforementioned manner. Then, the control section 10 detects, by means of the pressure sensor 35, the breath blown into the hole H1 by the human player. If the thus-detected breath pressure is equal to or over a predetermined threshold value (YES determination at step S16), the control section 10 references the tone volume table 130, stored in the storage section 12, to identify a tone volume level corresponding to the detected breath pressure, so that it instructs or indicates the identified tone volume level to the sound output section 14 and sends the tone generation instructing information, identified at step S15, to the tone generator section 13 (step S17).
The tone generator section 13 generates a tone signal of a tone pitch based on the tone generation instructing information sent from the control section 10 and outputs the thus-generated tone signal to the sound output section 14, where the amplification section 141 amplifies the tone signal, output from the tone generator section 13, in accordance with the tone volume level indicated or instructed by the control section 10 so that the amplified signal is audibly output or generated via the speaker 142 (step S18).
If no breath pressure equal to or over the predetermined threshold value is detected (NO determination at step S16), the control section 10 performs control to not generate a tone of the identified tone pitch and repeats the operations at and after step S11.
When the human player has positionally adjusted the mouthpiece section 31 to approach a desired tone, the above-described first embodiment allows the human player to confirm whether or not the mouthpiece section 31 is currently at a position corresponding to the desired tone. Thus, with the first embodiment, the desired tone can be generated reliably by the human player performing piston operation on the piston operation section 4 with the mouthpiece section 31 fixed at the operational position corresponding to the desired tone.
Next, a description will be given about an electronic wind instrument 1a employing a second embodiment of the present invention. In the following description, elements of the same constructions and functions as in the first above-described embodiment are indicated by the same reference numerals, and differences from the first embodiment will be mainly described hereinbelow.
<Outer Appearance and Construction>
The vibrating section 6 includes a vibrator that transmits to the outside a vibration signal as mechanical vibration, and, under control of the control section 10, the vibrating section 6 generates a vibration signal corresponding to an instructed frequency, and adjusts the vibration signal in accordance with an instructed gain so that the vibrator of the vibrating section 6 is caused to vibrate in accordance with the adjusted vibration signal. Whereas the vibrator in the second embodiment will be described below as an electromagnetic vibrator, the vibrator may be in the form of a so-called vibrating motor that rotates an eccentric weight. The storage section 12 stores therein a tone volume table 130 similar to that provided in the first embodiment, the tone pitch/gain determination table 220 and the vibrating pattern information 230 shown in
The sound output section 14 includes a first amplification section 141 having a similar function to the amplification section 141 provided in the first embodiment, the speaker 142 for audibly reproducing or sounding a tone signal, and a second amplification section 143 for adjusting the tone signal, amplified by the first amplification section 141, in accordance with a gain instructed by the control section 10 and outputting the thus-adjusted tone signal to the speaker 142. The following describe the data stored in the storage section 12 in the second embodiment.
<Data>
The tone pitch/gain determination table 220 shown in
In the case of the natural or acoustic trumpet, how a tone sounds depends on a vibrating state of human player's lips. Thus, in the instant embodiment, the reference point of each tone pitch is made a position where a tone of that pitch resonates most, so that the human player can recognize variation in resonance corresponding to individual operational positions of the mouthpiece section 31. Further, in the instant embodiment, variation in resonance is notified to the human player by the tone volume and mechanical vibration of the vibrator being varied depending on how deep the mouthpiece section 31 is depressed into the mouthpiece casing 32.
The following describe the vibrating pattern information 230.
<Behavior>
The following describe behavior of the electronic wind instrument 1a employing the second embodiment of the invention.
If the human player operates the piston operation section 4 with fingering “2”, the control section 10 references the tone pitch/gain determination table 220, stored in the storage section 12, to identify movement ranges of the mouthpiece section 31 corresponding to a harmonics row of fingering “2”. For example, once the human player moves the mouthpiece section 31 to a position X indicated by a downward solid-line arrow, the control section 10 not only identifies tone pitch “B3” as a tone pitch to be sounded, corresponding to fingering “2” and position X, but also identifies, for example, 50% as a gain corresponding to the position X on the basis of the gain information in the tone pitch/gain determination table 220 (step S23).
Further, the control section 10 sets the frequency of the tone pitch, identified at step S23, as a tone generating frequency, and identifies a vibrating frequency corresponding to the tone generating frequency on the basis of the vibrating pattern information 230 stored in the storage section 12 (step S24).
Further, the control section 10 detects breath, blown by the human player into the hole H1 of the mouthpiece section 31, by means of the pressure sensor 35, and, if the thus-detected breath pressure is equal to or over a predetermined threshold value (YES determination at step S25), the control section 10 references the tone volume table 130, stored in the storage section 12, to identify a tone volume level corresponding to the detected breath pressure at step S26.
Then, the control section 10 indicates, to the sound output section 14, the gain identified at step S23 and the tone volume level identified at step S26, indicates, to the tone generator section 13, the tone pitch identified at step S23 and also indicates, to the vibrating section 6, the gain identified at step S23 and the vibrating frequency identified at step S24.
The tone generator section 13 generates a tone signal of the tone pitch indicated or instructed by the control section 10 and outputs the thus-generated tone signal to the sound output section 14, where the first amplification section 141 amplifies the tone signal, output from the tone generator section 13, so that the tone signal assumes the tone volume level indicated by the control section 10. Further, the tone signal having been amplified by the first amplification section 141 is adjusted by the second amplification section 143 in accordance with the gain indicated by the control signal 10 and then output to the speaker 142. Furthermore, the vibrating section 6 generates a vibration signal based on the vibrating frequency indicated by the control section 10 and adjusts the vibration signal in accordance with the gain instructed by the control section 10 so that the vibrator is vibrated by the adjusted vibration signal in accordance with a predetermined vibrating pattern (step S27).
In the above-described example, the tone signal of tone pitch “B3” is audibly generated or sounded after having been adjusted by the first amplification section 141 to assume the tone volume level corresponding to the detected breath pressure and then adjusted by the second amplification section 143 so that the tone signal decreases in level to 50%. Further, the gain of the vibration signal based on the vibrating frequency corresponding to tone pitch “B3” is adjusted to 50% so that the vibrator is caused to vibrate in accordance with the thus-adjusted vibration signal. Because the gain is set at 100% when the mouthpiece section 31 is at an operational position corresponding to reference point “X3” of tone pitch “B3”, a tone signal of the maximum tone volume level corresponding to the breath pressure is output to the speaker 142, and the vibrator is vibrated in accordance with the vibration signal generated by the vibrating section 6.
Furthermore, if the breath pressure detected by the pressure 35 is below the predetermined threshold value (NO determination at step S25), the control section 10 reverts to step S21. to repeat the operations from steps S21 to S25. Namely, if the detected breath pressure is below the predetermined threshold value, the tone of the pitch identified at step S22 is not generated, and the mouthpiece section 31 does not vibrate either.
Namely, when a tone of a pitch corresponding to a detected operational position of the mouthpiece section 31 is to be sounded, the above-described second embodiment can not only vary the tone volume in accordance with the operational position of the mouthpiece section 31 and distance or deviation of the operational position of the mouthpiece section 31 from the reference point of the tone pitch, but also vary a vibrating pattern with which to vibrate the vibrator and hence the mouthpiece section 31. Thus, the instant embodiment can provide an indicator that is indicative of resonance of the cylinder of the mouthpiece section 31 and corresponds to the operational position of the mouthpiece section 31 and human player's piston operation, and the tone volume and vibration of the mouthpiece section 31 is maximized if the operational position of the mouthpiece section 31 coincides with the resonance of the cylinder. As a result, the human player can execute an intuitive performance with a feeling as if the human player were playing a natural or acoustic trumpet.
The present invention should not be construed as limited to the above-described embodiments and may be modified variously as exemplified below. Further, various modifications explained below may be combined as desired.
(1) Whereas the first embodiment of the present invention has been described above as notifying the human player of a harmonics state, corresponding to an operational position of the mouthpiece section 31, by displaying a tone generating style on the display section 5. The way of notifying the human player of a tone generating style is not limited to the aforementioned. For example, a vibrating section having a vibrator may be provided on the mouthpiece section 31 or the like as in the above-described second embodiment, and the vibrating section may be vibrated with a vibrating frequency corresponding to a tone pitch represented by an operational position of the mouthpiece section; for example, the vibrator may be vibrated with a low vibrating frequency when the operational position of the mouthpiece section represents a low tone pitch, with a high vibrating frequency when the operational position of the mouthpiece section represents a high tone pitch, in a vibrating style where the vibrator is vibrated intermittently at predetermined time intervals corresponding to a note name, or in any desired combination of the above-mentioned. Note that the vibrating section 6 may be provided on or near the piston operation section 4, rather than on the mouthpiece section 31, in such a manner that vibration of the vibrator can be transmitted to at least one hand of the human player operating the piston operation section 4. Alternatively, the vibrating section 6 may be provided separately from the electronic wind instrument 1 in such a manner that a vibrating signal output from the control section 10 can be received by the vibrating section 6 via wired or wireless communication and vibration of the vibrating section 6 can be transmitted to another body part of the human player than body parts contacting the electronic wind instrument 1. Further, the electronic wind instrument 1 may, for example, include a terminal for connection thereto of headphones in such a manner that a tone of a pitch corresponding to an operational position of the mouthpiece section 31 can be output from the headphones connected to the terminal in order to audibly notify an expected tone generating style.
(2) Whereas the above-described first embodiment is constructed to display a tone generating style, indicative of a tone pitch corresponding to an operational position of the mouthpiece section 31, in the fashion shown in
(3) Further, the above-described first embodiment is constructed to display, as the tone generating style, a tone pitch corresponding to a moved-to position (current operational position) of the mouthpiece section 31. As a modification of the above-described first embodiment, a pressure sensor may be provided on the mouthpiece section 31 for detecting, as a physical amount caused by human player's operation on the mouthpiece section 31, pressure with which the human player presses the lips against the mouthpiece section 31, and a tone pitch corresponding to the detected pressure may be displayed as the tone generating style. In this case, tone pitch information, in which various possible output values of the pressure sensor and tone pitches are associated with each other, may be stored so that a tone generating style indicative of a tone pitch corresponding to an output value from the pressure sensor provided on the mouthpiece section 31 can be displayed in generally the same manner as in the first embodiment.
(4) Whereas the first embodiment of the present invention has been described above as applied to an electronic wind instrument used as a tone generation apparatus, it may be applied to an acoustic or natural wind instrument. In such a case, a pressure sensor may be provided on the mouthpiece of the acoustic or natural wind instrument and values output from the pressure sensor when the human player plays tones of individual pitches may be prestored in association with the individual pitches, so that a tone pitch corresponding to an output result (value) of the pressure sensor can be notified to the human player in generally the same manner as in the above-described first embodiment. As an alternative, a sensor for detecting an operational state of the pistons may be provided in addition to the pressure sensor provided on the mouthpiece, and various tone pitches may be prestored in association with values output from the pressure sensor and operational states of the pistons when the human player plays tones of the individual pitches, so that a tone pitch corresponding to output results (values) of the pressure sensor and the pistons can be notified to the human player in generally the same manner as in the above-described first embodiment. Note that the above-described second embodiment too may be applied to an acoustic or natural wind instrument in the same manner as set forth above in relation to the first embodiment.
(5) Whereas the above-described first embodiment is constructed to identify one tone pitch in accordance with an operational position of the mouthpiece section 31, the first embodiment may be modified in such a manner that it identifies a plurality of potential tone pitches likely to be generated in correspondence with a combination of the operational position of the mouthpiece section 31 and fingering. In this case, at least one tone generating style indicative of any of the identified tone pitches that satisfies a predetermined condition, such as the lowest or highest one of the tone pitches may be notified, or a tone generating style indicative of all of the identified tone pitches may be notified.
(6) Further, whereas the above-described second embodiment of the present invention is constructed to notify variation in resonance, corresponding to an operational position of the mouthpiece section 31, by a tone volume (tone vibration level) and mechanical vibration of the vibrator, such variation in resonance may be notified by other means than the aforementioned. For example, a display section 5 may be provided on the electronic wind instrument 1a as in the first embodiment, and information indicative of a gain corresponding to an operational position of the mouthpiece section 31 may be visually displayed on the display section 5, or positional relationship between the reference point of a tone pitch corresponding to piston operation and the operational position of the mouthpiece section 31 and the operational position of the mouthpiece section 31 may be visually displayed on the display section 5. Alternatively, one of the tone pitch and gain may be notified by mechanical vibration of the vibrator, and the other of the tone pitch and gain may be visually displayed on the display section 5.
(7) Further, whereas the above-described second embodiment of the present invention is constructed to adjust a tone volume level corresponding to breath pressure in accordance with a gain corresponding to an operational position of the mouthpiece section 31, a tone color and quality of a tone pitch corresponding to piston operation and the operational position of the mouthpiece section 31 may be varied in accordance with the operational position of the mouthpiece section 31.
(8) Further, the second embodiment of the present invention has been described above in relation to the case where each tone pitch represented by an operational position of the mouthpiece section 31 is varied linearly as a characteristic of the tone pitch/gain determination table of
(9) Furthermore, whereas the above-described second embodiment of the present invention is constructed to notify variation in resonance, corresponding to an operational position of the mouthpiece section 31, by a tone volume and vibration of the vibrator, such variation in resonance may be notified by any one of the tone volume and vibration of the vibrator.
(10) Furthermore, the second embodiment of the present invention has been described above in relation to the case where tone pitches and gain information corresponding to moved-to positions of the mouthpiece section 31 are predefined. As a modification of the second embodiment, a pressure sensor may be provided on the mouthpiece section 31 for detecting, as a physical amount caused by human player's operation on the mouthpiece section 31, pressure with which the human player's lips are pressed against the mouthpiece section 31, and intensities of pressure with which the human player's lips are pressed against the mouthpiece section 31, tone pitches and gain information may be predefined so that a tone volume and vibration of the vibrator can be adjusted in accordance with the gain information corresponding to an output value from the pressure sensor provided on the mouthpiece section 31.
(11) The first and second embodiments of the tone generating style notification control apparatus of the present invention have been described above as applied to an electronic wind instrument, such as a trumpet. As another embodiment, the basic principles of the present invention may be applied or implemented as a program which notifies a tone generating style on the basis of a value of a pressure sensor and gain information output from the electronic wind instrument.
(12) Whereas the first and second embodiments have been described above in relation to the case where a tone of a trumpet tone color is generated, the present invention may be applied to still another application where a tone of another brass wind instrument, such as a trombone or cornet, is generated. In such a case, a table predefining relationship among various fingerings corresponding to a musical instrument of a tone color to be sounded, operating positions of the mouthpiece section 31 and harmonics may be stored in the storage section 12, and the tone generating style notification control may be performed using such a table. Further, the present invention may be applied to another application where a tone of a woodwind instrument is generated. In such a case, there may be stored a table indicative of relationship between tone pitches and various values of pressure with which a reed is held between human player's lips, and pressure with which the reed is held between the human player's lips or a physical amount corresponding to such pressure may be detected so that tone generating style notification control can be performed using the table. Further, for each of a plurality of musical instrument tone colors, a table predefining relationship among various fingerings corresponding to a musical instrument of that tone color, operating positions of the mouthpiece section 31 and harmonics may be prestored in the storage section 12. In this case, one of the tables is selected in accordance with selection of any one of the musical instrument tone colors, so that the tone generating style notification control can be performed using the selected table.
(13) The first embodiment has been described above in relation to the case where both information for identifying a tone pitch to be displayed and information for identifying a tone pitch at the time of tone generation is identified using the tone pitch determination table, separate tables having both of such information stored therein may be prestored.
This application is based on, and claims priorities to, JP PA 2010-217709 filed on 28 Sep. 2010 and JP PA 2010-217710 filed on 28 Sep. 2010. The disclosure of the priority applications, in its entirety, including the drawings, claims, and the specification thereof, are incorporated herein by reference.
Number | Date | Country | Kind |
---|---|---|---|
2010-217709 | Sep 2010 | JP | national |
2010-217710 | Sep 2010 | JP | national |