JP3768319B2 - Electronic percussion instrument device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electronic percussion instrument device, and more particularly to an electronic percussion instrument device that simulates a percussion instrument such as an acoustic drum that produces a musical tone when a player strikes with a stick or the like.
[0002]
[Prior art]
In general, an electronic percussion instrument such as an electronic drum simulating an acoustic drum is known. Among such electronic percussion instruments, for example, a structure capable of adjusting the tension of a striking surface called a head is known. Things have been proposed.
[0003]
In the present specification, adjusting the tension of the striking surface called a head is referred to as “tuning”.
[0004]
By the way, as an electronic percussion instrument apparatus capable of adjusting the tension of the head, that is, tuning the head, an electronic percussion instrument apparatus using a head similar to a normal acoustic drum is known. When tuning a head of an electronic percussion instrument that uses a head similar to that of an ordinary acoustic drum, as with the acoustic drum, the head is actually struck and the tuning is performed while listening to the impact sound. Just do it.
[0005]
Further, as an electronic percussion instrument device capable of tuning the head, there is a part that becomes a striking surface as disclosed in Japanese Patent Application No. 8-193986 (filing date: July 4, 1996) by the applicant of the present patent application. A head composed of a mesh material has been proposed, and when a head composed of a mesh material is used for such a striking surface, the impact sound is small even when the head is actually struck. There was a problem that even when listening to the sound, sufficient tuning could not be performed.
[0006]
In order to solve these problems, it is proposed to display the hit position of the head, but there is no standard for tuning which position of the head should be hit and what position information should be matched. There was a problem of being clear.
[0007]
For this reason, it has been pointed out that the tuning operation of the head requires the intuition of a skilled user.
[0008]
[Problems to be solved by the invention]
The present invention has been made in view of the above-described problems, and the object of the present invention is to clarify the striking position of the head at the time of tuning operation and display the tuning state while confirming it. It is an object of the present invention to provide an electronic percussion instrument device that can be tuned so that anyone can easily perform the tuning operation without requiring the intuition of a skilled user.
[0009]
[Means for Solving the Problems]
  In order to achieve the above object, the invention according to claim 1 of the present invention is an electronic percussion instrument that detects a hit as an electric signal and generates a musical tone based on the detected electric signal. A tunable head provided with a position mark, a hit point position detecting means for detecting a hit point position based on an electric signal generated by hitting the hit point position mark of the head, and a hit point position corresponding to a detection result by the hit point position detecting means And a display means for displaying tuning reference marks corresponding to the hit point positions when the hit point mark is hit in a state where the head has been tuned correctly.
[0010]
  Therefore, according to the first aspect of the present invention, when the user performs the tuning operation of the head, the user strikes the spot provided with the spot position mark on the head, and the detection by the spot position detection means at that time is performed. Since the tuning operation can be performed while confirming the result and the tuning reference mark at the position corresponding to the hit point position mark on the display means, when the user hits the spot provided with the hit point position mark of the head, Since the detection result of the hit point position detecting means and the tuning reference mark corresponding to the hit point position mark can be simultaneously confirmed by the display means, the tuning operation can be easily performed without depending on the user's intuition.
[0011]
  The invention according to claim 2 of the present invention is the invention according to claim 1 of the present invention, wherein the display means correctly performs the detection result by the hit point position detecting means and the tuning of the head. In this state, the deviation from the tuning reference mark corresponding to the hit point position when the hit point mark is hit is displayed.
[0012]
  In this case, when the user strikes the spot where the head spot position mark is provided, the deviation between the detection result by the spot position detection means and the reference information corresponding to the spot position mark is displayed by the display means. Since it can be confirmed, the tuning operation is further simplified.
[0013]
  The invention according to claim 3 of the present invention further comprises means for selecting the head type of the head as the tuning state of the head in the invention according to claim 1 of the present invention. The display of the dot position corresponding to the detection result by the dot position detecting means is corrected in accordance with the head type selected by the selecting means.
[0014]
  In such a case, the display corresponding to the detection result by the hit point position detecting means is corrected corresponding to the selected head type, so that the tuning operation is further simplified.
  The invention according to claim 4 of the present invention further comprises means for selecting a tuning type of the head as a tuning state of the head in the invention according to claim 1 of the present invention. The display of the hit point position corresponding to the detection result by the hit point position detecting means is corrected in accordance with the tuning type selected by the selecting means.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an example of an embodiment of an electronic percussion instrument apparatus according to the present invention will be described in detail with reference to the accompanying drawings.
[0016]
FIG. 1 is a block diagram showing an example of an embodiment of an electronic percussion instrument according to the present invention. This electronic percussion instrument detects a hit on a head 12 having a striking surface made of a net-like material as will be described later. Output from the head sensor 14 and the rim shot sensor 18 provided with the rim shot sensor 18 for detecting the hit to the rim 16 and the head sensor 14 as the hit detection means to perform. The detected signal is analog / digital (A / D) converted in a time-sharing manner and input to the DSP 22 described later, and the detection signal of the head sensor 14 input from the A / D converter 20 is used. The rim shot sensor input from the A / D converter 20 as well as the impact on the head 12 and its strength, striking position and performance with the brush are detected. A DSP 22 that detects the hit and strength of the rim 16 from the detection signal of the sir 18 and supplies it to the CPU 24 described later, and converts the output from the DSP 22 into necessary performance information by the sound source IC 34 described later and supplies it to the sound source IC 34. In addition, a CPU 24 that detects an operation of an operator group 30 to be described later and controls the DSP 22, a read-only memory (ROM) 26 that stores a program to be executed by the CPU 24, and the CPU 24 Random access memory (RAM) 28 as a working area necessary for program execution, and a mode selection operator, tone selection or level for setting a normal performance mode, brush performance mode or tuning mode as an operation mode An operator group 30 including operators for setting and the like; A display device 32 that displays the operation mode selected by the operators of the operator group 30, the timbre necessary for tone selection, and the tuning status in the tuning mode, and a waveform memory 36 to be described later based on performance information from the CPU 24. To generate a digital musical tone signal and output it to a digital / analog (D / A) converter 38, which will be described later, a waveform memory 36 storing sampling waveform data for forming a musical tone signal, and a tone generator IC 34 And a D / A converter 38 for converting the digital musical tone signal supplied from the digital musical tone signal into an analog musical tone signal and outputting the analog musical tone signal to a sound system including an amplifier and a speaker. Next, the configuration of the hit detection device 10 will be described with reference to a perspective view of the hit detection device 10 shown in FIG. 2 and a sectional view taken along line III-III of FIG. 2 shown in FIG.
[0017]
The hit detection device 10 includes a cylindrical body portion 50, and an engagement portion including a screw hole (not shown) in which a thread groove (not shown) is formed on the outer peripheral portion of the body portion 50. 52 is formed protruding in the radial direction with a predetermined interval. The engaging portion 52 is screwed with an engaging pin 54 formed with a screw thread that is screw-engaged with the thread groove formed in the engaging portion 52, and the head 12 is connected to the engaging portion 52 via the engaging pin 54. The rim 16 is attached to the body portion 50. The engaging pin 54 is formed with a locking projection 54 a for locking the rim 16.
[0018]
Here, as shown in FIG. 4 and FIG. 5, the head 12 includes a first net 56 and a second net 58 woven by a plain weave in which vertical and horizontal fibers are orthogonal as a net-like material. They are laminated so as to cross each other and adhered to the frame 60. Here, the weft direction of the first net 56 and the second net 58 is oblique, as shown in FIG. 6, the first and second nets 56 and 2 are perpendicular to each other at 90 degrees. This means that when the net 58 is overlapped, the fibers of the adjacent first net 56 and second net 58 intersect at an angle α smaller than 90 degrees.
[0019]
Further, as shown in FIG. 17, the dot position mark M for the tuning operation formed in a circular shape is displayed on the upper surface of the head 12 by printing.
[0020]
The rim 16 is formed by integrally molding a metal material. The rim 16 has an edge 66 having a hole 64 through which the engagement pin 54 can be inserted in the outer periphery, and extends to the inner periphery of the edge 66. A rim striking portion 68 is provided and formed to rise. And the upper part of the rim | limb hit | damage part 68 is coat | covered with the cover member 70 formed with elastic materials, such as rubber | gum and sponge.
[0021]
In order to attach the head 12 and the rim 16 having the above-described configuration to the body portion 50, first, the head portion 12 is covered with the head 12, and the rim 16 is further covered over the head 12. The position is adjusted so that the screw holes of the 50 engaging portions 52 communicate with each other. Then, the engaging pin 54 is inserted into the hole 64 of the rim 16 and the screw hole of the engaging portion 52 of the trunk portion 50, and the thread of the engaging pin 54 and the screw groove and screw of the engaging portion 52 of the trunk portion 50 are inserted. By coupling, the head 12 and the rim 16 are attached to the body 50 by the locking projection 54a of the engagement pin 54.
[0022]
That is, as the engaging pin 54 is screwed into the screw hole of the engaging portion 52 of the body portion 50, the edge 66 of the rim 16 is pushed downward in FIG. The frame 60 of the head 12 is also pushed downward. For this reason, the first net 56 and the second net 58, which are restricted from moving downward by the upper end 50a of the trunk 50, are stretched on the trunk 50 with a predetermined tension. Therefore, the tension between the first net 56 and the second net 58 can be arbitrarily controlled by adjusting the amount of the engaging pin 54 screwed into the screw hole of the engaging portion 52 of the body portion 50. As a result, the head 12 can be tuned.
[0023]
A head sensor support member 72 is disposed in the body portion 50 so as to intersect the axial center position of the body portion 50. The head sensor 14 is attached to the central portion of the upper surface of the head sensor support member 72 so as to come into contact with the second net 58 by a cushioning double-faced tape 78 described later. That is, the head sensor 14 is disposed in contact with the lower center surface of the net-like material formed by the first net 56 and the second net 58 of the head 12.
[0024]
As shown in FIGS. 7A, 7B, and 7C, the head sensor 14 includes a disk-shaped piezoelectric element 76 having an output signal line 74, and a cushion is provided on the lower surface of the piezoelectric element 76. A double-sided adhesive tape 78 is affixed. The diameter of the cushioning double-sided tape 78 is set to coincide with the node diameter of the piezoelectric element 76.
[0025]
Further, a truncated cone-shaped cushion member 80 made of an elastic material such as rubber or sponge is attached to the upper surface of the piezoelectric element 76. The cushion member 80 has a bottom surface formed to have a diameter larger than the diameter of the piezoelectric element 76, is tapered toward the upper side, and is in contact with the second net 58 at the distal end portion having a small diameter.
[0026]
Further, a rim shot sensor 18 is attached by a cushioning double-sided tape 78 in the vicinity of the rim hitting portion 68 on the inner upper side of the body portion 50. The rim shot sensor 18 includes a disk-shaped piezoelectric element 76 having an output signal line 74, and a cushioning double-sided tape 78 is attached to the lower surface of the piezoelectric element 76. The diameter of 78 is set to coincide with the node diameter of the piezoelectric element 76.
[0027]
In other words, in this electronic percussion instrument device, the cushion sensor 80 is removed from the head sensor 14 and used as the rim shot sensor 18 to improve the efficiency of parts.
[0028]
In this electronic percussion instrument device, various heads 12 having different diameters and body portions 50 suitable for the heads 12 are prepared, and the size of the head 12 can be changed as appropriate.
[0029]
  In the above configuration, when the head 12 is hit with a stick (not shown), the head sensor 14 detects the hit, and when the rim 16 is hit with a stick, the rim shot sensor 18 is When the hit is detected and the head 12 is rubbed or hit with the brush, the head sensor 14 detects the contact of the brush with the head 12.
[0030]
Next, electrical processing contents in the electronic percussion instrument apparatus will be described with reference to the attached flowchart.
[0031]
FIG. 8 shows a flowchart of a main routine executed by the CPU 24. When power is supplied to the electronic percussion instrument device, first, initialization of the memory, registers, etc. is performed (step S802).
[0032]
  Next, the operation mode of the mode selection operator of the operator group 30 is monitored, and a tuning mode is set as the operation mode, in which the tension of the mesh material of the head 12 is adjusted to change the hit feeling of the head 12. Or a normal performance mode in which a percussion instrument sound is generated by detecting a hit on the head 12 and a hit on the rim 16 or a rubbing or hitting of the head 12 with a brush is detected. It is determined whether a brush performance mode for sounding is set (step S804).
[0033]
If it is determined in step S804 that the tuning mode is set, the DSP 22 is set to the tuning mode, and the DSP 22 is set to execute the DSP hit signal processing routine shown in FIG. Step S806). Then, a tuning process routine by the CPU 24 shown in FIG. 14 is executed (step S808), the tuning mode stop process of the DSP 22 is performed (step S810), and the process returns to step S804.
[0034]
If it is determined in step S804 that the normal performance mode is set, the DSP 22 is set to the normal performance mode, and the DSP 22 is set to execute the DSP hit signal processing routine shown in FIG. Step S812). Then, the normal performance processing routine by the CPU 24 shown in FIG. 16 is executed (step S814), the normal performance mode stop processing of the DSP 22 is performed (step S816), and the process returns to step S804.
[0035]
If it is determined in step S804 that the brush performance mode is set, the DSP 22 is set in the brush performance mode (step S818). Then, a brush performance processing routine is executed by the CPU 24, the brush performance mode stop processing of the DSP 22 is performed (step S816), and the process returns to step S804. Since the brush performance mode processing is not related to the gist of the present invention, detailed description thereof is omitted.
[0036]
Next, a DSP hit signal processing routine executed by the DSP 22 shown in FIG. 9 will be described. This processing is based on the following characteristics.
[0037]
In other words, when the detection signal of the head sensor 14 is observed when the head 12 made of a net-like material is hit, there is a characteristic that the time of the first half wave changes depending on the hit point position in a certain frequency band. That is, as shown in FIGS. 10A and 10B, the time of the first half wave when the center of the head 12 (spot position A) is struck is T_AAnd the time of the first half wave when hitting the outer periphery (spot position C) of the head 12 is T_CAnd the time of the first half wave when hitting the middle of the head 12 and the outer periphery (spot position B) is T_BThen,
T_A> T_B> T_C
It becomes.
[0038]
As described above, when the head 12 made of a net-like material is hit, the time of the first half wave is gradually shortened as the hit point position moves from the center to the outer periphery.
[0039]
Further, when the tuning of the head 12 is increased, that is, when the tension of the head 12 is increased, the time T of the first half wave is increased._A, T_B, T_CIs "T_A> T_B> T_CIf the head 12 is tuned lower without changing the relationship, ie, the head 12 is tuned down, ie, the tension of the head 12 is reduced, the first half-wave time T_A, T_B, T_CIs "T_A> T_B> T_CIt becomes longer without changing the relationship.
[0040]
FIG. 11 is a functional block diagram showing the configuration of the head striking point position detecting means of the DSP 22. The outline of the DSP striking signal processing routine will be described with reference to FIG. 11. When the detection signal detected by the head sensor 14 is A A / D converted by the / D converter 20 and input to the DC cut filter. The DC cut filter is a high pass filter that removes a direct current component. The detection signal input to the DC cut filter is a low pass filter that removes an unnecessary high frequency component from the direct current component. (LP filter). The detection signal from which unnecessary high frequency components are removed by the LP filter is input to the first half-wave detection circuit. The first half-wave detection circuit detects the first half-wave by detecting the rising of the waveform of the input detection signal and the first zero cross. The counter counts only while the first half-wave detection circuit detects the first half-wave, and the arithmetic circuit calculates the hit point position based on the counter value. The hit point position thus calculated is input to the CPU 24 as head hit point position information.
[0041]
Here, the DSP hit signal processing routine will be described in detail with reference to FIG. 9. This DSP hit signal processing routine is repeatedly executed at every sampling period of the A / D converter 12.
[0042]
In this DSP hit signal processing routine, first, sampling data S is input (step S902), it is determined whether or not a rising edge has been detected (step S904), and if it is determined that a rising edge has been detected, The timer T is reset (step S906), the first half-wave count flag cf is turned on (ON) (step S908), and the maximum value detection flag mf is turned on (ON) (step S910).
[0043]
Here, the rise detection in step S904 is specifically performed by obtaining the difference between the sampling data S and the previous sampling data, and determining that the rise is when the difference is equal to or greater than a predetermined value. Alternatively, a known technique for detecting the rising edge of the input signal may be used.
[0044]
The timer T is for measuring a predetermined time for detecting the maximum value of the detection signal, and the predetermined time is determined by a register time for storing a preset time.
[0045]
The first half-wave count flag cf is a flag indicating whether or not the count process of the first half-wave counter ct is performed. When the first half-wave count flag cf is on, the first half-wave counter ct is counted. When the first half-wave count flag cf is off, the first half-wave counter ct is not counted. . The maximum value detection flag mf is a flag indicating whether or not to perform a maximum value detection process for input data. When the maximum value detection flag mf is on, the maximum value detection process is performed, and when the maximum value detection flag mf is off, the maximum value detection process is not performed. If the process in step S910 is completed or if it is determined in step S904 that no rising edge has been detected, the process proceeds to step S912 to determine whether the first half-wave count flag is on.
[0046]
Here, Step S912, Step S914, Step S916, and Step S918 are the first half-wave counting process. That is, the first half-wave counter ct is incremented from the step S912 until the first half-wave count flag cf is turned on and the first half-wave ends.
[0047]
Specifically, in step S912, if it is determined that the first half-wave count flag is not on, that is, the first half-wave count flag is off, step S914, step S916, and step S918 are performed. The process jumps to step S920 without performing the process.
[0048]
On the other hand, if it is determined in step S912 that the first half-wave count flag is ON, it is determined whether or not the first half-wave has ended (step S914). If it is determined that the first half-wave has not ended, the first half-wave counter ct is incremented (step S916). If it is determined that the first half-wave has ended, the first half-wave is incremented. The count flag cf is turned off (step S918), and the process proceeds to step S920.
[0049]
Note that the end of the first half-wave in step S914 is the time when the sampling data S crosses 0 (zero), and the determination of whether or not the sampling data S crosses 0 (zero) It can be determined that 0 (zero) has been crossed when the sign of the data S changes.
[0050]
In step S920, it is determined whether or not the maximum value detection flag mf is on, and if it is determined that the maximum value detection flag mf is not on, that is, the maximum value detection flag mf is off, this is left as it is. The DSP hit signal processing routine is terminated.
[0051]
On the other hand, if it is determined in step S920 that the maximum value detection flag mf is on, it is determined whether or not the timer T is greater than the register time (step S922).
[0052]
In step S922, when the timer T is equal to or less than the register time, that is, while the maximum value detection flag mf is on and the timer T is equal to or less than the register time, the maximum value detection process is performed in steps S924 and S926. Execute.
[0053]
  Specifically, the timer T is incremented (step S924), the maximum value max is compared with the absolute value of the sample data S, the maximum value max is rewritten with the larger value (step S926), and DSP hit signal processing is performed. Exit the routine.
[0054]
Accordingly, the maximum value max is the maximum value of the hit signal within a predetermined time determined by the register time.
[0055]
Further, when it is determined in step S922 that the timer T is greater than the register time and the maximum value detection process ends, the maximum value detection flag mf is turned off (step S928).
[0056]
Next, the first half-wave counter ct is changed to the spot position using the table 1 (table1) which is a spot position table for converting the first half-wave count value which is the value of the first half-wave counter ct into the spot position information AP. The information AP is converted (step S930).
[0057]
Here, the table 1 which is a dot position table for converting the first half wave count value which is the value of the first half wave counter ct into the dot position information AP is selected according to the head type and the tuning type. Is.
[0058]
The head type is set to Tom 1 (TOM1), Tom 2 (TOM2), or Snare (SNARE) according to the size of the head 12 in the electronic percussion instrument apparatus. The tuning type corresponds to the tuning state of the head 12, that is, the tension of the head 12, and in this electronic percussion instrument device, loose, medium, and tight. : Hard) is set.
[0059]
As described above, in this electronic percussion instrument apparatus, since three head types are set and three tuning types are set, a total of nine types of tables 1 are provided.
[0060]
FIG. 12 shows characteristics of loose, medium and tight tuning types with respect to the table 1 when the head type is a snare. Here, in FIG. 12, the hit point position A (center), the hit point position B (intermediate), and the hit point position C (outer periphery) of the hit point position information AP correspond to the hit point position A, the hit point position B, and the hit point position C in FIG. is doing.
[0061]
When the process of step S930 is completed, the process proceeds to step S932, and the hit point position information AP is obtained using the table 2 (table 2) which is a hitting force correction table for converting the hit point position information AP obtained in step S930 into the hitting force correction coefficient K. Is converted into a striking force correction coefficient K (step S932).
[0062]
Here, the table 2 which is a striking force correction table for converting the striking point position information AP into the striking force correction coefficient K is selected in accordance with the head type and the tuning type, similarly to the table 1.
[0063]
In this electronic percussion instrument device, as described above, Tom 1, Tom 2 and Snare are set as the head type, and Loose, Medium and Tight are set as the tuning type. A table 2 is provided.
[0064]
FIG. 13 shows the characteristics of loose, medium and tight tuning types with respect to the table 2 when the head type is a snare. Here, in FIG. 13, the hit point position A (center), the hit point position B (intermediate), and the hit point position C (outer periphery) of the hit point position information AP correspond to the hit point position A, the hit point position B, and the hit point position C in FIG. is doing.
[0065]
For example, in the example shown in FIG. 13, when the tuning type is loose, the hit point position A (center) is “K = 1”, and the hit point position B (intermediate) is “K = 4/3”. At the position C (outer periphery), “K = 3”.
[0066]
The head type and tuning type may be represented by numerical values, and the types of the table 1 and the table 2 are not limited to nine.
[0067]
When the process of step S932 is completed, the process proceeds to step S934, and a correction calculation process of multiplying the maximum value max and the hitting force correction coefficient K is performed, and corrected hitting force information V is calculated.
[0068]
When the process of step S934 is completed, the process proceeds to step S936, where the sound generation flag gf in the CPU 24 is turned on (ON), the hit point position information AP and the hitting force information V are set in the CPU 24, and this DSP hit signal processing routine is ended. .
[0069]
Next, the tuning process routine executed by the CPU 24 in step S808 will be described with reference to FIG.
[0070]
In this tuning processing routine, first, the head type setting operator (operator for setting the head type) or the tuning type setting operator (operator for setting the tuning type) of the operator group 30 is used. ), It is determined whether or not an instruction to change the head type or tuning type has been issued (step S1402). When the power is turned on, the initial setting process in step S802 causes the head to store the head type and the tuning to store the tuning type, the head type setting operator, and the tuning type setting operator. Each is set according to the initial setting state.
[0071]
If it is determined in step S1402 that the change of the head type or tuning type is instructed by the operation of the head type setting operator or tuning type setting operator of the operator group 30, It is determined whether or not a type change has been instructed (step S1404).
[0072]
If it is determined that the head type change has been instructed, the stored contents of the register head are changed according to the change instruction (step S1406).
[0073]
When the process of step S1406 is completed, or when it is determined in step S1404 that a change in head type has not been instructed, it is determined whether or not a change in tuning type has been instructed (step S1408). . If it is determined that a tuning type change has been instructed, the stored contents of the register tuning are changed according to the change instruction (step S1410).
[0074]
When the process of step S1410 is completed, or when it is determined in step S1408 that the tuning type has not been instructed, table 1 and table 2 are selected according to the stored contents of register head and register tuning, Set in the DSP 22 (step S1412).
[0075]
  When the process of step S1412 is completed as described above, or in step S1402, neither the head type setting operator or the tuning type setting operator of the operator group 30 is operated, and the head type or tuning If no change of type is instructed, the dot position information AP sent from the DSP 22 is displayed on the display device 32 (step S1414). That is, the hit point position information AP set in the CPU 24 in the DSP hit signal processing routine is displayed on the display device 32.
[0076]
FIG. 15 shows an example of a display mode of the hit point position information AP displayed on the display device 32 in step S1414. That is, in FIG. 15, “CENTER” indicates the center position of the head 12, and “RIM” indicates the position of the rim 16. A black triangle is a mark indicating the hit point position information AP, and a white triangle is a tuning reference mark displayed at a position corresponding to the hit point position mark M (see FIG. 17) displayed on the head 12.
[0077]
Since the position between the center (CENTER) and the rim 16 (RIM) in the head 12 is determined by the hit point position information AP, a black triangle is displayed at the determined position.
[0078]
Further, as described above, the tuning reference mark indicated by the white triangle indicates the position corresponding to the dot position mark M displayed on the head 12 shown in FIG. That is, since the hit point position mark M shown in FIG. 17 is displayed at the midpoint position between the center (CENTER) of the head 12 and the rim 16 (RIM), the tuning reference mark indicated by the white triangle is also shown in FIG. Is displayed at an intermediate point between “CENTER” and “RIM”.
[0079]
In FIG. 15, a number assigned in advance to each tuning type is displayed in the tuning type display field.
[0080]
When the processing of step S1414 is completed, it is determined whether or not the end operator of the operator group 30 has been operated (step S1416). If it is determined that the end operator of the operator group 30 has not been operated, Returning to step S1402, the processing is repeated.
[0081]
On the other hand, if it is determined in step S1416 that the end operator of the operator group 30 has been operated, the process returns to the main routine.
[0082]
Next, the normal performance processing routine executed by the CPU 24 in step S814 will be described with reference to FIG.
[0083]
In this normal performance processing routine, first, a level operator (operator for setting the volume of a musical tone to be generated), a tone operator (operator for setting the tone of a musical tone to be generated) or a tuning operator of the operator group 30. It is determined whether or not the (operator for setting the pitch of the musical tone to be generated) has been changed (step S1602). When the power is turned on, the register level for storing the level, the register tone for storing the timbre, and the register pitch for storing the pitch by the initial setting process in step S802 are the level operator, the timbre setting operator, and the tuning operation. Each is set according to the initial setting state of the child.
[0084]
If it is determined in step S1602 that the level operator, tone color setting operator, or tuning operator of the operator group 30 has been changed, it is determined whether the level operator has been changed (step S1604). .
[0085]
If it is determined that the level operator has been changed, the stored content of the register level is changed according to the change (step S1606).
[0086]
When the processing of step S1606 is completed, or when it is determined in step S1604 that the level operator has not been changed, it is determined whether or not the timbre operator has been changed (step S1608).
[0087]
If it is determined that the timbre operator has been changed, the stored contents of the register tone are changed according to the change, and the start address and end address of the waveform data corresponding to the stored contents of the register tone are set as the tone generator IC34. (Step S1610).
[0088]
When the process of step S1610 is completed, or when it is determined in step S1608 that the timbre operator has not been changed, it is determined whether or not the tuning operator has been changed (step S1612).
[0089]
If it is determined that the tuning operator has been changed, the stored content of the register pitch is changed according to the change, and pitch information corresponding to the stored content of the register pitch is set in the sound source IC 34 (step S1614). .
[0090]
When the process of step S1614 is completed as described above, when it is determined in step S1612 that the tuning operator has not been changed, or in step S1602, the level operator of the operator group 30 of the operator group 30; If neither the tone color setting operator nor the tuning operator has been changed, it is determined whether or not the sound generation flag gf is ON (step S1616). Specifically, in step S936 of the DSP hit signal processing routine, it is determined whether the sound generation flag gf of the CPU 24 is turned on and sound generation is instructed.
[0091]
If it is determined that the sound generation flag gf is on, the calculation result of “level × V” is set in the sound source IC 34 as level information (step S1618). That is, the sound level is calculated by multiplying the striking force information V by the value stored in the register level set by the level operator, and this calculation result is set in the sound source IC 34 as level information.
[0092]
When the process of step S1618 is completed, the hit point position information AP is converted into a filter coefficient for controlling the filter characteristics and set in the sound source IC 34 (step S1620). That is, by converting the hit point position information AP into a filter coefficient for controlling the filter characteristics and setting it in the sound source IC 34, a timbre corresponding to the hit point position can be obtained. Note that the process for obtaining the tone corresponding to the hit point position is not limited to the process shown in step S1620. Instead of the process in step S1620, the waveform to be read is switched or the mixing ratio of a plurality of waveforms is changed. You may make it do.
[0093]
When the process of step S1620 ends, the sound generation flag gf is turned off (step S1622). That is, when the sound generation process is completed as described above, the sound generation flag is turned off.
[0094]
When the process of step S1622 is completed, or when it is determined in step S1616 that the sound generation flag gf is off, it is determined whether or not the end operator of the operator group 30 has been operated (step S1624). If it is determined that the end operator of the operator group 30 has not been operated, the process returns to step S1602 to repeat the process.
[0095]
On the other hand, if it is determined in step S1624 that the end operator of the operator group 30 has been operated, the process returns to the main routine.
[0096]
Note that the process of emitting a musical sound from the electronic percussion instrument device to the outside is performed under the control of the sound source IC 34.
[0097]
Next, a typical operation procedure of the tuning operation of the head 12 will be described with reference to a flowchart shown in FIG. Note that the flowchart shown in FIG. 18 shows the procedure of the tuning operation performed by the user after the user selects the tuning mode.
[0098]
That is, when the user selects the tuning mode, first, a desired head type is set by operating the head type setting operator of the operator group 30 (step S1802), and then the tuning / setting of the operator group 30 is performed. A preferred tuning type is set by operating the type setting operator (step S1804).
[0099]
In accordance with the operations of step S1802 and step S1804, the processing of step S1402, step S1404, step S1406, step S1408, step S1410 and step S1412 of the tuning processing routine executed by the CPU shown in FIG. 14 is executed.
[0100]
Next, in this tuning operation, the user hits on the hit point position mark M of the head 12 close to the engaging pin 54 being operated (step S1806). Note that steps after S1806 are actual tuning operations.
[0101]
When the hit on the hit point position mark M of the head 12 in step S1806, the hit point position information AP sent from the DSP 22 by the execution of the hit signal processing routine of FIG. 9 is the step of the tuning process routine executed by the CPU shown in FIG. The image is displayed on the display device 32 in S1414.
[0102]
Here, by visually observing the display device 32, it is confirmed at which position the black triangle indicating the hit point position information AP resulting from the hit in step S1806 is displayed (step S1808).
[0103]
Then, it is determined whether or not there is a positional deviation between the position of the black triangle indicating the hit point position information AP and the position of the white triangle indicating the tuning reference mark (step S1810).
[0104]
Here, when it is determined that there is a positional deviation between the position of the black triangle indicating the hit point position information AP and the position of the white triangle indicating the tuning reference mark, the engagement pin 54 is set so as to correspond to the positional deviation. Is adjusted to adjust the tension of the head 12 (step S1812).
[0105]
Thus, after performing the operation of step S1812, the process returns to step S1806 and the operation is repeated.
[0106]
On the other hand, if it is determined that there is no positional deviation between the position of the black triangle indicating the hit point position information AP and the position of the white triangle indicating the tuning reference mark, it is determined whether or not the tuning operation has been completed (step). S1814). Here, the determination of whether or not the tuning operation has been completed specifically determines whether or not the tuning operation of all the engagement pins 54 has been completed.
[0107]
If it is determined that the tuning operation has not been completed, the process returns to step S1806 to perform the tuning operation on the engagement pin 54 that has not been tuned.
[0108]
On the other hand, if it is determined that the tuning operation has been completed, the tuning operation is terminated.
[0109]
In the embodiment described above, the hit point position mark M displayed on the upper surface of the head 12 is formed in a circular shape as shown in FIG. 17, but the shape of the hit point position mark M is shown in FIG. For example, as shown in FIG. 19A, the hit point position mark M may be displayed by a predetermined number of points. Further, as shown in FIG. 19B, the area of the head 12 is color-coded (in FIG. 19B, the hatched portion of the area of the head 12 is displayed in a different color from the other parts). .), And the boundary portion color-coded may be used as the hit point position mark M.
[0110]
Further, in the above-described embodiment, the tuning reference mark indicated by the white triangle in FIG. 15 is displayed corresponding to the hit point position mark M of the head 12, but is not limited to this. For example, together with the table 1 and the table 2 selected by the head type and the tuning type set in the tuning processing routine executed by the CPU shown in FIG. 14, the white triangle display position information is stored as tuning reference data. You may make it keep. In the above-described embodiment, as shown in FIG. 15, the display device 32 displays a black triangle indicating the hit point position information AP and a white triangle indicating a tuning reference mark corresponding to the hit point position mark M of the head. However, the display on the display device 32 is not limited to this. For example, as shown in FIG. 20, the deviation between the tuning reference data and the detected spot position information AP is displayed. Also good.
[0111]
Specifically, the tuning reference data is read out during the display process of the dot position information AP in step S1414 of the tuning process routine executed by the CPU shown in FIG. 14, and the tuning reference data and the dot position information AP are compared. The deviation may be calculated and the deviation indicated by the calculation result may be displayed on the display device 32. If the display device 32 is set to display “0” when the deviation is “0”, the tuning is correct when the display device 32 displays “0”.
[0112]
As a display method in the display device 32, in addition to the above-described method, when the difference between the tuning reference data and the hit point position information AP is equal to or less than a predetermined value, the fact that the tuning has been achieved is notified. Good. Alternatively, a method of displaying the difference between the tuning reference data and the hit point position information AP by a cent display as used in a tuning device for a stringed instrument such as a guitar may be used.
[0113]
【The invention's effect】
  Since the present invention is configured as described above, the user strikes a portion provided with the hit point position mark of the head, the detection result by the hit point position detecting means at that time, and the position corresponding to the hit point position mark Since the tuning operation can be performed while confirming the tuning reference mark with the display means, the tuning operation can be easily performed without relying on the user's intuition.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an example of an embodiment of an electronic percussion instrument device according to the present invention.
FIG. 2 is a perspective view of a hit detection device.
3 is a cross-sectional view taken along line III-III in FIG.
FIG. 4 is a perspective view of a head.
FIG. 5 is an exploded perspective view of a head.
FIG. 6 is an explanatory diagram showing a case where the texture direction of the first net and the second net cross each other.
7A and 7B are explanatory diagrams of a head sensor, in which FIG. 7A is a view as viewed from an arrow A in FIG. 7B, FIG. 7B is a front view, and FIG.
FIG. 8 is a flowchart of a main routine executed by the CPU.
FIG. 9 is a flowchart of a DSP hit signal processing routine executed by the DSP.
FIGS. 10A and 10B are explanatory diagrams of characteristics of a head formed of a net-like material, in which FIG. 10A shows the hit point position on the head, and FIG.
FIG. 11 is a functional block diagram showing a configuration of DSP head hitting point position detecting means in a normal performance mode.
FIG. 12 is an explanatory diagram illustrating characteristics of the table 1;
FIG. 13 is an explanatory diagram illustrating characteristics of the table 2;
FIG. 14 is a flowchart of a tuning process routine executed by the CPU.
FIG. 15 is an explanatory diagram showing an example of a display mode of hit point position information AP by the display device.
FIG. 16 is a flowchart of a normal performance processing routine executed by the CPU.
FIG. 17 is a schematic top view of the hit detection device showing an example of a hit point position mark displayed on the upper surface of the head.
FIG. 18 is a flowchart showing a typical operation procedure of a head tuning operation.
FIG. 19 is a schematic top view of a hit detection device showing another example of the hit point position mark displayed on the upper surface of the head, wherein (a) and (b) show different examples.
FIG. 20 is an explanatory diagram showing another example of a display mode of hit point position information AP by the display device.
[Explanation of symbols]
10 Stroke detection device
12 heads
14 Head sensor
16 rims
18 Rim shot sensor
20 A / D converter
22 DSP
26 ROM
28 RAM
30 operator group
32 display devices
34 Sound source IC
36 Waveform memory
38 D / A converter
50 trunk
52 engaging part
54 engaging pin
56 First net
58 Second net
60 frames
64 holes
66 Edge
68 Rim hitting part
70 Cover member
72 Head sensor support member
74 Output signal line
76 Piezoelectric element
78 Cushioning double-sided tape
80 Cushion material
M dot position mark

Claims (4)

In an electronic percussion instrument device that detects a hit as an electrical signal and generates a musical sound based on the detected electrical signal,
A tunable head with a dot position mark for tuning,
A hit point position detecting means for detecting a hit point position based on an electrical signal by hitting the hit point position mark of the head;
Display means for displaying a hit point position corresponding to a detection result by the hit point position detecting means and a tuning reference mark corresponding to the hit point position when the hit point mark is hit in a state where the head is properly tuned. And an electronic percussion instrument device. The electronic percussion instrument device according to claim 1.
The display means displays a deviation between a detection result by the hit point position detecting means and a tuning reference mark corresponding to the hit point position when the hit point mark is hit in a state where the tuning of the head is correctly performed. An electronic percussion instrument. The electronic percussion instrument device according to claim 1,
Means for selecting a head type of the head as a tuning state of the head;
The electronic percussion instrument apparatus, wherein the display of the hit point position corresponding to the detection result by the hit point position detecting means is corrected corresponding to the head type selected by the selecting means. The electronic percussion instrument device according to claim 1,
Means further comprising means for selecting a tuning type of the head as a tuning state of the head;
The electronic percussion instrument apparatus, wherein the display of the hit point position corresponding to the detection result by the hit point position detecting means is corrected according to the tuning type selected by the selecting means.

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