JP4665956B2 - Performance information acquisition device - Google Patents

Description

  The present invention relates to a hammer detection device that detects a physical quantity related to the movement of a hammer or pseudo hammer in a keyboard instrument such as a piano, and a performance information acquisition device that acquires information related to performance using the detection result of the hammer detection device.

Conventionally, in a keyboard instrument such as an automatic piano, movement of a key or the like is detected by a sensor, and this is recorded as performance data or supplied to an electronic sound source to generate musical sounds electronically. .
In a conventional automatic piano, for example, a sensor such as an optical sensor is arranged below each key, and a key sensor system is employed that detects the operation timing and operation speed of a shutter attached to the lower surface of the key with this sensor. Yes.
However, since the key operation and the hammer operation do not always match, the above key sensor method may cause the timing of pronunciation to be shifted or the intensity of the musical tone to be inaccurate when special keys such as continuous hitting are performed. was there. For example, when the key is moved in small increments, the keystroke is short and the loud sound is not generated with an acoustic piano. May end up.

  In view of this, a hammer sensor for detecting the operation of the hammer is provided, and the speed of the hammer immediately before striking is measured based on the detection result of the hammer sensor. Here, FIG. 18 shows an explanatory diagram of detection of the stringing speed of a conventional hammer. The hammering speed of the hammer 44 is detected by the hammer detection unit 70 as follows. When the hammer 44 approaches the string S, the shutter 71 attached to the hammer shank 43 is inserted into the hammer detector 70, and the leading edge of the shutter 71 is aligned with the optical axis P of the optical sensor 77, as shown by the one-dot chain line in FIG. Will be crossed.

  As a result, the light receiving portion of the optical sensor 77 is shielded, and the light shielding timing is detected by the controller. The positions of the hammer 44 and the hammer shank 43 at that time are indicated by H2 in FIG.

Thereafter, the hammer shank 43 is further rotated, and the window 71a of the shutter 71 crosses the optical axis P of the optical sensor 77 as shown by a two-dot chain line in FIG.
As a result, the light receiving portion of the optical sensor 77 is again in the light receiving state. This light reception timing is detected by the controller. The positions of the hammer 44 and the hammer shank 43 at that time are indicated by H3.
As described above, in the controller, the light blocking timing and the light receiving timing of the optical sensor 77 are detected. Then, while outputting the light shielding timing at the position H2 and the light receiving timing at the position H3, the string striking speed is calculated from the time from the position H2 to the position H3.

  By the way, when calculating the string striking speed as described above, the timing at which the window 71a of the shutter 71 passes the optical axis P is preferably just before the hammer 44 strikes the string S. However, adjusting the optical axis P and the position of the shutter 71 so that the windows 71a of the shutters 71 corresponding to all the hammers 44 of the piano pass the optical axis P immediately before stringing is performed for the following reason. Have difficulty.

  In the grand piano, the shank rail that supports the hammer action mechanism is provided in a straight line over the width direction of the piano. On the other hand, in a grand piano, a string tension of about 20000 kg is applied to an iron frame or support, etc., so that the frame is distorted, and the string height, that is, the vertical dimension between the string bottom surface and the shelf top surface is It is not always straight. For example, as shown in FIG. 19, due to the distortion generated as described above, the string height becomes larger in the middle part, as shown, the end part has a string height of 195 mm, and the center part has a string height of 195 mm. A difference of about 2 mm such as 197 mm occurs in any grand piano.

  When there is a difference in the string height in this way, when setting is made to detect the passage timing of the optical axis P immediately before the string hitting with the string height at the end as a reference, for example, H2 to H3 are 5 before the string hitting. When the detection interval is set to 5 mm to 0.5 mm, and the same setting is made for the central string, 7.5 mm to 2.5 mm before stringing becomes the detection interval. There is a risk that the error from the speed immediately before the string will be increased. In addition, when the above-described hammer detection unit 70 is used, if the member holding the hammer detection unit 70 is deformed, the position balance may be lost and the detection section may not be as set.

  In addition, as described above, when speed detection is performed using two points such as H2 and H3 as a detection section, a detection error at the time of weak hitting may increase. This is because the hammer 44 may be greatly decelerated within the detection section at the time of weak hitting. In this case, a large error occurs between the actual stringing speed and the detected speed.

  In addition, when speed detection is performed, it is ideal to change the detection section between a weak hit and a strong hit. Specifically, it is better that the detection interval is shorter when the hit is weak, and it is ideal that the detection interval is larger than when the hit is strong. However, in the method using the hammer detection unit 70, the detection interval is changed. I can't.

  Further, in the above-described hammer detection unit 70, in order to detect the speed more accurately, the mounting position must be adjusted for each key, and the mounting work is complicated. When adjusting the action mechanism or the like of the piano provided with the hammer detecting unit 70, the hammer detecting unit 70 must be removed and the hammer detecting unit 70 must be attached at an appropriate position again after adjusting the action mechanism. Therefore, the work is complicated.

  In particular, when performance data or the like is created using the stringing timing and stringing speed acquired by the hammer detector 70 as described above, it is necessary to acquire more accurate stringing timing and stringing speed. The mounting position of the hammer detection unit 70 has a very important meaning. Some automatic piano playback systems have a correction table for correcting the state of the piano or the like. The data detected by the hammer detection unit 70 is also used to create the correction table. Therefore, it is conceivable that erroneous detection by the hammer detection unit 70 affects the playback system of the automatic piano.

  The present invention has been made in view of the above circumstances, and is a hammer detection device that can detect the movement of a hammer or a pseudo hammer more accurately while requiring no complicated mounting work on a keyboard instrument. And a performance information acquisition apparatus including the same.

The performance information acquisition device according to the present invention includes a key, a string or a hit member, and a hammer provided to be movable between a rest position and a position where the string or hit member is hit according to the operation of the key. Alternatively, in a keyboard instrument provided with a pseudo hammer, it is a device for detecting physical quantities related to the movement of the hammer or pseudo hammer and obtaining information related to performance, and hits the string or hit member from the rest position. Based on the physical quantity related to the movement of the hammer or pseudo hammer continuously detected by the hammer detection means for continuously detecting the physical quantity related to the movement of the hammer or pseudo hammer until the return to the rest position. a performance information acquisition means for acquiring information relating to play, a key release timing after the key is pressed The to information is characterized by comprising a performance information acquisition means for acquiring with the information indicating the virtual moving distance or the correction time of the hammer or the hammer or pseudo hammer in accordance with the movement of the pseudo hammer.

  The performance information acquisition device according to the present invention is provided to be movable between a key, a string or a hit member, and a rest position and a position where the string or hit member is hit according to the operation of the key. In a keyboard instrument provided with a hammer or a pseudo hammer and a damper, a device for detecting physical quantities relating to the movement of the hammer or pseudo hammer and obtaining information relating to performance, wherein the string or hit from the rest position Hammer detection means for continuously detecting a physical quantity relating to the movement of the hammer or pseudo hammer until the member is hit and returned to the rest position, and continuous movement of the hammer or pseudo hammer detected by the hammer detection means Performance information acquisition means for acquiring information related to performance based on a physical quantity related to the hammer or pseudo The damper after striking the string or struck member by Ma is characterized by comprising a performance information acquisition unit that acquires information that indicates the timing of contact with the string or struck member.

In the performance information acquisition apparatus according to the present invention, the performance information acquisition means uses the virtual movement distance or correction time of the hammer or pseudo-hammer according to the movement of the hammer or pseudo-hammer as information indicating the key pressing timing. The structure acquired using the information shown may be sufficient.

  In the performance information acquisition apparatus according to the present invention, the hammer detection means may continuously detect at least one of the position, velocity or acceleration of the hammer or pseudo hammer.

  In the performance information acquisition apparatus according to the present invention, the performance information acquisition means may acquire information indicating a speed immediately before hitting the string or hit member of the hammer or pseudo hammer.

  In the performance information acquisition apparatus according to the present invention, the performance acquisition unit may acquire information indicating a timing at which the hammer or the pseudo hammer hits the string or the hit member.

  The performance information acquisition apparatus according to the present invention includes a key, a string or a hit member, and a hammer or a hammer provided so as to be movable between a rest position and the string or the hit member according to the operation of the key. A performance information acquisition device for acquiring information related to the performance of a musical piece in a keyboard instrument provided with a pseudo hammer, wherein the hammer or pseudo hammer hits the string or the hit member from the rest position. A hammer detecting device for continuously detecting a physical quantity related to the movement of the hammer or pseudo hammer for at least a section in the vicinity of hitting the string or the hitting member, and a continuous detection detected by the hammer detecting device. Based on the physical quantity related to the movement of the typical hammer or pseudo hammer, the hit position of the hammer or pseudo hammer is determined. It is characterized by comprising a performance information acquisition means for acquiring information relating to the performance of the song as a quasi.

  The performance information acquisition apparatus according to the present invention includes a key, a string or a hit member, and a hammer or a hammer provided so as to be movable between a rest position and the string or the hit member according to the operation of the key. In a keyboard instrument provided with a pseudo hammer, a performance information acquisition device for acquiring at least one of information indicating a speed immediately before hitting the hammer or the pseudo hammer or information indicating a hit timing of the hammer or the pseudo hammer. The hammer or pseudo-hammer is at least in the vicinity of hitting the string or hit member until the hammer or pseudo hammer hits the string or hit member from the rest position and returns to the rest position. Hammer detection device that continuously detects physical quantities related to the movement of the human body, and detection by the hammer detection device Based on a physical quantity related to the movement of the continuous hammer or pseudo hammer, at least one of information indicating a speed immediately before the hammer or pseudo hammer is hit or information indicating timing of hitting the hammer or pseudo hammer It is characterized by comprising performance information acquisition means for acquiring information.

According to the present invention, it is possible to continuously detect the physical quantity related to the movement of the hammer more accurately, without requiring a complicated mounting operation on the keyboard instrument, and the movement of the key or the string based on the detected physical quantity. Information about can be obtained . Moreover, if performance data is created using the acquired information , performance data capable of reproducing a more detailed performance can be created.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
A. Overall Configuration of Embodiment First, FIG. 1 shows a configuration of a main part of an automatic piano provided with a hammer sensor according to an embodiment of the present invention. As shown in the figure, this automatic piano has an action mechanism 3 that transmits the movement of the key 1 to the hammer 2, a string 4 that is hit by the hammer 2, a solenoid 5 that drives the key 1, and vibration of the string 4. And a damper 6 for stopping the operation, and these configurations are the same as those of a general automatic piano. Further, this automatic piano is provided with a back check 7 in the same manner as a normal acoustic piano, and prevents the hammer 2 from rampage when the hammer 2 after striking returns to the hammer action mechanism. In addition, this automatic piano has the same mechanism as that mounted on a normal acoustic piano.

  The automatic piano generates key trajectory data based on performance data supplied from a recording medium or a real-time communication device, and also generates a key original velocity instruction value (t, Vr) using the trajectory data. And a motion controller 11 that generates and outputs a speed instruction value Vr corresponding to the position of the key 1 at each time based on the supplied original speed instruction value (t, Vr), and a speed instruction An excitation current corresponding to the value Vr is supplied to the solenoid 5, and the output speed Vy as a feedback signal supplied from the solenoid 5 is compared with the speed instruction value Vr, and the servo controller 12 performs servo control so that both coincide with each other. And. In addition to the mechanical tone generation control by driving the solenoid 5 as described above, the pre-reproduction processing unit 10 generates a sound source, a speaker, and the like based on performance data supplied from a recording medium or a real-time communication device. A control signal is supplied to the electronic musical tone generator 25 composed of the following, and electronic musical tone generation according to performance data is controlled.

  The automatic piano further includes a hammer sensor (hammer detection means) 26 that continuously detects physical quantities (position, velocity, acceleration, etc.) relating to the movement of the hammer 2 throughout the hammer operation, and an output signal of the hammer sensor 26. A performance recording unit (performance information acquisition means) 30 is provided for acquiring performance-related information such as a string-striking speed, string-striking timing and key-pressing timing based on the acquired information and generating performance data from the acquired information. Details of the performance data creation process by the performance recording unit 30 will be described later.

B. Configuration of Hammer Sensor The hammer sensor 26 may have any configuration as long as it can continuously detect physical quantities related to the movement of the hammer 2, and specifically, those having various configurations as shown below are used. Can do.

B-1. Configuration example 1
First, in the configuration shown in FIG. 2, the position of the hammer 2 is continuously detected using the light reflection sensor 200. In this example, a light reflection sensor 200 having a light emitting element and a light receiving element is disposed on a portion of the back surface of the fixed substrate 201 facing the hammer shank 2a. The light receiving element receives the reflected light from the hammer shank 2a of the light irradiated by the light emitting element of the light reflection sensor 200, and the position of the hammer 2 is detected according to the amount of light received. Specifically, the light reflection sensor 200 can obtain an output voltage as shown in FIG. As shown in FIG. 3B, the received light amount and the position of the hammer 2 are associated with each other by performing linearization correction. Thereby, the position of the hammer 2 can be continuously detected from the output value of the light reflection sensor 200 during operation of the hammer 2.
Note that recent microcomputers can easily and instantaneously perform the above-described linearization correction and sensitivity correction of the light reflection sensor 200 provided for each hammer. Therefore, the position of the hammer 2 can be acquired using analog data acquired by the light reflection sensor 200.

B-2. Configuration example 2
Next, as the configuration example 2, the one shown in FIG. 4 can be used. As shown in the figure, in this example, the Hall element 203 is provided on the back surface of the substrate 201 that is fixedly arranged, and the magnet sheet 204 is provided in a portion facing the Hall element 203 in the hammer shank 2a. Under this configuration, when the hammer 2 moves, the output value of the Hall element 203 changes according to the amount of movement (see FIG. 3), and the position of the hammer 2 can be detected continuously from this output value.

B-3. Configuration example 3
Next, in addition to detecting the position of the hammer 2 as in the configuration examples 1 and 2 described above, a configuration in which the moving speed of the hammer 2 is continuously detected as shown in FIG. As shown in the figure, in this example, a coil 205 is provided on a substrate 201, and a magnet sheet 204 is provided on a portion of the hammer shank 2a facing the coil 205. When the hammer 2 moves, the moving speed of the hammer 2 can be continuously detected from the electromotive force generated in the coil 205 by this movement.

B-4. Configuration example 4
Moreover, as shown in FIG. 6, the structure which detects the acceleration of the hammer 2 continuously may be sufficient. As shown in the figure, in this example, an acceleration sensor 206 is provided in the hammer shank 2a, and the acceleration of the hammer 2 is continuously detected by the acceleration sensor 206. In this case, since the acceleration sensor 206 is provided in the moving hammer shank 2a, the acceleration sensor 206 may be electrically connected by the flexible substrate 207.

B-5. Configuration example 5
Further, a PSD (Position Sending Device) may be used as a configuration for detecting the position of the hammer 2. As shown in FIG. 7, in this example, a substrate 201 is provided with an LED (Light Emitting Diode) 240 and a PSD 241. On the other hand, the hammer shank 2a is provided with a reflecting surface 242 that reflects substantially beam-like light emitted from the LED 240. In this case, as shown in FIG. 8, the light receiving position of the reflected light from the reflective surface 242 by the PSD 241 changes due to the movement of the hammer 2 (the reflective surface 242 attached to the hammer shank 2a). When the PSD 241 detects such a light receiving position, the position of the hammer 2 can be continuously detected according to the detection result. Hereinafter, the principle of detecting the light receiving position by the PSD 241 will be briefly described. When the spot light is incident on the PSD 241, a charge proportional to the light energy is generated at the incident position. The charges thus generated pass through the resistance layer as a photocurrent and are output from electrodes (for example, provided at both the left and right ends in FIG. 8). Here, since the photocurrent is divided and taken out in inverse proportion to the distance (resistance value) to the electrode, the light receiving position can be detected from the photocurrent values taken out from the electrodes provided at both ends.

B-6. Configuration example 6
Further, instead of directly detecting the position of the hammer 2, as shown in FIG. 9, the angle θ with respect to the predetermined position of the hammer shank 2a is detected, and the position of the hammer 2 is detected from the detected angle θ. Also good. In this case, an optical tilt sensor 250 that irradiates the hammer shank 2a with detection light and detects the inclination of the hammer shank 2a by the bias of the reflected light may be provided.

B-7. Configuration example 7
In the configuration examples 1 to 6 described above, the physical quantity related to the movement of the hammer 2 is analog-detected, but the physical quantity related to the movement of the hammer 2 may be digitally detected as described below. For example, in the configuration shown in FIG. 10, the light reflection pulse sensor 210 is provided on the back surface of the substrate 201 that is fixedly arranged, and the reflection scale 211 having a circular arc cross section is provided on the portion facing the light reflection pulse sensor 210 in the hammer shank 2 a. Yes. As shown in FIG. 11, a sheet having a pattern in which light reflection areas 211 a and absorption areas 211 b are alternately formed is deposited on the outer peripheral surface of the reflection scale 211. When the hammer 2 moves under this configuration, the light reflection pulse sensor 210 reads the pattern on the reflection scale 211 and generates a pulse signal. As shown in FIG. 12, since the number of pulses of the pulse signal generated by the light reflection pulse sensor 210 and the position of the hammer 2 are associated with each other, by counting the number of pulses generated by the light reflection pulse sensor 210, the hammer 2 Can be detected continuously.

B-8. Configuration example 8
As a configuration for performing digital detection, the configuration shown in FIG. 13 can be used. As shown in the figure, in this example, an MR (magnetoresistive) element 220 is provided on the back surface of a substrate 201 that is fixedly arranged, and a magnetic pattern scale 221 having an arcuate cross section is formed at a portion facing the MR element 220 in the hammer shank 2a. Is provided. As shown in FIG. 14, magnetized regions 221 a and non-magnetized regions 221 b are alternately provided on the outer peripheral surface of the magnetic pattern scale 221. When the hammer 2 is moved, the magnetized region and the non-magnetized region of the magnetic pattern scale 221 alternately pass through the portions facing the MR element 220, thereby generating a pulse signal. Note that the width of the magnetized region is preferably small in order to reduce false detection. For this reason, in the figure, the magnetic pattern scale 221 is divided into three rows, each provided with a magnetized region and a non-magnetized region, and MR elements 220 corresponding to these three rows are provided. Thereby, even if the movement amount of the hammer 2 is very small, an H level pulse signal can be generated by the output of one of the MR elements 220.

B-9. Configuration example 9
The position of the hammer 2 is not limited to the one that detects the position of the hammer 2 from the count value of the number of pulses described above, but may be configured to absolutely detect the position of the hammer 2 as shown in FIG. As shown in the figure, in this example, a dedicated hammer flange 2c incorporating a magnetic head 230 is used. The magnetic head 230 reads the magnetic scale 231 attached to the rotating end of the hammer shank 2a, so that the position of the hammer shank 2a, that is, the position of the hammer 2 can be detected absolutely.

B-10. Configuration example 10
Moreover, you may make it use a magnetic sensor as shown to Fig.16 (a), (b). As shown in the figure, in this example, the hammer shank 2a is provided with a magnetic material 270 (iron or the like) extending substantially in the same direction as the rotation direction and having a plurality of slits formed in that direction. On the other hand, a magnetic sensor 271 such as a Hall element or a Hall IC is provided on the side of the magnetic material 270, and a magnet 272 is bonded to the opposite side of the magnetic material 270 of the magnetic sensor 271. When the hammer shank 2a is rotated under this configuration, the slits of the magnetic material 270 are sequentially passed through the side of the magnetic sensor 271 that is fixedly arranged. Thereby, a magnetic circuit changes and a sine wave, a square wave, etc. are obtained as an output of the magnetic sensor 271, and the position of the hammer 2 can be continuously detected from this waveform.
The resolution of the configuration for performing the digital detection shown in FIGS. 10 to 16 only needs to be accurate to detect information (described later) related to the performance. For example, the resolution is about 10 microns / pulse in terms of the stroke of the hammer 2. Resolution.

C. Operation of Embodiment Next, the operation of the automatic piano having the above configuration will be described. This automatic piano can record the performance content by the performer as performance data based on the detection result of the hammer sensor 26, and can reproduce the performance according to the performance data supplied. An outline of the recording / reproducing operation of the automatic piano will be described.

C-1. Outline Operation First, when a performer performs a performance, the performance recording unit 30 acquires information on various performances based on the detection result of the hammer sensor 26, and uses these information to generate performance data in a predetermined format. create. The performance data created in this way is recorded on a recording medium such as a floppy disk, a hard disk, an optical disk, or a semiconductor memory.

  Next, the operation at the time of playing the automatic piano will be described. In this automatic piano, when performing a reproducing operation, a key 1 is operated by a solenoid 5 and a hammer 2 strikes a string 4 to generate a musical sound (hereinafter referred to as a mechanical musical sound generation), or an electronic musical sound generating unit It is possible to select whether to generate electronic musical sounds according to No. 25. When the user selects mechanical musical sound generation, the reproduction pre-processing unit 10 drives and controls the solenoid 5 via the motion controller 11 and the servo controller 12 based on the supplied performance data, and the hammer 2 strikes the string. To generate musical sounds according to the performance data. On the other hand, when the user selects electronic musical sound generation, the reproduction preprocessing unit 10 controls the electronic musical sound generating unit 25 based on the supplied musical performance data, and the electronic musical sound generating unit 25 responds to the musical performance data. Musical sounds are generated electronically.

C-2. Performance recording operation In this automatic piano, the performance recording unit 30 acquires information related to performance from a physical quantity related to the movement of the hammer 2 continuously detected by the hammer sensor 26 (in the following description, the position of the hammer 2). This is characterized in that performance data is created, and the performance recording operation will be described in detail below. In this embodiment, information related to performance includes (1) hammer start timing, (2) string-striking timing, (3) hammer speed immediately before string-striking, (4) key-pressing timing, and (5) back check. Timing, (6) timing when back check is released, (7) hammer speed after back check is released, (8) damper return timing, (9) hammer operation end timing, (10) key release timing Yes. Hereinafter, these acquisition methods will be described in the case where a continuous relationship between the position of the hammer 2 and time as shown in FIG.

(1) Hammer Operation Start Timing First, a method for obtaining the operation start timing of the hammer 2 will be described. The operation start timing of the hammer 2 can be obtained from the detection result of the hammer sensor 26 shown in FIG. That is, the timing T _{1 at} which the hammer 2 starts to move from the rest position is the operation start timing. In an acoustic piano, because of its structure, the hammer 2 starts operating after the start of keystroke. However, if the position of the hammer 2 is continuously detected as in this embodiment, the hammer starts easily. Timing can be acquired.

(2) String striking timing Next, the string striking timing can also be obtained from the detection result of the hammer sensor 26 shown in FIG. When the hammer 2 hits the string 4, the hammer 2 that has moved to the string 4 side tries to return to the rest position side. Therefore, the timing T ₂ when the movement direction of the hammer 2 is changed becomes the stringing timing. This string striking timing indicates the timing at which sound generation is actually started, and is data used when an electronic musical tone is generated in the reproduction operation. In the conventional method of detecting the key movement using the key sensor, the string hitting timing is obtained by estimation from the output value of the key sensor. Also, even with a conventional method of detecting the behavior of a hammer using a shutter member (see FIG. 18), accurate stringing timing cannot be detected, and the hammering behavior is determined from the behavior of the hammer in an arbitrary section immediately before the stringing. The string timing was estimated and acquired. However, in the present embodiment, it is possible to accurately obtain the required string striking timing (sounding timing) when an electronic musical tone is generated. Therefore, when creating a performance data for electronic musical tone generation, it is possible to create data that the string striking timing T ₂ and note-on timing, it is possible to reproduce a more accurate performance at the time of reproduction.

(3) Hammer speed immediately before striking Next, a method for obtaining the speed of the hammer 2 just before striking will be described. In this case, a detection section distance D ₁ (for example, 5 mm) for detecting the stringing speed and a distance d ₁ (for example, 0.5 mm) between the detection section and the stringing timing are set in advance. Then, by calculating backward from the string striking timing T ₂ , the passage timing T _S1 and T _S2 of the start point and end point of the detection section are obtained. Using the passage timings T _S1 and T _S2 obtained in this way, the velocity V ₁ of the hammer 2 immediately before striking can be calculated by the following equation.
V ₁ = (T _S2 −T _S1 ) / D ₁
Also, when the speed of the hammer 2 immediately after striking is obtained, if the detection section distance D ₂ and the distance d ₂ are set in advance, the start point and end point of the detection section are calculated by calculating backward from the string striking timing T _2. Pass timings T _S3 , T _S4 can be acquired, and the speed can be calculated.

  As described above, in this embodiment, since the detection section is determined based on the striking position, the positional relationship between the string position and the detection section is always constant regardless of the distortion of the string height or the displacement of the sensor mounting position. Can be maintained. Therefore, it is possible to calculate the speed of the hammer 2 immediately before (right after) the stringing more accurately. These calculated stringing velocities are used as data indicating strength in the performance data created by the performance recording unit 30, so that the performance can be reproduced more accurately during reproduction.

(4) Key pressing timing Next, a key pressing timing acquisition method will be described. As described above, in the acoustic piano, the operation start timing of the hammer 2 is slightly delayed from the key pressing start. Therefore, in this embodiment, setting the virtual moving distance D ₁₀ for acquiring key depression start timing going back from operation start timing T ₁ of the hammer. When the detection result as shown in FIG. 17 is obtained, the key movement timing T ₁₀ is obtained using the virtual movement distance D ₁₀ for the detection result. Here, a plurality of virtual movement distances D ₁₀ are stored for each key in accordance with the speed immediately before the string hitting described above, etc., and D ₁₀ is appropriately selected according to the operated hammer and the speed immediately before the string hitting. If used, more accurate key pressing timing can be obtained. Such key pressing timing is data that is necessary as the drive start timing of the solenoid 5 when performing performance by driving the solenoid 5 of the automatic piano. Therefore, when creating mechanical musical tone performance data for driving the solenoid 5, data having the key pressing timing as the key-on timing may be generated. Although the virtual movement distance D ₁₀ may be stored as described above, the correction time data Δt (in this case, Δt) to be added to calculate the key pressing timing from the hammer operation start timing T _1. May be stored, and the correction time data Δt may be selected according to the speed of the hammer 2 and the timing obtained by adding Δt from the hammer operation start timing T ₁ may be acquired as the key pressing timing. .

(5) Back check timing Next, a back check timing acquisition method will be described. After hitting the string 4, the hammer 2 collides with the back check 7 and is received, and the hammer 2 temporarily stops. Accordingly, the section in which the hammer 2 by the back check 7 is received is a section in which the hammer 2 after the string striking timing T ₂ is stopped. Therefore, it is possible to acquire the start timing T ₃ in this section as the back check time.

(6) Timing at which the back check is released The timing at which the back check 7 is released is the end timing T ₄ of the section in which the hammer 2 stops after the stringing timing T ₂ described above, and this is acquired as the timing at which the back check is released. To do.

(7) Speed of Hammer after Back Check is Removed Next, a method for acquiring the speed of the hammer 2 after the back check 7 is removed will be described. In this case, using the detection interval distance D ₃ and the distance d ₃ set in advance with reference to the position where the hammer 2 is received by the back check 7 described above, the passage timings T _S5 and T _S6 of the start point and end point of the detection interval are determined. get. Using these passage timings T _S5 and T _S6 , the speed of the hammer 2 after the back check 7 is released can be calculated.

(8) Damper Return Timing Next, a damper return timing acquisition method will be described. In a series of keystroke operations, the damper 6 returns to the original position after the hammer 2 is detached from the back check 7 in conjunction with the key 1 and comes into contact with the string 4 to stop the sound. In the present embodiment, in consideration of this point, the damper 6 is defined as a point in time when the hammer 2 passes a predetermined position (for example, a distance D ₃ + d ₃ from the back check position) until it reaches the rest position after being removed from the back check 7. to get as a return timing T _D. This damper return timing can be used as a sound stop timing when an electronic musical tone is generated. Therefore, when creating a performance data for electronic musical tone generation, to create a data in which the damper return timing T _D and note-off timing. Note that the performance of returning the key 1 very slowly includes the player's will to slowly return the damper 6. In other words, when the performer slowly returns the damper 6, the player performs an operation such as slowly returning the key 1. Considering this point, the damper - when detecting the return timing, if to change the predetermined position depending on the speed of the hammer 2 in the detection section D _3, to detect the more accurate damper return timing It becomes possible.

(9) Hammer Operation End Timing Next, a method for acquiring the timing at which the hammer operation ends will be described. The timing at which the hammer operation ends can be acquired from the detection result shown in FIG. In other words, the timing T ₅ the hammer 2 has returned to the rest position is the operation end timing.

(10) Key Release Timing Next, a method for obtaining the key release timing will be described. Also in the case of the key release timing, a plurality of virtual movement distances D ₁₁ are stored for each key according to the speed of the hammer 2 (in this case, the detection section D ₃ ) as in the key pressing timing described above. Then, the virtual movement distance D ₁₁ is selected according to the detected speed of the hammer 2 and the key release timing T ₁₁ is obtained from the selected virtual movement distance D ₁₁ and the operation end timing T _{5 of the} hammer 2. This key release timing is used as the solenoid drive end timing when the musical sound is reproduced by automatic performance with the solenoid 5 driven. Therefore, when creating performance data for generating mechanical musical sounds for driving the solenoid 5, if the data with the key release timing as the key-off timing is created, the performance can be reproduced more accurately during reproduction. In this case as well, the correction time data Δt may be stored in place of the virtual movement distance in the same manner as the key pressing timing acquisition method described above.

The above-described detection result of the hammer sensor 26 (see FIG. 17) corresponds to a general operation in which the key 1 is pressed and returned by the performer. It may be called. For example, in the case of a grand piano, if the strike is repeated 15 times / sec or more, the positional relationship between the key 1 and the hammer 2 is broken (specifically, there is an instantaneous gap between the capstan screw and the support rail). Occurs). In this case, it is necessary to correct the acquired information instead of using the acquired information as it is as information recorded in the performance data.
For example, in performance data used for generating mechanical musical sounds by the solenoid 5, it is necessary to perform drive control of the solenoid 5 at a high speed. However, the high-speed continuous hitting as described above is performed, and the keystroke timing during continuous hitting is not equal. If this is the case, it is difficult to reproduce. Therefore, in such a case, performance data is created with corrections such that the keystroke timings during consecutive hits are equally spaced. In the case of an upright piano, the positional relationship between the key 1 and the hammer 2 is lost after repeated hits of 7 times / sec or more. Therefore, when creating performance data to be used in an upright piano, it is necessary to perform correction in consideration of this point.
On the other hand, in the case of performance data for electronic musical tone generation, the key pressing timing and the like do not pose any problem. Therefore, it is only necessary to create performance data using the string strike timing obtained by the above method as the sound generation timing without performing correction.

  In the present embodiment, based on the continuous position information of the hammer 2 detected by the hammer sensor 26, the performance recording unit 30 can acquire various information related to the performance, and the generation of mechanical and electronic musical sounds. It is possible to create performance data suitable for both reproductions. In addition, since information related to various performances as described above can be acquired, the performance can be reproduced more finely by performing playback using performance data including this information. In particular, in the case of mechanical musical sound generation using the solenoid 5, the solenoid 5 can be controlled more finely based on the above-described various information, so that the performance can be reproduced more finely.

  Further, it is possible to accurately acquire the information related to the various performances described above without being affected by the displacement of the mounting position of the hammer sensor 26 or the distortion of the string height. Therefore, more accurate performance reproduction can be achieved by using performance data created using information related to these performances. In other words, the mounting position of the hammer sensor 26 and the displacement of the string height do not affect the accuracy of the acquired information, so that the hammer sensor 26 can be easily attached to the piano.

D. Modifications The present invention is not limited to the above-described embodiment, and various modifications as described below are possible.

(1) In the above-described embodiment, the hammer sensor 26 is provided in the grand piano type automatic piano. However, the invention is not limited to this, and the hammer sensor 26 is provided in other keyboard instruments having a hammer such as an upright piano. The physical quantity may be detected. Further, the present invention is not limited to a keyboard instrument having a hammer and a string, but can be applied to a keyboard instrument having a pseudo hammer that simulates a hammer and a hit member that is hit by the pseudo hammer.

(2) In the above-described embodiment, the case where the hammer sensor 26 continuously detects the position of the hammer 2 has been described. However, the present invention is not limited to this, and the detection is performed by continuously detecting the speed and acceleration of the hammer 2. From the result, the performance recording unit 30 may acquire information related to various performances as described above.
In addition, a plurality of hammer positions, velocities, and accelerations are detected at the same time, and information related to each performance is obtained from each detection result, and information related to a plurality of performances obtained from each detection result is compared / averaged. For example, information relating to performance can be obtained more accurately.

(3) In the above-described embodiment, information related to the performance as shown in the above (1) to (10) is acquired, but information related to performance other than this is obtained from the detection result of the hammer sensor 26. You may make it acquire.
Further, the information regarding the performance shown in (1) to (10) may be appropriately selected and acquired. In that case, depending on the information to be acquired, physical quantities related to the movement of the hammer or pseudo hammer are continuously applied only in a part of the period from hitting the string or hitting member to returning to the rest position from the rest position. May be detected. For example, in the case where information indicating the speed immediately before the hammer or pseudo hammer is hit or information indicating the hammer or pseudo hammer hit timing is obtained, the vicinity of the hammer or pseudo hammer hitting the string or hit member Only in this section, the physical quantity relating to the movement of the hammer or pseudo hammer may be detected continuously.

It is a figure which shows the structure of the principal part of the automatic piano provided with the hammer sensor which concerns on one Embodiment of this invention. It is a figure which shows the structural example 1 of the said hammer sensor. It is a figure for demonstrating the principle by which the position of a hammer is acquired by the structural example 1 of the said hammer sensor. It is a figure which shows the structural example 2 of the said hammer sensor. It is a figure which shows the structural example 3 of the said hammer sensor. It is a figure which shows the structural example 4 of the said hammer sensor. It is a figure which shows the structural example 5 of the said hammer sensor. It is a figure for demonstrating the principle by which the position of a hammer is acquired by the structural example 5 of the said hammer sensor. It is a figure which shows the structural example 6 of the said hammer sensor. It is a figure which shows the structural example 7 of the said hammer sensor. It is a figure which shows the reflection scale of the structural example 7 of the said hammer sensor. It is a figure for demonstrating the principle by which the position of a hammer is acquired by the structural example 7 of the said hammer sensor. It is a figure which shows the structural example 8 of the said hammer sensor. It is a figure which shows the magnetic pattern scale of the structural example 8 of the said hammer sensor. It is a figure which shows the structural example 9 of the said hammer sensor. (A) is the disassembled perspective view which shows the structural example 10 of the said hammer sensor, (b) is the figure which looked at the structural example 10 of the said hammer sensor from the hammer side. It is a figure for demonstrating the method to acquire the information regarding a performance from the detection result of the said hammer sensor. It is a figure for demonstrating the detection method of the hitting timing and speed of the conventional hammer. It is a figure for demonstrating distortion of the string height which arises in a general piano.

Explanation of symbols

1 ... Key, 2 ... Hammer, 3 ... Action mechanism, 4 ... String, 5 ... Solenoid, 6 ... Damper, 7 ... Back check, 10 ... Pre-processing unit, 11 ... Motion controller , 12... Servo controller, 25... Electronic musical tone generator, 26... Hammer sensor (hammer detection means), 30 .. performance recording section (performance information acquisition means)

Claims (3)

A keyboard instrument comprising a key, a string or a hit member, and a hammer or a pseudo hammer provided to be movable between a rest position and a position where the string or hit member is hit according to the operation of the key. , A device for detecting physical quantities related to the movement of the hammer or pseudo-hammer and acquiring information related to performance,
Hammer detection means for continuously detecting a physical quantity related to the movement of the hammer or pseudo-hammer from hitting the string or hit member from the rest position to returning to the rest position;
Performance information acquisition means for acquiring information related to performance based on physical quantities relating to the continuous movement of the hammer or pseudo hammer detected by the hammer detection means, wherein the key release timing after the key is pressed is determined. A performance information acquisition device, comprising: performance information acquisition means for acquiring information indicating information indicating a virtual movement distance or correction time of the hammer or pseudo-hammer according to the movement of the hammer or pseudo-hammer. . A key, a string or a hit member, a hammer or a pseudo hammer provided movably between a rest position and a position where the string or hit member is hit according to the operation of the key, and a damper In a keyboard instrument, a device for detecting physical quantities related to the movement of the hammer or pseudo-hammer and acquiring information related to performance,
Hammer detection means for continuously detecting a physical quantity related to the movement of the hammer or pseudo-hammer from hitting the string or hit member from the rest position to returning to the rest position;
Performance information acquisition means for acquiring information related to performance based on physical quantities relating to continuous movement of the hammer or pseudo hammer detected by the hammer detection means, wherein the string or hit member by the hammer or pseudo hammer A performance information acquisition device comprising: performance information acquisition means for acquiring information indicating a timing at which the damper contacts the string or the hit member after the hit. The performance information acquisition means acquires information indicating a key pressing timing using information indicating a virtual movement distance or a correction time of the hammer or pseudo-hammer according to the movement of the hammer or pseudo-hammer. The performance information acquisition apparatus according to claim 1 or 2.

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