The present invention relates generally to keyboard apparatus provided in electronic keyboard instruments etc., and more particularly to a keyboard apparatus provided with force sense control and operation control functions for controlling an operational feeling and behavior of keys.
Keyboard units of natural keyboard instruments, such as acoustic pianos, which generate raw tones, are constructed to generate a tone by a hammer, pivoting in response to depression of a key, striking strings. In these keyboard units, an action mechanism, including a jack and a wippen, is provided between each key and a corresponding hammer. Such an action mechanism allows a characteristic reaction force to be applied from the key to a human player's finger. Thus, in the keyboard unit of a natural keyboard instrument, a key touch feeling characteristic of, or unique to, the keyboard instrument can be obtained.
Keyboard units of electronic keyboard instruments which generate electronic tones, on the other hand, include, among others, a spring and a mass member (pseudo hammer) for returning a depressed key to an initial position, and these keyboard units simulate a key touch feeling of a natural keyboard instrument through a reaction force provided by the spring and mass member. However, in the electronic keyboard instruments, which generate an electronic tone in response to depression of a key, there is provided no mechanism that actually strikes strings to generate an electronic tone and hence no complicated action mechanism as in the natural keyboard instruments. Consequently, the keyboard units of the electronic keyboard instruments cannot faithfully reproduce a key touch feeling provided through the action mechanism of the natural keyboard instruments, and thus, strictly speaking, the key touch feeling provided by the electronic keyboard instruments is different from that provided by the natural keyboard instruments.
Therefore, in the field of the electronic keyboard instruments, there have been proposed key drive and control devices (force sense control means) for changing a reaction force responsive to depression of a key with a view to achieving behavior of the key and key touch feeling approximate to that provided by the natural keyboard instruments. For example, a keyboard unit disclosed in Japanese Patent No. 2956180 (hereinafter referred to as “Patent Literature 1”) includes an actuator (solenoid) for driving a key and a control means for controlling the actuator. Thus, the keyboard unit disclosed in Patent Literature 1 can simulate a performance feeling of a natural keyboard instrument by appropriately adjusting a key touch feeling.
Further, in a keyboard apparatus disclosed in Japanese Patent No. 3644136 (hereinafter referred to as “Patent Literature 2”), a key is normally biased in both of key-depressing and key-releasing directions by springs, acting in the key-depressing and key-releasing directions, respectively, so that the key is balanced at its rest position. The key is driven by a bidirectional actuator, so that the disclosed keyboard apparatus can achieve both force sense control on key depression and an automatic performance.
Furthermore, a keyboard apparatus disclosed in Japanese Patent Application Laid-open Publication No. 2005-195619 (hereinafter referred to as “Patent Literature 3”) includes a mass member simulating a hammer member of an acoustic piano, and an inertial load of the mass member is imparted as a reaction force to operation of a corresponding key. The disclosed keyboard apparatus has a force sense control function in which other necessary viscous, elastic and frictional loads etc. are generated by an actuator (solenoid). The keyboard apparatus disclosed in Patent Literature 3 can create a key touch feeling approximate to that of an acoustic piano through cooperation between the mass member and the actuator.
With the keyboard unit disclosed in Patent Literature 1, where behavior of the key is controlled by the solenoid alone, it is difficult to replicate or reproduce a key touch feeling of an acoustic piano with high accuracy. Further, the keyboard apparatus disclosed in Patent Literature 2 includes the key-biasing springs as main elements for controlling behavior of the key. However, in the case where the behavior of the key is controlled by the springs, even if auxiliary force sense control of the key is performed through driving of the actuator, the keyboard apparatus disclosed in Patent Literature 2 cannot faithfully reproduce an inertial mass feeling characteristic of behavior of a key of a natural keyboard instrument, such as an acoustic piano. Particularly, whereas, in an acoustic piano, movement of a key has to be started at the start of depression of the key against a static load of a string-striking hammer, it is difficult for the keyboard apparatus disclosed in Patent Literature 2 to appropriately reproduce an operational feeling at the start of depression of a key on an acoustic piano. Further, even if the springs provided in the keyboard apparatus disclosed in Patent Literature 2 are replaced with a mass member that generates an inertial force in interlocked relation to movement of the key, a possibility of properly controlling a load applied from the mass member to the key through driving of the actuator would be limited because the mass member is provided separately from the actuator and because the mass member and the actuator differ in operating system. Therefore, it is necessary to further improve the keyboard apparatus, in order to create a key touch feeling more approximate to that of a natural keyboard instrument and permit an automatic performance with smooth movement of the keys.
Further, in the keyboard apparatus disclosed in Patent Literature 3, the actuator is provided in abutment with the key so as to directly impart a reaction force to the key. Further, although the mass member is also provided in abutment with the key so as to interlock with the movement of the key, it is not in abutment with the actuator; namely, the mass member and the actuator are provided separately from each other. Thus, the mass member and the actuator have different operating systems, so that there are limitations to appropriately controlling, through driving of the actuator, a load applied from the mass member to the key.
Further, in the known keyboard apparatuses including a key and a mass member operating in interlocked relation to the key, a driving force is transmitted between the key or mass member and another component part interposed therebetween in a driving force transmission path between the key and the mass member. Often, the key or mass member and the other component part perform mutually-different movement, such as pivoting movement and linear movement, in the force transmission path. In this case, in order to achieve a more natural operational feeling through force sense control, it is necessary to make an arrangement such that an appropriate frictional force is produced against relative movement between the key or mass member and the other component part while still securing interlocked movement between the key or mass member and the other component part. Because, a key touch feeling achieved by an action mechanism provided in an acoustic piano is created by differently-operating component parts, such as a spin roller, jack rod and hammer, moving relative to one another while involving appropriate friction thereamong, and it is required to reproduce the key touch feeling as faithfully as possible in the keyboard apparatus.
Furthermore, the keyboard apparatus disclosed in Patent Literatures 1 and 2 are constructed to simulate a key touch feeling of an acoustic piano by controlling the driving of the actuator that imparts a reaction force to the key. However, in natural keyboard instruments, such as an acoustic piano, including a complicated action mechanism, there is produced, during each of key depression and key release operation, a characteristic key touch feeling with an intensity of a reaction force varying from moment to moment in response to a changing key position (i.e., key depression amount), key velocity, etc. In order to faithfully reproduce such a key touch feeling of a natural keyboard instrument, there is a need to make further improvements in the driving control of the actuator performed in the conventionally-known keyboard apparatus.
In view of the foregoing, it is an object of the present invention to provide an improved keyboard apparatus which is simple in construction and yet can achieve creation of a key touch feeling extremely approximate to that of a natural keyboard instrument through force sense control and an automatic performance with smooth key movement.
It is another object of the present invention to provide an improved keyboard apparatus which can create a key touch feeling approximate to that of a natural keyboard instrument by producing an appropriate frictional force against relative movement between a key or mass member and another component part interposed therebetween while securing interlocked operation between the key or mass member and the other component part that perform mutually-different movement.
It is still another object of the present invention to provide an improved keyboard apparatus which can create a key touch feeling more approximate to that of a natural keyboard instrument through force sense control based on driving control of an actuator.
According to a first aspect according to the present invention, a keyboard apparatus includes a key, a mass member, a transmission member, an electromagnetic actuator, and a control section. The key is supported for pivoting movement about a key pivot point. The mass member imparts a reaction force to performance operation of the key in interlocked relation to movement of the key. The transmission member is in abutment with both of the key and the mass member to transmit a load from one of the key or the mass member to the other of the key or the mass member. The electromagnetic actuator includes a fixed coil and drives, via the coil, the transmission member toward at least one of the key or the mass member. The control section controls driving of the transmission member by the electromagnetic actuator.
With the mass member, which can constitute a main element for controlling behavior of the key, an inertial mass feeling characteristic of behavior of a key of a natural keyboard instrument, such as an acoustic piano, can be faithfully reproduced. The present keyboard apparatus can also appropriately reproduce an operational feeling at the start of depression of a key of an acoustic piano when movement of the key has to be started upon start of the depression of the key against a static load of a corresponding hammer. With the electromagnetic actuator, the keyboard apparatus can appropriately adjust a load (reaction force) to be imparted from the mass member to the key, so that a key touch feeling extremely approximate to that in a natural keyboard instrument, such as an acoustic piano, can be achieved.
Further, when imparting a key touch feeling to performance operation by a human player, the keyboard apparatus can provide a key touch feeling approximate to that in a natural keyboard instrument, such as an acoustic piano, only with the action of the mass member. Thus, the load control by the electromagnetic actuator can be relatively simple as compared to the load control performed in the force sense control by the conventionally-known keyboard apparatus. Even with such simplified load control, the present keyboard apparatus can appropriately reproduce an extremely good key touch feeling. Thus, using the simple construction and facilitated control, the present keyboard apparatus can faithfully reproduce a key touch feeling approximate to that in a natural keyboard instrument, such as an acoustic piano.
Further, by controlling the driving of the electromagnetic actuator, the present keyboard apparatus can adjust both the reaction force to be imparted from the mass member to depression operation of the key and the load acting from the mass member on the key. As a result, the present keyboard apparatus can achieve both force sense control on key depression operation by adjusting the load acting from the mass member on the key and an automatic performance involving automatic operation of the keys based on adjustment of forces acting on the keys in key depressing and releasing directions.
Furthermore, the transmission member to be driven by the electromagnetic actuator is located between the key and the mass member, and a driving force generated by the electromagnetic actuator is imparted to at least one of the key or the mass member. Thus, a same operating system can be shared between the mass member acting on the key and the electromagnetic actuator, so that the load acting from the mass member on the key can be appropriately controlled by the electromagnetic actuator and the force sense control and driving control can be performed appropriately on the key.
The mass member can include a mass section and an arm section that supports the mass section for angular movement in a region over the key. The transmission member can be provided in abutment with a portion of the key located on an opposite side from a key depression section of the key with respect to (i.e., as viewed from) the key pivot point and in abutment with the arm section of the mass member. Alternatively, the mass section and the arm section can supports the mass section for angular movement in a region under the key, and the transmission member can be provided in abutment with a portion of the key located on the same side as a key depression section of the key with respect to the key pivot point and in abutment with the arm section of the mass member. Such a construction is equivalent to a construction where a wippen assembly disposed between a key and a hammer in an action mechanism of an acoustic piano is replaced with the transmission member and electromagnetic actuator of the invention. Thus, by the transmission member and electromagnetic actuator performing the function of the wippen assembly, the present keyboard apparatus can achieve a key touch feeling extremely approximate to that of an acoustic piano with minimum necessary structural arrangements and control. In addition, the present keyboard apparatus can perform an automatic performance involving automatic operation of the keys.
The keyboard apparatus can further include an operation detection section that detects operation of at least one of the transmission member, the key, or the mass member. The control section controls, on the basis of a detection result of the operation detection section, a driving force to be generated by the electromagnetic actuator. Because force sense control can be performed on the key on the basis of actual movement or operation of the transmission member, key and mass member, the present keyboard apparatus can achieve a good operational feeling of the key.
The control section can include a force sense imparting table containing a pattern of driving forces to be generated by the electromagnetic actuator in response to depression of the key and a pattern of driving forces to be generated by the electromagnetic actuator in response to release of the key. The control section can reference the force sense imparting table in response to depression operation or release operation of the key to control the electromagnetic actuator in accordance with the pattern provided by the force sense imparting table.
The present keyboard apparatus can create a key touch feeling extremely approximate to that in a natural keyboard instrument and permits an automatic performance with automatic operation of the keys.
According to a second aspect according to the present invention, the keyboard apparatus includes the key supported for pivoting movement about a key pivot point, the mass member that imparts a reaction force to performance operation of the key in interlocked relation to movement of the key, the transmission member provided in abutment with both of the key and the mass member to transmit a load from one of the key or the mass member to the other of the key or the mass member, and a coupling mechanism that detachably couples the mass member and the transmission. Specifically, the coupling mechanism can comprise a magnet fixed to one of the mass member or the transmission member and an attraction member attractable to the magnet fixed to the other of the mass member or the transmission member. The attraction member can be a metal member attractable to the magnet, another magnet, etc.
With the mass member that imparts a reaction force to performance operation of the key in interlocked relation to movement of the key, the present keyboard apparatus can faithfully reproduce an inertial mass feeling characteristic of behavior of a key of a natural keyboard instrument, such as an acoustic piano. The present keyboard apparatus can also appropriately reproduce an operational feeling at the start of depression of a key of an acoustic piano when movement of the key has to be started upon start of depression of the key against a static load of a corresponding hammer.
Further, in the keyboard apparatus, where the mutually-abutting portions of the mass member and the transmission member are joined with each other by an attracting force of the magnet, the magnet and the attraction member move relative to each other. Thus, the mass member and the transmission member are allowed to move relative to each other relatively freely while being kept in contact with each other. Even where the mass member and the transmission member perform different movement, such as linear movement and pivoting movement, the mass member and the transmission member can reliably operate in interlocked relation to each other. Further, with the abutting portions of the mass member and the transmission member joined with each other by an attracting force of the magnet, the present keyboard apparatus can achieve, with a simple mechanism, a construction where the mass member and the transmission member are allowed to move relative to each other while being kept in contact with each other as the key and mass member operate.
In the mutually-abutting portions of the mass member and the transmission member, a certain frictional force is produced, due to the magnetic force, between the magnet and the attraction member moving relative to each other. In this way, the keyboard apparatus can appropriately reproduce a particular operational feeling of a key arising from friction produced within an action mechanism of an acoustic piano. As a result, the keyboard apparatus can also achieve an operational feeling of a key when a jack rod pushes up a spin roller and slides to escape in an action mechanism of an acoustic piano and an operational feeling (“so-called pseudo backcheck operation” feeling) approximate to rebound checking operation (i.e., “backcheck operation”) after a hammer abuts a stopper member in an action mechanism of an acoustic piano. Furthermore, with the mass member and the transmission member joined to each other through the magnetic attracting force, force transmission between the mass member and the transmission member can be effected steadily and reliably, as compared to a case where the mass member and the transmission member are merely held in abutment with each other with no attracting force therebetween. As a result, the keyboard apparatus can more faithfully reproduce an operational feeling of an acoustic piano. Further, with the mass member and the transmission member magnetically joined to each, the mass member can quickly return to its initial position by being taken by the key, as the key returns to its initial position. Thus, a state where next tone generation by operation of the key is enabled can be achieved quickly, which permits performance of quick passages.
One of the magnet or the attraction member can angularly move in response to movement of the mass member or the transmission member while the other of the magnet or the attraction member can linearly move in response to movement of the transmission member or the mass member. The magnet and the attraction member can slide along each other's surfaces in response to the movement of the mass member and the transmission member. Thus, in a region where the linearly-moving magnet or attraction member and the angularly-moving attraction member or magnet are joined to each other, the mass member and the transmission member are allowed to slidingly move relative to each other relatively freely while being kept in contact with each other. Consequently, the keyboard apparatus permits relative movement between the mass member and the transmission member involving an appropriate frictional force (static and dynamic frictional force) therebetween while securing interlocked relationship between the mass member and the transmission member, improving behavior and operational feeling of the key.
At least one of a surface of the magnet abutting against the attraction member or a surface of the attraction member abutting against the magnet can be formed in a curved shape. Consequently, the keyboard apparatus permits relative sliding movement between the mass member and the transmission member involving an appropriate frictional force, improving behavior and operational feeling of the key.
The keyboard apparatus can include the electromagnetic actuator that imparts a driving force generated thereby to the key and the mass member, and the control section that controls generation of the driving force by the electromagnetic actuator. The electromagnetic actuator can include a driving source that drives the transmission member toward at least one of the key or the mass member. Because a load (reaction force) to be imparted from the mass member to the key can be appropriately controlled by the electromagnetic actuator, the present keyboard apparatus can readily achieve a key touch feeling extremely approximate to that in a natural keyboard instrument, such as an acoustic piano.
The keyboard apparatus according to the second aspect also can create a key touch feeling approximate to that in a natural keyboard instrument by producing an appropriate frictional force between the key or mass member and another component part interposed therebetween and performing different movement from the key or mass member while securing interlocking operation between the key or mass member and the other component part.
According to a third aspect according to the present invention, the keyboard apparatus includes the key supported for pivoting movement about a key pivot point, the mass member that imparts a reaction force to depression or release operation of the key in interlocked relation to movement of the key, a bi-directionally driven actuator that imparts a driving force to the key to control a force sense to be imparted to the depression or release operation of the key, a control section that controls the driving force to be generated by the actuator, and a key operation information acquisition section that acquires information pertaining to a position and movement of the key, in a key depressing or releasing direction. The control section determines, on the basis of the information pertaining to the position and movement of the key acquired by the key operation information acquisition section, an instruction value of the driving force to be imparted to the key. The actuator selectively generates, as a driving force corresponding to the instruction value determined by the control section, one of (a) a driving force acting to increase a reaction force imparted from the mass member to the depression or release operation of the key, or (b) a driving force acting to decrease the reaction force imparted from the mass member to the depression operation of the key.
With the force sense control on the key performed through driving of the actuator, the present keyboard apparatus can appropriately adjust in real time, the key touch feeling that occurs in response to performance operation. As a result, the keyboard apparatus can faithfully reproduce a key touch feeling that occurs in response to performance operation in a natural keyboard instrument, such as an acoustic piano, including a complicated action mechanism.
The present keyboard apparatus is designed to simulate a key touch feeling of a natural keyboard instrument by the electromagnetic actuator generating an assisting driving force, a reaction force applied to key depression operation based only on the mechanical structure of the key and the mass member (i.e., reaction force when no driving force is generated by the electromagnetic actuator) would considerably differ from a reaction force generated in a natural keyboard instrument, such as an acoustic piano. Consequently, at an initial stage of depression of the key, from a time when the key starts moving in response the depression operation to a time when a predetermined key depression amount is reached, the actuator generates, as the driving force corresponding to the instruction value, the driving force acting to decrease the reaction force imparted from the mass member to the depression operation of the key.
The inertial load applied from the mechanical structure of the mass member to the key would take a great value as compared to an inertial load applied to a depressed key in the natural keyboard instrument. There has been no keyboard apparatus with an actuator that generates a driving force acting to decrease a reaction force imparted from the mass member to the key. This makes it impossible to appropriately correct a key touch feeling that occurs at an initial stage of depression of the key and that tends to be heavier than that in a natural keyboard instrument.
To achieve appropriate correction of a key touch feeling, it may be conceivable to make the mass member considerably light in weight and make an arrangement for covering most of the driving force, acting in the direction to increase the reaction force of the mass member, using the electromagnetic actuator. But to impart a driving force to maximize the reaction force of the mass member, it is necessary for the electromagnetic actuator to produce extremely great output, requiring excessively great electric power needed to drive the electromagnetic actuator. Consequently, electric power usable for tone control in the keyboard apparatus can run short, a tone generated via the keyboard apparatus can become undesirably distorted, and necessary control in the keyboard apparatus can undesirably become insufficient. Further, because the width of the key and an available installation space for the electromagnetic actuator are limited, there exist limitations to increasing the output of the electromagnetic actuator.
The present keyboard apparatus resolves the problem using the bi-directionally driven electromagnetic actuator, which not only imparts a driving force acting to increase the reaction force imparted from the mass member to operation of the key but also imparts a driving force acting to decrease the reaction force imparted from the mass member to operation of the key, and thus can effectively correct a difference in key touch feeling at the initial stage of depression of the key between the inventive keyboard apparatus and a natural keyboard instrument. In addition, the present keyboard apparatus can achieve a superior key-driving efficiency.
The present keyboard apparatus can be arranged so that, at an initial stage of depression of the key from a time when the key starts moving in response the depression operation to a time when a predetermined key depression amount is reached, the actuator generates the driving force acting to decrease the reaction force imparted from the mass member to the depression operation of the key. The keyboard apparatus according to the third aspect can create a key touch feeling more approximate to that in a natural keyboard instrument, through force sense control performed on the key based on driving control of the actuator.
The following will describe embodiments of the present disclosure, but it should be appreciated that the present invention is not limited to the described embodiments and various modifications of the present invention are possible without departing from the basic principles.
For better understanding of the object and other features of the present invention, its preferred embodiments will be described hereinbelow in greater detail with reference to the accompanying drawings.
First, first to third embodiments according to a first aspect of the present invention will be described with reference to
The key 20 is supported at its longitudinal middle position (i.e., middle position in a front-rear direction of the key 20) for vertical pivoting movement about a key fulcrum or key pivot point 12 of the frame 11. More specifically, the key 20 is supported on a support pin 12b that projects upward from a balance rail 12a extending horizontally across the keys 20 (i.e. in a key-arranged direction) on the frame 11. The key 20 is vertically pivotable, in response to human player's depression operation on a key depression section 20c, about the support pin 12b in such a manner that its front end region 20a and rear end region 20b can angularly move about the key pivot point 12 in an up-down direction. Further, a front pin 13 is provided under the front end region 20a of the key 20 to project upward from the frame 11 and has its upper end inserted in an underside of a front end region 20a of the key 20. Thus, the front pin 13 functions to prevent lateral swing of the front end region 20a of the vertically pivoting key 20.
An upper key's pivoting movement limiting stopper (hereinafter “upper key limit stopper”) 21 is provided under the rear end region 20b of the key 20, while a lower key's pivoting movement limiting stopper (hereinafter “lower key limit stopper”) 22 is provided under the front end region 20a of the key 20. Each of the upper key limit stopper 21 and lower key limit stopper 22 includes a shock absorbing material, such as felt, fixedly attached to the upper surface of the frame 11. The upper key limit stopper 21 abuts against the lower surface of the rear end region 20b of the key 20 when the key 20 is in the non-depressed position shown in
Further, a post-shaped support section 14 for supporting the mass member 30 is provided on a portion of the frame 11 located rearwardly of the key pivot point 12. More specifically, one such support section 14 is provided on the frame 11 per a predetermined plurality of the keys and projects upwardly from between adjacent ones of the keys 20. The support section 14 includes front and rear walls 14a and 14b provided at a predetermined horizontal interval from each other. The front and rear walls 14a and 14b each project vertically upward above the key 20.
A plurality of the mass members 30 supported by the support section 14 are provided in one-to-one corresponding relation to the keys 20 and each located immediately over the corresponding key 20 and rearwardly of the corresponding key pivot point 12. The mass member 30 includes a shank section (or arm section) 32 of a linear rod shape extending rearwardly from a mass member fulcrum or pivot point 31 that is provided at the upper end of the front wall 14a of the support section 14, and a mass section (i.e., weight) 33 having a predetermined mass and provided at the distal end of the shank section 32. The shank section 32 is supported for vertical pivoting movement about the pivot point 31; more specifically, the shank section 32 is pivotable in a vertical plane lying orthogonal to the length of the key 20. The mass section 33 is formed in a rod shape extending along a pivoting direction of the shank section 32. Namely, the mass member 30 is pivotable about the mass member pivot point 31 in such a manner that the mass section 33 angularly moves in the up-down direction in a region over the rear end region 20b of the key 20 with the shank section 32 functioning as a pivot arm.
On the rear wall 14b of the support section 14 are provided an upper mass member's pivoting movement limiting stopper (hereinafter “upper mass member limit stopper”) 34 for limiting pivoting movement, in the clockwise direction of
The electromagnetic actuator 40 for imparting a predetermined driving force to the key 20 and mass member 30 is provided between an upper surface portion of the key 20 located rearwardly of the key pivot point 12 and the shank section 32 of the mass member 30. In the instant embodiment, the electromagnetic actuator 40 is a bi-directionally-driven actuator which includes a fixed coil section 41 comprising two fixed solenoid coils, i.e. projecting coil 41a and retracting coil 41b, disposed in vertical coaxial alignment with each other, and a single plunger 42 vertically slidably inserted within the projecting coil 41a and retracting coil 41b. Further, yokes 40a and 40b are provided around, i.e. surround, the outer peripheries of the projecting coil 41a and retracting coil 41b, respectively.
Each of the above-mentioned yokes 40a and 40b is fixed at its rear surface to the front surface of the rear wall 14b of the support section 14 via a flat plate 15. Thus, the projecting coil 41a and retracting coil 41b are fixed to the support section 14 and frame 11 that are fixed component parts. The plunger 42 includes a body portion 42a in the form of a column-shaped ferromagnetic substance which is reciprocatively slidable in the up-down direction inside the projecting coil 41a and retracting coil 41b, a first rod 42b connected to the upper end of the body portion 42a, and a second rod 42c connected to the lower end of the body portion 42a. The body portion 42a, first rod 42b and second rod 42c are disposed in vertical axial alignment with one another. A flat plate member 43 for mounting thereon a later-described position sensor (operation detection section) 47 is fixed to the upper end of the first rod 42b. The plate member 43, which is a relatively light-weight member, includes a horizontal body portion 43a fixed to the upper end of the first rod 42b and a front wall portion 43b extending from the front end of the horizontal body portion 43a vertically downward; thus, the plate member 43 has a substantially “L” sectional shape. A support member 44 having a horizontal upper surface is fixed to the upper surface of the horizontal body portion 43a. A cylindrical roller 36 is mounted on the lower surface of the shank section 32 opposed to the support member 44. The cylindrical roller 36 has a horizontal axis extending in the key-arranged direction and is placed at its lower surface portion on the upper surface of the support member 44. Further, a cap-shaped cover member 45, having shock absorbing and sliding functions, is fixed to the lower end of the second rod 42c and placed at its lower end on a screw 25 that is opposed to the cover member 45.
The above-mentioned plunger 42 (including the body portion 42a, first rod 42b and second rod 42c), plate member 43 and support member 44 together constitute the transmission member 46 for transmitting a load (i.e., load by a mass or inertial load due to pivoting movement) from one of the key 20 and mass member 30 to the other of the key 20 and mass member 30. The transmission member 46 is held sandwiched between the mass member 30 and the key 20 by a load due to the self-weight of the mass member 30.
The electromagnetic actuator 40 can drive the transmission member 46 (i.e., plunger 42) in two directions by the projecting coil 41a and retracting coil 41b being supplied with driving currents. Namely, as the retracting coil 41b is supplied with the driving current, the transmission member 46 moves downward; thus, a downward load is imparted from the transmission member 46 to a portion of the key 20 located rearwardly of the key pivot point 12, so that a load acting on the key 20 in a key-releasing direction increases. On the other hand, as the projecting coil 41a is supplied with the driving current, the plunger 42 moves up; thus, the load acting downward on the portion of the key 20 located rearwardly of the key pivot point 12 decreases, so that the load acting on the key 20 in the key-releasing direction decreases.
Namely, the key 20 is normally biased in the key-releasing direction by the load (i.e., load by the mass of the mass member 30) applied thereto via the transmission member 46. The key 20 is caused to pivot in a key depressing direction as the load from the mass member 30 is reduced by the driving force of the electromagnetic actuator 40. In this case, when the key 20 is not being depressed, the load applied, in the key releasing direction, from the mass member 30 is greater than a biasing force, in the key depressing direction, applied by the self-weight of the key 20, and thus, the key 20 is held in a key-released position with the biasing force in the key depressing direction cancelled out. Then, as the load from the mass member 30 is reduced by the driving force of the electromagnetic actuator 40, the biasing force, in the key depressing direction, by the self-weight of the key 20 gradually becomes greater than the load, in the key releasing direction, from the mass member 30, so that the key 20 pivots in the key depressing direction.
While the key 20 and mass member 30 pivot about the respective pivot points 12 and 31, the transmission member 46 (plunger 42) linearly moves in its axial direction inside the projecting coil 41a and retracting coil 41b. Thus, as the key 20, mass member 30 and transmission member 46 move integrally with one another, the upper end of the vertically-linearly moving transmission member 46 slides on and along the outer peripheral surface of the roller 36 angularly moving in response to the vertical pivoting movement of the mass member 30, in a first abutment area 48 where the upper end of the transmission member 46 (i.e., upper surface of the support member 44) and the roller 36 of the mass member 30 is held in abutment with each other. Similarly, in a second abutment area 49 where the lower end of the transmission member 46 is held in abutment with the screw 25 of the key 20, the lower end of the linearly-vertically moving transmission member 46 slides on and along the upper surface of the screw 25 that angularly moves in response to the pivoting movement of the key 20.
Further, in the instant embodiment of the keyboard apparatus 10, the transmission member 46 may be held in abutment with the key 20 or mass member 30 in such a manner that it can disengage from the key 20 or mass member 30 depending on the operation of the key 20 or mass member 30, for the following reason. Namely, the transmission member 46 normally moves integrally with the key 20 and mass member 30 with its opposite ends (i.e., upper and lower ends) held in abutment with the key 20 and mass member 30. But, when the key 20 has been depressed rapidly with a great depressing force or depressed or released at an extremely high speed, and if acceleration produced in the transmission member 46 and acceleration produced in the key 20 or mass member 30 differ from each other, the transmission member 46 may sometimes instantaneously disengage from the key 20 or mass member 30. However, the transmission member 46 need not necessarily be disengageable from the key 20 or mass member 30, and the transmission member 46 may be non-disengageably coupled (e.g. via a link joint) to the key 20 or mass member 30, as long as a driving force can be transmitted from the transmission member 46 to the key 20 or mass member 30.
Further, in the keyboard apparatus 10, the position sensor (operation detection section) 47 is provided for detecting a position of the transmission member 46 (plunger 42). The position sensor 47, as shown in
As long as the position sensor 47 can detect a position of the transmission member 46 (plunger 42), it may be of any other type than the above-mentioned reflection type, such as another optical type or non-optical type. Alternatively, the position sensor 47 may be replaced with a position detecting switch or the like. Further, whereas the instant embodiment has been described above as including the position sensor 47 as one example of the operation detection section for detecting operation of the transmission member 46, the embodiment may include, in addition to the position sensor 47, a velocity sensor or an acceleration sensor for detecting an operating speed or velocity or acceleration of the transmission member 46, or a combination thereof.
Further, the instant embodiment of the keyboard apparatus 10 is constructed to detect operation (displacement, velocity, etc.) of the transmission member 46 and perform driving control on the electromagnetic actuator 40 on the basis of the detection of the operation of the transmission member 46. In addition, the instant embodiment of the keyboard apparatus 10 may include an operation detection section for detecting operation (position, velocity, acceleration, etc.) of the key 20 or mass member 30 and perform driving control on the electromagnetic actuator 40 on the basis of the detection of the operation of the key 20 or mass member 30. In an alternative, the instant embodiment of the keyboard apparatus 10 may include one or more operation detection sections for detecting operation of at least one of the transmission member 46, key 20 and mass member 30, so that any of the operation detection sections can be used for driving control on the electromagnetic actuator 40 while the remaining of the operation detection sections can be used for tone generation control on an electronic tone generator. Of course, one operation detection section may be used for both the driving control on the electromagnetic actuator 40 and the tone generation control on the electronic tone generator.
As set forth above, the instant embodiment of the keyboard apparatus 10 includes the mass member 30 provided for pivoting movement in the region over the key 20, and the electromagnetic actuator 40 and transmission member 46 provided between the key 20 and the mass member 30 for imparting a generated driving force to the key 20 and mass member 30. The electromagnetic actuator 40 and transmission member 46 are disposed between a portion of the key 20 located on an opposite side from the key depression section 20c with respect to (i.e., as viewed from) the key pivot point 12. Further, the electromagnetic actuator 40 is a single device that can be actuated to drive the transmission member 46 in two directions, i.e. a direction toward the mass member 30 and a direction toward the key 20.
The following describe the main control section 50 shown in
The instant embodiment of the keyboard apparatus 10 further includes a setting operation section 61, a display device 63, a sound output section 65, an external storage device 66, an HDD 67, a communication interface 68, a MIDI interface 69, etc. An external device 71 is connectable to the communication interface 68, and a MIDI device 72 is connectable to the MIDI interface 69. Further, the communication interface 68 permits communication with an external server apparatus 74 via a communication network 73, such as the Internet. The setting operation section 61 includes various switches (not shown) operable by the human player to enter setting operation information, and a signal generated in response to operation of any of the switches is supplied to the CPU 51. The external storage device 66 and HDD 67 are provided for storing various application programs, including the above-mentioned control programs, and various music piece data. The display device 63 is connected to the bus 51 via a display control circuit 62, and the sound output section 65 is connected to the bus 51 via a tone generator circuit 64.
The following describe behavior of the keyboard apparatus 10 constructed in the aforementioned manner. When no key depressing force is acting on the key 20, the key 20 is held in the non-depressed position shown in
By driving the transmission member 46 in the two directions by means of the electromagnetic actuator 40 when the key 20 moves using the inertial load of the mass member 30, the instant embodiment can assist or reduce the biasing force applied from the mass member 30 to the key 20. Thus, by the main control section 50 controlling the driving of the electromagnetic actuator 40, the instant embodiment can perform force sense control on a reaction force to be imparted key depression operation.
The following describe in greater detail the force sense control on key depression operation. In order to replicate or reproduce a particular key touch feeling (sense of resistance) felt through a finger on the basis of operation of an action mechanism of an acoustic piano, the instant embodiment of the keyboard apparatus 10 is constructed to impart a reaction force characteristic, corresponding to the key touch feeling of the acoustic piano, to the key 20 by driving the plunger 42 via the electromagnetic actuator 40 during a performance of the electronic keyboard instrument 1. The above-mentioned reaction force characteristic changes from moment to moment in response to a changing position of the key 20. Thus, in the aforementioned force sense control, a driving force is imparted on the basis of position information of the transmission member 46 detected by the position sensor 47. Namely, first, detection data generated by the position sensor 47 is output to the main control section 50. Then, the main control section 50 issues an instruction to the control driver 58 and PWM switching circuit 59 with reference to position information of the plunger 42 based on the detection data of the position sensor 47 and the force sense imparting table 80 stored in the ROM 52. Then, the control driver 58 and PWM switching circuit 59 supplies a driving current to the projecting coil 41a or retracting coil 41b on the basis of the instruction from the main control section 50. Thus, by driving of the projecting coil 41a or retracting coil 41b, a driving force is imparted to the transmission member 46 such that the transmission member 46 is driven toward the mass member 30 or the key 20. Whereas the instant embodiment has been described above in relation to the case where a driving force to be supplied by the electromagnetic actuator 40 is determined with reference to the force sense imparting table 80, such a driving force to be supplied by the electromagnetic actuator 40 may be determined through arithmetic operations based on the position information of the transmission member 46 detected by the position sensor 47.
With the force sense control performed on the key 20 in the instant embodiment of the keyboard apparatus 10, the reaction force applied from the key 20 to the human player's finger depressing the key 20 is a sum or of a reaction force L1 caused by the mass or inertial load of the mass member 30 acting on the key 20 and a reaction force L2 imparted to the key 20 by the electromagnetic actuator 40 (see one-dot-dash line in
The following describe in greater detail the distributions of reaction forces to operation of the key 20. First, the distribution of reaction forces of
Region A in
Region C in
Further, the distribution of reaction forces responsive to relatively slow release operation of the key 20 shown in
Thus, with the instant embodiment of the keyboard apparatus 10, a distribution of reaction forces applied to a human player's finger in response to depression of a key in an acoustic piano including a complicated action mechanism can be faithfully reproduced by a combination of the reaction force L1 by the mass member 30 and the reaction force L2 created by the electromagnetic actuator 40.
Further, the instant embodiment of the keyboard apparatus 10 can reduce a force acting on the key 20 in the key releasing direction, by the electromagnetic actuator 40 driving the transmission member 46 in a direction (in this case, upward direction) opposite from the direction (in this case, downward direction) where a reaction force is applied to the key 20. Thus, the key 20 pivots by its own weight in the key depression direction by the electromagnetic actuator 40 driving the transmission member 46 upward when no operation is being performed by the human player on the key 20 resting in the non-depressed position. Utilizing such action, the keyboard apparatus 10 can automatically move the key 20 even without key depression operation by the human player. As a result, the electronic keyboard instrument 1 can execute an automatic performance involving automatic (i.e., unmanned) operation of the keys 20.
In such an automatic performance, instructions pertaining to the automatic performance are issued from the main control section 50 to the control driver 58 and PWM switching circuit 59, on the basis of the automatic performance data 85 stored in the ROM 52. On the basis of the instructions, the control driver 58 and PWM switching circuit 59 supply a driving current to the projecting coil 41a. Thus, the transmission member 46 is moved upward (i.e., toward the mass member 30) through the driving of the projecting coil 41a, so that the key 20 pivots to the depressed position. Once the supply of the driving current to the projecting coil 41a is terminated, the plunger 42 moves downward (toward the key 20) by the load from the mass member 30. Thus, a load is applied from the plunger 42 to the key 20 in the key releasing direction, so that the key 20 pivots to the released position. Such movement of the key 20 is performed at predetermined timing according to operation information of the keys 20 based on the automatic performance data, so that the keys 20 can perform motions conforming to predetermined performance tones.
Although not particularly shown, a stopper mechanism may be provided for holding the mass member 30 in its upper limit position abutting against the upper mass member limit stopper 34. Thus, when the electromagnetic actuator 40 drives the transmission member 46 to effect automatic (unmanned) operation of the key 20, the mass member 30 can be held still in the upper limit position by the stopper mechanism. This can prevent the load of the mass member 30 from being applied to the transmission member 46, and thus, the transmission member 46 can be driven with a minimum force. As a result, the instant embodiment can effectively cut down on electric power required for an automatic performance.
As set forth above, the instant embodiment of the keyboard apparatus 10 includes, as a main component for performing operation control of the key 20, the mass member 30 that imparts a reaction force to performance operation of the key 20 in interlocked relation to the movement of the key 20. In this way, the instant embodiment of the keyboard apparatus 10 can faithfully replicate or reproduce an inertial mass feeling characteristic of, or unique to, a natural keyboard instrument, such as an acoustic piano. The instant embodiment of the keyboard apparatus 10 can also appropriately reproduce an operational feeling at the start of depression of a key in an acoustic piano when movement of the key has to be started against the static load of the corresponding hammer. On that basis, the keyboard apparatus 10 includes the transmission member 46 that abuts against both of the key 20 and mass member 30 to transmit a load from one of the key 20 and mass member 30 to the other, and the electromagnetic actuator 40 that drives the transmission member 46 toward at least any one of the key 20 and mass member 30 by means of the fixed coils 41 (i.e., 41a and 41b). With such a transmission member 46 and electromagnetic actuator 40, it is possible to appropriately adjust the load (reaction force) to be imparted from the mass member 30 to the key 20, so that the keyboard apparatus 10 can readily achieve a key touch feeling extremely approximate to that of a natural keyboard instrument.
Furthermore, because the instant embodiment of the keyboard apparatus 10 includes the mass member 30 that imparts an inertial load to the key 20 in order to impart a key touch feeling to depression operation, by the human player, of the key 20, the keyboard apparatus 10 can provide a key touch feeling approximate to that of a natural keyboard instrument, such as an acoustic piano. Therefore, the load control to be performed by the electromagnetic actuator 40 in the keyboard apparatus 10 may be relatively simple control as compared to the load control performed in the force sense control by the conventionally-known keyboard apparatus, and yet the keyboard apparatus 10 of the invention can provide an extremely superior reproduction of a key touch feeling of a natural keyboard instrument. As a result, the instant embodiment of the keyboard apparatus 10 can faithfully achieve a key touch feeling approximate to that of a natural keyboard instrument, such as an acoustic piano.
Furthermore, by controlling the driving of the electromagnetic actuator 40, the instant embodiment of the keyboard apparatus 10 can adjust both the reaction force to be imparted from the mass member 30 to depression operation of the key 20 and the load acting from the mass member 30 on the key 20. As a result, the instant embodiment of the keyboard apparatus 10 can achieve both force sense control on key depression operation by adjusting the load acting from the mass member 30 on the key 20 and automatic operation of the key 20 by adjusting (increasing or decreasing) forces acting on the key 20 in the key depressing and releasing directions.
Furthermore, in the keyboard apparatus 10, the transmission member 46 to be driven by the electromagnetic actuator 40 is located between the key 20 and the mass member 30, and a driving force generated by the electromagnetic actuator 40 is impartable to both the key 20 and the mass member 30. Thus, a same operating system can be shared between the mass member 30 and the electromagnetic actuator 40 both operatively coupled with the key 20, so that the load acting from the mass member 30 on the key 20 can be appropriately controlled by the electromagnetic actuator 40 and thus the force sense control and driving control can be performed appropriately on the key 20.
Furthermore, in the keyboard apparatus 10, the mass member 30 includes the shank section (arm section) 32 for supporting the mass section 33 for pivoting movement in the region over the key 20, and the transmission member 46 is held in abutment with a portion of the key 20 located opposite from the key depression section 20c with respect to (i.e., as viewed from) the key pivot point 12 and with the shank section 32 of the mass member 30. Such a construction is equivalent to a construction where a wippen assembly disposed between a key and a hammer in an action mechanism of an acoustic piano is replaced with the transmission member 46 and electromagnetic actuator 40 of the present invention. Thus, by the transmission member 46 and electromagnetic actuator 40 performing the function of the wippen assembly of an acoustic piano, the instant embodiment of the keyboard apparatus 10 can achieve a key touch feeling extremely approximate to that of an acoustic piano with minimum necessary structural arrangements and control. In addition, the instant embodiment of the keyboard apparatus 10 can perform an automatic performance involving automatic operation of the keys 20.
Furthermore, the key 20 provided in the keyboard apparatus 10 is a component part similar in construction and operation to a key of an acoustic piano, and the mass member 30 is a component part similar in construction and operation to a hammer of an acoustic piano. Using such component parts similar to a key and hammer of an acoustic piano, the keyboard apparatus 10 allows the static load and dynamic load of the key 20 to be approximate to those of an acoustic piano.
Furthermore, in the keyboard apparatus 10, the mass member 30 is pivotably supported over the key 20, and the electromagnetic actuator 40 and transmission member 46 are disposed between a portion of the key 20 located opposite from the key depression section 20c with respect to (i.e., as viewed from) the key pivot point 12 and the mass member 30. Such a construction is equivalent to a construction where a wippen assembly disposed between a key and a hammer in an action mechanism of an acoustic piano is replaced with the electromagnetic actuator 40 and transmission member 46. Thus, by the electromagnetic actuator 40 and transmission member 46 performing the function of the wippen assembly of an acoustic piano, the instant embodiment of the keyboard apparatus 10 can achieve a key touch feeling extremely approximate to that of an acoustic piano with minimum necessary structural arrangements and control. In addition, the instant embodiment of the keyboard apparatus 10 can perform an automatic performance involving automatic operation of the keys 20.
However, the key 20 and mass member 30 need not necessarily be constructed similarly to a key and mass member of an acoustic piano. In the case where the key 20 and mass member 30 are constructed differently from a key and mass member of an acoustic piano, influences which the key 20 has on a key touch feeling can be covered by controlling the driving force to be imparted to the key 20 and mass member 30 by means of the electromagnetic actuator 40.
Next, a description will be given about a second embodiment of the keyboard apparatus of the present invention. Similar elements to those in the first embodiment are indicated by the same reference numerals as used for the first embodiment and will not be described here to avoid unnecessary duplication. Namely, elements not described in the following description are similar to those in the first embodiment; the same can be said for the third and succeeding embodiments.
By the electromagnetic actuator 40-2 driving the transmission member 46 downwardly toward the key 20, a combination of a reaction force based on a mass or inertial load of the mass member 30 acting on the key 20 and a reaction force imparted to the key 20 by the actuator 40 becomes a reaction force applied to a finger of the human player performing depression operation of the key 20. Thus, the second embodiment of the keyboard apparatus 10-2 can create distributions of reaction forces similar to those of
The second embodiment of the keyboard apparatus 10-2, provided with the uni-directionally driven electromagnetic actuator 40-2, can be simplified in construction and can facilitate the driving control of the electromagnetic actuator 40-2 as compared to the first embodiment. Thus, the second embodiment of the keyboard apparatus 10-2 is suited for application to electronic keyboard instruments of simpler construction and inexpensive electronic keyboard instruments.
Next, a description will be given about a third embodiment of the keyboard apparatus of the present invention.
Namely, in the third embodiment of the keyboard apparatus 10-3, the mass member 30 is disposed under the key 20, and the electromagnetic actuator 40 and transmission member 46 are disposed between the lower surface of the key 20 and the mass member 30. In the transmission member 46, the upper end of the second rod 42c extending upward is held in abutment with a lower surface portion of the key 20 located forwardly of the key pivot point 12 (i.e., located on the same side as the key depression section 20c with respect to the key pivot point 12), and the lower end of the support member 44 fixed to the first rod 42b extending downward is held in abutment with an upper surface portion of the shank section 32 extending in an opposite direction from the mass member 33 with respect to the mass member pivot point 31.
Whereas the key 20, electromagnetic actuator 40 and transmission member 46 and mass member 30 in the first embodiment of the keyboard apparatus 10 are arranged from down to up in the order mentioned on a side (rear side) opposite from the key depression section 20c with respect to (i.e., as viewed from) the key pivot point 12, the key 20, electromagnetic actuator 40 and transmission member 46 and mass member 30 in the third embodiment of the keyboard apparatus 10-3 are arranged from up to down in the order mentioned on the same front side as the key depression section 20c. Namely, in the third embodiment of the keyboard apparatus 10-3, the mass member 30 includes the shank section (arm section) 32 supporting the mass section 33 for pivoting movement in a region under the key 30, and the transmission member 46 is held in abutment with a portion of the arm section 32 located on the same side of the key depression section 20c with respect to (i.e., as viewed from) the key pivot point 12.
In the third embodiment of the keyboard apparatus 10-3 too, when no depressing operation of the key 20 is being performed, the key 20 is held in the non-depressed position with the lower surface of the rear end region 20b of the key 20 held abutting against the upper key limit stopper 21, as shown in
Whereas the embodiments according to the first aspect of the present invention have been described above, the present invention should not be construed as limited to the described embodiments and may be modified variously within the scope of the technical ideas set forth in the appended claims and the specification and drawings. For example, the roller 36 mounted on the shank section 32 in the first and second embodiments of the keyboard apparatus 10 and 10-2 may be replaced with any other suitable member as long as the replacing member can perform appropriate shock absorbing and sliding functions with respect to the transmission member 46. As an example, the roller 36 may be a bearing member including a contact portion with a spherical surface. Alternatively, the transmission member 46 may be abutted directly against the key 20 with the roller 36 omitted.
Further, the embodiments according to the first aspect of the present invention have been described above as applied to the electronic keyboard instrument 1 having the electronic tone generator that generates a tone in response to operation of any one of the keys 20. Thus, in these described embodiments, each of the mass members 30 only has the function of merely imparting an inertial mass to the key 20 to create a key touch feeling approximate to that of a natural keyboard instrument, such as an acoustic piano; namely, the mass member 30 in each of the above-described embodiments does not have a function of actually striking a string to generate a tone. However, the keyboard apparatus of the present invention is not limited to such a described construction, and the mass member 30 may have the function of actually striking, like a hammer member of an acoustic piano, a string to generate a tone, in which case the mechanism for generating an electronic tone in response to operation of the key may be dispensed with.
Next, fourth to eights embodiments according to a second aspect of the present invention will be described with reference to
In
Referring to
It is desirable that the magnetic attaching force between the bearing 361 and the magnet 37 have the following intensity. Namely, it is desirable that the intensity of the magnetic attaching force be such that, when the key 20 and the mass member 30 are in normal operating condition, the bearing 361 and the magnet 37 are held attached together in the first abutment area 48 so that the transmission member 46 can operate integrally with the mass member 30 while being held abutting against the mass member 30, and that, when the key has been depressed extremely rapidly with a great depressing force or depressed or released at an extremely high speed, the bearing 361 and the magnet 37 may be instantaneously detached from each other if acceleration produced in the transmission member 46 and acceleration produced in the mass member 30 differs in direction.
The above-mentioned plunger 42 (including the body portion 42a, first rod 42b and second rod 42c), plate member 43, support member 44 and magnet 37 together constitute the transmission member 46 for transmitting a load (i.e., load by mass or inertial load produced by pivoting movement) from any one of the key 20 and mass member 30 to the other. The transmission member 46 is held sandwiched between the mass member 30 and the key 20 by the self-weight of the mass member 30. As set forth above, the electromagnetic actuator 40 can drive the transmission member 46 (more specifically, plunger 42) in two directions by the projecting coil 41a and retracting coil 41b being supplied with driving currents. The key 20 is normally biased in the key-releasing direction by the load (i.e., load by the mass of the mass member 30) applied thereto from the mass member 30 via the transmission member 46, so that the key 20 is caused to pivot in the key depressing direction as the load from the mass member 30 is reduced by the driving force of the electromagnetic actuator 40.
While the key 20 and mass member 30 vertically pivot about the respective pivot points 12 and 31, the transmission member 46 (plunger 42) linearly moves in its axial direction inside the projecting coil 41a and retracting coil 41b. Thus, when the key 20, mass member 30 and transmission member 46 move integrally with one another, the magnet 37 vertically moving in response to the motion of the transmission member 46 slides on and along the bearing 361 angularly moving in response to the vertical pivoting movement of the mass member 30, in the first abutment area 48 where the magnet 37 provided on the transmission member 46 and the bearing 361 provided on the mass member 30 are normally held in abutment with each other.
Note that the force sense control described above with reference to
Namely, the fourth embodiment of the keyboard apparatus 110 includes the mass member 30 for imparting a reaction force to performance operation of the key 20 in interlocked relation to the key 20. Thus, the fourth embodiment of the keyboard apparatus 110 can faithfully reproduce an inertial mass feeling characteristic of, or unique to, key operation in a natural keyboard instrument, such as an acoustic piano. Further, the fourth embodiment of the keyboard apparatus 110 can also appropriately reproduce an operational feeling at the start of depression of a key in an acoustic piano where movement of the key has to be started against the static load of the corresponding hammer.
Further, in the fourth embodiment of the keyboard apparatus 110, the mass member 30 and the transmission member 46 are detachably attached to each other, in the first abutment area 48, through the magnetic attracting force between the bearing 361 fixed to the mass member 30 and the magnet 37 fixed to the transmission member 46. Because the mass member 30 and the transmission member 46 are detachably attached to each other through the magnetic attracting force of the magnet as noted above, the magnet 37 and the bearing 361 move, during operation of the mass member 30 and the transmission member 46, while rubbing against each other. Thus, during operation of the mass member 30 and transmission member 46, the mass member 30 and the transmission member 46 are allowed to move relatively freely relative to each other while being kept in contact with each other. Therefore, in the keyboard apparatus 110, interlocked operational relationship between the mass member 30 and the transmission member 46 can be secured such that the mass member 30 and the transmission member 46 are allowed to perform different (i.e., pivotal and linear) movement. Further, because the mass member 30 and the transmission member 46 are attached to each other through the magnetic attracting force provided by the magnet 37, the fourth embodiment of the keyboard apparatus 110 can achieve, with a simple mechanism, a construction where, as the mass member 30 operates, the mass member 30 and the transmission member 46 are allowed to move relatively freely relative to each other while being kept in contact with each other.
Furthermore, in the first abutment area 48 where the mass member 30 and the transmission member 46 are held in abutment with each other, a certain frictional force is produced by the magnetic force therebetween. Thus, the keyboard apparatus 110 can appropriately replicate or reproduce a key operating feeling resulting from friction produced within an action mechanism of an acoustic piano. As a result, the keyboard apparatus 110 can also achieve an operational feeling approximate to rebound checking operation (i.e., “backcheck operation”) after a hammer abuts a stopper member in an action mechanism of an acoustic piano; namely, the keyboard apparatus 110 can achieve a so-called pseudo backcheck operation feeling.
In addition, with the mass member 30 and the transmission member 46 attached to each other through the magnetic attracting force, force transmission between the mass member 30 and the transmission member 46 can be effected steadily and reliably. As a result, the keyboard apparatus 110 can more faithfully reproduce an operational feeling of an acoustic piano. Further, with the mass member 30 and the transmission member 46 magnetically attached to each, the mass member 30 can quickly return to its initial position by being taken by the key 20, as the key 20 returns to its initial position. Thus, a state where next tone generation by the key 20 is enabled can be achieved quickly, which permits performance of quick passages.
Furthermore, the fourth embodiment of the keyboard apparatus 110 is constructed in such as manner that the bearing 361 fixed to the mass member 30 angularly moves in response to pivoting movement of the mass member 30 while the magnetic 37 fixed to the transmission member 46 linearly moves in response to vertical movement of the transmission member 46, and that the bearing 361 and the magnet 37 slide relative to each other at their magnetically-joined portions. Therefore, the bearing 361 and the magnet 37 are allowed to slidingly move relative to each other with a relatively high degree of freedom while maintaining the magnetically-attached state at their respective abutting portions. In this way, the fourth embodiment of the keyboard apparatus 110 permits relative movement between the mass member 30 and the transmission member 46 with appropriate frictional force (static and dynamic frictional force) while securing interlocked operational relationship between the mass member 30 and the transmission member 46, as a result of which it can achieve improved behavior and operational feeling of the key 20.
Further, in the fourth embodiment of the keyboard apparatus 110, the surface of the bearing 361 abutting against the magnet 37 is a spherical curved surface, so that the surface of the bearing 361 and the magnet 37 slide relative to each other with an appropriate frictional force. Thus, the keyboard apparatus 110 can achieve even further improved behavior and operational feeling of the key 20.
Next, a description will be given about a fifth embodiment of the keyboard apparatus of the present invention. In the following description about the fifth embodiment and related figures, similar elements to those in the above-described first to fourth embodiments are indicated by the same reference numerals as used for the first to fourth embodiments and will not be described here to avoid unnecessary duplication. Namely, elements not described in the following description are similar to those in the first embodiment; the same can be said for the sixth and succeeding embodiments.
Next, a description will be given about a sixth embodiment of the keyboard apparatus of the present invention.
By the electromagnetic actuator 40-3 driving the transmission member 46 downwardly toward the key 20, a combination of a reaction force by a mass or inertial load of the mass member 30 acting on the key 20 and a reaction force imparted to the key 20 by the actuator 40-3 becomes a reaction force applied to a finger of the human player performing depression operation of the key 20. Thus, the sixth embodiment of the keyboard apparatus 110-3 can create distributions of reaction forces similar to that of
The sixth embodiment of the keyboard apparatus 110-3, provided with the uni-directionally driven electromagnetic actuator 40-3, can be simplified in construction and can facilitate the driving control. Thus, the sixth embodiment of the keyboard apparatus 110-3 is suited for application to electronic keyboard instruments of simpler construction and inexpensive electronic keyboard instruments.
Next, a description will be given about a seventh embodiment of the keyboard apparatus of the present invention.
Namely, in the eleventh embodiment of the keyboard apparatus 110-4, the mass member 30 is disposed under the key 20, and the electromagnetic actuator 40 and the transmission member 46 are disposed between the lower surface of the key 20 and the mass member 30. In the transmission member 46, the upper end of the second rod 42c extending upward is held in abutment with a lower surface portion of the key 20 located forwardly of the key pivot point 12 (i.e., located on the same side as the key depression section 20c), and the lower end of the support member 44 fixed to the first rod 42b extending downward is held in abutment with an upper surface portion of the shank section 32 extending in an opposite direction from the mass member 33 with respect to the mass member pivot point 31.
Whereas the key 20, electromagnetic actuator 40 and transmission member 46 and mass member 30 in the fourth embodiment of the keyboard apparatus 110 are arranged from down to up in the order mentioned on a side (rear side) opposite from the key depression section 20c with respect to (i.e., as viewed from) the key pivot point 12, the key 20, electromagnetic actuator 40 and transmission member 46 and mass member 30 in the seventh embodiment of the keyboard apparatus 110-4 are arranged from up to down in the order mentioned on the same side as the key depression section 20c (i.e., on the front side).
In the seventh embodiment of the keyboard apparatus 110-4 too, when no depressing operation of the key 20 is being performed, the key 20 is held in the non-depressed position with the lower surface of the rear end region 20b of the key 20 held abutting against the upper key limit stopper 21 as shown in
Next, a description will be given about an eighth embodiment of the keyboard apparatus of the present invention.
A lower hammer limit stopper 95 for limiting pivoting movement of the hammer 90 is provided on the rear wall 14b of the support section 14. The lower hammer limit stopper 95 abuts the shank section 92 of the hammer 90 having pivoted to its lower limit position. A string 96 is struck by the string-striking section 93 having pivoted to its upper limit position. The keyboard apparatus 110-5 also includes a damper 97 for suppressing vibration of the string 96, a damper wire 98 for vertically moving the damper 97, a damper block 99, etc. Once the damper block 99 is lifted by the rear end of the key 20 having pivoted to the depressed position, the damper 97 is lifted via the damper wire 98 away from the string 96.
In this keyboard apparatus 110-5 too, the hammer 90 operates in interlocked relation to the key 20 via the transmission member 46 that is operatively connected to the hammer 90 via the magnet 37 and the bearing 361. Thus, the hammer 90 imparts a reaction force to performance operation of the key 20 in conjunction with the electromagnetic actuator 40. Further, in the keyboard apparatus 110-5, a tone is generated by the hammer 90 striking the string 96 in response to depression operation of the key 20. In this way, the keyboard apparatus 110-5 can, for example, dispense with a particular electronic tone generator for generating a tone in response to depression operation of the key 20, etc. Although not particularly shown, the keyboard apparatus 110-5 may include a stopper mechanism for holding the key 20 in the non-depressed position, so that the key 20 can be held in the non-depressed position as the transmission member 46 is driven by the electromagnetic actuator 40. Thus, the keyboard apparatus 110-5 can perform tone generation, based only on striking of the string 96, by driving only the hammer 90 with no load applied to the key 20. As a result, the eighth embodiment of the keyboard apparatus 110-5 can execute an automatic performance that comprises only performance tones involving no operation of the keys 20, with reduced energy and increased efficiency.
Further, in the eighth embodiment of the keyboard apparatus 110-5, where the hammer 90 and the transmission member 46 are operatively attached to each other through the attracting force of the magnet 37, it is possible to prevent the hammer 90 from bouncing back upon abutment against the lower hammer lower stopper 95, even without a component part corresponding to a backcheck member of an acoustic piano. Namely, with the hammer 90 and the transmission member 46 operatively attached to each other through the attracting force of the magnet 37, the eighth embodiment of the keyboard apparatus 110-5 can achieve an operational feeling (so-called pseudo backcheck operation) approximate to backcheck operation performed by a backcheck member immediately following a hammer abutting against a stopper in an action mechanism of an acoustic piano. As a result, the eighth embodiment of the keyboard apparatus 110-5 can even more faithfully reproduce an operational feeling of an acoustic piano while dispensing with a component part corresponding to a backcheck member of an acoustic piano and thereby simplifying the construction of the keyboard apparatus 110-5.
Whereas the embodiments according to the second aspect of the present invention have been described above, the present invention should not be construed as limited to the described embodiments and may be modified variously within the scope of the technical ideas set forth in the appended claims and the specification and drawings. For example, the shapes etc. of the magnet and attraction member provided in the keyboard apparatus may be modified as desired without being limited to those shown and set forth above.
Next, a ninth embodiment according to a third aspect of the present invention will be described with reference to
Now, prior to detailed description of the force sense control on the key 20, behavior of an action mechanism of an acoustic piano will be outlined.
In a key depression stroke, as depicted by one-dot-dash line in the graph of
In the key release stroke, as depicted by a broken line in
The instant embodiment of the keyboard apparatus 10 (which may be constructed in the manner shown in
Namely, detection data is output from the position sensor 47 to the main control section 50, as shown in
The following describe in detail the instruction value tables 81b and 82b of
The first key-depression load P1 is a load for reproducing a static load required for lifting, at the initial stage of depression of the key 102, the key 102 and hammer 108 from their rest positions according to the reaction force characteristics of the acoustic piano provided with the action mechanism 100 of
Because the mechanical construction for driving the key 20 in the instant embodiment of the keyboard apparatus 10 greatly differs from that in the action mechanism 100 of the acoustic piano, a reaction force when no driving force is being generated (i.e., reaction force against key depression/release operation based only on a mechanical structure of the key 20, mass member 30, etc.) differs from that in the acoustic piano. Thus, at the initial stage of key depression from a depression start time when the key 20 starts moving in response depression operation to a time when a predetermined key depression amount is reached, the value of inertial loads applied from the mass member 30 etc. are greater than that in the acoustic piano. Therefore, in the instant embodiment of the keyboard apparatus 10, a driving force is imparted, at the initial stage of key depression, in accordance with the first key-depression load P1 in such a direction as to decrease the reaction force imparted from the mass member 30 to the key 20, so that the key 20 can be operated with a less force; in this way, the instant embodiment can correct a difference in key touch feeling between the keyboard apparatus 10 and a natural keyboard instrument.
The second key-depression load P2 is a load for reproducing a load applied to the key 102 when lifting, by the key 102, of the damper 105 is started via the action mechanism 100 in the acoustic piano. In the illustrated example, the instruction value of the second key-depression load P2 is a constant value that does not depend on the key depressing velocity, and the key depression amount at a start position of the second key-depression load P2 is “3.0 mm” and the instruction value of the second key-depression load P2 is “+0.5 N”.
The third key-depression load P3 is a load for reproducing a load applied to the key 102 by the various component parts of the action mechanism 100 operating in the middle of depression of the key 102. In the illustrated example, the instruction value of the third key-depression load P3 is a constant value that does not depend on the key depressing velocity, and the key depression amount at a start position of the third key-depression load P3 is “5.2 mm” and the instruction value of the third key-depression load P3 is “+0.3 N”.
The fourth key-depression load P4 is a load for reproducing a sudden change in the load applied to the key 102 which is caused by the jack 106 escaping from the hammer roller 107 in the action mechanism 100 of the acoustic piano. The fourth key-depression load P4 has a distribution of reaction forces that depends on the key depressing velocity. In the specific example of
Next, a description will be given about the key-releasing instruction value table 82b shown in
The first key-release load P5 is a load for adjusting the static load applied to the key 20 during the key release. In the key depression amount at an end position of the first key-release load P5 is “0 mm” and the instruction value of the first key-release load P5 is “0 N”. Namely, in the illustrated example, no load for adjusting the static load is substantively imparted during the key release, so that the reaction force applied to the key 20 consists of (or is covered by) only the load of the mass member 30 near the end of the key release. The second key-release load P6 is a load for reproducing a load applied to the key 102 by lifting of the damper 105 in the acoustic piano. In the illustrated example, the key depression amount at an end position of the second key-release load P6 is “3.0 mm” and the instruction value of the second key-release load P6 is “0.5 N”. The third key-release load P7 is a load for reproducing a load applied to the key 102 by the action mechanism 100 during the release of the key 102. In the illustrated example, the key depression amount at an end position of the third key-release load P7 is “5.2 mm” and the instruction value of the third key-release load P7 is “0.3 N”.
The fourth key-release load P8 is a load that is unique to the electronic keyboard instrument 1 and necessary for returning the key 20 to the initial position; namely, the fourth key-release load P8 among the kinds of loads generated in the action mechanism 100 of the acoustic piano. The fourth key-release load P8 has a distribution of reaction forces that depends on the key releasing velocity. In the illustrated example, the key depression amount at an end position of the fourth key-release load P8 is “1 mm” and the maximum instruction value of the fourth key-release load P8 is “1 N”.
It should be appreciated that the instruction value tables 81b and 82b of
The following describe an example operational sequence of the force sense control performed in the instant embodiment on key depression/release operation, with reference to a flow chart of
If the acquired velocity data is of a negative value as determined at step ST2 (NO determination at step ST2), the key-releasing instruction value table 82b shown in
The following describe in greater detail the distributions of reaction forces to operation of the key 20. In this case, the reaction forces applied to the human player's finger depressing the key 20 exhibit a distribution starting at an initial value (zero load) corresponding to a zero key depression amount and including changes in four regions A, B, C and D, in generally the same manner as shown in
In this case, the reaction force L2 to be imparted to the key 20 by the electromagnetic actuator 40 at the initial stage of depression of the key 20 is of a negative value because the first key-depression load P1 is of a negative value (see
At the time of release of the key 20 shown in
As set forth above, the instant embodiment of the keyboard apparatus 10 according to the third aspect of the present invention is constructed in such a manner that instruction values of loads to be imparted to the key 20 by means of the bi-directionally driven electromagnetic actuator 40 are determined on the basis of information pertaining to a position of the key 20 acquired by the position sensor 47 and a velocity of the key 20 calculated on the basis of a change in the position, and that the electromagnetic actuator 40 selectively generates, as a driving force corresponding to the determined instruction values, any one of a driving force acting in such a direction as to promote or increase the reaction force imparted from the mass member 30 to depression operation of the key 20 (i.e., reaction force against the operation of the key) and a driving force acting in such a direction as to decrease the reaction force imparted from the mass member 30 to depression operation of the key 20 (i.e., force assisting the operation of the key). With the force sense control on the key 20 through the driving of the electromagnetic actuator 40, the instant embodiment of the keyboard apparatus 10 can appropriately adjust the reaction force to performance operation of the key 20 and thereby achieve a key touch feeling more approximate to that of a natural keyboard instrument. As a result, the instant embodiment of the keyboard apparatus 10 can faithfully reproduce a reaction force to performance operation of a natural keyboard instrument, such as an acoustic piano, including a complicated action mechanism.
Namely, in the instant embodiment of the keyboard apparatus 10 which is designed to simulate a key touch feeling of a natural keyboard instrument by the electromagnetic actuator 40 generating an auxiliary or assisting driving force, a reaction force to key depression operation based only on the mechanical structure consisting of the key 20, mass member 30, etc. (i.e., reaction force when no driving force is being generated by the electromagnetic actuator 40) would differ from a reaction force generated in a natural keyboard instrument, such as an acoustic piano. Consequently, at the initial stage of depression of the key 20, from the depression start time when the key 20 starts moving in response depression operation to the time when a predetermined key depression amount is reached, the inertial load (L1) applied from the mass member 30 to the key 20 would take a great value as compared to the natural keyboard instrument, as set forth above. However, in the instant embodiment of the keyboard apparatus 10, the bi-directionally-driven electromagnetic actuator 40 is provided for driving the transmission member 46 upwardly (away from the key 20) to thereby impart a driving force acting in such a direction as to decrease the reaction force imparted from the mass member 30 to depression operation of the key 20 (i.e., driving force assisting the operation of the key). Thus, the instant embodiment of the keyboard apparatus 10 can effectively correct a difference in key touch feeling at the initial stage of depression of the key between the keyboard apparatus 10 and the natural keyboard instrument.
The ninth embodiment of the keyboard apparatus 10 according to the third aspect of the present invention has been described as applied to the electronic keyboard instrument 1 including an electronic tone generator that generates a tone in response to operation of the key 20. Thus, in the ninth embodiment of the keyboard apparatus 10, the mass member 30 does not have the function of actually striking a string and has only the function of merely imparting an inertial mass to the key 20 to realize a key touch feeling approximate to that in a natural keyboard instrument, such as an acoustic piano. However, it should be appreciated that the keyboard apparatus of the present invention is not limited to the above-described construction and may have the function of causing a tone to be generated by the mass member actually striking a string. In such a case, a mechanism for causing an electronic tone in response to operation of the key may be dispensed with.
Further, whereas, in the above-described embodiments according to the first to third aspects, the mass member 30 is constructed to pivot about the mass member pivot point 31, the movement of the mass member 30 provided in the keyboard apparatus of the present invention is not limited to such pivoting movement and may be linear or any other type of movement. Furthermore, the positional relationship between the key, the transmission member and the mass member is not limited to the vertical positional relationship as shown and described in relation to the embodiments. For example, although not particularly shown, the key and the mass member may be arranged side by side in the horizontal direction with the transmission member interposed therebetween, so that the movement of the key can be transmitted in the horizontal direction to the mass member via the transmission member. In such a case, the mass member may be constructed to either pivot or linearly move.
While the present invention has been particularly shown and described with reference to preferred embodiment thereof, it will be understood by those skilled in the art that the foregoing and other changes in form and details can be made therein without departing from the spirit and scope of the present invention. All modifications and equivalents attainable by one versed in the art from the present disclosure within the scope and spirit of the present invention are to be included as further embodiments of the present invention. The scope of the present invention accordingly is to be defined as set forth in the appended claims.
This application is based on, and claims priorities to, JP PA 2009-151649 filed on 25 Jun. 2009, JP PA 2009-151650 filed on 25 Jun. 2009, and JP PA 2009-194675 filed on 25 Aug. 2009. The disclosures of the priority applications, in their entirety, including the drawings, claims, and the specifications thereof, are incorporated herein by reference.
Number | Date | Country | Kind |
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2009-151649 | Jun 2009 | JP | national |
2009-151650 | Jun 2009 | JP | national |
2009-194675 | Aug 2009 | JP | national |
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