JP2775759B2 - Tone control signal generator for electronic musical instruments - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tone control signal generator for an electronic musical instrument,
In particular, when a player operates a musical tone control operation element, a musical tone control signal having a magnitude corresponding to the operation position can be generated.

[Summary of the Invention]

The present invention relates to a tone control signal generator for an electronic musical instrument which controls a tone to be played in response to a player operating an automatic return type tone control for a music player.
By setting a predetermined value as the operator data when the operation of the musical tone control operator is released and the musical tone control operator returns to the automatic return position, an unnatural offset in the musical tone is prevented. Can be.

[Conventional technology]

As this kind of musical tone control signal generating device, there is one which generates a musical tone control signal for giving a so-called pitch bend effect to a musical tone by means of an automatic return type musical tone controlling operator (Japanese Patent Publication No. 61-47433). ).

For example, in the handheld electronic musical instrument 1 shown in FIG.
A keyboard portion 3 is provided on a front portion of the body portion 2 so as to extend in the left-right direction, and a tone control operator is provided on a rear portion of a tip portion of a neck portion 4 protruding leftward from a left end of the body portion 2. An operator 5 for pitch bend is provided, and a body part 2 is provided.
In a hand-held state with the strap 6 attached to the player's shoulder, the keyboard 3 is depressed with the right hand, and the index bend, middle finger, or ring finger is used while holding the net 4 with the left hand. The pitch of the musical tone generated in response to the depressed key, that is, the pitch, is changed in accordance with the turning position of the pitch bend operating element 5 by rotating the operating element 5 from the rear side. It has been done.

Here, as shown in FIGS. 15 and 2, the pitch bend operation element 5 has a configuration in which a part of the wheel 11 is projected from the panel surface of the neck portion 4, and is formed on the outer peripheral surface of the wheel 11. The player can reciprocate the wheel 11 by rubbing his finger against the anti-slip notch 12.

The rotating shaft of the wheel 11 is connected to a pitch bend volume 28 composed of a variable resistor, and a depression 13 is formed on the outer peripheral surface of the wheel 11, and the depression 13 is indicated by an arrow a as shown in FIG.
It can be rotated from the lower limit operation position MIN to the upper limit operation position MAX (this is called a forward operation), and a direction from the upper limit operation position MAX to the lower limit operation position MIN as shown by an arrow b. (This operation is referred to as a reverse operation).

A return spring (not shown) is attached to the wheel 11 so that when the player releases his / her finger from the wheel 11, the return spring automatically returns the wheel 11 to a predetermined operation position. (This automatic return position is called a neutral operation position).

Actually, the automatic return operation of the oil 11 is performed so that the player can easily confirm the depression 13 by returning to the neutral operation position MID predetermined at the intermediate point between the upper limit operation position MAX and the lower limit operation position MIN. ing.

Thus, when the player no longer needs to apply the pitch bend effect to the musical sound, the player releases the finger from the pitch bend operation element 5 to move the wheel 11 to the neutral operation position MID.
, Whereby it is possible to immediately switch from the performance state in which the tone with the pitch bend effect is generated to the performance state in which the pitch bend effect is not applied,
As a result, it has been devised so that the pitch bend effect can be imparted by an operation as simple as possible in performance.

[Problems to be solved by the invention]

However, when the pitchbend operator 5 having such a configuration is used, when the player releases his / her finger from the wheel 11 in a state where the player rotates the wheel 11 to a position other than the neutral operation position MID, the wheel 11 There is a possibility that it will not be possible to accurately return to the normal neutral operation position MID.

The return spring for returning the wheel 11 to the neutral operating position MID or the mechanical turning mechanism of the wheel 11 is to avoid fatigue when the use number of the pitch bend operating element 5 increases. As a result, the wheel 11 cannot correctly return to the normal neutral operation position MID.

In such a state, the pitch of the key depressed by the keyboard portion 3 is offset from the neutral operation position MID where the return position of the wheel 11 is correct to a higher pitch or a lower pitch by the offset. The consequences are:

The present invention has been made in consideration of the above points, and even if an offset of an operation element that does not allow a music control element to correctly return to a normal automatic return position occurs, a tone generated from an electronic musical instrument is generated. It is an object of the present invention to propose a musical tone control signal generating device for an electronic musical instrument which does not cause an unnatural offset in a pitch.

[Means for solving the problem]

In order to solve such a problem, in the first invention,
When the operation by the player is released, the automatic return position (MI
D), and an operation data generating means (2) for generating operation data DATA corresponding to the operation position of the operation control of the music control (5).
8, 29) and invariant time detecting means (23, SP21-SP) for detecting that the operation data DATA does not change for a predetermined time.
22-SP23-SP24-SP25-SP28-SP21) and when the invariable time detecting means detects that the operator data DATA does not change for a predetermined time, the tone control operation (5)
Sends the tone control data WHEELP corresponding to the control data DATA when the control data is at the normal automatic return position. In other cases, the control data DATA generated by the control data generating means (28, 29) is output. Setting means (23, SP26, SP27) for transmitting the tone control data WHEELP corresponding to the tone control data WHEELP, and the tone to be generated is controlled by the tone control data WHEELP.

Further, in the second invention, when the operation by the player is released, the musical tone control operation element (5) which automatically returns to the automatic return position (MID), and the operation of the musical sound control operation element Manipulator data generating means (28, 29) for generating manipulator data DATA corresponding to the position, and midpoint position data holding means (23, 25C) for holding the manipulator data DATA at power-on as midpoint position data MIDPNT ) And operator data D
Invariant time detecting means (23, SP21-SP22-SP23-SP24-SP25-SP) for detecting that the ATA does not change for a predetermined time.
28-SP21) and the operation data DATA
Is not changed for a predetermined time, the tone control data WHEE corresponding to the midpoint position data MIDPNT is detected.
Setting means (23, SP26, SP) for transmitting the LP and transmitting the tone control data WHEELP corresponding to the control data DATA generated by the control data generating means (28, 29) in cases other than the above.
27), the tone to be generated is controlled by the tone control data WHEELP.

[Action]

When the performer releases the operation and the musical tone control operator (5) automatically returns to the automatic return position, if an offset is included, invariable time detecting means (23, SP21-SP22-SP)
23-SP24-SP25-SP28-SP21)
After confirming that TA does not change for a predetermined time, the correcting means (23, SP26, SP27) converts the neutral operation position reference value data "63" or the midpoint position data MIDPNT into the tone control data.
Set as WHEELN, WHEELP.

Thus, even if a positional offset occurs in the musical tone control operation element 5, it is possible to prevent an unnatural offset from occurring in the musical sound, and when the musical tone control operation element 5 is operated, such an offset occurs. By not performing the processing, unnaturalness can be prevented in this case as well.

〔Example〕

In the following drawings, a fifteenth tone generation signal for giving a pitch bend effect to a tone is generated.
An embodiment in which the present invention is applied to the hand-held electronic musical instrument 1 shown in the figure will be described in detail.

[1] Overall Configuration of First Embodiment In FIGS. 1 and 2 in which parts corresponding to those in FIG. 15 are denoted by the same reference numerals, the electronic musical instrument 1 has key information KIN input from the keyboard 3 and a panel. The operator information PIN input from the operation unit 21 is stored in a ROM-structured program and data memory 22.
The data is stored in a RAM configuration data and a working memory 25 via a data bus 24 by a central processing unit (CPU) 23 that executes based on the program data stored in the RAM.

The CPU 23 executes predetermined data processing on these input information, and transmits the resulting key data KD and parameter data PRD via the data bus 24 to the tone signal generator (T
G) Give to 26. The tone signal generator 26 generates a tone signal specified by the key data KD and the parameter data PRD and sends the tone signal to the sound system 27.
27 converts this to a musical tone.

As shown in FIG. 2, the pitch-bending operator 5 is mechanically connected to the variable operator 28A of the pitch-bend volume 28, and thus converts the voltage output corresponding to the operating position of the variable operator 28A into an analog / digital conversion circuit 29. Is converted into 7-bit pitch bend operator data DATA.

Thus, the pitch bend control data 5, the pitch bend volume 28, and the analog / digital conversion circuit 29 are provided by the pitch bend control data DA according to the player's operation.
The controller data generating means 30 for generating TA is configured.

In the case of this embodiment, when the operation on the pitch bend operation element 5 is released, the variable operation element 28A moves to the neutral operation position MID at the midpoint of the upper limit operation position MAX and the lower limit operation position MIN of the pitch bend volume 28, for example. It is made to return automatically.

The analog / digital conversion circuit 29 (FIG. 2)
When the variable operator 28A is at the neutral operation position MID, the neutral operation position data D is used as the pitch bend operator data DATA.
_MID (= 63 (decimal number)) is transmitted, and when the variable operator 28A is operated to the upper limit operation position MAX, the upper limit operation position data D _MAX (=
126 (decimal number)), and when the variable operator 28A is operated to the lower limit operation position MIN, lower limit operation position data D _MIN (= 0 (decimal number)) is transmitted as pitch bend operator data DATA.

On the other hand, when the variable operator 28A automatically resets and the offset from the correct neutral operation position MID to the offset operation position OFS, the pitch bend volume 28 is reset to the offset position data D as the pitch bend operator data DATA.
_{MID (OFFSET)} is sent out, whereby the variable manipulator 28A is adjusted by the pitch offset data POFFST (= D _{MID (OFFSET)} -D _MID ) for the correct normal neutral operation position data D _MID (= 63). Pitch bend operator data DATA indicating that the new neutral operation position has been moved is taken into the data and working memory 25 by the CPU 23.

The panel operation section 21 is disposed on the rear surface of the body section 2 (FIG. 15) so as to be adjacent to the keyboard section 3.
A, Down switch 21B, Display 21C, Tempo setting switch 21D, Transpose setting switch 21
E, a tuning setting operation switch 21F, and a group of other operators 21G (including a tone color selection switch, a volume designation switch, a rhythm selection switch, etc.).

In this embodiment, the up switch 21A and the down switch 21B are used to set the tempo during automatic performance by the tempo setting operation switch 21D, to input the transposition data by the transpose setting operation switch 21E, and to set the tuning setting. It is commonly used when finely adjusting the reference pitch by the operation switch 21F and when setting the changeable width and change direction of the pitch bend.

The data and working memory 25 has various registers shown in FIG.

Current pitch bend operation position data acquisition register 25A
Stores current pitch bend operation position data WHEELN indicating the current operation position of the pitch bend operation element 5. Actually, this data WHEELN is generated by the CPU 23
The pitch bend operation data DATA supplied to the data bus 24 from the controller is fetched by repeatedly scanning at a predetermined cycle.

The previous pitch bend operation position data register 25B
While the current pitch bend operation data DATA is sequentially fetched by repeating the scan, the previous pitch bend operation position data WHEELD fetched into the current pitch bend operation position data fetch register 25A by the previous scan. Is stored.

The pitch bend data register 25D stores the pitch bend control data DAT when the pitch bend control 5 is not operated and the neutral position is at the correct neutral operation position MID.
Position data D _MID that can be obtained as A (= "63")
Pitch bend data WHEELP having the same value as (FIG. 2)
Is stored. The pitch bend data WHEELP after this correction is used as basic data for forming pitch bend control data for a tone to be generated in the tone signal generator 26 at present.

The range data register 25E stores correction coefficient data BRANGE indicating a changeable width and a change direction of the pitch bend. The correction coefficient data BRANGE includes a code data portion indicating the pitch change direction of the tone signal by a "+" or "-" sign, and a coefficient value indicating the dynamic range of the pitch bend to be added by coefficient values "1" to "12". It consists of a data section.

In practice, in order to form a control signal for a musical tone, the change range "0" to "126" of the pitch bend operation data DATA obtained from the pitch bend volume 28 is set to the correct neutral operation position value "63" (this is the neutral operation position). (Referred to as a reference value) is converted into a neutral change “−63” to “0” or “0” to “+63”, and then the contents of the correction coefficient data BRANGE “+1” to
Selectively multiplies “+12” or “−1” to “−12”.

The result of the multiplication is represented by the conversion straight line RANGE (+1
2), RANGE (+11) ... RANGE (+1) and RANGE (-
1) As shown by RANGE (−11) and RANGE (−12), when the pitchbend operator 5 is operated so as to increase the value of the pitchbend operator data DATA, the lower limit value RM is obtained.
IN = (+12) x (-63), (+11) x (-63) ... (+
1) From (-63) to the upper limit RMAX = (+12) x (+63),
(+11) x (+63) ... Data that changes with a positive gradient to (+1) x (+63) and lower limit RMIN = (-1) x (-63)
From (-11) x (-63), (-12) x (-63), the upper limit value RMAX = (-1) x (+63) ... (-11) x (+63),
Data that changes with a negative gradient to (−12) × (+63) is obtained.

Therefore, conversion straight lines RANGE (+12), RANGE (+11) …… RA
NGE (+1), RANGE (-1) ... RANGE (-11), RANGE
Upper limit value of (−12) RMAX = (+ 12) × (+63), (+11)
× (+63) ... (+ 1) × (+63), (−1) × (+6
3) Pitchbend control data for (-11) x (+63) and (-12) x (+63) in units of 100 cents "+1200" cents, "+1100" cents ... "+10"
"0" cent, "-100" cent ... "-1100" cent,
When "-1200" cents are assigned, when the pitch bend operation element 5 is finally operated from the lower limit operation position MIN to the upper limit operation position MAX through the neutral operation position MID, "+12" to "+1" are set as the correction coefficient data BRANGE. "," -1 "to" -1 "
2], the pitch bend control data (from “1200” cent to “+1200” cent) to (“−100” cent to “+100” cent), (“+100” cent) To "-100" cents)
Pitch bend control data that varies (from "+1200" cents to "-1200" cents) can be generated.

The conversion straight lines RANGE (+12) to RANGE (+1), RA in FIG.
As can be seen from NGE (-1) to RANGE (-12), if the sign of the code data part is selected to be "+" in the correction coefficient data BRANGE, the pitch bend operation element 5 is moved to the lower limit operation position MI.
While it is possible to control the cent value of the pitch bend data to increase during the operation from N to the upper limit operation position MAX (this is called a forward operation), the sign of the sign data part is changed to "-". Is selected, control is performed so that the cent value of the pitch bend control data is increased while the pi-bend operator 5 is operated from the upper limit operation position MAX to the lower limit operation position MIN (this operation is referred to as reverse operation). I can do it.

Accordingly, when the player operates the pitch bend control element 5 of the electronic musical instrument 1 (FIG. 15) in the forward direction from the rear side to the front side, the value of the pitch bend control data is changed to the code of the code data portion of the correction coefficient data BRANGE. When the pitch bend operation element 5 is to be operated in the reverse direction from the front side to the rear side when set to ascend, if the sign of the code data portion is inverted and set, the pitch bend control data is similarly set. Can be reset to increase the value of.

The invariable time data register 25F stores invariant time data WCNT as criterion data for determining whether or not the pitch bend operation element 5 has been operated for a predetermined period of time after it has not been operated. . The invariable time data WCNT is stored in the neutral operation whenever the pitch bend operation element 5 is automatically returned to the neutral operation position and then left unoperated for the time represented by the invariable time data WCNT. It is used to execute processing for generating the pi-bend data WHEELP having the position reference value “63”.

The setting state data register 25G includes an up switch 21A, a down switch 21B, and a display of the panel operation section 21.
21C stores setting state data STATE indicating which data is currently used for setting. In this embodiment, the setting state data STATE is state numbers "0", "1", "2". At this time, the setting operation switches 21D, 21E, and 21F are used to store the tempo setting state, the transpose setting state, and the tuning setting state.

The tone assignment register 25H stores frequency data FDATA of a key currently being depressed on the keyboard 3 for a plurality of N channels of tones that can be generated simultaneously in the tone signal generator 26.

The other data register 25I stores other data ANDATA relating to, for example, timbre, tempo, transpose, tuning, and the like.

[2] Operation of the First Embodiment In the above configuration, the electronic musical instrument 1 performs the main operation of the musical tone generation processing program from step SP1 of FIG. enter.

At this time, the CPU 23 initializes various registers including the data and the working memory 25 (FIG. 3) in the next step SP2, and then scans the pitch bend operation data DATA sent from the pitch bend volume 28 in step SP3. The current pitch bend operation position data WHEELN is taken into the current pitch bend operation position data take-up register 25A.

Thus, the initial condition setting process is completed, and then the CPU 2
Step 3 moves to step SP5 to execute the scan processing of the pitch bend volume 28. In this process, the CPU 23 executes the subroutine shown in FIG. 6 so that the neutral operation position reference value "63" is set as the neutral operation position when the pitch bend operation element 5 is not operated and is left for a predetermined time. Is set, and a process of giving a pitch bend effect to the tone control signal to be sent to the tone signal generator 26 when the pitch bend operation element 5 is operated is executed.

Subsequently, the CPU 23 proceeds to step SP6 to execute a scan process for the pitch bend-related operator. This processing is performed by the up switch 21A, the down switch 21B, and the display 21.
For the tempo setting switch 21D, the transpose setting switch 21E, and the tuning setting switch 21F that use C in common with the pitch bend processing, the CPU 23 sets the seventh.
The subroutines shown in FIGS. 8, 8 and 9 are executed.

When it is confirmed in step SP11 of FIG. 7 that the tempo setting operation switch 21D has entered the on-event state,
PU23 proceeds to the next step SP12 and sets the state data STATE.
= “0” is written in the setting state data register 25G, and then the process returns to the main routine from step SP13.

Upon confirming that the transpose setting operation switch 21E has entered the ON event state in step SP14 of FIG. 8, the CPU 23 proceeds to the next step SP15 and writes the setting state data STATE = "1" to the setting state data register 25G. After that, the process returns to the main routine from step SP16.

When it is confirmed at step SP17 in FIG. 9 that the tuning setting operation switch 21F has entered the ON event state, the CPU 23 proceeds to the next step SP18 and writes the setting state data STATE = "2" to the setting state data register 25G. Thereafter, the process returns to the main routine from step SP19.

Subsequently, in step SP7, the CPU 23 executes the panel operation section.
After the output of each operator included in the other operator group 21G of 21 is scanned, the process proceeds to step SP8 to scan the output of the key depressed on the keyboard unit 3 and fetch the key data. A process of allocating a sound generation channel to the key data and writing it as frequency data FDATA in the sound generation assignment register 25H is executed.

Thereafter, the CPU 23 returns to the above-mentioned step SP5, and thereafter repeats the processing of passing through the loop LOOP1 of the steps SP5-SP6-SP7-SP8-SP5, thus processing the data and working data each time the player performs a new performance operation. Take it into memory 25.

CPU 23 which entered the pitch bend volume scan processing subroutine from step SP21 of the subroutine of FIG.
In the next step SP22, pitch bend volume
The 28 pitch bend operation data DATA is scanned and written as the current pitch bend operation position data WHEELN in the current pitch bend operation position data acquisition register 25A.

In the following step SP23, the CPU 23 reads the data WHEELN and WHEEL from the register 25A for acquiring the current pitch bend operation position data and the register 25B for the previous pitch bend operation position data.
The ELD is read to determine whether these data are equal to each other. Here, if a negative result is obtained, this means that the pitch bend operation element 5 has been operated. Conversely, if a positive result is obtained, this means that the pitch bend operation element 5 has not been operated. .

If a positive result is obtained in step SP23, the CPU 23 proceeds to step SP24 and counts a time period during which the pinch bend operating element 5 is stopped without being operated (ie, an invariable time period). Then, when the invariable time is equal to or longer than a predetermined time, the process enters an arithmetic processing procedure for setting a neutral operation position reference value “63” as neutral operation position data of the pinch bend operation element 5.

However, the automatic return position (FIG. 2) to which the player returns by releasing his / her finger from the pitch bend operation element 5 is not always the correct neutral operation position MID, but the offset operation position OFS
Could be The CPU 23 executes arithmetic processing so as not to cause an offset in the pitch of the musical tone due to the positional offset.

That is, the CPU 23 adds “+1” to the data WCNT of the invariable time data register 25F in step SP24, and then proceeds to step SP25 to store the invariable time data WCNT after the addition of “+1” in the predetermined reference time data TMAX (for example, 1
[Seconds]), and if a negative result is obtained, the process immediately returns to the main routine from step SP28.

At this time, the CPU 23 repeats the processing of the loop LOOP1 (FIG. 5), and accordingly, the steps SP21-SP22-SP23-SP24
-The processing of the circulation loop LOOP2 of SP25-SP28-SP21 is repeated. Thus, the invariable time data WCNT of the invariable time data register 25F increases with the period of the operation clock of the CPU 23.

Immediately after power-on, such invariant time data WC
While calculating the NT, the CPU 23 has not yet executed the processing of the tone generation processing loops SP31 to SP34, which will be described later, so that the tone signal generator 26 maintains a state in which tone signals are not generated.

Eventually, when the invariable time data WCNT becomes equal to the reference time data TMAX, the CPU 23 obtains an affirmative result in step SP25 and moves to step SP26 to store the neutral operation position reference value "63" in the current pitch bend operation position data acquisition register. After writing to 25A, proceed to step SP27.

Here, the CPU 23 stores the current pitch bend operation position data WHEELN held in the current pitch bend operation position data acquisition register 25A in the pitch bend data register 25D.
And reset the data WCNT of the invariable time data register 25F to "0".

Thus, when the return position of the pitch bend operation element 5 which has been left unoperated after the automatic return is at the offset position OFS, the CPU 23 forcibly neutralizes the current pitch bend operation position data WHEELN and the pitch bend data WHEELP. By setting the operation position reference value to "63", an operation condition as if the pitch bend operation element 5 is presently at the correct neutral operation position MID is simulated.

Thereafter, the CPU 23 proceeds to step SP31 and enters a sound generation processing loop. That is, the CPU 23 shifts to step SP31 to convert the pitch change data PB _CENT which should change the pitch of the musical tone in accordance with the operation of the pitch bend operation element 5 by the following equation. To obtain pitch change amount data PB _CENT expressed in cent values.

In the equation (1), the right side (WHEELP-63) is centered on the _offset neutral operation position data D _{MID (OFFSET)} .
This means that data is obtained in which the range up to the upper limit operation position data D _MAX is a positive value and the range up to the lower limit operation position data D _MIN is a negative value.

The right side (BRANGE × 100/63) of the equation (1) is the correction coefficient data BRANG stored in the range data register 25E.
From the new neutral operation position OFS to the upper limit operation position MA based on E
For the range up to X or the lower limit operation position MIN, the number of cents per unit data is shown.

For example, when the correction coefficient data BRANGE is “+1”,
As described above in FIG. 4 as the conversion straight line RANGE (+1), the pitch bend change width when changing from the neutral operation position MID to the upper limit operation position MAX is "+100" cents (that is, a semitone). In addition, in the range from the neutral operation position MID to the lower limit operation position MIN, the pitch changes by "-100" cents.

On the other hand, BRANGE =
If “−12” is set, the neutral operation position MID
From the neutral operation position MID to the lower limit operation position MIN, and a change of "+1200" cents from the neutral operation position MID to the lower limit operation position MIN.

Thus, the pitch change data PB _CENT of equation (1) is
The operation amount from the new neutral operation position OFS (FIG. 2) after the correction to the current operation position PPB of the pitchbend operator 5 is expressed in cents.

In the following step SP32, the CPU 23 adds the pitch change amount data PB _CENT to the currently sounding frequency data to create frequency data with a pitch bend effect, and in the subsequent step SP33, based on the frequency data after the addition operation. By reading the F number table stored in the program and data memory 22, the F number data is transmitted to the musical tone signal generator 26.

The processing in steps SP32 and SP33 is executed for all the sounding channels, and when the processing is completed.
The CPU 23 returns to the main routine from step SP34.

By the way, when the power is turned on, the performer sets the reference time data TMAX
Operation for pitch bend for a time longer than the time corresponding to
Is not operated, in step SP31, the pitch bend data WHELP is set to the neutral operation position reference value "63" (step SP27), so the pitch change data PB _CENT by the CPU 23 becomes "0", As a result, even if the pitch bend operation element 5 is offset to the offset position OFS (FIG. 2), the CPU 23 executes a process of not correcting the pitch of the musical tone assuming that the pitch operation element 5 is at the neutral operation position MID.

Thereafter, the CPU 23 returns to the main routine from the step SP28 to reenter the step SP21, but unless the pitch bend operation element 5 is newly operated, the current pitch bend operation position data WHEELN is taken in the step SP22, so that the affirmative result is obtained in the step SP23. Thus, the count operation of the invariable time data WCNT is repeated by the loop LOOP2. Thus, the CPU 23 determines the time represented by the predetermined reference time data TMAX (that is, 1).
Every [second]), the processing is repeated assuming that the pitch bend operating element 5 which has been left unoperated has no pitch offset.

In this state, the player operates the pitch bend operating element 5.
When the pitch bend operator data DATA obtained from the pitch bend volume 28 by operating
U23 fetches the changed data into the current pitch bend operation position data fetch register 25A in step SP22. Therefore, the current pitch bend operation position data WHEE
Since the value of LN is different from the value of the last pitch bend operation position data WHEELD, the CPU 23 obtains a negative result in step SP23.

At this time, the CPU 23 proceeds to step SP29 and rewrites the data WHEELN currently stored in the pitch bend operation position data acquisition register 25A as the last pitch bend operation position data WHEELD in the previous pitch bend operation position data register 25B, and changes the invariable time data. Register 25F
Is reset to "0".

Thus, when the pitch bend operation element 5 is operated, the CPU 23 holds the pitch bend operation position data before the operation in the previous pitch bend operation position data register 25B as the previous pitch bend operation position data WHEELD,
The invariable time data register 25F is reset to a standby state in which counting can be newly started.

Subsequently, the CPU 23 proceeds to step SP30, reads the data WHEELD from the previous pitch bend operation position data register 25B, and writes it as pitch bend data WHEELP in the pitch bend data register 25D.

The pitch bend data WHEELP thus held in the pitch bend data register 25D represents the actual pitch bend operation amount based on the correct neutral operation position data D _MID (= 63) (FIG. 2).

Thus, the CPU 23 performs the process of creating the pitch bend data WHEELP when the pitch bend operation element 5 is operated, and then gives the pitch bend based on the pitch bend data WHEELP in the above-mentioned steps SP31, SP32, SP33 and SP34. Execute the pronunciation process.

The writing or updating of the correction coefficient data BRANGE of the range data register 25E is performed by operating the up switch 21A or the down switch 21B of the panel operation section 21.
U23 executes according to the processing procedure of FIG. 10 or FIG.

To increase the value of the correction coefficient data BRANGE, the player repeatedly turns on the switch 21A multiple times as necessary. At this time, the CPU 23 enters the step-up event processing program from step SP41 in FIG. 10, and in the next step SP42, the data WHEELD of the previous pitch bend operation position data register 25B is set to the maximum value "1".
26 "or a minimum value" 0 ".

If a positive result is obtained, the CPU 23 proceeds to step SP43 and determines whether or not the maximum limit data “+12” is exceeded if “+1” is added to the correction coefficient data BRANGE written in the range data register 25E. When a negative result is obtained, the process proceeds to step SP44 to correct the correction coefficient data BRANGE
To the range data register 25E.

Thereafter, the CPU 23 proceeds to step SP45 to display the correction coefficient data BRANGE of the range data register 25E on the display 21C to visually confirm the player, and then returns to the main routine in step SP46.

On the other hand, if an affirmative result is obtained in the above-mentioned step SP43, this means that the value of the correction coefficient data BRANGE held in the range data register 25E has already reached the maximum limit data “+12”, so that “ In this case, the CPU 23 jumps to step SP45 and displays the correction coefficient data BRANGE before the "+1" addition is displayed on the device play 21C to call the player's attention. .

On the other hand, when attempting to reduce the value of the correction coefficient data BRANGE held in the range data register 25E, the player operates the down switch 21B.

At this time, the CPU 23 enters the down switch event processing program in step SP51 of FIG. 11, and in step SP52, the data WHEELD held in the previous pitch bend operation position data register 25B becomes the maximum value "126" or the minimum value "0". It is determined whether or not the condition is satisfied, and when a positive result is obtained, the process proceeds to step SP53 to correct the correction coefficient data.
Assuming that "-1" is subtracted from BRANGE, the minimum data "-1"
2) or not, and when a negative result is obtained, in step SP54, the correction coefficient data
1 "is subtracted and written to the range data register 25E.

Subsequently, the CPU 23 proceeds to step SP55, displays the correction coefficient data BRANGE obtained by subtracting “−1” on the display 21C, and then returns to the main routine in step SP56.

On the other hand, when a positive result is obtained in step SP53, the CPU 23 stores “−” in the correction coefficient data BRANGE.
"1" The CPU jumps to step SP55 without subtraction to notify the player that the current correction coefficient data BRANGE is the lower limit value data.

In this manner, the value of the correction coefficient data BRANGE of the range data register 25E is operated by operating the pitch bending operator 5 to the upper limit operation position MAX or the lower limit operation position MIN, and then operating the up switch 21A or the down switch 21B. It can be changed step by step.

As a result, the conversion curves RANGE (+12) to RANGE (+
As described above for 1) and RANGE (-1) to RANGE-12), when the pitch bend operation element 5 is variably operated from the lower limit operation position MIN to the upper limit operation position MAX, the amount by which the pitch of the musical tone can be changed and controlled ( That is, the change width of the pitch bend) is set to the correction coefficient data BRANG
It can be easily changed by changing E.

In this case, the up-switch event processing program (the tenth program) must be performed on condition that the pitch bend operation element 5 is operated to the upper limit operation position MAX or the lower limit operation position MIN.
(FIG. 11) or a down-switch-on event processing program (FIG. 11), so that the correction coefficient data BRANGE is added or subtracted, so that a switch dedicated to pitch bend selection is not provided on the panel operation unit 21 and omitted. Therefore, the configuration as a whole can be simplified.

In the up-switching event processing program (FIG. 10) or the down-switching event processing program (FIG. 11), the CPU 23 performs correction when the pitch bend operation element 5 is not operated to the upper limit operation position MAX or the lower limit operation position MIN. Execute the setting processing mode other than the setting of the coefficient data BRANGE.

That is, when the up-switch 21A is operated, the CPU 23 enters the up-switch event processing program from step SP41 in FIG. 10. When a negative result is obtained in step SP42, the CPU 23 proceeds to step SP61. In this step SP61, the data and the data STATE of the setting state data register 25G of the working memory 25 are "0", "1",
Judge which of “2”, if “0”, step
The process proceeds to SP62 to execute the tempo speed-up process, and if "1", the process proceeds to step SP63 to execute the transpose-up process. If the process is "2", the process proceeds to step SP64 to execute the tuning-up process. I do.

These processing steps SP62, SP63, and SP64 add "+1" after confirming that the data is not the upper limit value in exactly the same way as steps SP43 and SP44, as shown in step SP47 regarding the processing procedure of the correction coefficient data BRANGE. Perform an operation such as

These data are written as part of the data ANDATA of the data and other data registers 25I of the working memory 25.

When the processing of these processing steps SP62, SP63, and SP64 is completed, the CPU 23 displays the data obtained by adding "+1" on the display 21C in step SP65 to make the player confirm the data, and returns to the main routine from step SP66.

On the other hand, when the player operates the down switch 21B, the CPU 23 enters the down switch event processing program from step SP51 in FIG. 11 and the previous pitch bend operation position data WHEELD is set to the maximum value "126" or the minimum value in step SP52. After confirming that the value is not "0",
The process proceeds to step SP71 to determine the contents of the data STATE of the setting state data register 25G.
At step SP73, a transpose down process is executed at step SP73, and when it is "2", a tuning down process is executed at step SP74. The process at this time is
As described above, for the steps SP53 and SP54 included in SP57, after confirming that they do not become smaller than the minimum value "0", "-1" subtraction processing is performed.

After completing this processing, the CPU 23 proceeds to step SP75, displays the processing result on the display 21C, and then returns to the main routine from step SP76.

[3] Effects of the First Embodiment According to the above configuration, when the player automatically releases the pitch bend operator 5 to the neutral operation position by releasing the finger from the pitch bend operator 5, a predetermined time ( For example, if the player keeps the pitch bend operation element 5 unoperated for 1 second, the CPU 23 proceeds to steps SP21-SP22-SP23-SP24-SP25-SP26-SP27 (the sixth step).
According to the loop of FIG.
Irrespective of the return position, the neutral operation position reference value "63" (that is, a predetermined constant value is set as the current pitch bend operation position data WHEELN and the pitch bend data WHEELP, and the subsequent steps SP31-SP32-SP33-SP34 (the By using the neutral operation position reference value "63" as the neutral operation position data by the loop of FIG. 6), pitch bend control data corresponding to the operation position of the pitch bend operation element 5 can be formed thereafter.

Accordingly, even when the pitch bend operation element 5 cannot be automatically returned to the correct neutral operation position due to, for example, mechanical fatigue, the pitch of a musical tone generated in a performance state in which the pitch bend operation element 5 is not operated is always maintained. Since the pitch corresponding to the neutral operation position reference value “63” can be set, it is possible to effectively avoid the possibility of unnaturally offsetting.

Further, according to the above-described embodiment, the correction coefficient data BRANGE is composed of the data of the "+" and "-" sign portions and the data of the coefficient value portion, and the correction coefficient data BRANGE having such a configuration is operated for pitch bending. Since the pitch bend control data is formed by multiplying the operation position data WHEELD of the slave 5, the correction coefficient data BR
Even if the operation direction of the pitch bend operation element 5 is reversed in accordance with the content of the data of the code part of the ANGE, the pitch bend increase direction (or decrease direction) of the musical tone can be made to coincide.

Therefore, for example, while the hand-held electronic musical instrument 1 shown in FIG. 15 is placed on a desk and the keys of the keyboard 3 on the front side are played with the right hand, the pitch bend operation element 5 is moved forward (upper limit operation position) with the left hand finger. Even if the rotation operation is performed in the direction from the MAX to the lower limit operation position MIN), if the data of the sign portion of the correction coefficient data BRANGE is set to the opposite sign, for example, "-", the pitch of the musical tone changes. Can be controlled so as to match the operational feeling during hand-held performance according to preference.

Not only in such usage but also in the case of hand-held performance or stationary performance in the same way, the sign of the code part data of the correction coefficient data BRANGE and the numerical value of the coefficient value data part should be selected according to the preference of the player. Thus, the tone can be pitch-bend-controlled in various pitch-bend operation modes.

[4] Second Embodiment FIGS. 12, 13, and 14 show a second embodiment of the present invention, in which the same reference numerals are assigned to corresponding parts as in FIGS. 3, 5, and 6, respectively. As shown in the figure, the standard pitch in the performance state in which the pitch bend operation element 5 is not operated is set based on the neutral operation position of the pitch bend operation element 5 when the power is turned on.

In the case of this embodiment, the data and the working memory 25 are
The CPU 23 has a neutral position data register 25C (FIG. 12), and the CPU 23 stores the neutral position data MIDPNT in step SP4 of the power-on main routine (FIG. 13).
It is made to write in 25C.

That is, when the power is turned on, the CPU 23 executes steps SP1 to SP5 in FIG.
After the various registers have been initialized in exactly the same manner as described above for SP3, the operation position data corresponding to the operation position of the pitch bend operation element 5 before the player operates the current pitch bend operation position data WHEELN as the current pitch bend operation position. The data is fetched into the data fetch register 25A.

Subsequent to this process, the CPU 23 stores the current pitch bend operation position data WHEELN fetched into the current pitch bend operation position data fetch register 25A in the middle point position data register 25C as the middle point position data MIDPNT in step SP4. It enters the loop processing loop LOOP1 of ~ SP8.

When the power is turned on in this way, the CPU 23 stores the midpoint position data MIDPNT stored in the midpoint position data register 25C by the CPU 23 in the main routine (the thirteenth step) when the performer subsequently performs the operation without operating the pitchbend operator 5. It is used as data for setting a standard pitch when executing the pitch bending volume scan process in step SP5 of FIG.

That is, as shown in FIG. 14, after entering the pitch bend volume scan processing SP21, the CPU 23 proceeds to step SP22.
When it is confirmed by the loop of SP23-SP24-SP25 that the pitch bend operation element 5 has not been operated for the reference time data TMAX, the middle point position of the middle point position data register 25C is determined at step SP26. The data MIDPNT is read out and written to the current pitch bend operation position data acquisition register 25A as the current pitch bend operation position data WHEELN.After that, at step SP27, the current pitch bend operation position data WHEELN is written to the pitch bend data register 25D as the pitch bend data WHEELP. Then, the invariable time data WCNT in the invariable time data register 25F is cleared.

Therefore, in the following steps SP31 to SP34, the tone change signal PB _CENT is calculated by using the value calculated by the cent value based on the difference between the midpoint position data MIDPNT and the neutral operation position reference value “63” in the musical tone signal. The generation unit 26 executes a process for generating a tone signal.

According to the second embodiment shown in FIGS. 12 to 14, the standard pitch when the player is in the playing state without operating the pitch bend control 5 is replaced with the pitch bend control 5 when the power is turned on.
By using the midpoint position data MIDPNT representing the return position of the pitch bend, the performance using the pitch bend control 5 and the performance without the pitch bend control 5 after power is turned on are sequentially performed. Even in the case where the pitch bend operation is repeated, the standard pitch of the musical tone during the performance without using the pitch bend operation element 5 can always be fixed to the pitch corresponding to the midpoint position data MIDPNT.

By the way, when the player repeatedly operates the pitch bend operation element 5, the position when the operation is released is not always the same, but the midpoint position data obtained when the power is turned on as the pitch of the musical tone in the subsequent performance state. Since the pitch based on MIDPNT can always be set forcibly, the standard pitch of the musical tone can be kept from fluctuating.

Here, if the return position of the pitch bend operation element 5 is offset from the correct neutral operation position MID (FIG. 2) to the offset position OFS, the pitch of the musical tone may be shifted by that amount. In practice, the correction can be made, for example, by performing the tuning operation only once after turning on the power of the tuning setting operation switch 21F.

Thus, according to the above-described configuration, even if an offset occurs such that the pitch bend operation element 5 does not return to the automatic return position, it is possible to effectively avoid the possibility that an unnatural offset occurs in the pitch of the musical tone.

[5] Other Embodiments (1) In the above-described embodiment, as a means for generating the pitch bend control data DATA, the pitch bend control 5 using a pitch bend volume 28 having a variable resistor structure is used.
Has been described in which the analog voltage corresponding to the operating position is generated and this analog voltage is converted into a digital value in the analog / digital conversion circuit 29. Instead of this, the operating position of the pitch bend operating element 5 is changed. The same effect as in the above case can be obtained by applying a configuration in which digital data corresponding to the above is directly generated.

(2) In the above-described embodiment, the embodiment in which the present invention is applied to the configuration for imparting the pitch bend effect to the musical tone has been described. However, the present invention is not limited to this, and for example, the tone color, volume, and modulation signal of the musical tone. The present invention can be widely applied to a case where a control signal for controlling a musical tone is formed in accordance with an operation amount of a musical tone control operation element, such as a case where a control signal such as a speed and a depth of a musical tone is formed.

(3) In the above embodiment, in order to obtain an effect control signal corresponding to the operation position of the pitch bend volume, the operation position is converted into a cent value, and then the cent value is converted into F number data (No. Step SP in Figure 6
31, SP32, SP33) may be used to form control data directly representing the frequency ratio in accordance with the operation position of the operation element.

(4) In the above embodiment, the tone control signal corresponding to the operation position of the tone control operator is obtained by a software processing program. May be realized by the above hardware.

(5) In the above embodiment, when the correction coefficient data BRANGE is set in the range data register 25E, the pitch bend volume 28 is set to the maximum value "126" corresponding to the upper limit operation position MAX and the minimum value corresponding to the lower limit operation position MIN. When the value is "0", the correction coefficient data BRANGE
As described above, the case where the value RMAX corresponding to the upper limit operation position MAX is set as the correction coefficient data BRANGE (FIG. 4), but the value RMI corresponding to the lower limit operation position MIN has been described.
N may be set. Further, the maximum value RMAX may be set when the pitch bend volume 28 is operated to the upper limit operation position MAX, and the minimum value RMIN may be set when the pitch bend volume 28 is operated to the lower limit operation position MIN.

When setting the minimum value RMIN in this way, the value of the sign part data of the correction coefficient data BRANGE may be set to the opposite sign to the case where the maximum value is set.

(6) In the above embodiment, the correction coefficient data BRANGE
Is configured to use the up switch 21A or the down switch 21B, but the input means is not limited to this, and another configuration such as a numeric keypad or a dedicated volume may be used.

(7) In the above-described embodiment, when the pitchbend operator 5 is changed from the lower limit operation position MIN to the upper limit operation position MAX through the neutral operation position MID, it is represented by one straight line as shown in FIG. Conversion curve RANGE (+12) to RANGE
By setting (+1) and RANGE (-1) to RANGE (-12), the operation position data in the range from the lower limit operation position MIN to the neutral operation position MID and the operation position data from the neutral operation position MID to the upper limit operation position MAX are set. It is configured to set the operation position data of the range all at once, but instead of this, the neutral operation position MID
From the minimum operating position MIN to the neutral operating position M
The conversion curve from the ID to the upper limit operation position MAX may be set separately.

(8) In the above-described embodiment, the pitch bend operation data DA output from the pitch bend volume 28 is used as a means for setting the pitch bend correction coefficient data BRANGE.
Based on the TA, the correction coefficient data BRA is set on condition that the player has set the upper limit operation position MAX or the lower limit operation position MIN.
Although the case where it is configured to determine that the NGE setting mode has been described has been described, instead of this, a pitch bend setting operation switch is provided similarly to the tempo setting operation switch 21D, the transpose setting operation switch 21E, and the tuning setting operation switch 21F. It may be configured as follows.

(9) In the above embodiment, the up switch 21A and the down switch 2
Although data of "+" and "-" are inputted by operating 1B, the same effect as in the above case can be obtained by providing a switch dedicated to code switching instead. be able to.

(10) In the above-described embodiment, the case where the invariable time data WCNT for determining that the position data of the neutral operation position needs to be replaced is selected to a fixed constant value (for example, 1 second) will be described. However, the invariable time may be changed.

(11) In the above-described embodiment, when the operation of the pitch bend operation element 5 is released, the system automatically returns to the neutral operation position MID at the midpoint of the upper limit operation position MAX and the lower limit operation position MIN. However, the automatic return position is not limited to the midpoint, and the upper limit operation position MAX to the lower limit operation position M
Any position up to IN is acceptable.

〔The invention's effect〕

As described above, according to the present invention, when the musical tone control operator is left in the state of returning to the automatic return position for a predetermined invariable time, the pitch of the musical tone is always set to a predetermined constant value. In contrast to the forced correction, when the tone control operator is operated, such correction is not performed, so that when the operator returns to the automatic return position, even if there is an offset. However, this does not cause an unnatural offset in the pitch of the musical tone due to this, and does not perform such processing when the operation element is operated. A tone control signal that can be prevented from being generated can be reliably generated.

[Brief description of the drawings]

FIG. 1 is a systematic block diagram showing a first embodiment of an electronic musical instrument using a musical tone control signal generator according to the present invention, FIG. 2 is a schematic connection diagram showing a detailed configuration of an operator data generating means thereof, FIG. 3 is a schematic diagram showing the detailed configuration of the data and working memory, FIG. 4 is a characteristic curve diagram for explaining the correction coefficient data BRANGE, FIG. 5 is a flowchart showing a main routine, and FIG. FIG. 7 is a flowchart showing a bend volume scan processing subroutine, FIG.
8 and 9 are flow charts showing the data processing procedure of the tempo setting operation switch 21D, the transpose setting operation switch 21E, and the tuning setting operation switch 21F.
FIG. 10 and FIG. 11 are flow charts showing a processing procedure for input data of the up switch 21A and the down switch 21B.
FIG. 12 is a schematic diagram showing a detailed configuration of data and working memory in the second embodiment, FIG. 13 is a flowchart showing a main routine in the second embodiment, and FIG. FIG. 15 is a plan view showing the appearance of the electronic musical instrument. 1 ... electronic musical instrument, 2 ... body part, 3 ... keyboard part, 4 ...
… Net part, 5… pitch bend operation element, 21 …… panel operation part, 21A, 21B …… up, down switch, 21C
...... Display, 21D, 21E, 21F ... Tempo, transpose, tuning setting operation switch, 22 ... Program and data memory, 23 ... CPU, 25 ... Data and working memory, 28 ... Pitch bend volume.

Claims (2)

(57) [Claims] An operation for controlling a tone control which automatically returns to a predetermined automatic return position when an operation by a player is released, and an operation for generating operation data corresponding to an operation position of the operation control for the tone control. Slave data generating means, invariant time detecting means for detecting that the manipulator data does not change for a predetermined time, and wherein the manipulator data does not change for a predetermined time by the invariant time detecting means. If detected, the tone control device sends out tone control data corresponding to the operator data when the tone control operator is at the normal automatic return position. Setting means for transmitting tone control data in accordance with the generated operator data; and a tone control signal generator for the electronic musical instrument, wherein the tone to be generated is controlled by the tone control data. Place. 2. An operation control device for automatically returning to a predetermined automatic return position when the operation by the player is released, and an operation for generating operation data corresponding to the operation position of the operation control device. Slave data generating means, midpoint position data holding means for holding the operation data at power-on as midpoint position data, and invariable time detection for detecting that the operation data does not change for a predetermined time Means, when the invariable time detecting means detects that the operation element data does not change for a predetermined time, sends out tone control data corresponding to the midpoint position data; Setting means for transmitting tone control data corresponding to the operator data generated by the operator data generating means, and controlling a tone to be generated by the tone control data. Musical tone control signal generating apparatus for an electronic musical instrument characterized.