JP2005148438A - Device and program for setting parameter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the operability of an operator for setting both a parameter indicating the ON/OFF state of a switch and a parameter showing a continuous value by one operator. <P>SOLUTION: When 324 deg is exceeded during the rotation of the operator, a 1st parameter is inverted from ON to OFF. Even when the operator is further rotated, a 2nd parameter is maintained so as to be still 0.0 until 312 deg is reached. When the operator is rotated exceeding 312 deg, a 2nd parameter corresponding to the quantity of rotation from 312 deg is set. A range L2 of 324 to 312 deg is a dead zone, and consequently the operability of the operator can be improved. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a parameter setting device that sets two different parameters using one operator.

  Conventionally, an LFO (Low Frequency Oscillator) is used as a modulation oscillator for a synthesizer or an effector. For example, an effector equipped with an LFO is provided with a volume for setting the speed (frequency) of the LFO. When this volume is set as a volume with a switch, it is possible to select whether to synchronize the LFO speed with the tempo input from the outside by the switch or to set the LFO speed parameter with the volume with a switch. In this case, the switch is turned on when the knob of the volume with the switch is turned fully counterclockwise, and the LFO speed is synchronized with the tempo input from the outside. Also, when the knob with a switch is turned fully counterclockwise, the switch turns off when the knob is gradually turned clockwise, and when the knob with a switch is turned, the parameter corresponding to the turned position This sets the LFO speed.

  In such a volume with a switch, which is a conventional parameter setting device, when the on / off state of the switch is reversed, a click feeling is obtained with the rotation of the knob and the on / off state of the switch is reversed. Can be easily recognized. By the way, synthesizers and effectors can be configured by software, but when setting LFO parameters in such a case, an image of a volume with a switch capable of setting two parameters of LFO is displayed on the display device. The tempo synchronization on / off setting and the LFO speed parameter are set by rotating the displayed knob with the switch using a pointing device or the like. However, there is a problem that it is difficult for the user to recognize that the on / off state of the switch has been reversed because the click feeling cannot be obtained when the knob of the volume with the switch displayed on the display device is rotated. It was. Furthermore, since it is difficult for the user to recognize that the on / off state of the switch has been reversed, it is difficult to set the position on the position where the on / off state is reversed, and it is difficult to operate the switch when the switch is reversed to the off state. When a parameter that represents a continuous value is set to a value that exceeds the minimum value, or when a parameter value that is set to a certain predetermined value is returned to the minimum value, the switch is turned over and the switch is turned on. There was a problem of end.

  Accordingly, the present invention provides a parameter setting device and a parameter setting program capable of improving the operability of an operator that sets a parameter that represents an on / off state of a switch and a parameter that represents a continuous value with a single operator. The purpose is to do.

  In order to achieve the above object, the parameter setting device and the parameter setting program of the present invention reverse the on / off state of the switch when the operating element moves beyond the first position, and from the first position. When the operator moves in the positive direction beyond the second position positioned in the positive direction, the parameter value representing the continuous value is set to a value corresponding to the movement amount from the second position. Main features.

  According to the present invention, the second parameter representing the continuous value is a dead zone in which the parameter value maintains the minimum value from the first position where the first parameter is inverted to the second position. It can be easily recognized that the on / off state of the switch has been reversed, and the second parameter can be easily set to the minimum value even if the switch is excessively operated. As a result, it is possible to improve the operability of the operator that sets the parameter indicating the on / off state of the switch and the parameter indicating the continuous value with one operator.

  For the purpose of improving the operability of an operator that sets a parameter that represents an on / off state of a switch and a parameter that represents a continuous value with one operator, the second parameter that represents a continuous value is the first parameter. This is realized by setting a dead zone from the first position to the second position where the inversion occurs.

FIG. 1 is a block diagram showing the configuration of the parameter setting apparatus according to the embodiment of the present invention.
In the parameter setting device 1 according to the present invention shown in FIG. 1, a CPU (Central Processing Unit) 10 controls the overall operation of the parameter setting device 1, and a first parameter indicating a switch on / off state and a continuous value. Is set, and the set parameter is supplied to an external effector or the like. A ROM (Read Only Memory) 12 stores operation software such as a parameter setting program executed by the CPU 10, and a RAM (Random Access Memory) 11 sets a work area of the CPU 10 and a storage area for various data. Has been. By making this ROM 12 a rewritable ROM such as a flash memory, the operation software can be rewritten and the operation software can be easily upgraded.

  The operation element 13 is a panel operation element provided on the panel of the parameter setting device 1 or a pointer device that can operate a knob of a volume with a switch displayed on the display unit 15. The detection circuit 14 detects an event by scanning a panel operation element, a pointer device, and the like, and outputs an event output corresponding to the operation element 13 having the event. The display circuit 16 includes a display unit 15 such as a liquid crystal display, and displays on the display unit 15 an image of a volume with a switch for setting the first parameter indicating the on / off state of the switch and the second parameter indicating the continuous value. When the operation element is operated, an image of the operation element moved according to the operation is displayed on the display unit 15. The external communication interface (I / F) 18 is an interface that connects the parameter setting device 1 to a communication network such as a LAN (local area network), the Internet, or a telephone line, and is connected to the external device 17 via the communication network. can do. As a result, various programs and data can be downloaded from the external device 17 to the parameter setting device 1. The downloaded program and data are stored in the RAM 11 or the like. Each unit is connected to a communication bus 19.

In this case, if the external device 17 is an effector, the parameter setting device 1 sets a first parameter for setting on / off of LFO tempo synchronization and a second parameter for setting an LFO speed parameter. 17 can be supplied to the effector. The effector of the external device 17 performs tempo synchronization on / off setting according to the supplied first parameter, and the LFO is set according to the second parameter supplied when tempo synchronization is set to off. Speed setting is performed. Then, it is possible to perform a process of applying an effect using the LFO set in this way as a modulation oscillator of the effector.
In the parameter setting device 1, when the CPU 10 executes an effect program or incorporates a DSP (Digital Signal Processor) for effect processing, the first parameter generated inside the parameter setting device 1 by the software effector is obtained. Accordingly, the tempo synchronization is set on / off, and the LFO speed is set according to the second parameter generated internally when the tempo synchronization is set to off. Then, the CPU 10 or the DSP can execute processing for applying an effect using the LFO set in this way as a modulation oscillator.

  An example of an image displayed on the display unit 15 of the volume with a switch for setting the first parameter indicating the on / off state of the switch displayed on the display unit 15 and the second parameter indicating the continuous value is shown in FIG. Shown in a). As shown in this figure, the switch-equipped volume 20 is represented by an image of a knob 20a, and the knob 20a is composed of, for example, a part gripped by a heptagonal finger and a substantially circular collar provided at the lower part. The knob 20a is provided with a linear indicating portion 20b indicating its rotational position. Around the knob 20a, a first indicating mark 20c1 indicating a position where the switch is turned on is indicated by a black circle, and a position where the switch is turned off. A second indication mark 20c2 indicating a position where the minimum value is set for the second parameter is indicated by a black circle, and a third indication mark 20c3 indicating the position where the maximum value is set for the second parameter is indicated. FIG. 2B shows an example of the angles of these instruction marks 20c1 to 20c3. When the direction indicated by the dotted arrow in FIG. 2B is set to 0 deg (degrees), the first indication mark 20c1 has an angle of about 336deg, for example, and the second indication mark 20c2 is clockwise from the first indication mark 20c1 For example, the third instruction mark 20c3 is rotated by about 24deg to about 312deg, and the third instruction mark 20c3 is rotated from the second instruction mark 20c2 by about 282deg in the clockwise direction at a position of about 30deg. In order to operate the knob 20a of the switch-equipped volume 20, the cursor displayed on the display unit 15 is positioned near the knob 20a with a pointing device such as a mouse and clicks and turns the pointing device. The knob 20a can be moved so as to rotate. The knob 20a cannot be rotated counterclockwise beyond about 336 deg, and cannot be rotated clockwise beyond about 30 deg.

Next, in the parameter setting device 1 according to the present invention, the first parameter representing the on / off state of the switch and the second parameter representing the continuous value when the knob 20a of the volume 20 with switch is operated are changed. A first example is shown in FIG. Here, the case where the LFO tempo synchronization on / off setting and the LFO speed parameter set to a continuous value are set by the volume 20 with a switch will be described with reference to FIG.
In FIG. 3, the horizontal axis is the rotation position of the operating element, that is, the axis indicating the position of the knob 20a, the unit is deg (degrees), and the knob 20a can be rotated between 336 deg and 30 deg. The vertical axis indicates the first parameter (# 1 parameter) indicating the on / off state of the switch for turning on / off tempo synchronization, and an arbitrary speed parameter value that is a continuous value from 0.0 to 1.0. Is the axis of the second parameter (# 2 parameter). The first parameter is a parameter representing on / off of the switch. When the knob 20a is at the position of 336 deg, the switch is turned on, the tempo synchronization of the LFO is on, and the LFO is supplied from the outside. Synchronize with the tempo. The case where the knob 20a is rotated clockwise from this state will be explained. When the knob 20a exceeds 324 degrees, the switch is turned off, the first parameter is inverted, and the tempo synchronization is turned off. In this case, the second parameter set by the volume with switch 20 is set as the LFO speed parameter. That is, tempo synchronization (first parameter) is turned on when the knob 20a is in the position of the range L1 shown in FIG. 3, and tempo synchronization (first parameter) is turned off when moving beyond the range L1, A second parameter is set as the speed parameter.

  The speed parameter (second parameter) is “0.0” which is the minimum value until the position of the knob 20a reaches 312 deg, and corresponds to the amount of movement from 312 deg when moving beyond 312 deg. When the knob 20a reaches 30 degrees, the maximum value is “1.0”. That is, by setting the knob 20a between 312 deg and 30 deg, an arbitrary speed parameter that continuously changes to LFO can be set. As described above, in the second parameter, the range L2 from 324 deg to 312 deg becomes a dead zone, and the speed parameter (second parameter) maintains “0.0” which is the minimum value. Accordingly, the range where the tempo synchronization is reversed to OFF and the speed parameter (second parameter) is 0.0 (minimum value) is expanded to the range L2 instead of the point. It becomes easier to set the position to flip off. Furthermore, since it is only necessary to stop within the dead zone in the range L2 when attempting to stop at the reverse position, a continuous value starting from 0.0 (minimum value) is used as the speed parameter (second parameter). Can be set.

  Further, when the knob 20a is rotated counterclockwise from the position of the knob 20a at the position of 30 deg, the second parameter is set as the knob 20a is moved from 30 deg to 312 deg. A speed parameter that gradually decreases from the maximum value “1.0” is set in the LFO speed parameter. Note that tempo synchronization (first parameter) is off. When the knob 20a reaches 312deg, the minimum value "0.0" is set in the LFO speed parameter (second parameter), and when the knob 20a is moved and exceeds 324deg, the tempo is synchronized (first Parameter) is turned on. Even when the knob 20a reaches 336 deg, the tempo synchronization (first parameter) remains on, and the speed parameter (second parameter) also maintains the minimum value “0.0”. Also in this case, the range L2 from 324 deg to 312 deg becomes a dead zone, and the speed parameter (second parameter) maintains “0.0” which is the minimum value. Accordingly, the range in which the speed parameter (second parameter) is 0.0 (minimum value) is expanded to the range L2 instead of the point, so that the speed can be changed without turning tempo synchronization (first parameter) on. It becomes easy to set the parameter (second parameter) to the minimum value of 0.0.

Next, in the parameter setting device 1 according to the present invention, the first parameter representing the on / off state of the switch and the second parameter representing the continuous value when the knob 20a of the switch-equipped volume 20 is operated. A second example of this is shown in FIG. Here, a case where the LFO tempo synchronization on / off setting and the LFO speed parameter are set by the volume 20 with a switch will be described with reference to FIG.
In FIG. 4, the horizontal axis is the rotation position of the operating element, that is, the axis indicating the position of the knob 20a, the unit is deg, and the vertical axis represents the on / off state of the switch for turning on / off tempo synchronization. 1 axis (# 1 parameter) and a second parameter (# 2 parameter) axis representing an arbitrary speed parameter value that is a continuous value from 0.0 to 1.0. The first parameter is a parameter representing on / off of the switch. When the knob 20a is at the position of 336 deg, the switch is turned on, the tempo synchronization of the LFO is on, and the LFO is supplied from the outside. Synchronize with the tempo. The case where the knob 20a is rotated clockwise from this state will be described. When the knob 20a exceeds 318 degrees, the switch is turned off, the first parameter is inverted, and the tempo synchronization is turned off. In this case, the second parameter set by the volume with switch 20 is set as the LFO speed parameter. That is, tempo synchronization (first parameter) is turned on when the knob 20a is in the position of the range L1 shown in FIG. 4, and tempo synchronization (first parameter) is turned off when moving beyond the range L1, A second parameter is set as the speed parameter.

  The speed parameter (second parameter) is “0.0” which is the minimum value until the position of the knob 20a reaches 312 deg. When the knob 20a moves beyond 312 deg, it continuously corresponds to the movement amount from 312 deg. When the knob 20a reaches 30 degrees, the maximum value is “1.0”. That is, by setting the knob 20a between 312 deg and 30 deg, an arbitrary speed parameter that continuously changes to LFO can be set. As described above, in the second parameter, the range L2 from 318 deg to 312 deg becomes the dead zone, and the speed parameter (second parameter) maintains the minimum value “0.0”. Accordingly, the range where the speed parameter (second parameter) is 0.0 (minimum value) at the position where the tempo synchronization is turned off is expanded to the range L2 instead of the point, so that the tempo synchronization is turned on. It becomes easier to set the position to flip off. Furthermore, since it is only necessary to stop within the dead zone of the range L2 when attempting to stop at the reverse position, a continuous value starting from 0.0 (minimum value) is set as the speed parameter (second parameter). Can be set.

Further, when the knob 20a is rotated counterclockwise from the position of the knob 20a at the position of 30 deg, the second parameter is set as the knob 20a is moved from 30 deg to 312 deg. A speed parameter that gradually decreases from the maximum value “1.0” is set in the LFO speed parameter. Note that tempo synchronization (first parameter) is off. When the knob 20a reaches 312 deg, the speed parameter (second parameter) of the LFO is set to “0.0” which is the minimum value. When the knob 20a is moved and exceeds 330 deg, the tempo is synchronized (first Parameter) is turned on. Then, in the range L5 until the knob 20a reaches 336 degrees, the tempo synchronization (first parameter) is kept on, and the speed parameter (second parameter) is also kept at the minimum value “0.0”. In this case, the range L4 from 312 deg to 330 deg becomes a dead zone, and the speed parameter (second parameter) maintains “0.0” which is the minimum value. Therefore, since the range in which the speed parameter (second parameter) is 0.0 (minimum value) is expanded to the range L4 instead of a point, the speed can be changed without turning tempo synchronization (first parameter) on. It becomes easy to set the parameter (second parameter) to the minimum value of 0.0.
As shown in FIG. 4, when hysteresis is provided in the first parameter representing the on / off state of the tempo synchronization switch, the on / off movement of the switch in the volume with switch 20 seems to have increased. It is possible to give the user a feeling of turning the physical volume.

By the way, when the volume 20 with a switch is operated, the image of the knob 20a displayed on the display unit 15 is changed to an image corresponding to the operation. An example of an effective animation method of the knob 20a indicating the operation state of the volume 20 with a switch will be described with reference to FIG.
As shown in FIG. 5, five images showing operation states of 336 deg, 330 deg, 324 deg, 318 deg, 312 deg are prepared as part of the volume animation. When the knob 20a is rotated clockwise, when the position of the operated knob 20a reaches the position of the five images, the corresponding images among the five images are sequentially displayed on the display unit 15. Normal animation display is performed. When the knob 20a is rotated in the counterclockwise direction, when the knob 20a is operated and the tempo synchronization is reversed from OFF to ON (in the example shown in FIG. 3, the example shown in FIG. 4 exceeds 324 degrees). In the case of exceeding 330 deg), the image is changed to a 336 deg image and displayed on the display unit 15, and the position of the knob 20 a is LFO tempo synchronization is off and the speed parameter is 0.0 (example shown in FIG. 1). In the case of 312 deg. To 324 deg. (In the example shown in FIG. 4, in the case of 312 deg. To 330 deg.), The 312 deg image is maintained and displayed on the display unit 15 even if the knob 20a is operated. As a result, when the knob 20a is rotated counterclockwise, when the switch is turned on / off, the knob 20a transitions to an image indicating the knob 20a. Click feeling can be obtained visually.

Next, another example of an effective animation method for the knob 20a will be described with reference to FIG.
As shown in FIG. 6, two images of 324 deg and 318 deg are prepared as the same image as the image of 312 deg, and an image of 330 deg is prepared as the same image as the image of 336 deg. That is, there are two types of images of the knob 20a. In this animation display, when the knob 20a is rotated clockwise from 336deg, an image of 336deg and then an image of 330deg are displayed on the display unit 15 according to the position of the knob 20a, but these images are the same image. It is visually felt that the volume 20 with the switch is not rotated. Then, when the knob 20a exceeds 324 deg, a transition to the same 324 deg image as the 312 deg image is displayed, so that the spring movement in the switch can be visually simulated. The same applies to the case where the knob 20a is rotated counterclockwise. From 312 deg to 324 deg, an image of 312 deg, an image of 318 deg, and an image of 312 deg are displayed on the display unit 15 according to the position of the knob 20 a. However, since these images are the same image, it feels visually that the volume 20 with the switch is not rotated. Then, when the knob 20a exceeds 324 deg, the image is shifted to the same 330 deg image as the 336 deg image and displayed.
In this animation method, the switch-equipped volume 20 does not rotate easily and can feel heavy.

Next, a flowchart of the parameter setting process executed by the parameter setting device 1 of the present invention is shown in FIG. However, the flowchart shown in FIG. 7 is a flowchart when the change mode of the first parameter and the second parameter changes as shown in FIG.
The parameter setting process shown in FIG. 7 is started by an interrupt to a main process (not shown) that occurs every predetermined time interval. In this case, it is assumed that when the knob 20a is operated, an interrupt is generated at an extremely short time interval such that the position of the knob 20a moves without exceeding a range adjacent to the previous position.
When the parameter setting process is activated by interruption, it is determined in step S10 whether or not the volume 20 with a switch, which is an operator that can operate the first parameter and the second parameter, has been operated. . In this case, if the position of the knob 20a of the volume with switch 20 is different from the previous position, it is determined that the operation element has been operated, and the process proceeds to step S11 to detect the position of the current knob 20a after the operation. If it is determined that the volume with switch 20 has not been operated, the parameter setting process ends and the process returns to the main process.

  When the process of step S11 is completed, the image of the knob 20a displayed on the display unit 15 of the switch-equipped volume 20 is changed to an image corresponding to the position of the knob 20a detected in step S11 and displayed in step S12. Next, in step S13, it is determined whether or not the position of the knob 20a of the switch-equipped volume 20 is in the range L1 without changing between the previous time and the current time, or in the range L2. If it is determined that the position of the knob 20a is within the range L1 or the range L2 without changing between the previous time and the current time, the parameter setting process ends and the process returns to the main process. If NO is determined in step S13, the process proceeds to step S14. In step S14, it is determined whether or not the position of the knob 20a of the volume 20 with switch is within the range L3 without changing between the previous time and the current time. Here, if it is determined in step S14 that there is no change in the range L3 between the previous time and the current time, the process branches to step S15. In step S15, for example, a parameter value corresponding to the position of the knob 20a after the operation is set in the second parameter, which is an LFO speed parameter, and reflected in the signal processing of the effector, for example. Then, the parameter setting process ends and the process returns to the main process.

  If NO is determined in step S14, the process proceeds to step S16. In step S16, it is determined whether or not the knob 20a of the switch-equipped volume 20 is moving in the clockwise direction, which is the forward direction. Here, if it is determined that the knob 20a is rotated in the clockwise direction, the process proceeds to step S17, and it is determined whether or not the position of the knob 20a previously located in the range L1 is within the range L2. Is done. Here, if the knob 20a has moved beyond the previously located range L1 to within the range L2, YES is determined and the process branches to step S18. In step S18, for example, a first parameter indicating ON / OFF of tempo synchronization is set to OFF, and a minimum value is set to a second parameter, for example, an LFO speed parameter, which is reflected in, for example, signal processing of the effector. . Then, the parameter setting process ends and the process returns to the main process. On the other hand, if the knob 20a has moved beyond the previously positioned range L2 to within the range L3 in step S17, NO is determined and the process proceeds to step S19. In step S19, for example, a parameter value corresponding to the position of the knob 20a after the operation is set in the second parameter, which is an LFO speed parameter, and reflected in the signal processing of the effector, for example. Then, the parameter setting process ends and the process returns to the main process.

  Further, if it is determined in step S16 that the knob 20a is rotated in the counterclockwise direction (negative direction), the process branches to step S20, and the position of the knob 20a previously located in the range L3 is the current range. It is determined whether or not it is within L2. Here, if the knob 20a has moved to the range L2 beyond the range L3 where it was previously positioned, YES is determined and the process branches to step S21. In step S21, for example, a minimum value is set for the second parameter, which is an LFO speed parameter, and is reflected in the signal processing of the effector, for example. Then, the parameter setting process ends and the process returns to the main process. On the other hand, if the knob 20a has moved to the range L1 beyond the previously located range L2, NO is determined in step S20 and the process proceeds to step S22. In step S22, for example, a first parameter indicating ON / OFF of tempo synchronization is set to ON, and reflected in, for example, the signal processing of the effector. Then, the parameter setting process ends and the process returns to the main process.

Next, FIG. 8 shows another flowchart of the parameter setting process executed by the parameter setting apparatus 1 of the present invention. However, the flowchart shown in FIG. 8 is a flowchart when the change mode of the first parameter and the second parameter changes as shown in FIG.
The parameter setting process shown in FIG. 8 is started by an interruption to a main process (not shown) as in the parameter setting process shown in FIG.
In the other flowchart of the parameter setting process shown in FIG. 8, the process of step S30 is the same as the process of step S10 of the flowchart shown in FIG. 7, and the process of step S31 is the same as the process of step S11 and the process of step S32. Since the processing of step S12, the processing of step S33 is the same as the processing of step S14, and the processing of step S34 is the same as the processing of step S15, the description thereof will be omitted, and the processing after step S35 will be described.

  In step S35, it is determined whether or not the knob 20a of the volume 20 with switch is moving in the clockwise direction, which is the forward direction. Here, if it is determined that the knob 20a is rotated in the clockwise direction, the process proceeds to step S36. In step S36, it is determined whether or not the position of the knob 20a of the volume 20 with switch is in the range L1 without changing between the previous time and the current time, or in the range L2. Here, if it is determined in step S36 that the knob 20a is within the range L1 or the range L2 without changing between the previous time and the current time, the parameter setting process ends and the process returns to the main process. If the range in which the knob 20a is located has changed between the previous time and the current time, NO is determined and the process proceeds from step S36 to step S37. In step S37, it is determined whether or not the position of the knob 20a previously located in the range L1 is within the range L2 this time. Here, if the knob 20a has moved beyond the previously located range L1 to within the range L2, YES is determined and the process branches to step S38. In step S38, for example, a first parameter indicating ON / OFF of tempo synchronization is set to OFF, and a minimum value is set to a second parameter, for example, an LFO speed parameter, which is reflected in, for example, signal processing of the effector. . Then, the parameter setting process ends and the process returns to the main process.

On the other hand, if the knob 20a has moved beyond the previously positioned range L2 to within the range L3 in step S37, NO is determined and the process proceeds to step S39. In step S39, for example, a parameter value corresponding to the position of the knob 20a after the operation is set in the second parameter, which is an LFO speed parameter, and is reflected in the signal processing of the effector, for example. Then, the parameter setting process ends and the process returns to the main process.
Further, if it is determined in step S35 that the knob 20a is rotated in the counterclockwise direction (negative direction), the process branches to step S40, and the position of the knob 20a of the switch-equipped volume 20 remains unchanged between the previous time and the current time. It is determined whether it is within L4 or whether it is within range L5. Here, if it is determined that the knob 20a is in the range L4 or the range L5 without changing between the previous time and the current time, the parameter setting process ends and the process returns to the main process. If the range in which the knob 20a is located has changed between the previous time and the current time, NO is determined and the process proceeds from step S40 to step S41. In step S41, it is determined whether or not the position of the knob 20a previously located in the range L3 is within the range L4 this time. Here, if the knob 20a has moved to the range L4 beyond the previously positioned range L3, it is determined YES and the process branches to step S42. In step S42, for example, a minimum value is set for the second parameter, which is an LFO speed parameter, and is reflected in the signal processing of the effector, for example. Then, the parameter setting process ends and the process returns to the main process. On the other hand, if the knob 20a has moved beyond the previously located range L4 to the range L5, NO is determined in step S41 and the process proceeds to step S43. In step S43, for example, the first parameter indicating ON / OFF of tempo synchronization is set to ON, and is reflected in the signal processing of the effector, for example. Then, the parameter setting process ends and the process returns to the main process.
The parameter setting program for executing the parameter setting process shown in FIG. 7 or FIG. 8 described above is stored in the ROM 12, and the CPU 10 executes the parameter setting program, whereby the first setting is performed according to the operation of the operator. And the second parameter are set.

In the above description, the LFO tempo synchronization on / off setting and the switch-equipped volume 20 for setting the speed parameter are used as the controls. However, the present invention is not limited to this, and the switch on / off setting and the continuous value are set. Any operator can be used as long as the parameters can be set with one operator.
Also, in the parameters shown in FIG. 3, a table defining parameter values for each position of the operator is prepared, and when the operator is operated, a parameter corresponding to the position after the operation is read from the table and set. You may do it. In this case, a range L2 in which the first parameter is off and the second parameter is the minimum value is defined on the table.
In addition, for the parameters shown in FIG. 4, a table defining parameter values for each position of the operator is prepared, and when the operator is operated, the parameter corresponding to the position after the operation is read from the table and set. You may make it do. In this case, when the position after the operation is located at a portion where the range L1 and the range L4 overlap, the operation element has moved in the positive direction (clockwise) or in the negative direction (counterclockwise). Prepare a table that defines different parameters depending on whether you have moved. In this table, when the movement is positive, the first parameter is on and the second parameter is the minimum value. When the movement is negative, the first parameter is off and the second parameter is Is the minimum value.

  In the above description, the parameter setting device supplies the parameter indicating ON / OFF of the switch set to the external device and the parameter indicating the continuous value, and performs signal processing using the two parameters supplied by the external device. Although described as a thing, you may make it perform signal processing using the parameter showing ON / OFF of the switch and the parameter showing a continuous value which were set in the parameter setting apparatus. In addition, the parameter setting program can be recorded on a recording medium and incorporated into various musical sound related devices.

It is a block diagram which shows the structure of the parameter setting apparatus of the Example of this invention. It is a figure which shows the image of the operation element displayed on the display apparatus of the parameter setting apparatus of the Example of this invention, and its rotation aspect. The figure which shows the 1st example of the change aspect of the 1st parameter showing the ON / OFF state of a switch at the time of operating the knob | pick of a switch with a parameter setting apparatus of this invention, and the 2nd parameter showing a continuous value. It is. The figure which shows the 2nd example of the 1st parameter showing the ON / OFF state of a switch at the time of operating the knob | pick of a switch with the parameter setting apparatus of this invention, and the 2nd parameter change mode showing a continuous value. It is. It is a figure which shows an example of the animation method of the knob | pick when operating the volume with a switch in the parameter setting apparatus of this invention. It is a figure which shows the other example of the animation method of the knob | pick when operating the volume with a switch in the parameter setting apparatus of this invention. It is a flowchart of the parameter setting process performed with the parameter setting apparatus of this invention. It is another flowchart of the parameter setting process performed with the parameter setting apparatus of this invention.

Explanation of symbols

1 parameter setting device, 10 CPU, 11 RAM, 12 ROM, 13 operation element, 14 detection circuit, 15 display unit, 16 display circuit, 17 external device, 18 communication I / F, 19 communication bus, 20 volume with switch, 20a Pick, 20b indicator, 20c1-20c3 indicator

Claims (5)

Display means for displaying on a screen an operation state of an operator capable of setting a first parameter representing an on / off state of a switch and a second parameter representing a continuous value;
Detecting means for detecting a position of the operation element when the operation element displayed on the display means is operated;
When the position of the operating element detected by the detecting means moves in the positive direction beyond the first position, the first parameter indicating the on / off state is inverted and set, and the detecting means detects The first parameter indicating the on / off state is reversed and set when the position of the operating element moves in the negative direction beyond the first position, and the operating element detected by the detecting means is detected. When the position moves in the positive direction beyond the second position positioned in the positive direction from the first position, the value of the second parameter is set to a value corresponding to the amount of movement from the second position. And setting means for setting the value of the second parameter to a minimum value when the position of the operating element detected by the detecting means moves in the negative direction beyond the second position;
A parameter setting device characterized by comprising: Display means for displaying on a screen an operation state of an operator capable of setting a first parameter representing an on / off state of a switch and a second parameter representing a continuous value;
Detecting means for detecting a position of the operation element when the operation element displayed on the display means is operated;
When the position of the operating element detected by the detecting means moves in the positive direction beyond the first position, the first parameter indicating the on / off state is inverted and set, and the detecting means detects The first parameter indicating the on / off state when the position of the operating element moves in the negative direction beyond the third position located in the negative direction from the first position, The value of the second parameter is set to the second position when the position of the manipulator detected by the detecting means moves in the positive direction beyond the second position positioned in the positive direction from the first position. And the value of the second parameter is set to a minimum value when the position of the operating element detected by the detecting means moves in the negative direction beyond the second position. Setting means to set to,
A parameter setting device characterized by comprising:   When the position of the operation element detected by the detection means is on the negative direction side from the second position, the display means keeps the operation element until the first parameter indicating the on / off state is inverted. The operation state screen is displayed without being changed even if operated, and when the first parameter is inverted, the operation state screen is changed to a screen corresponding to the inversion. 3. The parameter setting device according to 1 or 2. Computer to set parameters,
Display means for displaying on the screen an operation state of an operator capable of setting a first parameter representing an on / off state of the switch and a second parameter representing a continuous value;
Detecting means for detecting a position of the operation element when the operation element displayed on the display means is operated;
When the position of the operating element detected by the detecting means moves in the positive direction beyond the first position, the first parameter indicating the on / off state is inverted and set, and the detecting means detects The first parameter indicating the on / off state is reversed and set when the position of the operating element moves in the negative direction beyond the first position, and the operating element detected by the detecting means is detected. When the position moves in the positive direction beyond the second position positioned in the positive direction from the first position, the value of the second parameter is set to a value corresponding to the amount of movement from the second position. And setting means for setting the value of the second parameter to a minimum value when the position of the operating element detected by the detecting means moves in the negative direction beyond the second position;
Parameter setting program to function as Computer to set parameters,
Display means for displaying on the screen an operation state of an operator capable of setting a first parameter representing an on / off state of the switch and a second parameter representing a continuous value;
Detecting means for detecting a position of the operation element when the operation element displayed on the display means is operated;
When the position of the operating element detected by the detecting means moves in the positive direction beyond the first position, the first parameter indicating the on / off state is inverted and set, and the detecting means detects The first parameter indicating the on / off state when the position of the operating element moves in the negative direction beyond the third position located in the negative direction from the first position, The value of the second parameter is set to the second position when the position of the manipulator detected by the detecting means moves in the positive direction beyond the second position positioned in the positive direction from the first position. And the value of the second parameter is set to a minimum value when the position of the operating element detected by the detecting means moves in the negative direction beyond the second position. Setting means to set to
Parameter setting program to function as

Images