JP5531429B2 - Parameter display device - Google Patents

Description

The present invention relates to a parameter display device that stores a plurality of parameter sets including a plurality of parameter values and performs display related to each parameter set.

Conventionally, in an electronic organ that generates musical sounds according to the settings of various parameters such as timbre and volume that have been performed in advance according to the performance operation of the user, a set of a plurality of parameters used to generate the musical sounds, A plurality of registrations (hereinafter referred to as “registrations”) are registered, and the contents of the registrations are arbitrarily called according to the user's operation so as to be reflected in the musical tone generation.
As described in Non-Patent Document 1, the contents of the plurality of resists can be collectively referred to and edited.

For example, in the electronic organ described in Non-Patent Document 1, for each parameter selected on the parameter selection screen, the value of the selected parameter in each registered resist is listed in a graph on the list display screen. A function to display is provided.
Also, on the list display screen, select any number of registered registries from the registered registries for batch editing, and all the selected registries are displayed (selected on the parameter selection screen). A function is also provided in which the value of the parameter is simultaneously increased or decreased, and the value of the parameter being displayed is simultaneously set to the parameter value of that item in the arbitrarily selected reference resist.

“Electone (registered trademark) STAGEA (registered trademark) ELS-01 / 01C / 01X Instruction Manual”, Yamaha Corporation, 2004, p. 92-94

  In the electronic organ described in Non-Patent Document 1, it is possible to grasp the value of a specific parameter in each registered resist by referring to the graph on the list display screen. However, if you want to know which resist and which resist have the same parameter value, you must carefully compare each resist and the corresponding graph, which is difficult to grasp at first glance. There was a problem that there was.

In particular, when displaying a list display screen on a display that is not so high in resolution, the resolution of the graph is low, and even if the parameter values are slightly different, the difference does not appear in the graph. There was also.
Such a problem also occurs when a similar function is to be provided in a device other than the electronic organ.

This invention solves such a problem and makes it possible to easily confirm which parameter set and parameter value are common to a plurality of parameter sets registered in advance. Objective.

In order to achieve the above object, according to the present invention, in an acoustic signal processing device, a display, a parameter memory that stores a plurality of parameter sets each including a plurality of parameter values, and a plurality of values among the plurality of parameters are the plurality of parameters. and presenting means for presenting to the user the parameters except the parameters are consistent with all parameters set as an option, in response to a first selection operation of the user, selecting one of the parameters which the presentation means are presented a first selection means, second selection means for selecting one of the parameter sets according to the second selection operation of the user, depending on the user's display instruction, for each of the plurality of parameter sets the value of the selected parameter by the first selection means is displayed on the display unit, the time, the parameters obtained by the display In which one, those that match the value of the parameter in the parameter set selected by the second selection means, provided with collective display control means in other different from those embodiments is displayed on the display unit of is there.

Another acoustic signal processing apparatus of the present invention includes a display, a parameter memory that stores a plurality of parameter sets each including a plurality of parameter values, and a parameter group that includes a plurality of parameters included in the plurality of parameters. Of these, according to the first selection operation of the presenting means for presenting to the user a parameter group excluding the parameter group in which all parameter values belonging to the parameter group match in all of the plurality of parameter sets, as options. Te, a first selection means for selecting one of the parameter group in which the presentation means are presented, and a second selecting means for selecting one of the parameter sets according to the second selection operation of the user, depending on the user's display instruction, for each of the plurality of parameter sets, which is selected by the first selection means parameters If all the values of the parameters belonging to the data group matches the value of the corresponding parameter in the parameter set selected by the second selecting means, provided a batch display control means for displaying or not on said display device It is a thing.

According to the configuration of the present invention as described above, it is possible to easily confirm which parameter set and which parameter set have the same parameter value for a plurality of parameter sets registered in advance. it can.

It is a block diagram which shows the hardware constitutions of the acoustic signal processing apparatus which is one Embodiment of this invention. It is a block diagram of the parameter storage area | region which the acoustic signal processing apparatus shown in FIG. 1 has. It is a figure which shows the example of the list display screen which the acoustic signal processing apparatus shown in FIG. 1 displays. It is a figure which similarly shows the example of a parameter selection screen. It is a figure which shows the example of another state of a parameter selection screen.

It is a figure which shows the example of another state of a parameter selection screen. It is a figure which shows another example of the list display screen shown in FIG. It is a flowchart of the display process of the list display screen which CPU of the acoustic signal processing apparatus shown in FIG. 1 performs. It is a flowchart of the coincidence display process shown in FIG. It is a flowchart of the reference | standard registration change process which CPU of the acoustic signal processing apparatus shown in FIG. 1 performs.

It is a flowchart of a batch increase / decrease process similarly. It is a flowchart of a batch setting process similarly. It is a flowchart of the display process of a parameter selection screen similarly. It is a flowchart of the partial validation process shown in FIG.

Hereinafter, embodiments for carrying out the present invention will be specifically described with reference to the drawings.
First, FIG. 1 shows a hardware configuration of an acoustic signal processing apparatus according to an embodiment of the present invention.
As shown in FIG. 1, the acoustic signal processing apparatus 10 includes a CPU 11, a flash memory 12, a RAM 13, a communication I / O 14, a display 15, an operator 16, and an acoustic signal processing unit 17, which are connected by a system bus 18. Has been. In addition, a signal input unit 21 and a signal output unit 22 connected to the acoustic signal processing unit 17 are also provided.

  The CPU 11 is a control unit that controls the entire acoustic signal processing apparatus 10. By executing a necessary control program stored in the flash memory 12, the CPU 11 controls communication via the communication I / O 14 and the display 15. Control operations such as display control, detection of operation of the operation element 16 and editing of parameters according to the control, signal processing control in the acoustic signal processing unit 17 are performed.

The flash memory 12 is a rewritable nonvolatile memory that stores data that does not need to be changed frequently, such as a control program executed by the CPU 11 and a resist that is a set of parameters used by the acoustic signal processing unit 17 for signal processing. It is a storage means.
The RAM 13 is a storage unit that is used as a work memory of the CPU 11 or that stores parameter values that are reflected in the operation of the acoustic signal processing apparatus 10.

  The communication I / O 14 is an interface for communicating with an external device. The data transmitted / received via this I / O varies depending on the function of the acoustic signal processing apparatus 10, but is, for example, performance data for causing the acoustic signal processing unit 17 to perform an automatic performance, Timbre data for generating a sound with the timbre of, or control data for controlling the operation of the acoustic signal processing apparatus 10 from a remote controller. As the communication I / O 14, an interface with an appropriate standard such as USB (Universal Serial Bus), IEEE (Institute of Electrical and Electronic Engineers) 1394, Ethernet (registered trademark), or the like, depending on the type of external device to be connected. May be provided.

  The display unit 15 is configured by a liquid crystal display (LCD), a light emitting diode (LED) lamp, or the like, and displays the operating state and setting contents of the acoustic signal processing device 10 or a message for receiving a message to the user and an instruction from the user. Display means for displaying a user interface (GUI) or the like.

  The operation element 16 is an operation element such as a button, knob, slider, or touch panel provided on the operation panel of the acoustic signal processing apparatus 10. Various operations from the user such as parameter setting and screen / operation mode switching are performed. It is for accepting instructions. When the acoustic signal processing apparatus 10 is configured as an electronic musical instrument, the operation elements 16 include performance operators such as a keyboard and pedals.

The acoustic signal processing unit 17 is an acoustic signal processing unit that performs acoustic signal processing (including generation, the same applies hereinafter) according to various parameter values set by the user.
The content of the processing varies depending on the function of the acoustic signal processing device 10. For example, when the acoustic signal processing device 10 has a function of an electronic musical instrument or a sound source device, the CPU 11 generates it according to the operation of a performance operator. Or received from an external device via the communication I / O 14, or generated by the CPU 11 in accordance with the contents of the music data during automatic performance of the music (performance events or control data for controlling the generation of musical sounds, etc. ), Waveform data that is a musical tone signal is generated in a plurality of tone generation channels, and is output from the signal output unit 22.
Further, when the acoustic signal processing apparatus 10 has a function of a mixer or an effector, the music signal input from the signal input unit 21 or generated internally is mixed, equalized, and effected by a plurality of signal processing channels. Various processing such as application is performed and output from the signal output unit 22.

The signal input unit 21 includes an A / D converter, and is an interface for inputting an acoustic signal from an external device that supplies an acoustic signal such as a microphone or a musical instrument, and providing the signal as signal processing in the acoustic signal processing unit 17 as digital waveform data. is there.
The signal output unit 22 includes a D / A converter, and is an interface for outputting the acoustic signal processed by the acoustic signal processing unit 17 as an analog acoustic signal to an external device that is an acoustic signal output destination such as a speaker or a recorder. .
Note that these interfaces may be configured to allow digital input / output.

The acoustic signal processing device 10 as described above can be configured as various types of devices such as an electronic musical instrument including an electronic organ, a sound source device, an effector, a digital mixer, or a device having these functions.
However, in any case, the acoustic signal processing unit 17 performs signal processing according to various parameter values stored in the current memory, and a plurality of sets of parameter values to be stored in the current memory are registered in advance. A common point is that any one of them can be recalled (recalled) into the current memory and reflected in the signal processing in accordance with the user's operation.

This embodiment is characterized by the content of a function for referring to or editing a set of parameter values. Therefore, this point will be described below.
For convenience of explanation, examples of screens and flowcharts used in the following explanation are examples in which the acoustic signal processing apparatus 10 is assumed to be configured as an electronic organ that generates musical sounds according to a plurality of keyboard performance operations. Is used. The set of parameter values is referred to as registration (registration).

First, FIG. 2 shows a configuration diagram of a parameter storage area included in the acoustic signal processing apparatus 10.
As shown in FIG. 2, in the acoustic signal processing device 10, as parameter storage areas, a current memory for storing parameter values to be reflected in the signal processing in the acoustic signal processing unit 17 as described above, and each of the current memories There is prepared a resist memory for storing 16 resists # 1 to # 16, which are sets of parameter values to be stored in.

  Among these, the current memory is provided in the RAM 13 or the internal memory of the acoustic signal processing unit 17. The contents can be edited by the user at any time by operating the operation element 16, and when the parameter value is changed by editing, the parameter value after the change is immediately processed by the signal processing in the acoustic signal processing unit 17. (The processing relating to this editing is performed by the CPU 11 in response to the detection of the operation event of the operator 16, but detailed illustration is omitted here). Parameters that can be edited without using the GUI screen can be edited regardless of the contents of the screen even during display of a list display screen, which will be described later. When editing that affects the content of the GUI screen is performed, the CPU 11 updates the content of the GUI screen as needed according to the editing.

  Further, since the resist memory does not change its contents frequently, it may be provided in the flash memory 12. The contents of the resist stored in the resist memory are selected from one of the resists, the contents are called to the current memory, the contents are edited on the current memory, and the edited contents are changed to any one of ( It can be edited by saving (storing) it in the resist memory as a resist.

Note that the contents of the resist memory can also be edited by using a batch editing function described later.
As can be seen from the above description, the contents of the current memory have the same data format as the contents of the resist. Therefore, the acoustic signal processing apparatus 10 regards the contents of the current memory as one of the resists, and assigns the identifier “panel” to the current memory in consideration of being editable by the operator on the operation panel. ing. The “panel” shown in parentheses in FIG. 2 means this.

Next, FIG. 3 shows an example of a list display screen for accepting a batch editing operation. This figure shows an example of a screen used when one parameter is selected as a display and editing target.
The list display screen 100 is a GUI that is displayed on the display unit 15 by the CPU 11 in response to detection of a transition operation to the batch edit mode by the user.
The list display screen 100 includes a reference registration selection button 101, a parameter selection screen display button 102, a registration content display unit 110, a coincidence display unit 120, an edit target selection button 130, a batch decrease button 141, a batch increase button 142, a batch. A setting button 143 is provided.

  Among these, the reference resist selection button 101 is a button for accepting selection of a reference resist as a reference for displaying the match / mismatch of parameter values in the match display section 120 and displaying a resist that is currently a reference resist. . In the figure, a “panel” meaning the contents of the current memory is a reference resist.

  When the reference registration selection button 101 is touched, the CPU 11 displays a menu screen (not shown) on the display 15 and shows each registration of # 1 to # 16 registered in the registration memory and the contents of the current memory. The selection of a resist as a reference resist is accepted from a total of 17 “panels”. In addition, the resist can be selected as the reference resist by touching the display corresponding to the desired resist in the resist content display unit 110.

  The parameter selection screen display button 102 is a button for receiving selection of a display parameter to be displayed and edited on the list display screen 100 and displaying a parameter that is currently a display parameter. The figure shows a state in which the “reverb time” parameter is a display parameter.

When the parameter selection screen display button 102 is touched, the CPU 11 later displays a parameter selection screen 200 shown in FIG. 4 on the display 15 and displays a value on the resist content display unit 110 from the parameters included in the resist. Selection of a parameter to be a display parameter to be received is accepted.
The selected contents of the reference registration and display parameters are stored even after the list display screen 100 is closed, and are used as initial values when the list display screen 100 is displayed next time.

  The resist content display unit 110 is a display unit that displays the values of display parameters (parameters selected on the parameter selection screen 200) in each of the resists # 1 to # 16 and the 17 “panel” resists. . The resist number is displayed on the resist number display unit 111, and the display parameter value is displayed on the parameter value display unit 112 as a bar graph. In this bar graph, for example, the lower end may be displayed as the minimum value that the parameter can take, and the upper end may be displayed as the maximum value. Depending on the content indicated by the parameter, a logarithmic display may be used.

The coincidence display unit 120 is a display unit that displays, for each of the 17 resists, whether or not the display parameter value in the resist matches the display parameter value in the reference resist. Here, “*” marks indicating that the matching resists are displayed, and nothing is displayed for the non-matching resists.
The display content of the coincidence display unit 120 is a mark to be attached to the parameter displayed on the parameter value display unit 112, and among the display parameter values displayed on the parameter value display unit 112 by this mark, the display in the reference resist Those that match the value of the parameter and those that do not can be displayed in different ways.

Therefore, the user can grasp at a glance the resist whose display parameter value is equal to the reference resist. In addition, by appropriately selecting the reference resist and the display parameter, it is possible to easily grasp which resist is equal to the value of the parameter for any resist.
For the reference resist (“panel” resist in the example shown in the figure), the comparison target is its own parameter, so that it always indicates “matches the value in the reference resist”.

The edit target selection button 130 is a button for accepting a selection as to whether or not each of the resists # 1 to # 16 and the “panel” 17 resists is a target of batch editing. Batch editing is a function that performs batch editing of the same contents for all target resists. Then, by touching a button corresponding to a desired registration, the user can toggle whether or not the registration is a target for batch editing. Note that there is no limit to the number of registers to be batch edited, and it is not necessary to treat the reference resist specially in this selection.
This selection content to be edited is also saved after the list display screen 100 is closed, and used as an initial value when the list display screen 100 is displayed next time.

The batch decrease button 141, the batch increase button 142, and the batch setting button 143 are buttons for instructing execution of batch editing.
The collective decrease button 141 decreases the value of the display parameter by a predetermined change width for all the resists subjected to collective editing, and the collective increase button 142 similarly changes the display parameter value to the predetermined change width. It is a button for instructing to increase only.

The collective setting button 143 sets the display parameter value in the reference resist as the display parameter value for all resists subject to batch editing, that is, the parameter selected as the display parameter. This is a button for instructing to align the value with the value of the parameter in the reference resist.
When any of these buttons is operated, the CPU 11 immediately executes batch editing according to the operation, and updates the display of the parameter value display unit 112 according to the result.

  In the acoustic signal processing apparatus 10, if the registration of “panel” is set as a target of batch editing, not only the contents of the already registered resist but also the contents of the current memory can be edited simultaneously by the batch editing function. . Therefore, the result of batch editing is immediately reflected in the processing contents in the acoustic signal processing unit 17, and it is easy to hear and confirm how the output sound from the acoustic signal processing unit 17 changes as a result of batch editing. can do. Therefore, batch editing can be performed while easily grasping the relationship between the editing result and the output sound.

It should be noted that only the display parameters are subject to batch editing, and in the case of increase / decrease editing, the parameter values of each resist after editing do not necessarily match the contents of the current memory. However, as the direction of increase / decrease is the same direction of editing, for example, batch editing while checking the direction of the editing results, such as what kind of change the output sound when changing the reverb depth and time, etc. If you can, you can grasp the changes made in batch editing as an image, which is useful enough.
In addition, if batch setting is performed with the reference resist set to “panel”, the value of the output sound can be confirmed by manipulating the parameter value on the current memory, and then the confirmed value can be set to any resist. . Therefore, even with such a method, it can be said that batch editing can be performed while easily grasping the relationship between the editing result and the output sound.

  When performing batch editing as described above, it is not preferable that the resist is stored in the flash memory 12 because of problems in response speed and the number of rewrites. Therefore, when displaying the list display screen 100, the contents of the resist memory are read in advance into the RAM 13, the read contents are edited, and the list display screen 100 is closed after the editing is finished. The edited resist may be stored in the flash memory 12.

Next, FIGS. 4 to 6 show display examples of the parameter selection screen. 4 and 5 are display examples in the normal mode, and FIG. 6 is a display example in the difference detection mode corresponding to FIG.
These parameter selection screens 200 are GUIs that the CPU 11 displays on the display unit 15 in response to pressing of the parameter selection screen display button 102, and accepts selection of display parameters to be displayed and collectively edited on the list display screen 100. It is a screen for.

The parameter selection screen 200 includes a block selection button display unit 210, a parameter selection button display unit 220, a difference detection button 231, and a close button 232.
The block selection button display unit 210 is a block for accepting selection of parameters belonging to which parameter block among a plurality of parameter blocks into which selectable parameters are divided, and the parameter selection button display unit 220 displays the parameter selection button. This is an area for displaying a selection button. The block selection button display unit 210 displays a block selection button for each parameter block prepared in advance, and when the button is turned on, the CPU 11 corresponds to the touched button on the parameter selection button display unit 220. A parameter selection button corresponding to each parameter (or parameter group) belonging to the parameter block to be displayed is displayed.

  FIG. 4 shows a state in which the other button 212 for selecting the “other” parameter block is turned on, and FIG. 5 shows that the upper key 1 button 211 for selecting the parameter block of “upper keyboard 1” is turned on. It shows the state that was done. As can be seen by comparing these figures, the parameter selection buttons displayed on the parameter selection button display unit 220 differ depending on which block selection button is turned on.

  As described above, the parameter selection button display unit 220 is an area for displaying a button for selecting a parameter belonging to the selected parameter block as a display parameter. The user can select a parameter corresponding to the button as a display parameter by touching any of the buttons displayed here.

  FIG. 4 shows a state in which the reverb time button 221 for selecting the “reverb time” parameter is turned on. FIG. 5 shows a state in which the parameters of the other parameter blocks are selected, and all the parameter selection buttons displayed on the screen are OFF. For example, when the upper keyboard 1 button 211 is turned on in the state shown in FIG. 4, the parameter selection screen 200 is in the state shown in FIG.

Here, the number of parameter selection buttons that can be selected ON at the same time is only one through all the parameter blocks. However, the number of parameters corresponding to one button is not limited to one, and there is a button for selecting a parameter group including a plurality of parameters collectively.
For example, as shown in FIG. 4, the other button 222 prepared in the “other” parameter block displays all parameters other than the parameters corresponding to the button displayed on the screen among the parameters belonging to the parameter block. It is a button for selecting as a display parameter at the same time.

  Further, as shown in FIG. 5, the “effect 1” and “effect 2” buttons prepared in the parameter block of “upper keyboard 1” are used to set a plurality of parameters such as processing type and processing depth related to a specific effect. It is a button for selecting collectively. The “all upper keyboard 1” button is a button for collectively selecting all parameters belonging to the parameter block of “upper keyboard 1”.

In this way, a parameter selected by a certain button may overlap with a parameter selected by another button. Further, even if a parameter can be selected only in a batch on the parameter selection screen 200, it can be edited individually for each parameter by means other than batch editing.
Such a correspondence relationship between the types of parameter selection buttons displayed on the parameter selection button display unit 220 in response to the selection of the parameter block and the types of parameters for which selection is accepted by each button is prepared in advance in the flash memory 12. Just remember.

Next, the difference detection button 231 is a button for accepting an on / off operation of the difference detection mode with a toggle.
Here, the difference detection mode means that for each parameter selection button displayed on the parameter selection screen 200, the values of the parameters selected by the button are all registered (in this difference detection function, the registration of “panel” is included). In this mode, it is possible to distinguish whether there is a resist having a different value or at least one different value. For buttons for selecting multiple parameters at once, a match display is displayed when the values for all the parameters corresponding to the button match in all the resists, and there is a mismatch in other cases. Is displayed.

  FIG. 6 shows a display example when the difference detection button 231 is turned on in the state of FIG. In this example, in the parameter selection button display unit 220, the buttons corresponding to the parameters whose values do not match are displayed in the same manner as in the normal mode of FIG. The button corresponding to the parameter to be displayed is only displayed that the button exists, is grayed out, and the button function is disabled so that the user cannot operate it. Therefore, in this state, only parameters whose values do not match can be selected as display parameters.

  When the user of the acoustic signal processing apparatus 10 is not very skilled, the usage is such that many parameters that are not familiar among the many prepared parameters are left at the default values and only some of the parameters are edited. It is assumed that In this case, it is assumed that the parameters whose values are the same in all the resists are not so familiar to the user, so there is not much intention to edit (thus, there is no intention to refer to). On the other hand, since it is known that the user has edited a parameter with a resist having a different value, it is assumed that editing will continue in the future.

Therefore, by displaying the parameter selection button display unit 220 so that a parameter whose value matches in all the resists and a parameter whose value does not match can be distinguished, the parameter to be edited by the user can be selected from many parameters. Can be easily found.
Further, if only parameters whose values do not match can be selected as display parameters, it is possible to prevent erroneous selection of parameters that are not intended to be edited. Even in this case, if the difference detection button 231 is pressed again to cancel the difference detection mode (or if the difference detection mode is not used from the beginning), all parameters can be selected. Even when it is desired to use the same parameter for all resists as the display parameter, the effect on operability is small.

Next, the close button 232 is a button for confirming the selection of the display parameter on the parameter selection screen 200 and returning to the list display screen 100.
Note that whether the operation of the parameter selection screen 200 was the normal mode or the difference detection mode has no effect on the operation of the list display screen 100.

Next, FIG. 7 shows a display example different from FIG. 3 of the list display screen. This figure shows an example of a screen used when a plurality of parameters are selected together as display parameters.
When returning to the list display screen in a state where the parameter selection button for selecting a plurality of parameters at a time is pressed on the parameter selection screen 200, the CPU 11 replaces the screen shown in FIG. 3 with that shown in FIG. A list display screen 100 ′ is displayed on the display 15.

This screen has the same general configuration as the list display screen 100 shown in FIG. 3, but differs in the following points.
First, the parameter value display unit 112 is not provided in the resist content display unit 110. This is because it is difficult to easily display the contents of a plurality of parameters in a graph because of the resolution and size of the display 15. Instead, the coincidence display unit 120 is provided inside the resist content display unit 110. However, the “*” mark indicating coincidence is displayed only for the resist in which the values of all the parameters that are display parameters match the values of the corresponding parameters in the reference resist.

  Of the buttons for instructing execution of batch editing, the batch decrease button 141 and the batch increase button 142 are disabled on the list display screen 100 ′. This means that when multiple parameters are subject to editing, the meaning differs for each parameter, so if all parameters are linked and changed in a certain direction, the interaction and harmony between parameters will be disturbed. This is because it can be considered.

  However, for the batch setting button 143, the function is enabled, and the values of all the parameters that are display parameters for all the resists that are the targets of batch editing can be aligned with the values of the parameters in the reference resist. I can do it. This is because if it is a copy of a value, it is considered that a harmonized set of values is originally copied, so it is considered that there is no problem even if it is performed for a plurality of parameters at the same time. If such editing is permitted, it is not necessary to set parameters one by one at a time, so that operability can be improved.

Next, processing executed by the CPU 11 of the acoustic signal processing device 10 to realize the functions of the respective screens described above will be described.
First, FIG. 8 shows a flowchart of display processing of the list display screens 100 and 100 ′.
When the CPU 11 detects an instruction to shift to the batch edit mode from the user by operating the operation element 16 on the operation panel or the like, the CPU 11 starts the process shown in the flowchart of FIG.
First, the frame of the list display screen is displayed on the display 15 (S11). This frame is common to the list display screen 100 shown in FIG. 3 and the list display screen 100 ′ shown in FIG.

Next, the resist rr selected as the reference resist is displayed as the caption of the reference resist selection button 101 (S12). Further, the edit target selection button 130 of each resist is displayed in an ON or OFF state based on whether or not the resist is set as a batch edit target (S13).
In the following description, the term “resist” includes a “panel” resist indicating the contents of the current memory unless otherwise specified.

Next, the CPU 11 determines whether or not the parameter p selected as the display parameter is a single parameter (S14). If the parameter is a single parameter, a graph indicating the value of the parameter p stored in the resist is displayed on the parameter value display unit 112 for each resist to display the list display screen 100 in the format shown in FIG. Displayed (S15). If the parameter p is a parameter group composed of a plurality of parameters in step S14, the list display screen 100 'in the format shown in FIG. 7 is displayed, so that the process of step S15 for displaying the parameter value display unit 112 is performed. Absent.
In either case, next, the coincidence display process (S16) shown in FIG. 9 is performed, and the process ends.

FIG. 9 shows a flowchart of the coincidence display process. This process is a process for displaying the coincidence display unit 120.
In this process, the CPU 11 sequentially selects all the resists one by one as processing targets (S21, S26, S27), and performs the processes of steps S22 to S25 for each resist.

  That is, the value of the parameter p selected as the display parameter is compared between the resist to be processed and the resist rr selected as the reference resist (S22). The coincidence mark “*” for the resist to be processed is displayed in the section 120 (S23, S24). If there is no match, the match mark “*” for the resist to be processed is not displayed (S25). If there are a plurality of parameters p, the determination in step S23 is YES only when the values match for all of them. Although not shown, the display position of the coincidence mark differs between the case where there is one parameter p and the case where there are a plurality of parameters p, as described with reference to FIGS.

When the above process is completed for all the resists, the process returns to the original process. When returning to the process of FIG. 8, the process is ended.
With the above processing, the CPU 11 displays a list on the display unit 15 according to whether the display parameter is selected as an individual parameter or a parameter group when there is an instruction to shift to the batch editing mode. The screen 100 or the list display screen 100 ′ can be displayed.

Next, FIG. 10 shows a flowchart of the reference registration changing process.
When the CPU 11 detects on the list display screen 100 that there is an operation for selecting the resist rr as the reference resist by operating the reference resist selection button 101 or touching the resist content display unit 110, the flowchart of FIG. The process shown in FIG.

First, the selected resist rr is set as a reference resist (S31). Further, when the reference resist is changed, the reference used for the display of the coincidence display unit 120 is changed. Therefore, the coincidence display process shown in FIG. 9 is performed again to update the display of the coincidence display unit 120 (S32). Exit.
With the above processing, the reference registration can be changed and the display on the list display screen 100 can be updated accordingly.

Next, FIG. 11 shows a flowchart of batch increase / decrease processing.
When the CPU 11 detects that the batch decrease button 141 or the batch increase button 142 is operated on the list display screen 100, the CPU 11 starts the processing shown in the flowchart of FIG.

First, for each resist set as a batch editing target, the value of the parameter p selected as a display parameter is increased or decreased by a predetermined change width according to the detected operation (S41). This change width is determined in advance according to the parameter type and resolution.
If there is only one parameter p after the change (S42), the graph of each resist in the parameter value display unit 112 is updated based on the value of the parameter p after the change (S43). When there are a plurality of parameters p, there is no parameter value display unit 112, so this update process is unnecessary.

In any case, since the match / mismatch with the reference resist may change when the parameter value is changed, the match display process shown in FIG. 9 is performed again to update the display of the match display unit 120. (S44), and the process ends.
Through the above-described processing, the parameter value can be collectively increased / decreased and the display on the list display screen 100 can be updated accordingly. In the example shown in FIG. 7, when the parameter p is plural, the batch increase / decrease editing function is disabled, so the processing in steps S42 and S43 is not necessary, but this can be canceled. For this reason, FIG. 11 also shows the processing of steps S42 and S43.

Next, FIG. 12 shows a flowchart of the batch setting process.
When the CPU 11 detects that the batch setting button 143 is operated on the list display screen 100, the CPU 11 starts the process shown in the flowchart of FIG.
First, for each resist set as a batch editing target, the value of the parameter p selected as the display parameter is set to the value of the parameter p in the resist rr selected as the reference resist (S51).

Thereafter, the display is updated in the same manner as in steps S42 to S44 of FIG. 11 (S52 to S54), and the process is terminated.
Through the above processing, it is possible to edit the parameter value batch setting and update the display of the list display screen 100 associated therewith.

Next, FIG. 13 shows a flowchart of the display process of the parameter selection screen 200.
When the CPU 11 detects that the parameter selection screen display button 102 is operated on the list display screen 100, the CPU 11 starts the process shown in the flowchart of FIG.
First, the frame of the parameter display screen is displayed on the display unit 15 (S61). This frame includes buttons other than the parameter selection buttons displayed on the parameter selection button display unit 220.

Next, the parameter block including the parameter p selected as the display parameter is specified (S62), and the block selection button corresponding to the specified parameter block in the block selection button display unit 210 is turned ON (S63).
Thereafter, a predetermined parameter selection button for selecting a parameter belonging to the parameter block identified in step S62 is displayed on the parameter selection button display unit 220 (S64). Then, the parameter selection button corresponding to the parameter p is turned ON (S65). The correspondence here is based on the fact that the number and type of parameters completely match.

Next, the CPU 11 determines whether or not the difference detection mode is turned on by the difference detection button 231 (S66). If it is OFF, there is no need to perform special processing, all the parameter selection buttons displayed in step S64 are validated (S67), and the processing ends.
On the other hand, if it is ON in step S66, the partial validation process shown in FIG. 14 is executed (S68).

FIG. 14 is a flowchart showing a part of the validation process. This process is performed by using each parameter displayed on the parameter selection button display unit 220 in accordance with the match or mismatch of the parameter values, as described with reference to FIG. This is a process for controlling the validity / invalidity of the selection button.
In this processing, the CPU 11 sequentially selects the parameter selection buttons being displayed as processing targets one by one (S71, S76, S77), and performs the processing of steps S72 to S75 for each parameter selection button.

  That is, for all resists (excluding “panel” resists), the values of the parameters selected by the parameter selection button to be processed are compared (S72). The selection button is validated (S73, S74). If there is even a mismatched resist, the parameter selection button to be processed is invalidated (S75). If there are a plurality of parameters selected by the parameter selection buttons to be processed, the determination in step S73 is YES only when the values are the same for all the resists for all of them. In addition, the display mode is different between the button to be enabled and the button to be disabled.

When the above process is completed for all the parameter selection buttons being displayed, the process returns to the original process. When returning to the processing of FIG. 13, the processing is ended.
With the above processing, when there is an instruction to display the parameter selection screen 200, the CPU 11 displays the parameter selection screen 200 on the display unit 15 while the parameter selection button corresponding to the display parameter at that time is turned on. be able to.
When the difference detection mode is ON, the display mode of the parameter selection button can be varied depending on whether or not the corresponding parameter values match in all the resists.

  It is also conceivable that the parameter selection button turned on in step S65 in FIG. 13 is invalidated by the processing in FIG. However, there is no particular problem even if this happens. This is because the invalidation of the button is merely performed to alert the user or prevent an erroneous operation, and the selection of the corresponding parameter itself does not adversely affect the operation of the acoustic signal processing apparatus 10. Therefore, it is not necessary to cancel the parameter selection simultaneously with the invalidation, and when any valid parameter selection button is pressed, the parameter corresponding to the button may be set as a display parameter as usual.

The processing executed by the CPU 11 when various buttons are operated on the parameter selection screen 200 is not shown, but the outline is as follows.
First, when the difference detection button 231 is pressed, ON / OFF of the difference detection mode is reversed, and the processing of step S66 and subsequent steps in FIG. 13 is performed.
When one of the parameter selection buttons is pressed, the parameter corresponding to the button is set as a display parameter, and the on / off state of the button is changed according to the setting.

When any one of the block selection buttons is pressed, it is assumed that the block is specified in step S62, and the processing in step S63 and subsequent steps in FIG. 13 is performed. In this case, there may be no parameter selection button to be turned on in step S65.
When the close button 232 is pressed, the parameter selection screen 200 is closed and the processing of FIG. 8 is executed to display the list display screens 100 and 100 ′.
With the processes described above, the function of matching and displaying the parameter values on the list display screens 100 and 100 'and the function of detecting the difference on the parameter selection screen 200 described with reference to FIGS. can do.

[Modification]
This is the end of the description of the embodiment, but it goes without saying that the configuration of the apparatus, screen display content, data format, specific processing content, and the like are not limited to those described in the above embodiment.
For example, in the example of FIG. 3, the parameter values for each resist are displayed as graphs. However, the values may be displayed as characters (numerical values or identifiers). In this case, even if a plurality of parameters are selected, all the values can be displayed as long as space allows. Therefore, also on the screen shown in FIG. 7, the value of each parameter selected as the display parameter may be displayed on the resist content display unit 110.

It is also conceivable that a plurality of parameter selection buttons can be turned on on the parameter selection screen. In this case, on the list display screen 100, values may be displayed and the coincidence display unit 120 may be displayed in units of parameters corresponding to one parameter selection button.
Further, on the list display screen 100, the display indicating whether or not the parameter value of each resist matches the reference resist is not a mark but the color or pattern of the resist content display unit 110 or the parameter value display unit 112 is changed. You may go by.

  Further, the coincidence display function in the above-described embodiment is similarly effective even when the contents of the “panel” resist are not displayed on the list display screen 100 and cannot be selected as the reference resist. Furthermore, even when the functions of coincidence display, batch editing, and difference detection are provided independently, the effect of each function can be obtained.

In addition, each function described in the above embodiment uses a remote controller such as a physical controller as well as a case where an operation is received by an operator provided in the main body of the acoustic signal processing apparatus 10 and display is performed by a display device. It is also applicable to cases. In this case, for example, the acoustic signal processing device 10 stores programs and data necessary for screen display and parameter setting instructions, and provides those data to the remote controller in response to a request from the remote controller. An operation may be accepted by displaying a screen on the display of the remote controller.
In addition, the configurations and modifications described above can be applied in appropriate combinations within a consistent range.

As is apparent from the above description , according to the present invention, it is possible to easily confirm which parameter set and which parameter set have the same parameter value for a plurality of parameter sets registered in advance. can do.
Therefore, by applying the present invention, the operability of the acoustic signal processing device can be improved, for example .

DESCRIPTION OF SYMBOLS 10 ... Acoustic signal processing apparatus, 11 ... CPU, 12 ... Flash memory, 13 ... RAM, 14 ... Communication I / O, 15 ... Display device, 16 ... Operator, 17 ... Acoustic signal processing part, 18 ... System bus, 21 ... Signal input unit, 22 ... Signal output unit, 100, 100 '... List display screen, 101 ... Standard registration selection button, 102 ... Parameter selection screen display button, 110 ... Registration content display unit, 120 ... Match display unit, 130 ... Edit object selection button 141 ... Batch decrease button 142 ... Batch increase button 143 ... Batch setting button 200 ... Parameter selection screen 210 ... Block selection button display section 220 ... Parameter selection button display section 231 ... Difference detection button 232 ... Close button

Claims (2)

An indicator,
A parameter memory for storing a plurality of parameter sets each including a plurality of parameter values;
Presenting means for presenting a parameter as an option to the user except for a parameter whose value is the same in all of the plurality of parameter sets among the plurality of parameters,
First selection means for selecting any of the parameters presented by the presentation means in response to a first selection operation by the user;
Second selection means for selecting one of the parameter sets in response to a user's second selection operation;
In response to a display instruction from the user, for each of the plurality of parameter sets, the value of the parameter selected by the first selection unit is displayed on the display, and among the displayed parameter values And a collective display control means for causing the display to display a parameter that matches the value of the parameter in the parameter set selected by the second selection means in a different manner from the others. Parameter display device . An indicator,
A parameter memory for storing a plurality of parameter sets each including a plurality of parameter values;
Of the parameter group consisting of a plurality of parameters included in the plurality of parameters, a parameter group excluding a parameter group in which all parameter values belonging to the parameter group match in all of the plurality of parameter sets is selected as a user. Presenting means to present to,
A first selection means in response to a first selection operation of the user to select one of the group parameters the presentation means is presented,
Second selection means for selecting one of the parameter sets in response to a user's second selection operation;
In response to a user's display instruction, for each of the plurality of parameter sets, all parameter values belonging to the parameter group selected by the first selection unit are in the parameter set selected by the second selection unit. it matches the value of the corresponding parameter, the parameter display device is characterized by providing a collective display control means for displaying or not on the display device.

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