JP2005252543A - Control program for acoustic signal processor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a control program for an acoustic signal processor in which a link operating function is not affected by an individual operating function of a parameter. <P>SOLUTION: When a controlled and operated operating element is assigned with a parameter, an operating function setting section 2c handles this operating element as an individual operating element. When the individual operating element is controlled and operated, only the value of the assigned parameter is controlled and the resulting value is stored in a parameter memory 3. Meanwhile, when a group is assigned to the controlled and operated operating element, the operating function setting section 2c handles this operating element as a link operating element. When the link operating element is controlled and operated, values of all the parameters belonging to the assigned group are subjected to link control according to a prescribed link control characteristic and the resulting values are stored in the parameter memory 3. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a technique for controlling an operation parameter when a digital signal processing of an acoustic signal is used for an acoustic signal processing device such as an audio mixing system or an electronic music device.

In an audio mixing system, a configuration is known in which a personal computer that executes a control program (such as an editing program) for an acoustic signal processing device is connected to an engine (acoustic signal processing unit) (see Non-Patent Document 1). .
On the personal computer side, CAD (Computer Aided Design) data having a plurality of components and wiring data between them is edited. In the editing by the control program described above, a plurality of components included in the CAD data and wiring data between them are graphically displayed on the CAD screen.
The user can add and delete components and connections, or change the arrangement by operating the mouse on the CAD screen. The edited CAD data is converted for the engine and transferred to the engine in accordance with the CAD data transfer instruction.

The engine controls the operating parameters based on the received CAD data, and processes the acoustic signal by digitally processing the acoustic signal.
The personal computer also has an operation parameter operation function.
In the real-time control mode, multiple operating elements are placed on the display screen, and the operating parameters assigned to each operating element are controlled by operating these operating elements with the mouse. Is transmitted to the engine, and the operation parameter is controlled on the engine side.

FIG. 10 is a block diagram for explaining a conventional audio mixing system.
111 is a personal computer, the engine 112 ₁ is connected.
The engine 112 ₁ has an input / output terminal for acoustic signals, a panel operator and a display (not shown), and an external controller 113 may be connected.
The editing program of the personal computer 111 uses a GUI (Graphical User Interface) technique to arrange a plurality of operators on a display screen, and controls these operators with a mouse, so that parameters stored in the current scene are stored. At the same time, an operation event is transmitted to the engine 112 ₁ .

FIG. 11 is a block configuration diagram showing an example of a hardware configuration of the engine 112 ₁ shown in FIG.
In the figure, 121 is a bus and 122 is a CPU (Central Processing Unit). A flash memory 123 stores a control program and preset data. The control program is loaded into a RAM (Random Access Memory) 124. The RAM 124 has a current scene area for storing current values of operation parameters for acoustic signal processing.
125 is a display, 126 is a panel operator, 127 is an interface unit with the personal computer 111, 128 is a MIDI interface unit with a MIDI device, and 129 is an interface unit with other input / output devices.

The external controller 113 shown in FIG. 10 is connected using the MIDI interface unit 128 or the interface unit 129 of another input / output device.
A waveform input / output interface unit 130 A / D converts an analog input signal input from the outside and sends the analog input signal to a signal processing unit (DSP: digital signal processing device) 131, and a digital output from the signal processing unit 131. An analog output signal obtained by D / A conversion of the signal is output to the outside.
On the other hand, the digital waveform signal is input / output to / from the signal processing unit 131 via the waveform input / output interface unit 130 on a common line.

The signal processing unit 131 performs acoustic signal processing such as gain control, mixing control, effect addition control, and equalizer control on the acoustic signal by executing a microprogram in synchronization with the internal or external word clock.
Parameters for controlling the operation of the signal processing unit 131 are controlled not only by a panel operator (not shown) and an operator of the external controller 113 but also by operation event data transmitted from the personal computer 111 in an online state. The
The engines 112 ₁ , 112 ₂ , 112 ₃ ... Can be cascade-connected to the engine 112 ₁ and similarly controlled by the personal computer 111. Reference numeral 132 denotes a cascade input / output interface to which the engine 112 ₂ shown in FIG. 10 is connected.

In the prior art described above, a plurality of parameters for acoustic signal processing whose values are controlled according to the control operation of each operator are assigned to the plurality of operators displayed on the operation screen.
This operation element is a display component (GUI component).
In the real-time control mode, double-clicking on the component displayed on the CAD screen opens the control screen (see page 71 of Non-Patent Document 1) for controlling these operating parameters and displays the above-mentioned controls. Is done.

On the other hand, a group is set for at least one of the plurality of parameters. A group can be set between a plurality of parameters controlled in the same component and / or parameters controlled in different components.
The value of the parameter belonging to the set group is link-controlled by the control operation of any operator to which the parameter belonging to this group is assigned by the link (link) operation function. That is, when a certain parameter in a group is controlled with a certain operator, other parameters in the same group are also link-controlled (see p. 80 of Non-Patent Document 1).

Conventionally, there are a number of techniques related to the function of grouping parameters and performing link control.
For example, a dedicated group operator that controls a plurality of different parameter values is known (see Patent Document 1). However, there is no operator for individually controlling each parameter value.
In addition to an individual fader that individually controls each parameter value, there is a known one that includes a group master fader that collectively controls all parameter values (Patent Document 2 Prior Art and Claims). Range). However, the conversion characteristic of each parameter by the operation of the group master fader always changes depending on the control operation of the individual fader.

By the way, the above-described conventional technology also includes a “user control function”. The area of the user control screen (user operation panel) customized by the user by copying (copying) any operation element from the controls placed on the preset control screen (preset operation panel) of any preset component By pasting (pasting), a parameter assigned to an arbitrary operator can be assigned to the paste operator and placed on the user control screen (see p.192 of Non-Patent Document 1). .
At that time, if a group is set for the parameter assigned to the original control, as with the original control, if the pasted control is controlled, other parameters belonging to the same group are linked. Designed to control.
"DIGITAL MIXING ENGINE DME32 Owner's Manual", [online], Yamaha Corporation, Internet <http://www2.yamaha.co.jp/manual/pdf/pa/japan/signal/DME32J.pdf> Japanese Patent No. 2696868 JP-A-3-58351

In the prior art (Non-Patent Document 1), all parameters belonging to a set group are controlled regardless of which control element to which a parameter belonging to the group is assigned is controlled. For this reason, it is difficult to determine which operator has the link control function.
It becomes easier to understand if link control is performed with a dedicated operator. However, parameters belonging to the group could not be individually controlled (Patent Document 1).
Alternatively, even if link control is performed with a dedicated operator and individual control can be performed individually, the conversion characteristics of link control have changed due to individual control (Patent Document 2). If the link control characteristic is changed, there are cases where the balance between parameters belonging to the group is lost, and there is a case where it is desired to positively change the link control characteristic according to the individually controlled value.
The present invention has been made in order to solve the above-described problems, and makes it easy to confirm the operation function of the operator, and the acoustic signal processing in which the link operation function is not affected by the individual operation function of the parameter. An object of the present invention is to provide a device control program.

In the invention according to the first aspect, the computer realizes a function of controlling the values of the plurality of parameters stored in the parameter memory in accordance with the operations of the plurality of operators displayed on the operation screen. A program for controlling an acoustic signal processing device to be set, wherein a group including at least one of the plurality of parameters and a link characteristic according to a link operator operation of a parameter belonging to the group are set and a group and link characteristic setting A control operation detecting step for detecting an operation event of the operation element, and an operation element for which the operation event has been detected by the control operation detecting step is assigned with one parameter among the plurality of parameters. When it is an operator, according to the control operation of the individual operator, the parameter memory When only the value of the parameter assigned to another operator is controlled, and the operator for which the operation event is detected by the control operation detection step is a link operator assigned a set group, According to the control operation of the link operator, a parameter control step for link-controlling the values of all parameters belonging to the group in the parameter memory according to the set link characteristics, and according to the control operation of the individual operator When the parameter assigned to the individual operator is individually controlled, the operation screen of the link operator assigned to the group to which the individually controlled parameter belongs is controlled so that the operation position of the link operator does not move. And having a step of displaying above.
Therefore, since the individual operator and the link operator are independent, it is easy to confirm the operation function of the operator.
Further, the fact that the operation position of the link operator does not move indicates that the input value of the link operator has not changed. Therefore, when the link operator is controlled after the individual operator is controlled, the link control is performed starting from the parameter value immediately before that, ignoring the parameter value controlled by the individual operator. . As a result, the link operation function is not affected by the parameter individual operation function.
It can be visually recognized that the operation position of the link operator displayed on the operation screen does not move. Next, when the link operator is controlled, it can be visually confirmed that the link control is started from the operation position of the link operator displayed on the operation screen.

According to the second aspect of the present invention, in the acoustic signal processing device control program according to the first aspect, the values of all the parameters belonging to the group are link-controlled according to the control operation of the link operator. A step of causing the individual operator assigned to each parameter belonging to the group to be displayed on the operation screen so that the operation position of the individual operator moves according to the link-controlled value of the parameter. It is what has.
Therefore, when the individual operator is controlled after the link operator is controlled, the control by the individual operator is performed with the parameter value controlled according to the operation of the link operator as a starting point.
As a result, link control can be reflected in individual control. The reflection can be visually recognized by moving the operation position of the individual operator displayed on the operation screen. Next, when the individual operation element is controlled, it can be visually confirmed that the individual operation element is individually controlled from the operation position of the individual operation element displayed on the operation screen.

According to the third aspect of the present invention, in the acoustic signal processing device control program according to the first or second aspect, the parameters assigned to the individual manipulators are individually set according to the control operation of the individual manipulators. When controlled, it has a parameter link correction step of correcting the link characteristic of the parameter based on the changed value of the individually controlled parameter in accordance with a user instruction.
Therefore, depending on the user's instruction, the control operation of the individual operator can be reflected in the link characteristics.

According to the present invention, there is an effect that it is easy to confirm whether a link operation function is set for an operator or an individual operation function is set.
Further, link control has an effect that it can be prevented from being influenced by individual control.

FIG. 1 is a functional configuration diagram for explaining an embodiment of the present invention.
The engine 112 ₁ , 112 ₂ , 112 ₃ shown in FIG. 10 is used to control the operation element (display component) displayed on the display device by a user using a pointing device such as a mouse. Controls the operation parameters of.
In the figure, 1 is a control operation detection unit, 2 is a parameter control unit, 3 is a parameter memory, 4 is an operation position display control unit of an operator, and 5 is a parameter link control characteristic correction unit. Reference numeral 6 denotes a parameter link control characteristic correction instruction unit, which may not be required.
The functional configuration shown in the figure is realized by the CPU executing the control program of the acoustic signal processing device in the personal computer 111 shown in FIG.

The control operation detection unit 1 detects a control-operated operator or a drag operation based on a left mouse button click on a display part of a movable part (knob or button) of the operator displayed on the operation screen. The operation amount of the operation element controlled by is detected.
The parameter control unit 2 includes a parameter or group assignment unit 2a for the operator, a group and link characteristic setting unit 2b for the parameter, and an operation function setting unit 2c.

In the parameter assigning unit 2a for the operation element, a parameter for acoustic signal processing whose value is controlled according to the control operation is assigned to each operation element, or a group including at least one of a plurality of parameters Is assigned.
The assigned parameter or group is stored in a storage device. A certain parameter or group may be assigned to a plurality of operators.

  In the parameter group and link characteristic setting unit 2b, a group is set for at least one parameter. For example, group A is set for parameters a, b, and c, and group B is set for parameters g and h. There may be multiple groups. However, in order not to complicate link control, only one group may be set for each parameter. The set group configuration information and link control characteristics are stored in the storage device.

When a parameter is assigned to a control-operated operator, the operation function setting unit 2c uses the operator as an individual operator regardless of which group the parameter belongs to. Set the function. When the individual operator is controlled, only the assigned parameter value is controlled and stored in the parameter memory 3.
On the other hand, the operation function setting unit 2c sets a link operation function by using this operation element as a link operation element when a group is assigned to the operation element controlled. When the link operator is controlled, all parameter values belonging to the assigned group are link-controlled according to predetermined link control characteristics and stored in the parameter memory 3.

  In the prior art (Non-patent Document 1), the value of a parameter belonging to a group is link-controlled by any operator assigned with the parameter belonging to this group. In contrast, in this embodiment, if individual parameters are assigned, only the individual parameters are individually controlled. On the other hand, link control is performed by a dedicated operator assigned to a group.

  In the description to be described later with reference to FIG. 6 to FIG. With the pasting operator, a selection screen for selecting whether to link control all parameters belonging to the group or to control only the parameters assigned to the copy source operator is displayed to allow the user to select. However, the operation screen is not limited to the preset control screen or the user control screen. The operation function may be selected by other methods.

Also, assign different parameters belonging to a group to each of a number of existing controls, and either before the control operation or when the control operation is performed, the individual operation functions and link operations are assigned to the controls. Which function is to be set may be selected on a selection screen such as a pop-up menu.
For example, in an audio mixing system, the present invention can be applied to controlling a gain assigned to a fader operator that controls signal levels of a plurality of channels.

When the values of all the parameters belonging to the group are link-controlled according to the control operation of the link operator, the operation position display control unit 4 of the operator controls the individual operator assigned with the parameter belonging to the group. The operation position of the individual operator is displayed on the operation screen so as to move in accordance with the link-controlled value of the parameter.
In addition, when only the parameter assigned to this individual operator is controlled in accordance with the control operation of the individual operator, the link operator to which the group to which the individually controlled parameter belongs is assigned to this link operator. It is displayed on the operation screen so that the operation position does not move.

A parameter link control characteristic correction unit 5 may be provided. In this case, when only the parameter assigned to the individual operator is controlled according to the control operation of the individual operator, this parameter is determined based on the changed value of the individually controlled parameter according to the user instruction. Correct the link characteristics.
For example, a button (display component) for instructing correction is displayed in an arbitrary area on the operation screen, and the parameter link control characteristic correction instruction unit 6 detects that this button has been selected by the pointing device. It can be corrected.
In addition, when the parameter assigned to the individual operator belongs to a certain group, when the control operation of the individual operator is detected, or after that, the control operation of the link operator to which the above-described group is assigned. When the parameter link control characteristic correction instructing unit 6 described above is detected, the user may be instructed whether or not to correct a preset parameter link control characteristic.

FIG. 2 is an explanatory diagram showing a data configuration example on the personal computer 111 side for realizing the embodiment shown in FIG.
2A is a data configuration diagram of component data, FIG. 2B is a configuration data configuration, and FIG. 2C is a data configuration diagram of current parameter values.
A component refers to a component in which functions such as signal processing, control operation, display, input, and output are unit parts. As for signal processing, there are a mixer, a graphic equalizer, an effector, and the like. There are faders, switches, pans, etc. related to control operations. As for display, there are meters and the like.
Configuration means a configuration in which the above-described components are combined and connected to each other.
The current parameter value is a value set in a parameter for controlling the operation of each component constituting the current configuration, and is stored in the current scene area of the memory.

In FIG. 2A, the component data is a set of a large number of preset (PC) component data. It is stored in the storage device in advance. A similar one is stored in the flash memory 113 in FIG. 11 on the side of the engines 112 ₁ , 112 ₂ ,.
The preset component data includes a header, configuration information, a preset component processing routine, and a display / edit processing routine. The preset component data can be password protected so that it cannot be altered by unspecified users.

The header includes a preset component ID and preset component version data.
The configuration information includes image data for displaying the preset component, data for specifying one or more parameters constituting the preset component, information on a delay time (essential delay time) required for executing the process, and an operator for each parameter. Including conversion characteristics of parameter values such as how to change according to the operation amount.
Preset component processing routine, the engine 112 _1, in the case of special processing when passing parameters to the signal processing unit (DSP) 131, is a description of the processing procedure thereof.
The display / edit processing routine describes a processing procedure for displaying a block of preset components, an operator in the block, and a processing procedure for editing a parameter value.

In FIG. 2B, as the zone (1) data, one or a plurality of configuration data (configuration data) is stored in the storage device together with the zone management data.
The zone (1) management data describes the zone ID, the number of engines, the ID of each engine, the number of configurations included in the zone (1), and the like.
Each configuration data includes configuration management data, one or more CAD data, one or more preset data, link setting data, and user control data.

The configuration management data describes the configuration ID, the number of engines, the number of preset data, and the like.
CAD data, as shown as E1, E2, E3, each engine 112 _1, 112 _2, 112 ₃ are provided separately, each CAD data has CAD management data, one or more Cp data, the connection data ing.
The CAD management data describes the number of components.
The Cp data is component instruction data, and is data that indicates a preset component that constitutes this configuration from among a large number of preset components shown in FIG.

On the other hand, the preset data is data of preset values of parameters assigned to the respective operators included in this configuration. E1, E2, as shown as E3, each engine 112 _1, 112 _2, 112 ₃ are separately provided. The configuration of the preset data is the same as current scene data described later.
The link setting data is group configuration information. For example, a parameter in which a group is set, an operator ID for specifying an operator assigned to this parameter, and a parameter belonging to the group are assigned to each operator (group control operation). It includes a parameter link control characteristic indicating how the link control is performed according to the operation event (operation amount) of the child.
The user control data includes ID data for specifying a pasting operation element arranged on the user control screen described in the related art. When a group is set in the parameter assigned to the copy source operator, data is included indicating whether to function as a link operator or an individual operator.

FIG. 2C shows the data structure of the current scene area in the memory of the personal computer 111.
The data structure of operation parameters stored as current scene data is controlled based on CAD data. For example, separate areas for engines 1121, 1122, and 1123 are prepared corresponding to CAD data of E1, E2, and E3, and corresponding to the Cp data A, B, C, and D in the area of E1. An area for each preset component is prepared.
When editing program the personal computer 111 is in RUN mode, between the engine 112 ₁ is online. When the parameter value in the current scene is changed by controlling the operator, the operation event is transmitted to the engine 112 ₁ at the same time, and the current scene memory of each engine 112 ₁ , 112 ₂ , 112 ₃ ,. Thus, the signal processing unit 123 shown in FIG. 11 is controlled and immediately reflected in the acoustic signal processing being executed.

FIG. 3 is an explanatory diagram showing a specific example of the configuration screen (CAD screen) 11 displayed when the personal computer 111 is executing the editing program.
The configuration of the engine 112 ₁ shown in FIG. 10 is displayed.
12 to 18 are blocks indicating components. The terminals of each component are connected. Reference numeral 19 denotes a “parameter link correction” button which will be described later with reference to FIGS. 8C to 8E and 9C.

FIG. 4 is an explanatory diagram showing the parameter link setting screen 21.
Group configuration information is displayed as a linked parameter list 23 for each group set for one or more parameters.
In the illustrated example, a linked parameter list 23 is displayed in a group 22 named “CompTH”. The DSP column unit (U1) represents engine 112 ₁ shown in FIG. 10, the unit (U2) is indicative of the engine 112 _2.
“Compressor 1” and “Compressor 2” in the component column correspond to the block 14 of “Compressor 1” and the block 15 of “Compressor 2” shown in FIG. 3, respectively.

Incidentally, "compressor" in the third column corresponds to the "compressor" constituting a configuration (not shown) of the engine 112 _2. The illustrated parameter column designates “threshold” which is one parameter among a plurality of parameters of each compressor.
As will be described later with reference to FIGS. 8 and 9, CP is a control point (0 ≦ change range ≦ 100), CL is a control level (dB, −∞ <change range ≦ 0), and CR is a control ratio (−∞). <Change range <∞), which is an example expressing a function of conversion characteristics of each parameter with respect to an input operation amount. The relationship between the conversion characteristics of the parameters represents the link control characteristics of the parameters.
“CLoff” is an offset of the control level, “CRoff” is an offset of the control ratio, and is a value indicating the correction amount of the parameter link control characteristic.

The “parameter link correction” button 24 is the same as 19 shown in FIG.
The “Apply” button 25 is a button for immediately reflecting the displayed group configuration information in the processing of the editing program in a state where this window screen is opened, and the “OK” button 26 is immediately reflected on the displayed group configuration information. It is a button that closes this window screen. The “Cancel” button 27 is a button for closing the window screen without reflecting the changed group configuration information.

FIG. 5 is an explanatory diagram showing an outline of a program of the personal computer 111 shown in FIG. 10, which realizes the embodiment shown in FIG.
The CAD data editing task 31 displays the configuration screen shown in FIG. 3 and realizes a function of pasting required components and wiring between components.
The user control editing task 32 realizes a function of dragging and dropping an operator from the preset component control screen 41 to a user control screen 46 described later with reference to FIG.
The parameter editing task 33 realizes a function of controlling the assigned parameter value by performing a control operation on a possible portion of the operator with a mouse on the control screen.

Examples of other tasks 34 include a process of transmitting CAD data and operation event data to the engine 112.
If the data is not consistent between the personal computer 111 and the engines 112 ₁ , 112 ₂ , 112 ₃ ,. Therefore, when the CAD data editing task 31 is executed, the offline state is automatically set. Here, when the user instructs “move online”, the CAD data is processed for each engine 112 ₁ , 112 ₂ , 112 ₃ ,..., Transferred to each engine together with other data, and brought into an online state.

FIG. 6 is an explanatory diagram of a drag-and-drop operation of an operator on the user control screen.
FIG. 6A is a diagram showing a preset control screen 41 displayed as a pop-up when the component 14 of “Compressor 1” shown in FIG. 3 is double-clicked.
Here, each preset component has a unique preset control screen. This screen is controlled by a “display / edit processing routine” in “preset component data” corresponding to the preset component in FIG. The user cannot edit the contents of this screen, for example, which operator is arranged at which position, parameter assignment to the operator, and the like.

The parameter value of “Compressor 1” is controlled by controlling the operator on this screen.
On the left side of the figure, a plurality of controls for controlling compressor parameters are displayed. One example is a “THRESHOLD” operation element 42 for setting a level at which compression of an input signal is started.
On the left side, a graph 43 showing the characteristics of the output signal level (dB) with respect to the input signal level (dB) is displayed. The threshold signal level (Th) 44 in the graph 43 is changed by dragging the knob of the operator 42 with the mouse. The “ON” button 45 is a button for controlling on / off of the function of the “Compressor 1”.

FIG. 6B shows a user control screen 46. The preset component control screen 41 shown in FIG. 6A provides operators for a number of controllable parameters.
The user configures a necessary and sufficient user control screen 46 by pasting an operator assigned a necessary parameter to the user control screen 46 in accordance with the individual use environment such as the engine 112 _1. Will be able to.
The user can instruct this pasting by dragging and dropping a desired operator on the preset control screen 41 to a desired position on the user control screen 46 by a mouse operation.

Here, there are cases where the parameters assigned to the above-described copy source controls belong to a preset group.
For example, a group is set in the “threshold” operation element 42 shown in FIG. 6A as shown in FIG.
In this embodiment, the operators assigned parameters, including the operators on the preset control screen, always function as individual operators, and control only the parameters assigned to each operator.

In the illustrated example, the “threshold” operation element 42 is an operation element on the preset control screen, and thus always functions as an individual operation element, and controls only the “threshold”.
On the other hand, the control operation of the pasted operation element 47 controls the link of all parameter values belonging to the group, or controls only the parameters assigned to the copy source operation element 42. I want to be able to select child operation functions.

However, in the preset component control screen 41 shown in FIG. 6A, it is not known whether a group is set. Therefore, there is an inconvenience that an operation for displaying the parameter link setting screen 21 shown in FIG. 4 must be performed to check whether or not the parameter assigned to the copy source operator is included.
Further, after placing the pasting operator 47 on the user control screen 46, an operation for displaying the parameter link setting screen 21 shown in FIG. 4 may be performed, but the operation is easily forgotten.
Therefore, in this specific example, when a group is set in the parameter assigned to the copy source operation element 42, “Paste operation” is displayed in FIG. 6C in response to the detection of the mouse drop operation. An inquiry dialog box exemplified as “child selection screen” 51 is pop-up displayed.
For example, if parameter link setting as shown in FIG. 4 is performed, this dialog box pops up when the “threshold” operator on the control screen 41 is dragged and dropped onto the user control screen 46.

FIG. 7 is a flowchart for explaining an operation example when a drop operation is performed on the user control screen shown in FIG.
By dragging the operation element 42 shown in FIG. 6A to the user control screen 46, it is copied to the clipboard.
In S61, the link setting (group setting) status of the parameter assigned to the copy source operator on the preset control screen is determined. In S62, if there is a link setting, the process proceeds to S63, and if there is no link setting, the process proceeds to S64.

In S63, the “pasting operator selection screen” 51 shown in FIG. 6C is displayed.
The user clicks on the radio button 52 to select whether to paste “individual controls” or “link controls”.
When the “link operator” is pasted, the paste operator 47 performs link control on the values of all parameters belonging to the group set for the parameter assigned to the copy source operator 42. On the other hand, when the “individual operator” is pasted, the paste operator 47 controls only the parameters assigned to the copy source operator 42.

Although the operation is omitted in the flowchart of FIG. 7, the “link status display” button 53 displays the group setting status set in the parameter assigned to the copy source operation element 42 (for example, FIG. 4). For displaying the parameter link setting screen 21 shown in FIG. By looking at the display on the setting screen 21, the group configuration information of the group to which the parameter belongs can be confirmed.
The “OK” button 54 is a button for enabling the selection instruction and closing the screen, and the “Cancel” button 55 is a button for canceling the copy itself and closing the screen. Although not shown in FIG. 7, if the “Cancel” button is operated, the process is immediately terminated in S <b> 65.

In S65, when a link operator is selected, the process proceeds to S66, and the pasted operator 47 is arranged as a link operator.
One group set in advance is allocated to the link operator, and the values of all parameters belonging to the group are link-controlled according to the operation. Individual parameters are not directly assigned.
On the other hand, when an individual operator is selected, the process proceeds to S64, and the pasted operator 47 is arranged as an individual operator.
The individual operator is assigned a parameter, and only the value of the assigned parameter is controlled according to the operation.

After the operator is pasted, the user control screen 46 (preset operation panel) of the original preset component may be closed.
If the user control screen 46 (operation panel customized by the user) and the control screen 41 of the original preset component are displayed at the same time, the same parameter can be controlled by the operator on any screen.

As shown in FIG. 6B, an input channel input level setting operator 48, an output channel output level setting operator 49, and a 4-band EQ ON button 50 for controlling on / off of the function of the 4-band equalizer. By using a plurality of different preset components as a copy source, a plurality of different operators can be pasted on the user control screen 46.
As a result, the link-controlled parameters are not necessarily the same type. There are cases where complicated link control is performed such that conversion characteristics such as a parameter change range and a change characteristic curve with respect to an operation amount are different.
Even in such a case, it is possible to cope with the problem by storing the link configuration information represented by the linked parameter list 23 shown in FIG.
Also, when performing complex link control, it is easier to identify which operator has a link control function by using a dedicated link operator.

In the above description, the operator previously arranged on the preset control screen is copied and dragged on the user control screen 36 by a drag and drop operation.
However, the copy and paste operation can be performed according to other methods.
For example, in FIG. 6A, by detecting that the copy source operation element 42 arranged on the preset control screen 41 is selected by right-clicking the mouse, a pop-up menu is displayed. Lets you select an operation.
Next, the mouse pointer is moved to the user control screen 36. Here, when the right-click operation of the mouse is detected, either the “Paste as individual operation from menu” operation or the “Paste as link operation” operation displayed in the pop-up menu may be selected. .

FIG. 8 is a diagram showing an example of parameter conversion characteristics of individual operators and link operators.
FIG. 8A is an example of parameter conversion characteristics of an individual operator that controls only the value of the assigned parameter regardless of whether or not the assigned parameter belongs to a group.
The conversion characteristic of the parameter (1) value (usually the unit is dB) using the operation amount of the individual operator as an input value is shown as the parameter (1) conversion characteristic.

  For the parameter (1) conversion characteristic, for example, a parameter value (MIN end value) a at the minimum value of the input value and a parameter value (MAX end value) b at the maximum value are set, and the MIN as shown in FIG. It is defined as a straight line that passes through the end value and the MAX end value. Alternatively, as shown in the parameter link setting screen of FIG. 4, the position (CP) and level (CL) of the control point and its control ratio (CR) are set, and the control point is passed as shown in FIG. You may prescribe | regulate as a straight line which has the inclination according to CR.

FIG. 8B is a diagram showing parameter conversion characteristics when the operation element functions as a link operation element.
In the illustrated example, when a link operator assigned to the group to which the parameters (1), (2), and (3) belong is controlled, the parameter (1) is set according to the input value (operation amount) of the link operator. ), (2), and (3) are linked and change according to the parameter (1) conversion characteristic, the parameter (2) conversion characteristic, and the parameter (3) conversion characteristic, respectively.

If the individual controls of parameters (1), (2), and (3) are displayed at the same time, the display value of the movable part that indicates the operation position of the individual controls is set to the value of the link-controlled parameter. (The input value of the individual operation element also changes in conjunction with it.)
Conversely, when any of the individual controls of parameters (1), (2), and (3) is operated, the operation position and the value of the parameter assigned to the control change, but the link control It is preferable not to move the movable part according to the operation of the individual operation element (the input value of the link operation element does not change).

The conversion characteristics of the parameters (1), (2), and (3) may also be defined by the MIN end value and the MAX end value or by the above-described CP, CL, and CR. The group configuration information shown in the linked parameter list 23 shown in FIG. 4 is defined by the latter method.
In the above description, the conversion characteristic is a linear function (straight line) with the operation amount on the horizontal axis and dB on the vertical axis, but it is a quadratic function, cubic function, SIN function, logarithmic function, or any other function. It's okay.
In the above description, the parameter (1) conversion characteristic assigned when the link operator functions as an individual operator uses the same function when functioning as a link operator. However, it is not always necessary to match, and different conversion characteristics may be used.

In the prior art (Non-Patent Document 1), when a group to which a certain parameter belongs is set, there is no individual operator for individually operating that parameter.
On the other hand, in the embodiment of the present invention, an individual operator for individually operating parameters is prepared separately from the dedicated link operator.
For example, each operator on the preset control screen 41 shown in FIG. 6A has this parameter regardless of whether the parameter assigned to the operator belongs to one of the preset groups. It functions as an individual operator of.
Also, the paste operation element 47 on the user control screen shown in FIG. 6B is selected from the copy source operation element 42 by selecting “individual operation element” on the paste operation element selection screen 51 at the time of the paste. Similarly, it becomes an individual operator for controlling one parameter.

In such a control operation, when the value of one parameter included in a group is changed by an individual operator and then the link operator assigned to the group is operated, the value of the parameter is as shown in FIG. The link is controlled with the original parameter conversion characteristics of the same group as shown in FIG.
This is because the original parameter conversion characteristics are not changed by the operation of the individual operator. For example, in the data structure of the group configuration information corresponding to the linked parameter list 23 shown in FIG. 4, CP, CL, and CR are not changed even if they are individually operated.
However, when the value of one parameter included in a certain group is changed by an individual operator, the parameter value resulting from the individual control may be desired to be reflected in the subsequent link control.
For example, when a group is assigned to the paste operator 47 and pasted as a link operator, one parameter (1) of the group is finely adjusted by the individual operator 41 of the copy source control screen 41. Later, there was a demand to reflect this fine adjustment result in the conversion characteristics of the parameter (1) at the time of link control by the pasting operator 47.

In FIG. 8C, when the parameter conversion characteristic is defined by the MIN end value and the MAX end value, the value of the individually controlled parameter (1) is reflected in the subsequent link operator parameter conversion characteristic. FIG. 6 is a diagram showing an example (first example) for correcting the parameter conversion characteristics.
When the “current input value” of the link operator is at the position shown in the figure, the paste operator 47 is operated (individual operation), and the parameter (1) is changed by “delta” from the value before correction, It is assumed that the value has been changed individually.
In this case, the “corrected conversion characteristic” is changed by “delta” as a whole. That is, when the parameter conversion characteristic is defined by the MIN end value a and the MAX end value b, “delta” is absorbed by the common offset of the MIN end value and the MAX end value. Specifically, the MIN end value is “a + delta” and the MAX end value is “b + delta”. The control ratio (CR) does not change.

FIG. 8D is a diagram showing an example (second example) of correcting the parameter conversion characteristic when the parameter conversion characteristic is defined by CP, CL, and CR.
It is assumed that the pasting operator 47 is controlled (individually operated), and the parameter (1) is changed by “delta” from the value before correction to become “individually changed value”.
“Conversion characteristics after correction” shifts the entire control point by “delta” by changing the control point level (CL) without changing the control point position (CP) and the slope (CR) of the conversion characteristic there. Like that. As shown in FIG. 4, when the control point level offset (CLoff) parameter is prepared separately from the CL, the “CLoff” is changed by “delta” without changing the CL itself.

FIG. 8E is a diagram showing another example (third example) in which the parameter conversion characteristics are similarly corrected when the parameter conversion characteristics are defined by CP, CL, and CR.
It is assumed that the pasting operation element 47 is controlled (individually operated) and the parameter (1) is changed to “individually changed value” from the value before correction.
“Conversion characteristics after correction” changes the control ratio to “CR + delta” without changing CP and CL. However, the “corrected conversion characteristic” is a characteristic that passes through the “individually changed value” in the “current input value” of the link operator.
“Conversion characteristics after correction” changes the control ratio (CR) by “delta” without changing the position (CP) and level (CL) of the control point, and changes the slope of the conversion characteristic at that control point. When the control ratio offset (CRoff) parameter is prepared separately from the CR as shown in FIG. 4, the “CRoff” is changed by “delta” without changing the CR itself.

FIG. 9 is a flowchart illustrating an example of a parameter conversion operation when an operator that functions as an individual operator and an operator that functions as a link operator are operated.
FIG. 9A is a flowchart when an operation event of the individual operator (i, j, k) is detected. i is the engine number (DSP unit number), j is the component number, k is the parameter number, and the individual operator (i, j, k) is the i-th engine in the operation parameters stored in the current scene. This is an operator to control the kth parameter of the jth component of the signal processing based on the CAD data being executed at This process is executed only in the online mode.

In S71, it transmits the data of the detected operation event to the engine 112 _1. Operation event as long as the other engine number, transmitted from the engine 112 ₁ to the engine.
In S72, the value of the parameter indicated by (i, j, k) in the current scene of the personal computer 111 is changed according to the input value (operation amount) of the operation element from which the detected operation event is detected. .
Also on the i-th engine side, the parameter value of the current scene is similarly changed based on the transmitted operation event data, and signal processing in the engine is controlled according to the changed parameter.

FIG. 9B is a flowchart illustrating an example of an operation when an operation event of the link operator is detected.
In S81, it is determined whether or not linked parameters (parameters belonging to the same group) have been individually changed. For example, the parameters are individually changed when the pasting operator 47 shown in FIG. 6B is controlled and operated as an individual change operator.
When there is a change in S82, the process proceeds to S83, and when there is no change, the process proceeds to S84.

In S83, a dialog display “Individual change, reflect in link setting?” Is displayed. If the user inputs YES in S85, the process proceeds to S86, and the conversion characteristics are corrected according to the individually changed parameter values as shown in FIGS. 8C to 8E.
In S87, it transmits the data of the corrected parameter conversion characteristic engine that relationship engine 112 ₁ side. In the current scene of the engine to which the corrected parameter conversion characteristic data is transmitted, the parameter value is subsequently changed according to the corrected parameter conversion characteristic.

In S84, it transmits the data operation event of the detected link operator to the engine 112 _1. This data is also transmitted to all engines ahead. In each engine to which the operation event data of the link operator is transmitted, if the parameter change information of the link operator group includes the parameter change information of the engine, the data of the operation event and the parameter change thereof are included. The parameter value of the current scene is changed based on the information, and signal processing in the engine is controlled according to the changed parameter.
In S88, the first parameter of the linked parameters is prepared. For example, when this step is reached without individual change, the parameter (1) having the characteristics shown in FIG. 8B is prepared.

In S89, the input value of the operator is converted into a parameter value according to the conversion characteristic of the first parameter.
In S90, the parameter value in the current scene of the personal computer 111 is changed to the converted parameter value.
In S91, the following parameters are prepared. In S92, if there is a next parameter, the process returns to S89, and steps S89 to S92 are repeated for the next parameter.
For example, when this step is reached without individual changes, the steps S89 to S92 are repeated for the characteristic parameter (2) shown in FIG. 8B. If there is no next parameter, the process is terminated.

In the description with reference to FIG. 9B, when there is an individual change, when the link operator is controlled, a first inquiry is made as to whether or not to correct the conversion characteristics of the individually changed parameter. The method was adopted.
On the other hand, even if there is an individual change, a second method that does not uniformly correct the conversion characteristics of the individually changed parameters may be adopted. Alternatively, if there is an individual change, a third method for uniformly correcting the conversion characteristics of the individually changed parameters may be employed. Any one of the methods may be selected in the environment setting performed in advance.

The “parameter link correction” button 19 in FIG. 3 and the “parameter link correction” button 24 in FIG. 4 are provided, and correction can be performed by selecting them with the mouse.
FIG. 9C is a flowchart showing an example of the operation when the operation of the “parameter link correction” buttons 19 and 24 described above is detected.
However, the “parameter link correction” buttons 19 and 24 are buttons that can be operated only when the parameters belonging to the group are individually changed. While there is no individual change of the parameter, for example, “grayed out” is displayed so that it cannot be selected.

In S101, the corresponding conversion characteristic is corrected by the method shown in FIGS. 8C to 8E in accordance with the individually changed parameter value, and in S102, this correction is transmitted to the engine. (Same as S86 and S87).
In S103, the individual change of linked parameters is set to “none”. As a result, the “parameter link correction” buttons 19 and 24 are displayed as “grayed out”, and in S82 of FIG. 9B, it is determined that there is no change.

In the above description, when the parameter value is link-controlled by the link operator, the operation position of the individual operator also moves. When the parameter value is again individually controlled by the individual operator, the value changed according to the link control characteristics. Was controlled individually.
Instead, when the parameter value is link-controlled by the link operator, the operation position of the individual operator is not moved, and the input value of the individual operator shown in FIG. 8A is not changed. Also good. Again, when individual control is performed by the individual operator, individual control is performed starting from the parameter value before link control.

In the description with reference to FIG. 6, it is assumed that the existing operator on the preset control screen 41 is copied and pasted on the user control screen 46.
However, the operator on the user control screen 46 may be pasted on the same or another user control screen. In this case, if the copy source operation element is an individual operation element, it may be pasted by the same process as in FIG.

It is a functional block diagram for demonstrating one Embodiment of this invention. It is explanatory drawing of the data structure by the side of the personal computer for implement | achieving one Embodiment shown in FIG. It is explanatory drawing which shows a specific example of the configuration screen displayed when the editing program is executed with the personal computer. It is explanatory drawing which shows the setting screen of a parameter link. It is explanatory drawing which shows the program outline | summary which implement | achieves one Embodiment which showed the function structure in FIG. It is explanatory drawing of operation of drag-and-drop of the operation element to the user control screen. 7 is a flowchart for explaining an operation example when a drop operation is performed on the user control screen shown in FIG. 6. It is a diagram which shows the parameter conversion characteristic example of an individual operation element and a link operation element. It is a flowchart which shows an example of parameter conversion operation | movement when operating the operation element which functions as an individual operation element, and the operation element which functions as a link operation element. It is a block block diagram for demonstrating the conventional audio mixing system. It is a block block diagram which shows an example of the hardware configuration of the engine shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Control operation detection part, 2 ... Parameter control part, 3 ... Parameter memory, 4 ... Manipulator operation position display control part, 5 ... Parameter link control characteristic correction part, 6 ... Parameter link correction instruction part

Claims (3)

A control program for an acoustic signal processing device that causes a computer to realize a function of controlling the values of a plurality of parameters stored in a parameter memory in response to operations of a plurality of operators displayed on an operation screen,
A group including at least one of the plurality of parameters, and a group and link characteristic setting step for setting a link characteristic according to a link operator operation of a parameter belonging to the group;
A control operation detecting step of detecting an operation event of the operation element;
When the operation element in which the operation event is detected by the control operation detection step is an individual operation element to which one parameter of the plurality of parameters is assigned, according to the control operation of the individual operation element, Control only the value of the parameter assigned to the individual operator in the parameter memory; and
When the operation element for which the operation event is detected by the control operation detection step is a link operation element to which a set group is assigned, the operation unit in the parameter memory corresponds to the control operation of the link operation unit. A parameter control step for link-controlling the values of all parameters belonging to the group according to the set link characteristics;
When the parameter assigned to the individual operator is individually controlled according to the control operation of the individual operator, the link operator to which the group to which the individually controlled parameter belongs is assigned as the operation of the link operator. Displaying on the operation screen so that the position does not move;
A program for controlling an acoustic signal processing device, comprising: When the values of all the parameters belonging to the group are link-controlled in accordance with the control operation of the link operator, the individual operator assigned to each parameter belonging to the group is the link-controlled value of the parameter. According to the step of displaying on the operation screen so that the operation position of the individual operator moves,
The computer program for controlling an acoustic signal processing device according to claim 1, comprising: When the parameter assigned to the individual operator is individually controlled according to the control operation of the individual operator, the link of the parameter is determined based on the changed value of the individually controlled parameter according to a user instruction. Parameter link correction step for correcting characteristics,
The computer program for controlling an acoustic signal processing device according to claim 1, wherein:

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