JP2008252171A - Acoustic equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To send a signal from an arbitrary point in a main path to a sub-bus, and to perform a signal processing of different contents from the main path in the sub-path. <P>SOLUTION: A first selection switch SW1 selects and sends a signal from an arbitrary point in a plurality of processing units 30 to 35 to a MIX bus 37, and a second processing unit comprising a plurality of processing units 39 to 41 performing mutually different kinds of signal processing and a send level adjusting unit 42 which adjusts the send level of an input signal sent to the MIX bus 37 are inserted into the sub-path. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an audio device including an input channel that performs signal processing on an input signal and outputs the processed signal to a mixing bus.

Conventionally, there is known an acoustic device called a mixer used in a concert hall or the like that adjusts and mixes the level and frequency characteristics of audio signals output from a large number of microphones or electric / electronic musical instruments and sends them to a power amplifier. . The operator operating the mixer adjusts the volume and tone of each audio signal of the instrument sound and singing to the state that seems to best represent the performance by operating various panel controls on the mixer. . The mixing apparatus includes a plurality of input channels as input signal sequences, a bus for mixing signals output from the input channels, and an output channel that is an output sequence for outputting the mixed signals. Each input channel controls the frequency characteristics and mixing level of the input signal and outputs it to each mixing bus, and each mixing bus mixes the input signal and outputs it to the corresponding output channel. The output from the output channel is amplified and emitted from a speaker or the like.
JP 2007-43249 A

FIG. 9 shows the configuration of a bus for mixing with an input channel in a conventional mixer.
In the input channel, signal processing modules that perform different signal processing of Φ130, ATT131, HPF132, PEQ133, GATE134, COMP135, and FADER136 are cascaded and connected to the main path. Φ130 is a phase shifter that performs a process of switching the phase of the input signal, and ATT 131 is a level controller that performs a process of attenuating or amplifying the level of the input signal. The HPF 132 is a high-pass filter that performs a process of removing a low frequency component from a specific frequency, and the PEQ 132 is a parametric equalizer that performs a process of adjusting a frequency characteristic of an input signal. GATE 134 is a gate that performs a process of rapidly decreasing the output level when the input level becomes lower than the threshold level, and COMP 135 is a compressor that performs a process of compressing the dynamic range of the signal. FADER 136 is a fader that performs processing for adjusting the input level of the channel. When the channel belongs to the DCA group, it is also operated by a DCA fader that collectively operates the levels of a plurality of channels belonging to the DCA group.

  An input signal output from the FADER 136 is supplied to the pan PAN 1 via a switch ON for switching the channel on / off, and the L and R signals in which the localization of the sound image is set are supplied to a stereo bus (ST bus) 138 which is a main bus. Supplied respectively. Further, the signal from the first selection switch SW1 constituting the sub path is panned via a first send level adjuster (MIX SEND1) 139 for adjusting the send level of the signal sent to the mixing bus (MIX bus) 137. The L and R signals, which are supplied to the PAN 2 and set the localization of the sound image, are supplied to two buses of the MIX bus 137 that is a sub bus. The first selection switch SW1 includes a post-comp signal (PC) via COMP 135, a post-fader signal (PF) via FADER 136, and a post high-pass signal (PH) via HPF 132. Either signal is selected. Further, the signal from the second selection switch SW2 constituting another sub-path is sent to the pan PAN3 via the second send level adjuster (MIX SEND2) 140 that adjusts the send level of the signal sent to the MIX bus 137. The L and R signals to which the sound image localization is set are supplied to two buses of the MIX bus 137 as a sub bus. The second selection switch SW2 also includes a post-comp signal (PC) via COMP 135, a post-fader signal (PF) via FADER 136, and a post high-pass signal (PH) via HPF 132. Either signal is selected.

  Here, when a post-comp signal or a post-fader signal is selected by the selection switches SW1 and SW2, and an input signal is sent to the MIX bus 137, an equalizer process by the PEQ 132, a gate process by the GATE 134, and a compressor by the COMP 135 are applied to the input signal. Each signal processing of the processing is performed. In this case, there is a case where it is desired to perform signal processing having a different content from the main route in the sub route, but there is a problem that such signal processing cannot be performed. Further, when a post high pass signal (PH) is selected by the selection switches SW1 and SW2 and sent to the MIX bus 137, there is a problem in that the signal cannot be subjected to equalizer processing, gate processing and compressor processing. there were. Further, there are only three types of points for selecting an input signal to be sent to the MIX bus 137, and there is a problem that a signal from an arbitrary point on the main path cannot be sent to the MIX bus 137.

  SUMMARY OF THE INVENTION An object of the present invention is to provide an audio device that can send a signal from an arbitrary point on a main route to a sub-bus, and can perform signal processing of contents different from those of the main route on the sub-route.

  In order to achieve the above object, the audio equipment of the present invention selects at least one sub-route that selects a signal from an arbitrary point in the first processing unit provided in the main route to be sent to the main bus and sends it to the sub-bus. The second processing unit is inserted into the sub-path, and the type of signal processing performed by the second processing unit corresponds to the type of signal processing performed by the first processing unit. Main features.

  According to the present invention, there is provided at least one sub route for selecting a signal from an arbitrary point in the first processing unit provided in the main route to be sent to the main bus and sending the selected signal to the sub bus. Since the two processing units are inserted and the type of signal processing performed by the second processing unit corresponds to the type of signal processing performed by the first processing unit, it is provided in the main route to be sent to the main bus. The signal sent from the arbitrary point of the first processing unit to the sub-bus and the signal sent from the arbitrary point to the main bus in the second processing unit can be sent to the main path by the second signal processing unit. It becomes possible to perform signal processing with different contents.

FIG. 1 is a block diagram showing a schematic configuration of an audio device such as a mixer according to an embodiment of the present invention.
The audio device 1 shown in FIG. 1 includes a signal processing circuit 2 that performs mixing processing when a mixer is used, and a processing circuit 3 that controls mixing processing. The processing circuit 3 includes a CPU (Central Processing Unit), controls the mixing process according to an operation signal from the operation element 6 that performs the mixing operation, and displays an operation screen or the like on which various settings can be made on the display unit 7. Yes. The signal processing circuit 2 includes a DSP (Digital Signal Processor), performs a mixing process on the audio signals of a plurality of input sequences input from the audio signal input circuit 4 according to a control signal from the processing circuit 3, and outputs a plurality of output sequences. To the audio signal output circuit 5.

Next, the block diagram which shows the detailed structure of the audio equipment 1 concerning this invention is shown in FIG.
In FIG. 2, a CPU (Central Processing Unit) 10 constitutes a processing circuit 3, and controls the overall operation of the audio equipment 1 and displays a drawing program for displaying an operation screen for performing various settings on the display 16. Operating software such as a control program is executed. A ROM (Read Only Memory) 11 stores operation software such as a drawing program executed by the CPU 10 and a control program, and a RAM (Random Access Memory) 12 stores a work area of the CPU 10 and a storage area for various data. Is set. By making this ROM 11 a rewritable ROM such as a flash memory, the operation software can be rewritten and the operation software can be easily upgraded. The DSP 13 constitutes a signal processing circuit 2 that performs a plurality of types of signal processing, and performs a plurality of types of signal processing on a plurality of input series audio signals as described above.

  The detection circuit 15 detects an event of the operation element 14 by scanning the operation element 14 such as a panel operation element, and outputs an event output corresponding to the operation element 14 having the event. The operation element 14 includes an operation element for controlling the characteristics of the input signal of each channel and a number of operation elements for switching scenes. The operator 14 can set or adjust parameter values such as phase processing, level processing, and frequency characteristic processing of the input signal performed by the DSP 13. The display circuit 17 includes a display 16 such as a liquid crystal display (LCD), and an operation screen for setting the type of signal processing applied to the input signal of each channel is displayed on the display 16. For various operations, a user can perform setting operations on an operation screen using a GUI (Graphical User Interface). The communication interface (I / F) 19 is an interface for connecting the external device 18, and the acoustic device 1 and the external device 18 are logically connected via this interface. The audio signal input circuit 21 corresponds to the audio signal input circuit 4 shown in FIG. 1 and takes in an audio signal from the input unit 20 such as a microphone for taking in external sound into the audio equipment 1, and the audio signal output circuit 23 is shown in FIG. 1 corresponds to the audio signal output circuit 5 shown in FIG. 1 and outputs an acoustic signal that has been subjected to signal processing, such as mixing processing, output from the acoustic device 1 to an output unit 22 such as an external speaker to emit sound. The input unit 20 can be an input unit that inputs a microphone / line audio signal, and the output unit 22 can be an output unit that emits sound from a speaker or the like. These units are connected to a communication bus 24 and exchange data via the communication bus 24.

Next, FIG. 3 shows a block diagram showing a configuration of a bus that performs mixing with the input channel in the audio device 1.
In the input channel, a first processing unit composed of a plurality of signal processing modules of Φ30, ATT31, HPF32, PEQ33, GATE34, COMP35, and FADER36 is connected to a main path that is sent to a stereo bus (ST) 38 that is a main bus. ing. Different types of signal processing are applied to the input signal by a plurality of cascaded signal processing modules in the first signal processing unit. Here, Φ30 is a phase shifter that performs a process of switching the phase between the positive phase and the reverse phase of the input signal, and ATT31 is a level controller that performs a process of attenuating or amplifying the level of the input signal. The HPF 32 is a high-pass filter that performs processing for removing low frequency components from a specific frequency, and the PEQ 32 performs processing for adjusting the frequency characteristics of the input signal. For example, a parametric equalizer having four bands of HIGH, HIGH MID, LOW MID, and LOW. It is said that.

  Also, GATE 34 performs gate processing for abruptly decreasing the output level when the input level falls below the threshold level, or ducking processing for dynamically reducing the signal gain, and COMP 35 is a compressor for compressing the dynamic range of the signal, and signal dynamics. An expander that expands the range or a limiter that suppresses the maximum signal level to the set level is performed. The FADER 36 to which the signal from the COMP 35 is input is a fader that performs a process of adjusting the input level of the input channel. When the input channel belongs to the DCA group, the levels of the plurality of input channels belonging to the DCA group are set. It is also operated by a DCA fader that operates collectively. The input signal output from the FADER 36 is supplied to the pan PAN1 through the switch ON for switching on / off of the input channel, and the L and R signals whose sound image localization is set by the pan PAN1 are the main buses of the ST bus 38. L and R are respectively supplied.

  In the input channel, “path 1” and “path 2” are provided as sub-paths for supplying input signals to the MIX bus 37 serving as a sub-bus. In “Route 1”, the first selection switch SW1 selects an arbitrary point of the plurality of signal processing modules in the first signal processing unit. That is, a post-fader signal (PF) via FADER 36, a post-comp signal (PC) via COMP 135, a post-gate signal (PG) via GATE 34, and a post-equalizer signal (P) via PEQ 33 .P) and the post high pass signal (P.H) via the HPF 32, the first selection switch SW1 selects any one of them. In addition, the “path 1” adjusts the second signal processing unit composed of a plurality of signal processing modules for performing different types of signal processing of PEQ 39, GATE 40, and COMP 41, and the send level of the signal sent to the MIX bus 37. A first send level adjuster (MIX SEND1) 42 is inserted. In this case, the types of signal processing performed by the PEQ 39, the GATE 40, and the COMP 41 correspond to the PEQ 33, the GATE 34, and the COMP 35 in the first signal processing unit. Then, the signal selected by the first selection switch SW1 is supplied to the second signal processing unit, each type of signal processing is performed by each signal processing module, and the localization of the sound image is set in the pan PAN2. The L and R signals are supplied to two of the MIX buses 37 which are sub-buses.

  Also, the PEQ 39, GATE 40, and COMP 41 in the second signal processing unit have the same parameter values as the parameter values set in the corresponding PEQ 33, GATE 34, and COMP 35 in the first signal processing unit, or arbitrarily set parameters. Can be set by specifying one of the values. Furthermore, each signal processing function can be turned off by bypassing each signal processing module of PEQ39, GATE40, and COMP41 in the second signal processing unit. As a result, regardless of which point is selected by the first selection switch SW1, the selected signal can be subjected to equalizer processing, gate processing, and compressor processing and sent to the MIX bus 37, which is a sub-bus. In this case, by setting parameter values different from the parameter values set in the first signal processing unit to the plurality of signal processing modules in the second signal processing unit, signals having different signal processing contents from the main path Processing can be performed in the second signal processing unit.

  Next, “path 2” has the same configuration as “path 1”, and the second selection switch SW2 also selects an arbitrary point in the first signal processing unit. That is, a post-fader signal (PF) via FADER 36, a post-comp signal (PC) via COMP 135, a post-gate signal (PG) via GATE 34, and a post-equalizer signal (P) via PEQ 33 ., P) and the post high-pass signal (P.H) via the HPF 32, the second selection switch SW2 selects any one of them. In “path 2”, a third signal processing unit including a plurality of signal processing modules for performing different types of signal processing of PEQ 43, GATE 44, and COMP 45, and a send level of a signal sent to the MIX bus 37 are adjusted. A second send level adjuster (MIX SEND2) 46 is inserted. In this case, the types of signal processing performed by the PEQ 43, GATE 44, and COMP 45 correspond to the PEQ 33, GATE 34, and COMP 35 in the first signal processing unit. Then, the signal selected by the second selection switch SW2 is supplied to the third signal processing unit, and different types of signal processing are performed by each signal processing module. Further, the L and R signals for which the localization of the sound image is set in the pan PAN 3 are respectively supplied to two buses of the MIX bus 37 which is a sub bus.

  Also, the PEQ 43, GATE 44, and COMP 45 in the third signal processing unit have parameter values that are the same as the parameter values set in the corresponding PEQ 33, GATE 34, and COMP 35 in the first signal processing unit, or parameters that are arbitrarily set. Can be set by specifying one of the values. Furthermore, each signal processing function can be turned off by bypassing each signal processing module of PEQ43, GATE44, and COMP45 in the third signal processing unit. As a result, regardless of which point is selected by the second selection switch SW2, the selected signal can be subjected to equalizer processing, gate processing, and compressor processing, and can be sent to the MIX bus 37, which is a sub-bus. In this case, by setting a parameter value different from the parameter value set in the first signal processing unit to each signal processing module in the third signal processing unit, the signal processing content differs from that of the main path. Can be performed in the third signal processing unit.

The MIX bus 37 and the ST bus 38 are selectively supplied and mixed with the input signals that have been subjected to the signal processing by the first to third signal processing units from a plurality of input channels. The mixing signals mixed in the MIX bus 37 and the ST bus 38 are output to a plurality of output channels (not shown). Although not shown, each output channel is provided with cascaded signal processing modules such as the equalizer processing, compressor processing, and fader processing described above, and the signal processing is performed on the mixing signal by the plurality of signal processing modules. The The output signal that has been subjected to signal processing and output from the output channel is output from the audio signal output circuit 23 and emitted from a speaker or the like in the output unit 22.
As described above, in the audio device 1 of the present invention, the type of signal processing applied to the signal sent to the MIX bus 37 and the reflected parameter are set in the first selection switch SW1 or the second selection switch SW2. Even if any point is selected, it can be varied. As described above, even when a signal from the point selected by the first selection switch SW1 or the second selection switch SW2 is sent to the MIX bus 37, a lot of signal processing can be performed and arbitrary parameters can be reflected. Therefore, a more flexible operation is possible, and it becomes possible to meet the demands of more users.

  By the way, PEQ39, GATE40, COMP41 in the second signal processing unit and PEQ43, GATE44, COMP45 in the third signal processing unit can designate turning on / off the respective signal processing modules. FIG. 4 shows an example of a setting list table displayed on the display 16 when making this designation. The setting list table shown in FIG. 4 is a setting list indicating the setting of ch1 when input channel 1 (ch1) is selected from the input channels. In this setting list, the “Bus” column designates a route to be sent to the MIX bus 37. In this case, sub-routes MIX1, MIX2, MIX3,... Any of the sub-routes can be specified. The “Point” column specifies the point at which the signal to be sent to the MIX bus 37 is taken out. Post-fader signal (Post Fader: PF), post-comp signal (Post Comp (Pre Fader): PC), post-gate Signal (Post Gate (Pre Comp): PG), post equalizer signal (Post PEQ (Pre Gate): PP), or post high pass signal (Post HPF (Pre PEQ): PH) Can be specified.

  Each column of “PEQ”, “GATE”, and “COMP” designates ON / OFF of each signal processing module that performs equalizer processing, gate processing, and compressor processing. When ON is designated, a synchronous setting (On (Synchronization) is set in the corresponding signal processing module with a parameter value equal to the parameter value set in PEQ33, GATE34, and COMP35 in the first signal processing unit. )) Or individual setting (On (Individual)) for arbitrarily setting the parameter value regardless of the parameter value set in each signal processing module of the first signal processing unit can be specified. . When OFF is specified, the specified signal processing module is bypassed (Off (Bypass)).

  In the example of the setting list table shown in FIG. 4, a post high-pass signal (Post HPF (Pre PEQ): PH) is designated as a signal to be sent from the sub-path of MIX 1 to the MIX bus 37 in ch1, and “PEQ ”Is specified as an individual setting (On (Indivi)) that specifies parameter values individually, and“ GATE ”is also specified as an individual setting that specifies parameter values individually (On (Indivi) )) Is specified, and “COMP” is set to ON, and a synchronous setting (On (Synchro)) for setting a parameter value equal to the parameter value set in COMP 35 is specified. Further, a post gate signal (Post Gate (Pre Comp): PG) is designated as a signal sent from the MIX 2 sub-path to the MIX bus 37, and “PEQ” and “GATE” are off (bypass). “COMP” is designated as ON, and an individual setting (On (Indivi)) for individually setting parameter values is designated. Further, a post-fader signal (Post Fader: PF) is designated as a signal sent from the sub-path of MIX 3 to the MIX bus 37, and “PEQ”, “GATE” and “COMP” are turned off (bypass). It is specified.

  FIG. 5A shows an example of a window that opens on the display device 16 when specifying in the “Point” column in the setting list table shown in FIG. This window shows the window opened by clicking `` ▼ '', Post HPF (Pre PEQ), Post PEQ (Pre Gate), Post Gate (Pre Comp), Post Comp (Pre Fader), Post Fader You can select any of the following. In the example shown in the figure, Post HPF (Pre PEQ) is selected and the post high pass signal (P.H) is designated. FIG. 5B shows an example of a window that opens on the display device 16 when making a designation in the “PEQ” column in the setting list table shown in FIG. This window shows a window opened by clicking “▼”, and one of Off (Bypass), On (Synchronization), and On (Individual) can be selected. In the illustrated example, Off (Bypass) is selected and off (bypass) is designated. Although not shown in the figure, the window that opens when specifying in the “GATE” and “COMP” fields is the same as the window shown in FIG.

Next, FIG. 6 shows a flowchart of bus send signal creation processing for creating a signal to be sent to the MIX bus 37 executed for each channel in the audio equipment 1 according to the present invention.
The bus send signal creation process is activated when the timing to be activated periodically is reached, or when the power of the audio device 1 is turned on, and is sent to the MIX bus 37 from each sub-path of the set input channel. The type and parameter value of signal processing to be applied to the points and signals are determined in step S10 with reference to the setting list table shown in FIG. In this case, the signal processing type of the signal processing module that is set to ON in the setting list table is determined, and the parameter value is determined according to whether ON is set to On (Synchronization) or On (Individual). The Next, in step S11, the bus send level set in the send level adjuster (MIX SEND) in the channel is determined as the send level to be sent to the MIX bus 37. In this case, when there are two or more sub routes, the bus send level set in the send level adjuster (MIX SEND) is determined for each sub route. And the parameter value acquired in the process of step S10 and step S11 is set to a register as a coefficient. The coefficient set in the register is set in each signal processing module of each sub-path, but is actually used as a parameter value when the DSP 13 performs signal processing. As a result, the bus send signal creation process ends.

Next, FIG. 7 shows a flowchart of the signal processing determination process executed in step S10 in the bus send signal creation process.
When the signal processing determination process starts, the signal processing setting is acquired by referring to the setting list table shown in FIG. 4 in step S20. Next, a point (Send Point) sent from the plurality of signal processing modules in the first signal processing unit to the MIX bus 37 based on the content of the acquired signal processing setting is acquired for each sub-path in step S21. Furthermore, the setting content of the signal processing module “PEQ” inserted in the sub-path based on the acquired signal processing setting content is acquired in step S22. The setting content acquired here is whether On (Synchronization), On (Individual), or Off (Bypass) is set, and if it is set to On, the parameter value to be set for the signal processing module Also get. Furthermore, the setting contents of the signal processing modules “GATE” and “COMP” are acquired in step S23 and step S24 based on the acquired signal processing setting contents. The setting content acquired here is also whether On (Synchronization), On (Individual), or Off (Bypass) is set, and if it is set to On, the parameter value to be set for the signal processing module Also get. Next, a coefficient is created in step S25 based on the send point acquired in step S21 and the parameter value acquired in steps S22 to S24, and the signal processing determination process ends. When Off (Bypass) is acquired as the setting content acquired in step S22 to step S24, a coefficient that bypasses the signal processing module is created.

Next, FIG. 8 shows a flowchart of PEQ setting acquisition processing executed in step S22 in the signal processing determination processing.
When the PEQ setting acquisition process starts, the “PEQ” column in the setting list table shown in FIG. 4 is referred to in step S30, and the “PEQ” setting is acquired for each sub-path. Taking the setting list in the table shown in FIG. 4 as an example, On (Individual) is acquired for the sub-path of MIX1, and Off (Bypass) is acquired for the sub-path of MIX2 and MIX3. If On (Individual) is acquired as the setting content, the process branches to step S31, and the parameter value set in “PEQ” of the sub route is acquired. If On (Synchronization) is acquired as the setting content, the process branches to step S32, and the parameter value set in the PEQ 33 of the main route is acquired. Further, when Off (Bypass) is acquired as the setting content, the PEQ setting acquisition process ends. Note that the PEQ setting acquisition process also ends when the processes of step S31 and step S32 are completed.
The flowchart of the GATE setting acquisition process and the COMP setting acquisition process executed in step S23 and step S24 in the signal processing determination process is the same as the flowchart of the PEQ setting acquisition process shown in FIG.

In the present invention described above, the acoustic device is a mixer, but the present invention is not limited to this, and can be applied to a general-purpose acoustic device that handles audio signals.
In the input channel, two sub-paths of “path 1” and “path 2” are provided as paths for supplying an input signal to the MIX bus 37. However, the present invention is not limited to this, and three or more sub-paths are provided. This path may be provided for each input channel.

It is a block diagram which shows the structure of the outline | summary of the audio equipment concerning the Example of this invention. It is a block diagram which shows the detailed structure of the audio equipment concerning the Example of this invention. In the audio equipment concerning the Example of this invention, it is a block diagram which shows the structure of the bus | bath which mixes with the input channel in an audio equipment. It is a figure which shows the example of the table of the setting list of the set input channel in the audio equipment concerning the Example of this invention. FIG. 5 is a diagram showing an example of a window that is opened when designation is made in the “Point” and “PEQ” fields in the table of setting lists of input channels shown in FIG. 4. It is a flowchart of the bus send signal preparation process which produces the signal sent to the MIX bus | bath performed for every channel in the audio equipment concerning the Example of this invention. It is a flowchart of the signal processing determination process performed in step S10 of the bus send signal creation process performed in the audio equipment of the Example of this invention. It is a flowchart of the acquisition process of PEQ setting performed in step S22 of the signal processing determination process performed in the audio equipment of the Example of this invention. It is a block diagram which shows the structure of the bus which mixes with the input channel in the conventional mixer.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Audio equipment, 2 Signal processing circuit, 3 Processing circuit, 4 Audio signal input circuit, 5 Audio signal output circuit, 6 Operator, 7 Display, 10 CPU, 11 ROM, 12 RAM, 13 DSP, 14 Operator, 15 Detection circuit, 16 display, 17 display circuit, 18 external device, 19 communication I / F, 20 input unit, 21 audio signal input circuit, 22 output unit, 23 audio signal output circuit, 24 communication bus, 30 Φ, 31 ATT , 32 HPF, 33, 39, 43 PEQ, 34, 40, 44 GATE, 35, 41, 45 COMP, 36 FADER, 37 MIX bus, 38 ST bus, 42 1st send level adjuster, 46 2nd send Level adjuster, PAN1 to PAN3 Pan, SW1 first selection switch, SW2 second selection switch

Claims (3)

A mixing bus having a main bus and a sub-bus for mixing;
A plurality of input channels that perform signal processing on each of the input signals and selectively output to the main bus and the sub bus,
In each of the input channels, a first processing unit including a plurality of processing units that perform different types of signal processing on the input signal is provided in a main path that is sent to the main bus, and the first processing unit includes: A second process comprising a plurality of processing units each provided with at least one sub-path for selecting a signal from an arbitrary point of the plurality of processing units and sending the selected signal to the sub-bus; And a send level adjusting means for adjusting the send level of the input signal sent to the sub-bus,
A type of signal processing performed by the second processing unit corresponds to a type of signal processing performed by the first processing unit.   For each processing unit in the second processing unit, a parameter value set in a corresponding type of processing unit in the first processing unit or an arbitrary parameter value may be selected and set. The audio device according to claim 1, wherein the audio device is configured to be able to perform the operation.   The acoustic apparatus according to claim 1, wherein a setting for bypassing each processing unit in the second processing unit can be performed.

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