JP2004207826A - Control method of mixing system, and control apparatus and program for mixing system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a digital mixing system for outputting signals of a plurality of input channels to a plurality of MIX buses capable of efficiently setting the mixing state of signals of multi-systems. <P>SOLUTION: Keys 202, 204 select the operating mode of a bus operating unit 200. A plurality of rotary encoders 218 in a mix send mode act like operating elements for adjusting the signal gain of each input channel supplied to a designated MIX bus. Further, each encoder 218 in a mix master mode acts like an operating element for adjusting the output gain of each MIX bus. Moreover, a SEL key 222 in the mix master mode acts like a key for designating a channel wherein detail setting such as sound quality are performed. In addition, when a CUE key 224 is operated in the mix mater mode and reaches an ON state, the SEL key 222 is set to an On state interlocked with the operation. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a mixing system control method, a mixing system control device, and a program suitable for a mixing system having a large number of monitor signal systems.
[0002]
[Prior art]
2. Description of the Related Art In recent years, digital mixing systems have become widespread, particularly for professional audio equipment. In this system, all audio signals collected from a microphone or the like are converted into digital signals, and a mixing process is performed in an engine constituted by a DSP array or the like. Here, the audio signal output by the mixing system includes not only an audio signal emitted to a concert hall or the like, but also a monitor signal for a performer. In particular, when performing an ensemble concert or the like, since the demands for monitor signals are different for each player, it is required to supply different monitor signals according to the demands of each player. In order to meet such a demand, a mixing system capable of outputting monitor signals of several tens of systems is also known. A mixing system that outputs monitor signals of multiple systems in this way is disclosed in, for example, Non-Patent Document 1.
[0003]
[Non-Patent Document 1] "CS1D CONTROL SURFACE Instruction Manual" Yamaha Corporation, December 2000 [0004]
[Problems to be solved by the invention]
By the way, when outputting a multi-system monitor signal in this way, an operator (operator) of the mixing system must set the mixing state of each monitor signal according to each player's request. There was a problem that the burden would be enormous. The present invention has been made in view of the above circumstances, and provides a mixing system control method, a mixing system control device, and a program that can efficiently set a mixing state of multi-system signals and reduce the burden on an operator. It is intended to be.
[0005]
[Means for Solving the Problems]
In order to solve the above problems, the present invention is characterized by having the following configuration. The contents in parentheses are examples.
In the control method of the mixing system according to the first aspect, the signals of the plurality of input channels are supplied to the plurality of mixing buses (32) via the corresponding input channel adjusting units (30-1 to 30-24). A mixing algorithm for executing an algorithm for outputting the signals mixed in each of the mixing buses (32) as signals of a plurality of output channels via output channel sections (36-1 to 36-24) corresponding to the respective mixing buses. In the control method of the system, a setting channel selecting step of selecting one mixed bus (32-k) to be adjusted from among the plurality of mixed buses (32) (pressing of a MIX bus selecting key 109-k); It is selected by a send level adjusting operator (rotary encoder 514 in the normal mode) provided for each input channel. Adjusting the send level from each of the input channel adjustment units (30-1 to 30-24) to the one mixing bus (32-k); and adjusting the send level of any one of the input channel adjustment units or the output channel units. When the one mixed bus (32-k) is selected in the monitor channel selection process of selecting a signal as a monitor signal (depression of the CUE keys 224, 526, etc.) and the setting channel selection process, the process is performed in conjunction with the selection. An interlocking step of selecting a signal of the output channel section (36-k) corresponding to the one mixing bus (32-k) as the monitor signal.
Further, in the control method of the mixing system according to the second aspect, the signals of the plurality of input channels are supplied to the plurality of mixing buses (32-32) via the corresponding input channel adjusting units (30-1 to 30-24). 1-32-24), and the signals mixed in these mixing buses (32-1 through 32-24) are output via output channel sections (36-1 through 36-24) corresponding to the mixing buses. In a method for controlling a mixing system that executes an algorithm for outputting signals as signals of a plurality of output channels, a step of adjusting a frequency characteristic of an arbitrary selected channel in a selected channel control unit (300); Select a channel to be adjusted in the process from any of the input channels or the output channels (Selection of the SEL keys 222 and 516) and a monitor channel selection step of selecting a signal of any one of the input channel adjustment units or the output channel units as a monitor signal (pressing of the CUE keys 224 and 526). And, when one channel is selected in the monitor channel selection process, interlockingly selecting the one channel as an adjustment target in the selected channel control unit (300). And
Further, in the configuration of the third aspect, in the mixing system control method according to the second aspect, a first mode (LAST_CUE mode) for outputting only a signal of one channel selected as the monitor signal; Or a mode selection step of selecting one operation mode from a second mode (MIX_CUE mode) for outputting a mixed result of signals of a plurality of channels as the monitor signal (an operation of the control unit 770), The interlocking selection process is performed on condition that the first mode (LAST_CUE mode) is selected as the operation mode.
According to a fourth aspect of the present invention, there is provided a control apparatus for a mixing system, wherein the control method for a mixing system according to any one of the first to third aspects is performed.
According to a fifth aspect of the present invention, there is provided a program for executing the control method of the mixing system according to any one of the first to third aspects.
[0006]
BEST MODE FOR CARRYING OUT THE INVENTION
1． Next, a hardware configuration of a mixing system according to an embodiment of the present invention will be described with reference to FIG.
In the figure, reference numeral 2 denotes an operation panel, which is composed of various displays, operators, and the like. Here, the “operator” includes types such as an electric fader, a rotary encoder, and a key. When the electric fader is operated by the operator (operator), the operation state is output via the bus 7. The same applies to the rotary encoder and the key.
[0007]
Further, the electric fader is configured such that, when an operation command is supplied via the bus 7, the operation position is automatically set. On the other hand, the key or rotary encoder is not physically driven. However, each key has a built-in LED, and the on / off state of the operation content related to the key is displayed by turning on / off the LED. In addition, an indicator for displaying the operation amount of the rotary encoder is provided near each rotary encoder. The blinking state of the LED built in the key may be automatically set via the bus 7 in some cases.
[0008]
The display corresponding to the rotary encoder includes a plurality of LEDs arranged in a ring around the rotary encoder (for example, the rotary encoder 312 in FIG. 7), or an eight-segment LED provided near the rotary encoder (the same as the rotary encoder 312). There is a display 324) for the rotary encoder 326 in the figure. In any case, the operation amount related to each rotary encoder can be automatically displayed by these indicators. The detailed configuration of the operation panel 2 will be described later.
[0009]
Returning to FIG. 1, reference numeral 4 denotes a waveform I / O unit for inputting and outputting an analog audio signal or a digital audio signal. In the present embodiment, mixing processing, effect processing, and the like of various audio signals are all performed by digital processing. However, the audio signal input from the outside and the audio signal to be output to the outside are often analog signals. Therefore, cards having various functions such as microphone level analog input, line level analog input, digital input, analog output, and digital output are inserted into the waveform I / O unit 4 as necessary. Conversion processing is performed. A part of the analog output is emitted through the operator monitor device 16.
[0010]
Next, reference numeral 6 denotes a signal processing unit, which is constituted by a group of DSPs (digital signal processors). The signal processing unit 6 performs a mixing process and an effect process on the digital audio signal supplied via the waveform I / O unit 4, and outputs the result to the waveform I / O unit 4. Reference numeral 8 denotes another I / O unit, which inputs and outputs time code and other information to and from various external devices. In the present embodiment, remote control of an external device can be performed via the other I / O unit 8. Reference numeral 10 denotes a CPU, which controls each unit via the bus 7 based on a control program described later. Reference numeral 12 denotes a flash memory, in which a control program is stored in a program area 12a. A RAM 14 is used as a work memory of the CPU 10.
[0011]
By the way, a setting state of the mixing system according to a certain stage situation or the like is called a "scene". In the mixing system of the present embodiment, the contents of the current “scene” (current scene) are stored in the current scene area 14 a in the RAM 14. Then, the contents of the current scene area can be appropriately stored in the scene area 12b in the flash memory 12 or another storage device. The scene area 12b can store the contents of a plurality of types of scenes. Therefore, when changing the stage, the operator can reproduce a necessary scene in the current scene area with one touch.
[0012]
2． Next, the content of the algorithm realized in the signal processing unit 6 and the like will be described with reference to FIG.
In the figure, an analog input unit 22 receives a microphone-level or line-level analog audio signal, converts it into a digital audio signal, and supplies it to the signal processing unit 6. Reference numeral 24 denotes a digital input unit, which receives a digital audio signal and converts it into a format inside the signal processing unit 6. An analog output unit 44 converts a digital audio signal supplied from the signal processing unit 6 into an analog audio signal and outputs the analog audio signal to the outside. Reference numeral 46 denotes a digital output unit which converts a digital audio signal in an internal format supplied from the signal processing unit 6 into a digital audio signal in a predetermined format (AES / EBU, ADAT, TASCAM, etc.) and outputs the digital audio signal. Reference numeral 49 denotes a monitor analog output unit which converts the supplied audio signal into an analog audio signal and outputs the analog audio signal to the operator monitor device 16.
[0013]
The configuration described above is realized by the waveform I / O unit 4 which is hardware separate from the signal processing unit 6 and various cards inserted therein. It is implemented by a running program. Reference numeral 30 denotes an input channel adjustment unit that adjusts the volume and sound quality of up to 48 input channels based on the operation of the electric faders and controls on the operation panel 2. Reference numeral 28 denotes an input patch unit which assigns digital audio signals supplied from a plurality of input ports such as the input units 22 and 24 to an arbitrary input channel of the input channel adjustment unit 30. Reference numeral 26 denotes a built-in effector, which performs effect processing on audio signals of up to eight channels, and supplies the result to an input channel adjustment unit 30 via an input patch unit 28.
[0014]
A MIX bus group 32 is composed of MIX buses 32-1 to 32-24 (see FIG. 4) of the "24" system. In each of the MIX buses 32-1 to 32-24, a digital audio signal of each input channel is mixed. In each input channel, whether or not the audio signal is supplied to the MIX buses 32-1 to 32-24 can be set for each MIX bus. When the audio signal is supplied, the send level for each MIX bus is also set for each system. Can be set independently. Reference numeral 36 denotes a MIX output channel section, which performs level adjustment and sound quality adjustment of the mixing results on the MIX buses 32-1 to 32-24. Reference numeral 42 denotes an output patch unit, which allocates the adjustment result of the MIX output channel unit 36 to each of the output units 44 and 46 or an arbitrary output port of the built-in effector 26.
[0015]
Although details will be described later, each unit of the operation panel 2 is provided with a CUE key for designating whether to monitor an audio signal relating to the operation. Reference numeral 34 denotes a CUE bus, which mixes an audio signal at a location where the CUE key is turned on, and outputs a mixing result as a CUE signal. Reference numeral 38 denotes a monitor selector, which selects a monitor part of a different system from the CUE bus 34. The CUE signal and the monitor signal selected by the monitor selector 38 are further mixed in the monitor mixer 40, and the result is output via the monitor analog output unit 49.
[0016]
Next, an algorithm configuration in the input channel adjustment unit 30 and the MIX output channel unit 36 will be described with reference to FIG. In the figure, reference numeral 30-1 denotes a first input channel adjustment unit that adjusts sound quality and volume in the first input channel. Reference numeral 36-1 denotes a first MIX output channel unit for adjusting sound quality and volume in the first MIX output channel.
[0017]
Reference numeral 52 in the first input channel adjustment unit 30-1 denotes a sound quality adjustment unit that performs a limiter process, a compressor process, an equalizer process, and the like on the first input channel. An on / off switching unit 54 switches on / off of the entire first input channel. When the on / off switching unit 54 is set to the off state, no audio signal is supplied to any of the MIX buses 32-1 to 32-24.
[0018]
Reference numeral 56 denotes a volume control unit that controls the level of the audio signal of the first input channel. Reference numeral 60 denotes a CUE on / off switching unit, which switches whether or not to supply the audio signal to the CUE bus 34. Reference numeral 58 denotes a signal switching unit for a CUE signal, which is a signal before the volume adjustment by the volume adjustment unit 56 (hereinafter, referred to as pre-fade) as an audio signal output to the CUE bus 34 via the CUE on / off switching unit 60. , Or a signal after volume control (hereinafter referred to as post-fade).
[0019]
Reference numerals 62-1 to 62-24 denote signal switching units for the MIX bus, and select a signal to be output to each MIX bus from one of prefade and postfade. Send level adjustment units 64-1 to 64-24 adjust the send levels of signals output to the respective MIX buses. 66-1 to 66-24 are send on / off switching units, which turn on / off the supply of audio signals to the MIX buses 32-1 to 32-24.
[0020]
Next, inside the first MIX output channel unit 36-1, reference numeral 72 denotes a sound quality adjustment unit that performs limiter processing, compressor processing, equalizer processing, and the like on the first MIX output channel. An on / off switching unit 74 switches on / off of the first MIX output channel. Reference numeral 76 denotes a volume control unit that controls the output level of the audio signal of the first MIX output channel. Reference numeral 80 denotes a CUE on / off switching unit that switches whether to supply the audio signal of the first MIX output channel unit 36-1 to the CUE bus 34. Reference numeral 78 denotes a signal switching unit for a CUE signal, which selects one of pre-fade and post-fade audio signals as an audio signal to be output to the CUE bus 34 via the CUE on / off switching unit 80.
[0021]
The details of the algorithm of the first input channel adjustment unit 30-1 for the first input channel and the first MIX output channel unit 36-1 for the first MIX output channel have been described above. Input channel adjustment units 30-2 to 30-24 and MIX output channel units 36-2 to 36-24 similar to these are provided (not shown).
[0022]
3． Next, the overall configuration of the operation panel 2 will be described with reference to FIG. In the figure, reference numeral 100 denotes a bus selection unit, which is provided with operators and the like for selectively selecting any one of the MIX buses 32-1 to 32-24. Reference numeral 200 denotes a bus operation unit, which includes an operation unit that sets a send level from each input channel to the MIX bus selected by the bus selection unit 100 and a level of each volume adjustment unit 76 in the MIX output channel unit 36. It is configured. Reference numeral 300 denotes a selected channel control unit, which is composed of operators for performing detailed settings of the sound quality adjustment units 52 and 72 for one selected input channel or MIX output channel.
[0023]
Reference numeral 500 denotes an input channel strip unit, which includes a plurality of faders corresponding to the volume control unit 56 of the input channel, and other controls related to the input channel adjustment unit 30. Reference numeral 600 denotes an assigned channel strip unit, which is provided with controls such as faders and the like, according to assigned functions such as volume control of an input channel, volume control of a MIX output channel, or volume control of a DCA group (to be described later in detail). Perform the operation. 710 and 740 are level meters for displaying the levels of input channels, MIX output channels, and the like.
[0024]
Reference numeral 720 denotes a display (graphic display), which displays graphs and the like of various characteristics when a setting such as a limiter process, a compressor process, or an equalizer process is performed in the selected channel control unit 300. Reference numeral 730 denotes a scene selection unit for performing operations such as transferring the contents of the current scene area 14a to the scene area 12b or reproducing a scene already stored in the scene area 12b in the current scene area 14a.
[0025]
Next, a screen selection unit 750 controls a screen to be displayed on the display 720. For example, if the operator sets the compressor processing of the sound quality adjusting sections 52 and 72 in the selected channel control section 300, the display 720 is displayed on the compressor characteristic screen, and if the operator performs the equalizer processing, the display 720 is displayed on the equalizer characteristic screen. Can be arbitrarily set. A screen control unit 760 includes a cursor key for moving a cursor displayed on the display 720, a pointing device, a rotary encoder for data input, an enter key, and the like. Reference numeral 770 denotes another control unit, which includes various controls other than those described above.
[0026]
Here, when a predetermined operation is performed on the screen selection unit 750, a “preference screen” for customizing the mixing system is displayed on the display 720. On the preference screen, three buttons for turning on / off the following three types of interlocking functions are displayed, and the on / off state of these buttons can be switched by operating the screen control unit 760.
(1) Input CUE linking button: This button selects the ON / OFF state of a function (input CUE linking function) for linking the SEL key 516 with the operation of the CUE key 526 provided in the input channel strip section 500. Button.
(2) Output CUE link button: This button selects the ON / OFF state of a function (output CUE link function) of linking the SEL key 222 in conjunction with the operation of the CUE key 224 provided on the bus operation unit 200. Button.
(3) Bus selection interlocking button: This button is used to select an on / off state of a function (bus selection interlocking function) for interlocking the CUE key 224 with the operation of the MIX bus selection key 109.
[0027]
Here, either the input CUE interlocking function (1) or the output CUE interlocking function (2) and the bus selection interlocking function (3) cannot be simultaneously turned on. That is, the buttons (1) and (2) can be simultaneously set to the on state, and when the button (3) is set to the on state, the buttons (1) and (2) are automatically set to the off state. You. When any one of the buttons (1) and (2) is set to the ON state, the button (3) is automatically set to the OFF state. In addition to the buttons (1) to (3) described above, in addition to the buttons (1) to (3), on / off functions such as an interlocking function of screen switching for operation of various operators, a display function of various confirmation dialogues, a display function of various warning dialogues, etc. Several buttons are displayed to control turning off.
[0028]
3.1. Bus selector 100
Hereinafter, a main part on the operation panel 2 will be described in detail. First, a detailed configuration of the bus selection unit 100 will be described with reference to FIG.
In FIG. 5, reference numerals 109-1 to 109-24 denote MIX bus selection keys, and "24" MIX buses are provided corresponding to the "24" MIX buses 32-1 to 32-24. The MIX bus selection keys 109-1 to 109-24 are used to operate MIX buses (hereinafter, referred to as “operation target MIX buses”) operated by the rotary encoder 514, the ON key 512, and the like provided in the input channel strip unit 500. The MIX bus selection key 109-k is turned on in response to the operation (on operation) of the MIX bus selection key 109-k corresponding to the MIX bus 32-k other than the operation target MIX bus. At the same time, the MIX bus 32-k is selected as the operation target MIX bus.
[0029]
Therefore, when a plurality of MIX bus selection keys are sequentially turned on, only the MIX bus 32-k corresponding to the MIX bus selection key 109-k that was turned on last becomes the operation target MIX bus. Further, in response to the operation (off operation) of the MIX bus selection key 109-k corresponding to the MIX bus 32-k already selected as the operation target MIX bus, the MIX bus selection key 109-k is turned off and the operation target The MIX bus does not exist (non-selected state). Reference numeral 104 denotes an LED display, which displays the number (“1” to “24”) of the operation target MIX bus or a character string “−−” indicating a non-selected state.
[0030]
By the way, although details will be described later, in the present embodiment, an operation mode is selected from the “normal mode”, the “FLIP mode”, the “HA_REMOTE mode”, and the “PAN mode” for the input channel strip section 500. Has become possible. The details of each operation mode will be described later. Reference numeral 102 denotes a FLIP key, reference numeral 106 denotes an HA_REMOTE key, and reference numeral 108 denotes a PAN key. Each of the ON / OFF states of the “FLIP mode”, “HA_REMOTE mode”, and “PAN mode” is toggled, and a corresponding operation mode is set. , The built-in LED is turned on. Here, the FLIP mode, the PAN mode, and the HA_REMOTE mode can be exclusively set to the ON state. That is, when the corresponding operation mode is turned on by operating the keys 102, 106, and 108, the other operation modes are forcibly turned off. If all of these “3” modes are in the off state, the operation mode becomes the normal mode. The selection of the MIX bus to be operated by the MIX bus selection keys 109-1 to 109-24 can be executed in the HA_REMOTE mode or the PAN mode. The result is that the input channel strip unit 500 is used only in the normal mode and the FLIP mode. Is reflected in
[0031]
3.2. Input channel strip section 500
Next, a detailed configuration of the input channel strip section 500 will be described with reference to FIG. The input channel strip section 500 is provided with “24” channel strips 510-1 to 510-24. As described above, the number of input channels is “48”, but the input channels are divided into “2” layers for each “24” channels. When one of the layers is selected, the input channels belonging to the selected layer are assigned to the channel strips 510-1 to 510-24, and the volume and the like can be adjusted. Hereinafter, the input channels assigned to the individual channel strips are referred to as “assigned input channels”. Since each of the channel strips 510-1 to 510-24 has the same configuration, the detailed configuration will be described below using the channel strip 510-1 as an example.
[0032]
Inside the channel strip 510-1, a rotary encoder 514 functions as follows based on the operation mode described above. That is, the rotary encoder 514 serves as an operator for setting a send level to the operation target MIX bus (gain of the send level adjustment units 64-1 to 64-24 in FIG. 4) in the normal mode, and in the PAN mode. It becomes an operator for adjusting the PAN balance of each channel. In the HA_REMOTE mode, it becomes an operator for remotely operating other devices connected to the I / O unit 8, and in the FLIP mode, the level of the assigned input channel (FIG. 4). Of the volume adjustment unit 56 at the same time.
[0033]
Reference numeral 512 denotes an ON key, which functions as follows based on the operation mode. That is, the ON key 512 is a key for switching the ON / OFF state of the send to the operation target MIX bus (the state of the signal switching units 62-1 to 62-24 in FIG. 4) in the normal mode, and in the FLIP mode. It is a key for switching the on / off state of the assigned input channel (the state of the on / off switching unit 54 in FIG. 4), does not function in the PAN mode, and does not function in the HA_REMOTE mode in other devices connected to the I / O unit 8. It is a key for remote operation for operating a predetermined on / off state. The ON key 512 has a built-in LED. In any mode, the LED is turned on when the corresponding state is turned on, and turned off when the corresponding state is turned off.
[0034]
Reference numeral 516 denotes a SEL key, which instructs to set a channel (hereinafter, referred to as “selected channel”) to be operated in the selected channel control unit 300, the bus operation unit 200 (mix send mode), and the like as an assigned input channel. Key to do. Here, the SEL keys 516 are provided on all the channel strips 510-1 to 510-24, but only one of the SEL keys can be selectively turned on. Therefore, when the SEL key 516 is depressed in one of the channel strips and is set to the on state, the SEL key 516 of the other channel strip is forcibly set to the off state.
[0035]
A display 518 displays the channel name (up to four characters) of the assigned input channel. Reference numeral 520 denotes an ON key, which functions as follows based on the operation mode. That is, in the FLIP mode, the ON key 520 is a key for switching the ON / OFF state of the send to the operation target MIX bus (the state of the signal switching units 62-1 to 62-24 in FIG. 4). In this operation mode, the key is used to switch the on / off state of the assigned input channel (the state of the on / off switching unit 54 in FIG. 4). Note that the ON key 520 is also provided with an LED that is turned on / off according to the corresponding on / off state.
[0036]
An electric fader 524 functions as follows based on an operation mode. That is, in the FLIP mode, the electric fader 524 serves as an operator for setting a send level to the MIX bus to be operated, and in another operation mode, the level of the assigned input channel (the level of the volume adjustment unit 56 in FIG. 4). Gain). Reference numeral 526 denotes a CUE key, which switches an on / off state of the CUE of the assigned input channel. When the CUE is turned on, the audio signal of the assigned input channel is supplied to the CUE bus 34.
[0037]
Here, there are two types of operation modes of the CUE key 526 and other CUE keys to be described later, a “MIX_CUE mode” and a “LAST_CUE mode”. The MIX_CUE mode is an operation mode that allows a plurality of CUE keys to be turned on, and audio signals related to the plurality of CUE keys set to the on state are mixed on the CUE bus 34, and the result is used as a CUE signal. Will be output. On the other hand, the LAST_CUE mode is an operation mode in which only the audio signal related to the last CUE key set to the on state is supplied to the CUE bus 34, and the audio signal related to another CUE key is automatically set to the off state. . Note that an operator for selecting the MIX_CUE mode or the LAST_CUE mode is provided in the other control unit 770.
[0038]
Further, when the input CUE linking function is turned on, in the LAST_CUE mode, when the CUE key 526 of any of the channel strips 510-1 to 510-24 is turned on, the SEL key 516 is also linked. Set to ON state. Here, there is one of the features of the present embodiment. That is, in the case where the LAST_CUE mode is selected, if the CUE key 526 is operated in any one of the channel strips and the channel strip is turned on, the state of the input channel assigned to the channel strip is automatically transmitted to the selected channel control unit 300. Will be reflected in However, on the contrary, even when any of the SEL keys 516 is operated, the ON / OFF state of the CUE keys 526 belonging to the same channel strip is characterized in that it is not linked.
[0039]
The reason why such an operation method is employed in the present embodiment will be described.
First, the case where the operator sets the CUE key 526 to the ON state in the LAST_CUE mode in a certain channel strip is a case where “only the audio signal of the assigned input channel is to be monitored intensively”. In most cases, “when it is desired to monitor only a specific input channel” is “when the sound quality of the input channel is adjusted”, that is, when the selected input channel is selected by the selected channel control unit 300. It is clear from experience that this is equivalent to "if you want to set a channel."
[0040]
Therefore, in this embodiment, if only the CUE key 526 is operated in such a case, the channel to be monitored by the CUE bus 34 and the operation target channel in the selected channel control unit 300 and the bus operator unit 200 (mix send mode) are changed. At the same time, the switching is performed, thereby reducing the operation labor of the operator. On the other hand, the reason that the CUE key 526 is not linked based on the operation of the SEL key 516 is that the channel to be monitored by the CUE bus 34 is changed even when the operator switches the channel to be operated in the selected channel control unit 300. This is because there are many cases where switching should not be performed. For example, this corresponds to a case where the operator wants to adjust a specific input channel in the selected channel control unit 300 while monitoring the overall sound quality and volume.
[0041]
3.3. Assigned channel strip section 600
Next, a detailed configuration of the assigned channel strip section 600 will be described with reference to FIG.
In the figure, 630-1 to 630-8 are "8" channel strips, and each channel strip has the same configuration. Various functions can be assigned to these channel strips. A state in which functions are assigned to channel strips 630-1 to 630-8 on a one-to-one basis is referred to as "1 fader mode", and a total of "7 fader mode" functions can be assigned to these channel strips. A fader mode selection unit 610 selects one of the fader modes using keys 612 to 622 provided therein. The keys 612 to 622 are alternatively set to the ON state.
[0042]
Functions (operation modes) assigned to each channel strip include volume control of an input channel (input channel mode), volume control of a MIX output channel (MIX output channel mode), and gain control of an internal effector 26 (see FIG. 2) (effector). Mode) and DCA level adjustment (DCA mode). First, the volume control of the input channels can be performed in the input channel strip unit 500 described above. However, by assigning the input channels to the channel strips 630-1 to 630-8, the input channels belonging to the unselected layers are assigned. The volume can be adjusted by the fader.
[0043]
Further, a rotary encoder is provided in the bus operator unit 200 (details will be described later), which can adjust the volume of each MIX output channel. By allocating to any channel strip, the operability of the MIX output channel can be enhanced. Next, a description will be given of “DCA (Ditigal Controlled Amplifier or Ditigal Controlled Attenuator). In DCA, a common fader (DCA fader) different from the fader of each input channel is assigned to a plurality of input channels. , Multiplying a gain set by a fader of each input channel by a gain set by a fader of each input channel, thereby determining the gains of the plurality of input channels. This is used for controlling the volume of large instruments and, for example, some parts of an orchestra.
[0044]
Generally, performance sounds of a large musical instrument such as a piano are collected by a plurality of microphones. Each of these microphones is assigned to an individual input channel in order to perform balance adjustment. Then, these input channels are assigned to one DCA fader. Thus, the balance between the audio signals collected from the individual microphones is adjusted by the faders of each input channel, and the volume of the entire instrument is adjusted by the DCA fader.
[0045]
Therefore, when the function of any one of the channel strips 630-1 to 630-8 is assigned to DCA, the level of the input channel belonging to the DCA group, that is, the level set for the volume control unit 56 (see FIG. 4) becomes , And the multiplication result of the operation amount of the input channel-specific fader and the operation amount of the DCA fader.
[0046]
Next, inside the channel strip 630-1, a display 631 displays a channel name (up to four characters) assigned to the channel strip. A DCA_MUTE key 632 functions only when the operation mode is the DCA mode. That is, when the DCA_MUTE key 632 is set to the ON state in the DCA mode, the levels of the input / output channels included in the DCA group (the gain of the volume adjustment unit 56) are all set to “0”.
[0047]
An electric fader 634 adjusts a DCA level, an input / output channel level, and the like according to a function assigned to a channel strip. Reference numeral 636 denotes a CUE key, which is a key for controlling on / off supply of an output signal of a corresponding input / output channel or effector to the CUE bus 34 in an operation mode other than the DCA mode. In the DCA mode, the CUE key 636 is a key for simultaneously turning on / off the CUE on / off switching units 60 (see FIG. 4) for all input channels belonging to the DCA group. The other channel strips 630-2 to 630-8 provided in the assigned channel strip section 600 have the same configuration as the channel strip 630-1.
[0048]
3.4. Selected channel control unit 300
Next, the details of the selected channel control unit 300 will be described with reference to FIGS. First, in FIG. 7, reference numeral 310 denotes an attenuator unit that performs attenuation, phase switching, insertion of an insertion effect, and the like in the sound quality adjustment units 52 and 72 of the selected channel. Reference numeral 320 denotes a noise gate unit which sets a noise gate in the sound quality adjustment units 52 and 72. Reference numeral 340 denotes a level meter, which displays the audio signal level of the selected channel.
[0049]
Reference numeral 350 denotes a channel selection unit for designating a selected channel. The selected channel can be specified by the SEL key 516 or the like provided on the input channel strip section 500, but can also be specified by the channel select section 350. The display 352 displays the channel number of the selected channel inside the channel selection section 350. An INC key 354 increases the number of the selected channel by “1”. Reference numeral 356 denotes a DEC key, which decreases the number of the selected channel by “1”.
[0050]
Reference numeral 364 denotes a COPY key which, when operated, copies the setting contents of the selected channel control unit 300 to a copy buffer (a predetermined area in the RAM 14). Reference numeral 368 denotes a PASTE key, which reflects the setting contents stored in the copy buffer to the selected channel control unit 300 as the setting contents of the selected channel. Reference numeral 370 denotes a group setting unit for performing operations such as joining a selected channel to a DCA group or the like or excluding a selected channel from a DCA group or the like. A delay unit 380 sets the delay characteristics of the audio signal.
[0051]
Next, in FIG. 8, reference numeral 400 denotes a compressor unit, which sets a built-in compressor in the sound quality adjustment units 52 and 72 of the selected channel. Reference numeral 430 denotes an equalizer unit, which is a four-band frequency composed of a treble section (HIGH), a high / middle section (HIGH MID), a low / middle section (LOW MID), and a low section (LOW) in the equalizers of the sound quality adjustment sections 52 and 72. This is for setting the characteristics. Here, the rotary encoder 438 sets the center frequency of the high-pitched sound section (HIGH), and the set frequency is displayed on the display 434. The rotary encoder 437 adjusts the gain at the center frequency of high sound (HIGH), and the rotary encoder 432 adjusts the Q value. These manipulated variables are displayed by LEDs arranged in a ring around the rotary encoder. Similar controls and indicators are provided for the high / middle sound section (HIGH MID), the low / middle sound section (LOW MID), and the low sound section (LOW). A high-pass filter setting unit 480 sets a high-pass filter applied to the audio signal.
[0052]
3.5. Bus operation unit 200
Next, a detailed configuration of the bus operator unit 200 will be described with reference to FIG. In the bus operator section 200, an operation mode of “mix send mode” and “mix master mode” can be selected. Here, the mix send mode is an operation mode for controlling a signal level (send level) supplied from the input channel to a plurality of MIX buses when any of the input channels is a selected channel. For example, if the first input channel is selected by the SEL key 516 of the input channel strip section 500, the plurality of send level adjustment sections 64-1 to 64-24 in the input channel adjustment section 30-1 (see FIG. 4). ) Is adjusted in the bus operation unit 200. The mix master mode is a mode for adjusting the level and the like of the volume control unit 76 in each of the MIX output channel units 36-1 to 36-24. If any output channel is the selected channel, only the mix master mode can be selected as the operation mode, and the mix send mode cannot be selected. If the selected channel is changed to any one of the MIX output channels while the mix send mode is selected, the operation mode is such that neither the mix send mode nor the mix master mode is selected. The operation in the unit 200 is invalidated.
[0053]
202 is a mix send key, 204 is a mix master key, and switches the operation mode to “mix send mode” or “mix master mode” each time the key is pressed, and when the corresponding operation mode is selected, the internal The LED is turned on. Reference numerals 210-1 to 210-24 denote bus control units, which correspond to the MIX buses 32-1 to 32-24 in any operation mode. Inside the bus control unit 210-1, 216 is an ON key, 218 is a rotary encoder, 224 is a CUE key, and 222 is a SEL key. It should be noted that the other bus controllers 210-2 to 210-24 are provided with similar operators. The functions of these controls will be described in detail below for each operation mode.
[0054]
3.5.1. Mix Send Mode First, in the “mix send mode”, the bus control units 210-n (where n = 1 to 24) are associated with the MIX bus 32-n, and the bus control unit 210-n is a selected channel. This is a group of operators for controlling the signal supply from the m-th input channel to the MIX bus 32-n. In this operation mode, the ON key 216 toggles on / off of signal supply from the m-th input channel to the MIX bus 32-n, that is, on / off state of the signal switching unit 62-n in the input channel adjustment unit 30-m. Become a key.
[0055]
Further, the rotary encoder 218 is an operator for adjusting the level of the send level adjuster 64-n in the input channel adjuster 30-m. In this mode, the CUE key 224 does not function, and the key is always turned off. The function of the SEL key 222 is the same as the function of the MIX bus selection keys 109-1 to 109-24 provided in the bus selector 100, and the SEL key 222 is linked with the corresponding MIX bus selection key 109-n. Key to select the operation target MIX bus. However, the SEL key 222 is always off, and the display of the operation target MIX bus is performed only by the MIX bus selection key 109-n.
[0056]
3.5.2. Mix Master Mode Next, in the mix master mode, the bus control units 210-k (where k = 1 to 24) are associated with the MIX output channel units 36-k, and control in the MIX output channel units 36-k is performed. Is a group of operators that perform. In this operation mode, the ON key 216 is a key that toggles the on / off state of the entire MIX output channel section 36-k, that is, the state of the on / off switching section 74. Further, the rotary encoder 218 serves as an operator for adjusting the level of the volume control unit 76 in the MIX output channel unit 36-k.
[0057]
In this operation mode, the CUE key 224 is a key that toggles the on / off state of the CUE on / off switching unit 80, that is, whether or not to supply the audio signal of the MIX output channel unit 36-k to the CUE bus 34. Become. The SEL key 222 is a key for setting the MIX output channel unit 36-k as a selected channel (a channel to be operated by the selected channel control unit 300 and the like). As described above, when any one of the MIX output channels is the selected channel, the operation mode of the bus operation unit 200 cannot be set to the mix send mode.
[0058]
Here, the operation mode of the CUE key 224 is selected from a LAST_CUE mode or a MIX_CUE mode, like the other CUE keys described above. Here, one of the features of the present embodiment is the operation in the LAST_CUE mode when the output CUE linking function is turned on. That is, when the output CUE linking function is on and the LAST_CUE mode is selected, if the CUE key 224 is set to the on state in any one of the bus control units 210-k, the bus control unit 210-k The SEL key 222 belonging to is also set to the on-state in conjunction with it. However, conversely, even when any of the SEL keys 222 is operated, the ON / OFF state of the CUE keys 224 belonging to the same bus control unit is characterized in that it is not linked.
[0059]
The reason for employing this operation method in the present embodiment is the same as the reason for employing the operation method of the SEL key 516 and the CUE key 526 in the input channel strip section 500 described above. That is, the case where the operator sets the CUE key 224 to the ON state in the LAST_CUE mode in the certain bus control unit 210-k is, in most cases, "the case where the sound quality of the MIX output channel unit is adjusted".
[0060]
Therefore, in the present embodiment, similarly to the case of the input channel strip section 500, if only the CUE key 224 is operated in such a case, the channel to be monitored by the CUE bus 34 and the channel to be operated by the selected channel control section 300 are changed. At the same time, the switching is performed, thereby reducing the operation labor of the operator. On the other hand, it is conceivable that the operator wants to adjust a specific MIX output channel in the selected channel control unit 300 while monitoring the overall sound quality and volume, so that even if the SEL key 222 is operated, the CUE key 224 is not operated. The status is not linked.
[0061]
Further, the following interlocking function of the CUE key 224 that operates irrespective of the LAST_CUE mode or the MIX_CUE mode also has a feature of the present embodiment.
(Interlocking Function 1) First, when any one of the MIX bus selection keys 109-k is set to the ON state in the bus selecting section 100 when the bus selection interlocking function is ON, the MIX bus 32-k. When the CUE on / off switching unit 80 of the MIX output channel unit 36-k corresponding to the above is turned on (the linked CUE is on) and the bus operator unit 200 is in the mix master mode, the corresponding bus control unit 210 The CUE key 224 belonging to -k is turned on.
[0062]
(Interlocking function 2) If the CUE (existing CUE) of any input channel or MIX output channel is already on when the MIX bus selection key 109-k is turned on, the existing CUE is temporarily released. Instead, the linked CUE of the MIX output channel unit 36-k is turned on. Further, when another MIX bus selection key 109-j is turned on in this state, the immediately preceding interlocked CUE is released, and the interlocked CUE of the MIX output channel unit 36-j is turned on instead.
[0063]
(Interlocking function 3) When the MIX bus selection key 109-k of the operation target MIX bus is turned off while the interlocking CUE is on, the interlocking CUE is released. Here, when the existing CUE is temporarily released at the time of starting the linked CUE, the temporarily released existing CUE is restored at that time.
[0064]
(Interlocking function 4) When the interlocking CUE is on and any one of the input channels or the MIX output channel CUE keys 526 to 224 is turned on, the interlocking CUE is released and turned on. Only the CUE corresponding to the CUE key is turned on.
[0065]
Hereinafter, the significance of providing each function will be described.
(About interlocking function 1)
In a conventional mixing system, when adjusting a monitor signal returned to a performer in a concert or a monitor signal returned to a performer of a program, the monitor signal is mixed by operating a MIX bus selection key 109-k. After selecting the MIX bus 32-k as the operation target MIX bus, the CUE key 224 in the bus control unit 210-k corresponding to the operation target MIX bus must be further operated. In the mixing system of the present embodiment, by setting the bus selection interlocking function to the ON state, it becomes possible to simultaneously specify the operation target MIX bus and set the interlocking CUE of the operation target MIX bus.
[0066]
(About interlocking function 2)
When the interlocking function 1 is executed, even if the CUE signal in the LAST_CUE mode or the MIX_CUE mode has already been designated, the existing CUE is released and the operation target MIX is released according to the ON operation of the MIX bus selection key 109-k. A single coordinated CUE can be set for the bus.
[0067]
(About interlocking function 3)
Further, when the off operation of the MIX bus selection key 109-k is executed, the linked CUE is released, and the state of the CUE before the linked CUE is executed is restored. Therefore, even if the operator receives a monitor signal adjustment request by interruption while performing a normal operation, the previous operation can be started immediately after the monitor signal adjustment. Since the monitor signal adjustment request is a temporary operation and is generated at irregular intervals, the operator's labor can be greatly reduced by quickly switching between the monitor signal adjustment and the normal operation. .
[0068]
(About interlocking function 4)
It is also possible to set a new CUE state by operating the CUE keys 526 and 224 of the input channel or the MIX output channel. Further, since the CUE keys 526 and 224 are toggle keys, the new CUE state can be canceled by operating the same CUE key continuously, and all CUEs can be set to the released state. it can.
[0069]
3.5.3. As described above regarding the relationship between the bus operation unit 200 and other parts, in the bus operation unit 200, the bus control units 210-1 to 210-24 are arranged in 8 rows and 3 columns. That is, the bus control units 210-1 to 210-8 are sequentially arranged in the top row, the bus control units 210-9 to 210-16 are sequentially arranged in the second row, and the bus control unit 210-210 is arranged in the bottom row. 17 to 210-14 are sequentially arranged. With this arrangement, the operator can very easily specify the bus control units 210-1 to 210-24 corresponding to the input channels or the MIX buses to be adjusted.
[0070]
In this embodiment, the bus selector 100, the bus operator 200, the selected channel controller 300, and the display 720 are sequentially arranged from left to right in parallel with the input channel strip unit 500. one of. First, when the setting of the limiter processing or the like is performed in the selected channel control unit 300, a graph of the set characteristics is displayed on the display 720 adjacent to the selected channel control unit 300. Accordingly, the operator can set the characteristics while easily comparing the relationship between the operation position of each operation element in the selected channel control unit 300 and the graph of the characteristics being set. On the other hand, since the settings in the bus operation unit 200 are gains and the like, it is not necessary to compare any graph with the operation contents of the bus operation unit 200. Therefore, even if the distance between the bus operation unit 200 and the display 720 is large, there is almost no trouble.
[0071]
By the way, in a conventional mixing system (for example, a mixing system described in Non-Patent Document 1), an operation group for setting a send level for a plurality of MIX buses, that is, an operation group irrelevant to the display content of the display 720. Since the child group was included in the selected channel control unit 300, the number of operators in the selected channel control unit 300 increased, and there was a problem that the operation was complicated and difficult to use. Furthermore, in the technique disclosed in Non-Patent Document 1, the selection channel control unit for the input channel and the selection channel control unit for the MIX output channel are separately provided, so that the number of operators is further increased. There was also a problem.
[0072]
On the other hand, according to the present embodiment, the group of operators conventionally set in the selected channel control unit 300, that is, the group of operators for setting the send levels for a plurality of MIX buses, It is independent of the control unit 300 and is arranged next to the selected channel control unit 300 and away from the display 720. This makes it easier for the operator to understand the arrangement of the operators, and can reduce the distance of the viewpoint movement.
[0073]
Furthermore, in the present embodiment, by switching the operation mode, the bus operation unit 200 is controlled to “control a signal to be transmitted from one selected channel to a plurality of MIX buses” and to “control a plurality of MIX buses. Since the bus control unit 200 can be shared for "control of the signal transmitted from the MIX output channel", the number of controls can be significantly reduced, and the operability can be further improved. Moreover, these two types of signal control are controls respectively corresponding to the plurality of MIX buses 32-1 to 32-24, and the bus control unit 210-k corresponding to an arbitrary MIX bus 32-k operates. It is constant regardless of the mode. Therefore, according to the present embodiment, although the plurality of functions corresponding to the operation modes are assigned to the common operator, the correspondence between the target MIX bus and the operator is clear and easy to understand. The effect is achieved.
[0074]
Further, in the present embodiment, operators corresponding to the respective MIX buses of the bus operator unit 200 are arranged in eight rows and three columns. This arrangement is exactly the same as the arrangement of the MIX bus selection keys 109-1 to 109-24 in the bus selection unit 100 for switching the functions of the rotary encoder 514 and the like of the input channel strip unit 500. Therefore, when the operator operates the bus selection unit 100 after operating the bus operation unit 200, or when operating in the reverse order, the relationship between each individual operation unit and the corresponding MIX bus can be easily visually determined. Can be recognized. Further, when the operation mode of the bus operation unit 200 is the mix send mode, the SEL key 222 in the bus operation unit 200 is the same as the MIX bus selection keys 109-1 to 109-24 in the bus selection unit 100. Function. Thereby, the case where the send level adjustment from one selected channel to a plurality of MIX buses in the bus operator unit 200 and the send level adjustment to one MIX bus by the rotary encoder 514 in the input channel strip unit 500 are alternately performed In this case, the present embodiment can exhibit high operability.
[0075]
Four. Operation of the embodiment
4.1. General Operation Next, the operation of the mixing system of this embodiment will be described.
First, in the mixing system, when an operation event of an operation element such as a fader, a rotary encoder, or a key occurs, a routine corresponding to the operation content is started. In particular, when an operation event related to general volume / tone control (excluding a special operation event such as scene reproduction, etc.) occurs, the operation event routine shown in FIG. 11 is started.
[0076]
In the figure, when the processing proceeds to step SP2, the contents of the current area including the current scene area 14a are updated based on the contents of the operation. For example, when an electric fader or a rotary encoder is operated, control data (level data, frequency data, etc.) corresponding to an operation amount after the operation is stored in a corresponding area of a current area. The on / off state after the operation is stored. Next, when the process proceeds to step SP4, various parameters in the mixing algorithm (see FIGS. 3 and 4), that is, the contents of the parameter register provided in the signal processing unit 6 are updated based on the current area.
[0077]
Next, when the process proceeds to step SP6, various settings on the operation panel 2 are executed based on the contents of the updated current area. For example, turning on / off an LED inside a key, turning on / off an LED around a rotary encoder, changing display contents of various displays, driving an electric fader, and the like are executed. In the mixing system according to the present embodiment, three types of interlocking, an input CUE interlocking function, an output CUE interlocking function, and a bus selection interlocking function, are possible, but all of the interlocking processes are performed in step SP2. That is, in step SP2, based on the operation content of the operated operator, the control data corresponding to the operator in the current area is updated, and the interlocking function related to the operator is set to the ON state. It is determined whether or not the control data is on, and if it is set to the ON state, the control data of another operator to be linked is also updated according to the link function.
[0078]
4.2. Specific Operation Example Next, a typical operation example in the present embodiment will be specifically described.
As an example, it is assumed that the second MIX output channel is assigned as a monitor signal for a certain performer on the stage. Then, it is assumed that there is a request for the monitor signal, "I want the volume to be raised as a whole and the percussion sound to be dropped." The operation of the operator to satisfy such a demand is as follows.
[0079]
First, when the operator presses the mix master key 204 on the bus control unit 200, the operation mode of the bus control unit 200 is set to the mix master mode, and each bus control unit 210-k has a MIX output channel unit 36-k. Is reflected. That is, the lighting state of the LEDs around the rotary encoder 218 in each bus control unit 210-k changes according to the gain set in the volume control unit 76 (see FIG. 4) in each MIX output channel unit 36-k. Is set.
[0080]
Next, when the operator turns on the MIX bus selection key 109-2 in the bus selection unit 100, the second MIX output channel corresponding to the MIX bus selection key 109-2 is selected as the MIX bus to be operated. At this time, if the bus selection interlocking function is set to the on state, the CUE on / off switching unit 80 of the MIX output channel unit 36-2 is automatically set to the on state as the interlocked CUE. That is, the monitor signal of the second MIX output channel is emitted from the headphone or the monitor speaker.
[0081]
If the operation mode of the bus operation unit 200 is set to the mix master mode, the CUE key 224 of the bus control unit 210-2 is automatically turned on. The existing CUE state before the linked CUE is set is temporarily stored in a predetermined area in the RAM 14. Further, when the second MIX output channel is set as the operation target MIX bus, if the operation mode of the input channel strip unit 500 is the normal mode, the rotary encoder 514 included in each of the channel strips 510-1 to 510-24 is set to the rotary encoder 514. Reflects the send level from each input channel to the second MIX output channel at that time.
[0082]
Therefore, the operator can adjust the overall volume of the second MIX output channel by operating the rotary encoder 218 in the bus control unit 210-2 corresponding to the second MIX output channel. Further, by operating the rotary encoder 514 of the channel related to “percussion” among the input channels, the send level of “percussion” can be reduced. Since the CUE on / off switching section 80 of the MIX output channel section 36-2 is automatically set to the on state as the linked CUE, it is possible to perform these operations while actually listening to the monitor sound of the second MIX output channel. it can.
[0083]
Then, after the setting of the second MIX output channel is completed, when the operator presses the MIX bus selection key 109-2 again (off operation), the CUE state before the linked CUE is set is read from the predetermined area in the RAM 14. And is reproduced on the operation panel 2. As a result, the operator can quickly continue the adjustment or the like that has been performed before.
[0084]
Five. Modifications The present invention is not limited to the above-described embodiment, and various modifications are possible as follows, for example.
(1) In each of the above embodiments, the mixing system was controlled by a program operating on the CPU 10, but only this program was stored in a recording medium such as a CD-ROM or a flexible disk and distributed, or distributed through a transmission path. You can also.
[0085]
(2) In the above embodiment, the bus control units 210-1 to 210-24 are arranged in three rows and eight columns, but the arrangement direction of the bus control units 210-1 to 210-24 is not limited to this. Not something. That is, if P and Q are arbitrary natural numbers equal to or greater than “2” and “Bus control units” provided by “P × Q” are arranged in horizontal P rows and vertical Q columns, all of them fall within the scope of the present invention. included. Further, it is more preferable that both P and Q be natural numbers equal to or greater than “3”, since the arrangement shape of the entire bus control units 210-1 to 210-24 can be made closer to a square shape. Similarly, in the bus selection unit 100, the MIX bus selection keys 109-1 to 109-24 are arranged in three rows and eight columns, but R and S are set to any natural numbers equal to or more than “2” and “R × S If all the MIX bus selection keys 109-1 to 109-24 provided only in "?" Are arranged in the horizontal R rows and the vertical S columns, they are all included in the scope of the present invention. Also in this case, it is more preferable to set R and S to be natural numbers equal to or more than "3" because the arrangement of the MIX bus selection keys 109,...
[0086]
(3) In the above embodiment, the CUE key 526 is not linked by the operation of the SEL key 516, and the CUE key 224 is not linked by the operation of the SEL key 222. This is because, as described above, the operator adjusts a specific MIX output channel in the selected channel control unit 300 while monitoring the overall sound quality and volume. However, depending on the usage of the mixing system, it may be desirable to link these keys,
By operating the SEL key 222 or 516, the CUE key 224 or 526 may be linked.
[0087]
(4) Further, according to the bus selection interlocking function of the above embodiment, the CUE on / off switching unit 80 in the MIX output channel unit 36-k responds to both the ON operation and the OFF operation of the MIX bus selection key 109-k. Although the states are linked, the state of the CUE on / off switching unit 80 is set to the on state in conjunction with the "only" on operation of the MIX bus selection key 109-k, and is not linked with the off operation. It may be.
[0088]
(5) In the above embodiment, each unit of the mixing system is controlled by the program stored in the flash memory 12, but only this program is stored in a recording medium such as a CD-ROM or a flexible disk and distributed. Alternatively, it can be distributed through a transmission path.
[0089]
【The invention's effect】
As described above, according to the present invention, when one mixed bus is selected in the setting channel selection process, the signal of the output channel section corresponding to the one mixed bus is selected as a monitor signal in conjunction with the selection. Alternatively, since the adjustment target channel in the selected channel control unit is automatically selected in conjunction with the monitor channel selection process, it is possible to efficiently set the mixing state of multi-system signals.
[Brief description of the drawings]
FIG. 1 is an overall block diagram of a mixing system according to an embodiment of the present invention.
FIG. 2 is an overall plan view of an operation panel 2 of the mixing system according to one embodiment.
FIG. 3 is an overall block diagram of a mixing algorithm executed in a signal processing unit 6 and the like.
FIG. 4 is a block diagram of a main part of a mixing algorithm.
FIG. 5 is a plan view of the bus selector 100.
FIG. 6 is a plan view of the bus operator unit 200.
FIG. 7 is a plan view (1/2) of a selection channel control unit 300;
FIG. 8 is a plan view (2/2) of the selected channel control unit 300;
FIG. 9 is a plan view of an input channel strip unit 500.
FIG. 10 is a plan view of an assignment channel strip unit 600.
FIG. 11 is a flowchart of a control program executed by the CPU 10;
[Explanation of symbols]
2: operation panel, 4: waveform I / O section, 6: signal processing section, 7: bus, 8: other I / O section, 10: CPU, 12: flash memory, 12a: program area, 12b: scene area, 14: RAM, 14a: current scene area, 16: monitor device for operator, 22: analog input unit, 24: digital input unit, 26: built-in effector, 28: input patch unit, 30: input channel adjustment unit, 32: MIX bus group, 34: CUE bus, 36: MIX output channel section, 38: monitor selector, 40: monitor mixer, 42: output patch section, 44: analog output section, 46: digital output section, 49: monitor Analog output unit, 54: On / off switching unit, 56: Volume adjustment unit, 58: Signal switching unit, 60: CUE on / off switching unit, 62-1 to 62-24: Signal off , 64-1 to 64-24: Send level adjusting section, 66-1 to 66-24: Send on / off switching section, 74: On / off switching section, 76: Volume adjusting section, 78: Signal switching section, 80: CUE on / off Switching section, 100: bus selection section, 102: FLIP key, 104: LED display, 106: HA_REMOTE key, 108: PAN key, 109,..., 109: MIX bus selection key, 200: bus operation section, 202 : Mix send key, 204: mix master key, 216: ON key, 218: rotary encoder, 222: SEL key, 224: CUE key, 300: selected channel control section, 500: input channel strip section, 510: channel strip, 512 : ON key, 514: Rotary encoder, 516: SEL key, 18: display, 520: ON key, 524: electric fader, 526: CUE key, 600: assigned channel strip section, 720: display, 730: scene selection section, 750: screen selection section, 760: screen control section, 770 : Other control unit.

Claims (5)

The signals of the plurality of input channels are supplied to the plurality of mixing buses via the corresponding input channel adjustment units, and the signals mixed in the respective mixing buses are output to the plurality of output buses via the output channel units corresponding to the respective mixing buses. In a control method of a mixing system for executing an algorithm for outputting as a channel signal,
A setting channel selecting step of selecting one mixed bus to be adjusted from among the plurality of mixed buses,
A step of adjusting a send level from each of the input channel adjusting units for the selected one mixing bus by a send level adjusting operator provided for each of the input channels;
A monitor channel selecting step of selecting a signal of any one of the input channel adjusting units or the output channel units as a monitor signal;
When the one mixed bus is selected in the setting channel selecting step, an interlocking step of selecting a signal of an output channel unit corresponding to the one mixed bus as the monitor signal in conjunction therewith is provided. Control method of the mixing system. The signals of the plurality of input channels are supplied to the plurality of mixing buses via the corresponding input channel adjustment units, and the signals mixed in the respective mixing buses are output to the plurality of output buses via the output channel units corresponding to the respective mixing buses. In a control method of a mixing system for executing an algorithm for outputting as a channel signal,
Adjusting a frequency characteristic of the selected one channel in the selected channel control unit;
A setting channel selection step of selecting a channel to be adjusted in the selection channel control step from any of the input channels or the output channels;
A monitor channel selecting step of selecting a signal of any one of the input channel adjusting units or the output channel units as a monitor signal;
The method according to claim 1, further comprising: an interlocking selection step of, when one channel is selected in the monitor channel selection step, selecting the one channel as an adjustment target in the selected channel control unit in association with the selection. Control method. One operation mode is selected from a first mode for outputting only a signal of one channel selected as the monitor signal and a second mode for outputting a mixed result of signals of a plurality of channels as the monitor signal. Further comprising a mode selection process,
The method according to claim 2, wherein the interlocking selection step is performed on condition that the first mode is selected as the operation mode. A control device for a mixing system, which executes the method for controlling a mixing system according to claim 1. A program for executing the method for controlling a mixing system according to claim 1.

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